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The optic tectum of gymnotiform teleosts Eigenmannia virescens and Apteronotus leptorhynchus: A golgi study
THE OPTIC TECTUM OF GYMNOTIFORM TELEOSTS EIGENMANNIA VIRESCENS AND APTERONOTUS LEPTORH~NCHUS~ A GOLGI STUDY E. SAS and L. MALE-R Dcpartmcnt
of Anatomy.
Faculty
of Health Sciences, University of Ottawa. Ott;twa. Ontario KlH 8M5. Canada
451 Smjth
Rnxi.
Abstract Golg~. Nissl, Bielschowsky and cholinesterase techniques have been used to analyze the optic tectum of the ~cakly clcctric teleost tish Ei~mnranniu rirrscens and Aprcronorus keprorh~nc~huc. Six layer\ r~rc rcad~ly dlstlnguished: a fairly thick stratum marginale. a narrow stratum opticum and stratum librosum et grlseum supcrficiale. a well-developed stratum griseum centrale, a stratum album centralc and ii compact stratum prrivcntriculare. Fifty-six neuronal types are present. In regard to comparative aspects of tectai organization. it became apparent that although most neuron~~l rqpcs are similar to those reported m other telcostean fish, there are certain obvious differences such 35: ti) pyramidal ccl1 somata not confined to stratum fihrosum et griseum superficiale, but also clustered in tlte aci~acent stratuni opticurn. presenting stratified or diffuse basilar dendritic arbors: and a change from vertlcai IO oblique and almost horizontal neuronal orientation in the ventral and caudal &turn. (ii) The presence of pyramidal cells with aligned and misaligned apical and basal dendritic tieids. (ii)) PI cell of
The cbptio tectum of lower vertebrates as well as the superior colliculus of mammals arc important targets for highly topographical visual and multisensory input\. which convcrgc upon tectal neurons. This complex sensory information is fed via descending tcctol’ugal pathways to motor centers of the lower blain stem and spinal cord, thus resulting in the orienting hchavior of the animal towards stationary or moving objects. The deep tcctal layers have been shown to contrihutc to the des~~n~iing tcctofugal pathways presumably rcsponsiblc for the motor responses in frog, .‘N birds.“’ fish” and mammals.” in most vcrtcbratcs the tcctal celis in the superficial lavers rcceivc topographically organized visual 4i.Wh2.711Nhich is completely or partially inpui. 111-1: crossed according to the species, whereas the dcqx~r laycrb rcccive a wide variety of other sensory
.~llr/~~r~r~,r,cio,f.\ : IPI_, Inner plexiform laqcr; JAR, Jamming ;i\ oitiance response: SAC. Stratum album centrale: St GS. Stratum fihrosum et griscum supcrficiale; SGC, Stratum grismm ccnt~tk: SM. Stratum marginale: SO. St!-atum opt~cum: SP\‘. Stratum pcriventricuiare~ TS.
-rcbrtis w3nicircuktris
modalities,
including
auditory’.‘5 ” and somatctBesides these ubiquitous nonvisual sensory inputs. certain species have devclopcd special sensory organs, such as: heat sensors in rattlesnakes and pythons.‘h.‘2 electroreceptors in various teleosts.hx chemoscnsitivc finrays in the tclcost and these non-visual modalities Prionotus carolinus.‘b will also be represented in the tectum. Although a few superficial tectal units receive only visual and other deeper units only unimodal non-visual input. in most vertebrates the overwhelming majority of deep tectal neurons reccivc visual and ~~t~iti~n(~~i~~i sensory information. The visual and non-visual inputs to the tcctum at-c generally in topographic register (visual and Inl‘rared heat sensory input.2h.S’ visual and auditory information,*‘,” visual and somatosensory input” ‘_ ‘l”‘). and this alignment is dependent upon proper scnsorb input? Taking into account the above informatlon pointing to the large variety of sensory modalities converging upon tectal neurons also receiving visual input, it is not surprising to find that the clectrosensory system of Gymnotids reaches the tcctum‘.“““’ and that this input is also in topogr~~phi~ register wtth sensory,9.‘?,‘2.1h.17.19.30.hS
216
I?, SAS and
L.
MAL~K
Table 1. Thickness of the tectal lamina expressed as a percentage of the total tectal thickness Ap~eronotu.s
Eigenmmnia
Mid
Caudal
Mid
Caudal
18 18 31 15 IX
15 20 34 II 20
14 14 39 II 22
23 20 37 II 9
22 16 40 13 9
16 16 42 I1 15
100
77
72
100
64
54
Rostrai
SM SO/SFGS SGC SAC SPV Total
Rostra1
Measurements were made at rostra], mid and caudal levels and the bottom line (total) is percentage of tectal thickness in comparison with the thickest (rostra]) portion. These measurements were made at the dorsolateral aspect of the tectum; the percentages are somewhat different at the dorsomedial and ventrolateral aspects. Note that the caudal tectum is more drastically reduced in Apferonotusthan Eigenmunnia; this correlates with the reduced retinal input in the former species.“’
the visual input. 2,6 These two sensory modalities appear to converge on the same tectal cells, since Bastian’ reported that many cells of the optic tectum in Gymnotids gave good responses to both visual and electrosensory stimuli. Many other deep t&al cells of high-frequency Gymnotids are responsive to only electrosensory input and may be specialized to analyze electrosensory input related to communication.6’ The aim of this work is to compare the anatomical organization of the Gymnotid tectum with those of other non-electrosensory teleosts, and to correlate it with recent electrophysiological results in Gymnotid fish. METHODS
Rapid Golgi and Golgi-Kopsch material was drawn from a large collection prepared by Maler,4s and new additional material was prepared from 10 small Apteronotus lepforhynchus intracardially perfused with buffered aldehydes4* and stained with Valverde’s rapid Golgi method. Bielschowsky, cresyl violet and cholinesterase? material was also drawn from a previously prepared collection. Wheat germ agglutinin conjugated to horseradish peroxidase (Sigma Chemicals) was iontophoresed into the torus semicircularis of four ApteronotusIeptorhynchus,using pipettes broken to 10-20 pm. A Midgard constant current source was used with currents of 050.8 PA for 3-8 min. After 3-4 days’ survival times, the animals were perfused with 1.25% glutaraldehyde-1% paraformaldehyde in phosphate buffer, followed by 20% sucrose in buffer and sectioned the next day at 40 pm on a freezing microtome. The sections were treated according to the procedure of Mesulams’ and counterstained with neutral red. RESULTS
of Vanegas et al.,@ since this corresponds closely to the laminar pattern of Gymnotids, although the scheme of Meek and SchellartSo is used to designate the cell types, when found to be comparable. The laminar pattern and cellular morphology are generally similar in both species of Gymnotid and a We adopted the nomenclature
(see Fig. 1) for the tectal laminae,
distinction between Eigenmannia and Apteronotus will only be made where differences have been noted. Cytoarchitectonics of the gymnotid optic tectum
In general the Gymnotid tectum conforms to the teleost plan50,69as seen in Nissl, reduced silver and cholinesterase preparations (Fig. 1). From surface to depth the layers are: stratum marginale (SM), stratum opticum (SO), stratum fibrosum et griseum superficiale (SFGS), stratum griseum centrale (SGC), stratum album centrale (SAC) and stratum periventriculare (SPV). The SM and the deeper layers, SGC and SAC, are better developed than the thinner SO and SFGS (see Table 1). Acetylcholinesterase histochemistry (Fig. KY). There
is a dense band of cholinesterase in SO which extends slightly upwards into SM and downwards into superficial SFGS. A second band is present in deep SFGS. More moderate staining is also seen in mid SGC and somewhat more intense in SPV. The laminar distribution is similar to that found in other teleosts,‘i,‘4.‘6 but it is less complex in SO and SFGS, presumably due to the relatively poor development of these layers. In SO and SFGS the cholinesterase is present as patches. The patches in SO are aligned with and connected to those in SFGS. A patchy distribution of cholinesterase has been described for the mammalian superior colliculus mid gray layer,” but does not appear to have been seen in other teleosts. Toral a&rents to the rectum (Fig. ZA). A large toral input to the Gymnotid tectum has been demonstrated.6*638Recently we have repeated these studies using a more sensitive tracer (wheat germ agglutinin conjugated to horseradish peroxidase). Although our description6 was correct in terms of its topographical organization, we now62,63find that this projection is even more massive than previously suspected; because this result is so important for the functional correlation of our Golgi results, we include it in this paper.
Fig. I. Photomicrographs of transverse sections through the optic tcctum. (A) Bielschowsky stain shows laminar distribution of axonal plexuses. (B) Ntssl stained section illustrates the layers of the tectum: SM. stratum marginale: SO, stratum opticum: SFGS. stratum tibrosum et griseum superficiale; IPL. mner plexiform layer: SGC. stratum griseum centralc: SAC. stratum alhum centrale: SPV. stratum periventriculare. Tectal laminae in (A) and (B) are aligned. (C) Specific laminar distribution of acetylcholinesterase in the tectum of Apteronotus. Bar: 50 nm.
Fig. 2. Photomicrographs of transverase sections of optic tectum. (A) Following horseradish peroxidase injection into the torus semicircularis, note sublaminar segregation of toral input in SAC, mid SGC, and a patchy termination of tufts in SFGS (arrows). (B) Horseradish peroxidase filled retinotectal afferents in superficial SO, SO/SFGS border, mid and deep SFGS, mid SGC and SACSPV interface. The retinal projection is only dense at SOjSFGS boundary. This material was taken from our companion paperO) to assist the reader. Bars: 50 pm.
SFGS
SGC
f’SM
SFGS
C
Fig. 5. Camera lucida drawing of pyramidal cell types. Pyramidal cell in (A) has a semiovoid soma. a stratified basilar dendrite and an axon (ax) which forms a “descending” loop in SGC. (B) Two pyramidal cells that form part of a cluster, one has a semiovoid spinous soma, with a basilar arbor confined to SFGS. the second cell shown in dotted lines is a pyramidal cell with fusiform soma with the basilar arbor in mid SGC. (BI) Insert shows an example of a pyramidal cell with two apical dendrites, and a lack of basilar trunk. (B2) Insert is an example of assymmetric pyramidal cell. (C) Pyramidal cell with inverted pyramidal shape, has stratified basilar arborizations in mid and adjacent deep SGC. The axon descends without a recurrent loop. (D) Pyramid with fusiform, sparsely spinous soma, and a diffuse pattern of the basilar dendrite. The axon forms a small “ascending” loop hefore descending to ramify within its basilar dcndritlc field. Arrows indicate axon. Insert in (D) shows detail of somatic spines of a pyramidal cell. Bar for (A. B, C and D): 25 pm. Bar for (BI) also applies for (82) insert: 50 /irn.
219
The
optic
tectum of Gymnotid
fish: a Golgi
t.lg. 3. Camera lucida drawings of Golgi- Kopsch preparations. intcrneurons: (A) glioform cell; (B) horizontal cell with round 3 /tm.
Tor,ll tibcrs end in moderate numbers within SAC and deep SGC. as previously noted. They form a very dense (crminal field in the mid cellular layer of SGC uhich continues unabated through the inner plexiI’orm laqer (IPL). Small tufts of terminals continue Into SFGS; where they reach into approximately the middle of this lamina. These tufts in SFGS (Fig. 2A) l’orm ;i \cry regular array and the terminal patches arc ncvcr in the neuropil below the cell clusters 01 superficial SFGS’SO border (see below). Thus, the clectroscnsory input to SFGS is in patches disjunct fr-om I hc retinal input. which preferentially terminateh upon the cell clusters (Fig. 2B).
A description of the neuronal types and composltinn of the neuropil of each layer will follow. .S/~r//rr/~ mwgide. As in other teleosts the stratum marginale contains the densely packed parallel fibers nhich arise from the cells of the torus longitudln;~lis.7ii One cell type with a round soma and a ~cond glioform cell type (Fig. 3) have been seen in the SRI: both types of neurons are very sparsely distributed. The cell with a round soma has one or IV,O thin dendrites which run horizontally within SM and scarcely branch. These dendrites rarely bear hplnous processes; a fine axon originates from the ticndriric shaft and courses horizontally. The plioform neuron has a characteristically fusiform anti rugged soma, with several thin dendrites which branch rcpcatedly within a small volume of
A
study
Two types of stratum marginale (SM) soma. .Arrow indicates axon (ax). Bar
SM. The dendrites spine.
have small nodosities
and a rare
Strufutn opticurn. SO contains a sparse population of horizontal cells as well as the somata of pyramidal cells displaced upwards from SFGS; the latter cell type will be discussed with the SFGS pyramid. The horizontal cells are of two distinct types (Fig. 4). One type has a small rounded soma and thin dendrites which branch sparsely within SO. This ccl1 has been observed in other teleosts, and corresponds to Type III (a. b, or c) of Meek and Shellart.i” The other horizontal cell has a flask-shaped soma with its narrow portion pointing to SFGS and giving rise to two dendrites which ramify entirely within SFGS. Typically the dendritic arbor is histratified with one set of branches just below SO and the other roughly in the middle of SFGS; the distal dendritic branches bear fine spines. An axon usually arises from the thicker dendrite and it descends into SFGS; but its further distribution is unknown. This cell type is probably Type III (e) of Meek and Shellart.“’ Stratun~,fihroswn et grisrum suprrficialc. The SFGS contains the somata of pyramidal, bipolar and horizontal cells. The pyramidal cells are by far the predominant cell type of this lamina and this category includes numerous subtypes.
The soma of these cells can assume a scmiovoid. fusiform. pyramidal or inverted pyramidal shape. and according to the subtype and location of the somata.
SM
FIN. 4. Projection drawings of horizontal cells of SO. Axons (ax) are indicated by arrows Bar for (A) and (B): 25 /urn. Bar in (C) 50 ilrn. This and following figures are drawings from rapid Golgi preparation\ unless otherwise specified.
317 ---
E. SAS
and L.
it may possess a significant number of spines. The presence of somatic spines was not reported in other studies of teleost tectum. The somata of pyramidal cells are scattered throughout the depth of SFGS. At the boundary of SFGS and SO. however. they tend to form clusters of two or three cells; it is these clustered pyramids which can intrude into SO. Although we have not studied this point systematically, it is clear that each cluster can contain more than one pyramidal subtype (see Fig. SB). Typically every pyramidal cell has in addition to its apical dendrite within SM, at least two other tiers of dendritic arborizations. A superficial tier in the uppermost portion of SFGS at the SO boundary, and a second tier at SFGSjSGC border. When a third dendritic tier is present, it reaches mid SGC (layer 314 of Meek and Shellarts’). For the most part the dendritic tiers within SFGS and SGC he on the same vertical axis; although on some occasions we found pyramidal cells with the arbors in SFGS and SGC misaligned. Such asymmetric pyramidal cells have not previously been described, and since the morphologic asymmetry may have functional significance, we will describe them separately.
Symmetrical pyramidal cells (Tjjpe I qf Meek and Shellart 50) Most pyramidal cells have an apical dendritic shaft ramifying in SM, a basilar dendritic shaft arborizing in SFGS and SGC, and an axon whose terminal field overlaps that of the basilar dendrites. Exceptions to this rule are: (a) the pyramidal cell with two apical dendrites and no basilar arbor, similar to Ramon y Cajal’s” cell “G” (Fig. 146); (b) the pyramidal cells with a basilar dendritic tier in SFGS, but none in mid SGC, and (c) pyramidal cells without a basilar tier in superficial SFGS, but rather raimfying in SGC. The more common type of pyramidal cell has a narrow thorny dendritic tier in SFGS just below SO. This dendritic arbor may arise directly from the soma, from the apical dendrite or from direct or recurrent branches of the basilar dendrite, but it always has the same appearance and is usually less than IOOpm in width. Because these dendrites ramify in that part of SFGS receiving the densest retinal input,h3 we will refer to it as the optic dendritic tier of the pyramidal cells (Fig. 2B). In some cases, especially in Apteronotus, this optic dendritic arbor is apparently lacking; but then the dendritic trunk passing through the retinoreceptive region of SFGS, is very rich in spines. Perhaps this pyramidal subtype receives less visual input than those pyramids with an optic dendritic tier. The apical dendrites have a small number of spines as they pass through SFGS, they usually bifurcate in SO and give rise to an extensive exuberantly spiny arbor in SM. The apical trees have thick, only slightly tapering dendrites which arborize over 20&4.50~m
MALEK
and overlap extensively with the amcal irccs OI adjacent pyramids. The basilar dendritic tree always has one dendrittc arbor either in SFGSjSGC border, or in the inner plexiform layer (IPL), and may have an additional arborization in mid SGC. Mostly these hasilat arborizations are horizontally stratified, but rn one pyramidal cell subtype the basilar dendrite ramifies diffusely downward from SFGS to mid XX’. The basilar dendritic branches are much thinner than the apical dendrites and are only sparsely spiny. Because the basilar dendrites overlap so extensively m IPL. it is difficult to estimate their horizontal spread, but this is probably at least 200-3OOpm. and is far grcatcr than the spread of the optic dendritic tier. The deeper branches of the basilar dendritic tree are in a position to receive electrosensory input from the torus semicircularis (TS) (see Fig. 2A), and will bc described as the electrosensory dendritic tier. One variety of pyramidal cell deserves special mention-this is the pyramidal cell with the triangular soma which is very frequently found in the Apteronotid fish. This pyramidal subtype differs from the others in the following features: (a) the optic dendritic tier is lacking; (b) the soma gives off two thick apical dendritic branches which inittally run horizontally along the SMjSO boundary; (c) the tertiary branches of the apical tree are obliquely oriented, and arborize over partially overlapping territories within SM; (d) the basilar dendrite ramifies within mid SGC (electrosensory tier). This cell type has been described in the goldfish by Romeskie and Sharma. 6” The pyramidal cell axon usually arises from the basilar dendrite, but can also originate from the soma or the apical dendritic trunk. The axonal plexus of a pyramidal cell is always vertically aligned with its dendritic tiers. Although the axon of a pyramidal cell may dcsccnd to deep SGC, it usually describes a loop and ascends to form a horizontal terminal plexus in exactly those strata of SFGS and SGC where its basilar dendrite ramifies. On a few occasions short delicate nodous collaterals were observed at the turn of the loop, when the axon descended deep into SGC, thus pointing to a clear difference in the axonal pattern of a subtype of pyramids. Asymmetric pyramidal cells (Fig. 5) Some pyramidal cells were found with the optic dendritic tier not aligned with the electrosensory dendritic tier. No other distinguishing features of the dendrite or axon appears to be present; however the asymmetry of the dendritic fields is striking and may relate to functional attributes (see Discussion). The asymmetric pyramid has not been described previously, but the other SFGS pyramids have been reported in numerous other teleosts. The pyramidal cell’s basilar dendritic arbor in IPL has been illustrated in the goldfish, ” but has not otherwise been
SM This
(a)
neuron
incidental
spine.
one side
of
spinous The
I[
descends
ramifies
soma
dendrltic
P
IPl
is
/ +\ ax
at
IPL
arhorlration
telcost:
within
mid
typically SGC
only
the
has ken
deepel
noted.
01‘ lhc
icnglh
boundal->
is
MCII dcvclopod
(IPI.).
diversity
of neuronal
bell
fusiform.
us
a
Lo arc
ported
in other
;I striking
types
A
prcscnr
in
Ci~mnotid~.
strata.
and
Xi(‘)
p! r:tmldal.
\ariet!
;I\
an ;IWII
nc‘uron M lth
gangl~<>n~c
;I
of multipolar.
01‘ niultipolai-
Itian
tliow
and surprisin~l!
to
and ;15 ;I deep
c‘
pl riform.
telcost<.
;I\ \i\ell
S
consl\tlns
wider in
rcscmblancc
7(‘)
The
undescribed
SO.
neurons
&Y-
Its o\in dendritlc
(mid
border).
horirontal.
heretofore
ascending
(Fig.
intcrmcdlate SAC
modcratclg
after si\~ng ott‘collalur;lls
deep cellular
(SGC
small
scmlcii-cular
within
to SGC
neuropll
lield
pi-c\ Iou\
cell has
;I small
formin, (I
and
spine.
7H).
axon ramilics
a mid
th~nncr
arc
the
SFGS
bipolar. an)
bt-anchcs
ticld. and descends
Iaycr
lat-gc
branching
and
a( the XC‘
supcrticial
in
sccondar)
;I
ha\
sparscl>
Iypc of‘ horizontal
ticld. The
ccII
thlcl,
horirontall)
branches
This
described
single
cell type (Fig.
exhlblts
and
Lbhcrc II
c)nly J rare or~cntcd dcndrltlc
twice
(c) A third spinous
liclci.
soma
(11~‘
horder
of horvonk~l
;I
nodohitics
1‘~
of this
horizontal
dritic
type The
;I
Icast
laniinai-
(‘I-0111
an
from
IMO \parscl>
narro\\
the SFGS’SGC‘
and
trunk.
and prcscnt len$h
or
ulth
;II-IW\
7A).
second
rounded
W~~I
shal‘t
one
;I
ccl1 originates
towards
(Fig. A
(b)
gi\cs
forming
of this
rounded
dcndritlc
and
the cell
branches.
axon
The
has ;I small A single
~mc
ccl/\
rcbear
rc‘pc~r~cd
111
the frog.“’ This
cell type possesses
occasional or~entcd spinous ar!
spine:
and
in the vertical dcndritic
originates
shortly
ax011 course
A
IS
and
given off‘which
\\;I\ not
forming
at the SFGSWX
dclicalcl~
bifurcates.
dcndt-ites
two
confined
spinous into
(Fig.
The
SGC 6A).
large
and SAC
and
SGC: class.
cell gives rise to dendrite
The
multipolar
cells
of Mech and Shcllart.“’
along
dendrite coursing
the opposite
dcsccnds
bound-
boundary.
bipolar
from
imprqnatcd)
-
soma with an
polar
one at the SO:‘SFGS
(FIN. 6H). Another
ascending
an
round
slender
from the ascending for a short distance
could be followed St
small
plant
fields.
and the other
axon
;I
two
thus
SGC
they
Al-c
boundary hill
in the straltmi
(Types
most and
Ol‘kll
the uhua1 I~>cation of the
and XIII,
li~~llld
Ic\s frequcntl!
bc considcrcd album
Xlll
ccnlralc.
SOI~~;I n11l
togcthcr
Ill
SAC‘
III ciccp ;I\ otrc
and in c‘;~li bc \~,~rcd
c‘;I\c’
which pole.
an
(its further
Allhotigh SGC
lhc
p!raniids
with a$ccnding
of
XC
and
lhe
ayon to SO arc multipolar-\.
ccl1 01‘ the>
224
SFGS-
/i
SAC
f ax
SPV
A
\
5M
so
CSAC
The optic tectum of (rqmnotid
will
hc discussed
The
soma
LISU;III~ Sonic
of
separately the
located of them
at the end of this
medium-sized
in SGC
cells
and less frequently
rcscmblc
ccl1 Types
IX
drites.
seclion.
multipolar
is
in SAC.
Four
mediutn-strcd
he designated (a) Thts
The
apical
\+ithin
dcndrires
dendrite
r>pc
“b”
in SGC.
u,hich
ascends
to SFGS.
dcnJr_iIic
shaft
arccnd\
towards
been noted. both
species
especially was
not
of
(c) Type scvcral
“c”
type
frequency
of this
nat-rob
ccl] (Fig.
tine.
of this
leave the
in SGC
modcratcly
:I short
towards
number
deep
illustrated
(Fig.
l4D).
The
alon onI!
tn S(i<’
is vet-1 rare:
dcndritc
SO.
:I
iI hits
gt\es ;t few lint
These
locall!
dcndritch
111deep 111uppc~.
c;trr\
spincx.
ccl] \\~th similar bk
onI\ :I
The
and gi\c< ;t rccurrcnl
onI!
;I\OII
collalcral
appcarancc
Kome\htc
it
dcndrita
br:tnching
of long-stcmmcd
in IPL
SGC‘.
been
XD)
which
ticcp SI:GS
,~nc! was
one side. that ramil)
and adjacent ;t plexus
S
W~:I
diztancc
cell (Fig. soma
This
ovoid rami-
ih an eaoccdingI>
high-frequency has never
dondrtte and then
appears
and
ha\
Sharma’“’
to be unique
the apical
may
and
sensor!
tectal input.
collaterals
hale
not
in
SC;<‘.
is \cry
common
Gytnnotid of other
dccpcr SGC‘.
i>
numerous
ot
ccl] type has a bipolar field
(Fig.
has a multipolar spinous,
radiating
A vcr!
neuron
tclcosts
mid
in
and
This
ha\c ;I role
OE)
The
ctrcumscribed also laden uith tn
IPL
soma
SFGS.
dcn-
axon
and
The
at-iscs
clthcr
it
ncuroli
to
the
clcctroli~und
bc tii\pl;tccd
an irt-cguI;tr
ct~ntoui.
IO 1%tth
and spine\ dendritic
tree’ r;tmtfic\
arca in deep SGC‘. spines.
Since
thih
is t!l~tcall>
somelime\ ha
basilar
and tinally
tclcost. fish.
cell body
can
soma
lower
OLII- kno~+lcdgc.
to Gymnot~d
excrcsccnces $ptny
to
in anolhcr
specificall\
but
ccl1 I\ pc 111 both
but.
been dcscribcd
sotna
from
common
Gqmnotids
the
dendritic XF)
to
“d”
in mid the
itt
1(> deep
This
an
apical
leaves
in the tcctutn
and
The
dendrite
in the caudal tectum.
A variant
configuration Lvitlt
high
rcportcd
axon
have
arises
local
neuronal
prevalent
amphibians.
axon latter
SFGS:
This
XC) basilar
branches
the
to ascend
modcrvtc forms
branches
from
and an ascending
SFCiS
vet-lically
branchlcts
arises
spheroid
SGC.
tout-SC’ hort/oncall>
ascend
II cell in the frog.”
prominent
The
it
SGC.
in SFGS.
The
Type (Fig.
spinous as
in
and may thus
a small
and a more
gives fatrly
sparsely
:I
and
have not been identified.
neurons Mith
ramifies
spinous.
resembles
perikarya
fying
some
ccl]
(d) Type
XH) lbith
dendrite
perpendicular
SW
local collaterals
(b)
which
gives
arc moderately
cell (ypc strongly thorn!
gtbtng this
oriental
(Fig.
apical
and also ramifies
cell type is seen to enter tcctum:
soma
;I prominent
dendrite
SGC
after
stna]]
they will
which
most
predon-
in SGC:
a. b. c and d.
cell has an ovotd dircctcd
cells with
are found
as types
contour.
larerally
multipolar
dendrites
of
while
obserccd
vertical
rug&
\omc
SGC. of
and X of Meek
and Schellart.5’ inantI)
lish. ;I G~>l,y ~~uci>
accndc
SFGS. forms
The
to ramit\
Ihen ;t small
fr<>ni
lhc
hort/onLall:,
continue\ bouquet
5om;t
obct- :I
;tp~c:tl dendrite.
01
Ihrottgh
tn SM. the
The apical
I:. 5~s
SFGS
SFGS
MID SGC
SAC
and L.
MALER SFGS
Yr
SFGS
The optic tectum
of Gymnotid
lish: ;I Golgi
rtudy
SO SFGS
”
:
b Fig. 9. Bipolar cells of SGC. (A) Type “a” bipolar with an asymmetric basilar dendrite. and an axon (a\-) with collaterals in SGC which appears to leave the tectum. (B) Type “b” bipolar with soma in deep SGC‘. (C and F) Type “c” bipolars are present in different suhlaminac of SGC. (D) 1 ypc “d” bipolar with soma m superficial third of SGC. (E) This cell is a bipolar variant of type “b” medium size multipolar: it5 axon also ascend\ to SFGS, and the soma lies in mid SGC. Laminae a\ indicated in the adjacent fi_eurc.t<;) Infrequent type “e” bipolar cell with soma in superficial SGC, shows an asymmetric apxal arbor m SFGS. Bar for (A,B,C,D and E): 25pm. Bar in (F). (G): 501lm.
dcndrltc and ascends to SO after giving some collaterals in SFGS. This axon is found to extend over ;I ~idcr area than the dendritic trees. therefore only part of the axonal plexus is aligned with the dcndritic arbor. The thick longer axonal branch possibly leaves the tectum via SO. On numerous occasions the axon of the ccl1 has been observed crossing the proximal segment of the apical trunk of the pyramidal cell of SF
Two pyramidal cell types are found in SGC: one is heavily invcstcd with spines and the other has a non-spinous basilar arbor in SGC and only a sparse amount of spines in the apical arbor at SO,!SM bordt_Y.
The somata of this ccl1 type is typically pyramidal m shape and is located in midcellular or adjacent deep sublamina of SGC. It has a basilar dendritic tree which ramifies widely within SGC; occasionally dendritic branches are given off at right-angles to this horizontal arbor to ramify downwards within deep SGC. The apical dendritic tree gives off two horizontal at-hors one in mid SGC and a second at SO. The
dcndritic tiers in SGC arc richly endov.cd \vith spines. The apical dendritic trunk has a small number (~1 spines except when it passes through SO. uherc it is bare. Its terminal branches in SO are moderately spinous. The axon Icaves the basilar dendrite and dcsccnds towards SAC. but it has not been fully impregnated. Ramon y CajalTh (Fig. 146b) is the only author who has described pyramidal cells of SGC with an efrerent axon in the tclcost tcctum. but his illustration doe\ not indicate whcthcr these cells arc spiny.
Thcsc pyramids have ;I very planar. non-spinous basilar dendritlc tree with wide horizontal spread in SGC. The sotna is located in SGC and gives rise to an apical dendrite which divides at the SOXM boundary. The peculiarity of this pyramidal cell. IS the lack of spines or appendages in the basilar arbor. while possessing a moderately spinous dendritic ticld in SO!SM border. The tine and smooth appearance of the basilar branches makes the idcntitication of the axon difficult.
Bipolar cells xc vertically
oriented
neurons
which
are not homogeneously distributed through the depth of SGC since particular types are found at specific depths in this layer. (a) Type “a” has an ovoid soma located in deep SGC. with an apical dendrite which terminates forming a small nodous, scarcely spinous arbor in SFGS. The basilar dendrite is oriented towards one side of the soma and has a sparse arbor in deep and adjacent mid SGC. The axon arises from a dendrite at the SGCiSFGS border and courses downwards giving some collaterals in SGC; it passes through SAC, and it appears to leave the tectum (Fig. 9A). (b) Type “b” bipolar has an elongated soma in deep SGC (Fig. 9B). and two polar dendrites. The basilar trunk forms a confined, delicately spinous arbor in SAC. whereas the apical arbor bifurcates in mid SGC. The axon of this cell was not impregnated. This neuron is comparable to cell “b”. Fig. I2 of Schroeder et ~1.~’ (c) Type “c“ bipolar was observed as frequently in mid as in deep SGC (Fig. 9C and F); the elongated soma gives rise to a thick short and smooth apical process. which bifurcates and forms a moderately spinous narrow arbor in SFGS. The axon arises from the basilar aspect of the cell and was observed descending into SAC. This is probably a projection neuron of SGC. In Eigenmannia both types “b” and “c” bipolars have a more spherical soma than in Apteronotus. A comparable cell is shown by Vanegas et al.“’ (Fig. 3, cell “d”); Ram6n y Caja15* (cell “b”. Fig. 146); and Meek and Schellart.‘” (d) Type “d” bipolar has an ovoid soma in the upper third of SGC: it presents a few thorny spines (Fig. 9D) and gives rise to a single thick basilar trunk with a sparse arborization in mid and deep SGC. The short apical dendrite is thick and breaks up into a bouquet of nodous branches with few spines, that spread in SFGS and SO or SOiSM border. The apical and basilar arbors of this subtype arc wider than those of the previous type of bipolars. The axon originates from the basilar dendrite at mid SGC level, and appears to take an ascending course. We have not encountered a description of this cell type in the literature of teleost tectum. (e) Type “e” bipolar cell (Fig. 9G) was infrequently observed; the soma is located close to the SGCjSFGS border, with a basilar dendrite which descends and ramifies in deep SGC forming a cone-shaped sparsely spinous delicate arbor. The apical dendrite arborizes in the SGCjSFGS border, having its branchlets oriented towards one side. The axon of this cell was not impregnated. This neuron perhaps is analogous to bipolar cell “e”. Fig. 10 of Schroeder et al.,w and cell “b”, Fig. 3 of Vanegas er uI.,~” with the varient that their cells have symmetrical dendritic trees. Fus$orm
cell
The large fusiform cell with the shepherd’s axon (Fig. 19B) has the same characteristics
crook as de-
scribed in other teleosts, Type XII cell 01 Llcch and Schellart.” fusiform vertical cell of Romcskic .tnd Sharma.“’ fusiform with shepherd’s crook .!\on 0:’ Schroeder r/ ~1.~’ and cell “a cross” of Ramon 1 Cajal.5x The very elongated soma is locatcd throughout the length of SGC and gives rise to LUO thick\ polar dendrites. The basal dendritic shaft arhorircs in a horizontal fashion at the SACjSGC border: whereas the apical shaft ascends, giving r15c to ;I dendritic tier in SGC and a more superficial one at the SFGS/SO border. The axon originate> from the apical trunk high in SGC and turns down towards SAC. Another large fusiform cell has its efferent axon originating from the basal pole of the soma (Fig. IOA), and possesses a thick, nodous and wider apical arbor at the SOjSM border than the fusiform with the shepherd’s crook axon. This neuron has combined characteristics of Types Ilb and XI of Meek and Schellart.50 The axon is not shown in the drawings of these authors. Horizontal
cells of stratum griseum centrale
Type “a” horizontal cell has a rounded soma, giving rise to one or two sparsely spinous dendrites which ramify only sporadically in the horizontal plane of SGC (Fig. 11). The axon arises from the soma and appears to course within the plane of one of its dendrites. Ram6n y Cajal’s’* horizontal cell (Fig. 164, cell “d”), Vanegas et a1.69(Fig. 7) and Meek and Schellart’s’” Type V, seem comparable to the Gymnotid variety. Type “b” small horizontal cell has an octopus-shaped soma and fairly spinous confined dendritic field at different levels of SGC. After a short trajectory, the axon bifurcates into two small slightly beaded branchlets. These are probably small interneurons of SGC (Fig. 11C and D). Stratum
album centrule
The SAC is chiefly a fibrous layer containing scattered large multipolar cells, a few medium-sized multipolars, and a small number of pyriform cells displaced from SPV. According to the preferential orientation of the dendrites, the large multipolar cells of SAC, can be divided in: (ai and aii) Cells with a chiefly horizontal dendritic spread (Fig. 12A,B). (b) Cells with a predominantly horizontal arbor, and one vertically oriented dendrite (Fig. 13). (c and d) Cells with a substantial vertical dendritic component, in addition to the major horizontal tree (Fig. 14A,B and C). Some of these cells can be found displaced upwards to deep SGC. (a,) This cell has a widespread dendritic field in deep SGC. The soma has a peculiar flask shape, and gives rise to a descending dendrite with a characteristic widening before it bifurcates in SAC. These dendrites have a nodous sinuous contour and are non-spinous. The axon was impregnated for a short distance ascending in SGC (Fig. 12A).
SFGS
MID
SGC
\
DEEP
SGC
mid SGC
\, SAC
SPV
A
(a, ) This dcndritic a fa\
cell generates
tree at the XC.
branches
reaching
drltes are moderately
an extensive
SAC interface. down
to SW.
(Fig.
12B).
A
similar
only for ;I short
cc11 type
described for both. teleost (Schroeder cell
“b”)
and
Thcsc den-
spinous. An axon arises from
the cell body and could bo fotlowcd distance
horixon(al and also has
amphibian
tcctum
(bl This large multipolar dendritic
and Marc
Sharma.“”
Discussion).
istic of this neuron
(Fig.
13) has ;I
processes. and a wide and deep SGC.
An importanl
is that in addition
character-
it posscs~s ;I
we have only been able to
this process to the IPLiSFGS
border.
The
in SAC.
13: Vanegas
Fig.
rccentt!
1’1trl..“’ Fig!. I2 c’t (I/..“’
and teavcs ~hc It‘ctum
collaterals
al‘tcr
Th~j
ccl1
type has been described in other teteos;ts (Komcskic
intraceltut;ir
(L6Gr
of SAC
tietd in SAC
is sparsely spinous.
single ascending dendrite; follow
recurrent
this neuron recording
(c) This multipolar large triangular
round soma with tine hair-like horizontal
off
has been
t-I& 4E).
*hich
axon descends to SPV giving
to scvcral dendrites
or (I/..‘“’ Fig.
has been identiticd
and
filled
ccl1 (Fig.
\4ilh
I-IA)
(!t>~call!
thick
spine laden
reach SO to form
The
horirontul h:i\c
;I
apical
SAC‘ and EC.
ha\ ;I
dendri~c~. Tv.o
dcndritcs
cul-vitincalThe
~XUII
:rp~cal
small hcrI;LItb arranged L~IW gi\c
branchcs in mid Xc‘.
wictc
h> (\ec
sparseI> spinou\ cell hod! giving 1-1s~‘
tufts: rhesc tuft? arc nodosc and ont! nous.
dye”’
7).
sparhcly
\p~-
oft‘ spinou\
Two ba\al dcndritc\
asccnding ;~sccncis
courxc to
S
through \\hc‘t-c if
I-. S4\
c
and 1.. MAIJH
Fig.
SAC
t I. (A and R) Horizontal cells of WC. Bar for both liguresr 25 pm. (C and D) Flask-shaped cells of SGC
Bar in (C): 2Spm.
forms a loop and then descends to exit the tectum. This cell corresponds to Type XIII, of Meek and Schellart,‘” and Ram6n y CajaI’s” ceil with thick protoplasmic expansions (Fig. 145b). A fairly similar cell has an ovoid soma with irregular lumpy contour. A variation of the triangular multipolar, has a large candelabra shape dendritic tree; the basilar dendrites are very spinous, while the shorter branches have a nodose appearance. The longer ascending dendrites bifurcate at SFGS (Fig. 14B). (d) Another large multipolar cell (Fig. 14C) gives rise to two or three widely spreading horizontal dendrites with wavy nodose appearance. From these dendritic trunks a series of vertically oriented branches take off, which break up into delicately nodose tufts at the SFGS/SO border. The axon leaves the ventral aspect of the soma and descends into SAC. This cell type has been described by Ram& y Caja15* (Fig. 145a), and by Meek and Schellart% as Type XIII cell.
Bar in Fig. D: 50pm.
small
ax, axon
Medium -size ~luitip~i~r~qf stratum album centrafe These neurons can have a predol~iIlant vertical orientation (Types e and f), or be (Types g, h. i) confined to the deeper layers. (Type e) This multipolar neuron has a mediumsized soma (Fig. 15B) with a wide dendritic field which is formed by obliquely ascending dendrites, These dendrites give off vertically ascending branches which terminate mostly in SGC, although a few branchlets may reach SO. ‘The dendrites are thin, nodose and sparsely spinous. The axon of this cell was not impregnated. A similar cell type has been described in the frog.4O (Type f) This neuron has an ovoid soma in SAC which gives rise to an axon with collaterals f~lluwing a recurrent trajectory. A thick ascending dendrite reaches the IPL/SFGS border after giving two or three oblique branchlets along its course, while a thinner descending dendrite forms a small field in SAC (Fig. 15A).
The optic tcctum of Gymnotid
IPL
fish a
232
A
SFV
-_
(‘fhpc
g) This
\tcllats
mcdium-siLcd
appearance
nc>n-spinous
hr !nchlets
111;I layered
fashion.
co~~,c‘~ in SAC‘
I)
course
tv;mclllcth.
spheroid
horiconlal
The
c,irr I<\ on1\
lint
(Fig.
dcndritic
mod-
in mid
in Xc‘.
(Fig.
16H).
sonia
gives
to
tvio
horizontal
of
arbor
il
shol-ter
dcndritic
amount
SAC‘
trot
tint
Iong
is confind
was incon--
axon
IK).
ascending
SGC:
presenting
tier\
mid SGC
and descend\ (c) Thi\
~II;I
arc the chicl‘ constituents
of this
p! preform cells arc also present Ior
convcnicncc
thq
Th~~ire arc eight ;1\on5. four
will
;dso
with
ctfercnt
hut
ascending
small
branch&),
with
cells
axons.
hcrc.
two types
do ,iot appear to ha\c an axon and ;I candelabra ccl1 \zh~~ Iv
fine ;IYO~ like
idcntilicd I
with
process
in SAC
~n\cstipators
have not
illustration\
ol’iill the
(;\lnnotitis.
and did not she\+ somatic
pyriform
p11‘~cncc ,II- ;tb~ncc
of
I~K;I~I~~~\. it i\ dltTicu/t ,,u~ matcrI;il
with
cell varieties
dcndritic
spines
in
typIcal
to make exact comparison\
thox
spccics
of other
ol
of tclcosts.
avoids
the
(g) The
(Schrocdcr
\mooth
in
round
~ma
amount
rn~tl WC‘.
Upon
brc,lh\
up into
gi\cs an ascending reaching
;I l’airl~
which
reach ah far branch
Irom
SO.
the
ascending
bifurcation.
rcachcs
~~vcrl;tpping
it\ dcndritic
Another
,o~;I
111 XC‘
.~rboi- In \tipcl-licial (h) The
or
This
dclldritic ‘The
“b”
it
the
in SFGS
emerges
(Fig.
I7A).
type has the dendritic
branch
branch
;IXOII
pyril‘orm narrow
usually
IO the
ha\c Tao
a wide field in mid SGC field
in
reaches
ascends and forms
II y~\c,s ;I collatci-al
cells in SPV.
;i5ccndin~
SFGS.
A
single
SM.
a loop. to IPL.
spine\ othcl-
at M hich point and c~dciccnd-
;i
tclc‘osts
ati
with
rescmblc
SI’V
(i) Thib
Thus 17(‘).
(Schrocdcr
(‘I (I/.“‘)
dendrites.
Sonic
;~~;on;il cells
p>riform
ccl1 of mid an asccndinf
this
and
subl;i\er
forms
uruall)
;I f:tir-ly
brancheh
and
dcndritic
tree in
breaks
l\idc
ramities
horvontal oni’
withln (I+$.
up
cell tape dot\ ,I similar W;I~
not
cell 111
report&
of these
to
p) I-iform partialI>
and Schcll;~t-t.” ~&IS :I \01n;1 ulth
dcndt-Itc MIth almost
the aplcal
I‘rom IPI.
SGC
The
nunibcr
c\crc4ccncc\ and
and (>ti1\ ;i Ii‘M splncs
of S<;(‘
,,riginatcx
;i small
raniification5.
of Meek
L;~I;III
base.
boundary
presenting
one: or tM0 spines.
In
proce\\
;I \cr>
at It\
carrIc5
neuron.
no spine\ in mid KC.
numbcl
Ifoloc~cvrr~r,.v the axon h;i\
has
is indented
;kxon (Fig.
XIV
111011
19).
dcndritc
intrinsic Type
;I\OII
ha> ;I daunt)
niodcr-ate
has an a\on-like
cell of
to this
habc
ccl1
the
raniItic\
In our material.
houquct
ha\c pre\! naptlc cells
and
and at the SO ‘SFGS
to
hroadc\t
ccllh.
ccl1 type‘ in
%I)
\omctimcs
typical
mod-
p> riform
cell of SC;{‘
(Fig.
ascending
as-
piLc> otl
the
the
111
the
I7D) with
Fig.
QI~;I
shaft
p>r~form
comparable
;I confined
appear
of
a plexus
a wider
;I dcndritic
shaft
point
forms
pyriform
and forms
lacks
Iramilications,
rclaticcly
J
arbor of this
bvith
v+hile ;I
which
near
whcrc
into
branchlcts
border.
axon
of qncs
deep and
dendritic
of spiny
and
.I short
and onlv
formtng
arbor.
pyr-Iform
which
for
bundle.
SPV
among
SF<;S.
been idcntitied
The
layer\. tylx
1na1n dcndritic ,Incl
this
dendrite
SAC
but
The
IPL
\arict>
11’1.
IPL.
\vidu arbor
dendrite SAC.
as the SFGS:SO
cntcrs
in SPV.
profundum.
01 \pines in SPV.
Gn!rle
(.lii)
ccl1 is found album
\trat imi
in
tier’\? in mid
).
dcndritic
SGC
(F:ig.
(‘I trl..“’
~crrucou~ t!17c’ ofp)riform
mid
\vh~ch reaches deep SM.
som;i.
in
The
dcndritic
4
spine\.
(hi
(.II) 7‘h1\
in
111 IPL tree
I7H
till (OI-
hpinous
and another
elTcrcnt
is smooth
sm;111 p!r-ifor-m
dcndritic
not
t1111\ ml-cl>
the
the previous
supcl-ficially
of
in
soma
of yncs
two sparscl\
arboriation
Lnllkc
numhcr
cell type has a smooth it
in the SI‘CiS
smooth
been imprcgnatcd
in SGC.
hranchcs
in tMc>
17(i).
remains
(FIN.
111
branchlct\
has ;I smooth
in SAC
in SAC
dendrite
types.
in
ot- the
haa
spinous
spin!
found
spines.
awn
clthcr
;I loop in IPI
uhlch
It forms arbor-
spiny
(FilJ-.
It hax ;I moderate
deep to
ccnding
horl/ontal
provided
y%nou\
it terminates
cell of SPV
pyrilhrm
or
that
certainty.
pi-~IOLIX
This
type
have yet to
and
tn mid
ramification\
befhrc
deep XC
coursing
erately
intrinsic
SPL
to an aaccnding
or
HYO~ forms
width
The
(f)
plexus
sparscl)
rise
of its
dendrite,
where
SPV.
The
Into
SAC‘.
Sonic
and SG<‘.
be described
thpe\ of pyriform
I!Ix~
lamina.
in SAC
in
spines.
ccl1 is located
spines most
p>ril’orm
distance
cells and pericpcnd~mal
I‘uund
somatic
is only
pike5
and Sf:GS
of SM.
deep half
X3<‘. types of pyiform
soma
and giving
a medium \ arious
It5 dcn-
and axonal
pyriform
its
in S.4C.
and
cell
two
dendrite
type “d”
or
dendrite.
to
pyriform arbor
wIthin
l7B).
SCiC.
((1) The
2
The
origin
and
The
with
SFGS.
The
ramitia
(Fig.
one or
has
dcndritic (Fif.
thpc‘ “c” pi-esents
cell of SAC
ad_iaccnt deep SGC.
plc‘lcl> inlpwgnatcd
The l7E)
has both the dcndritic
at IPL
which
SGC
axon
;I tuft
nodous
branch in mid
The
dcndritc
The
field
SGC.
mild
211 ltlzlgniticant
~tcmmc1.1 \pincs.
recurrent
(c)
asymmetricall\
dendrites
into
111 deep SC;C
long
ing dritic
nndous
SC<‘.
ascending
The
cell has a
delicate
IbA).
breaking
:~~on cour\cs
S:\l . and
to
a semicircular
boat-shaped
\p~nou,
l~~ngcr branch
thicl,cr
which
forming
(Fig.
( f\ pc 11)This
(.I‘hpc
multipolar rise
deep and adjacent
t~eld 111MC‘.
L,I.,IIcI~
giving
IICI-.
01’ thc\c the
17b)
in IPI
\haI‘t bil’urc;itc\.
plant
l‘hc
,i\c)n
\ccondar-> of It\ 0v.n
E. SAS and L. MALEK
SFGS
SFGS SFGS
M SGC
\
&
a
sic
A
sac
:
Fig. 15. (A,B) Medium-sized
Fig. 16. (A,B,C)
SGC
ax
Medium-sized
multipolars
multipolars
of SAC with a preferential axon.
vertical
of SAC with dendrites 50pm. ax, axon.
ramifying
SPV
orientation.
mainly
Bar: 25 pm. ax.
in deep layers.
Bar:
The optic tectum
of Gymnotid
SAC’. The dendritic shaft is fairly smooth through deep SGC. and then it gives spinous branchlets in mid SW‘ and IPL. One tine dendrite ascends to SM and carrlcs a moderate amount of fine long-stemmed spines. The axon originates at IPL; where it gives a few branches and then, it takes a long recurrent cout~se and leaves the tcctum via SPV (Fig. 18A). (b) This projection pyriform cell type (Fig. 18B) has the soma located in SAC. with dendrites ramiI\ins appropriately deep in SAC and SGC, but do not cntcr SFGS. This subtype dots give off local collaterals at the height of the axonal loop in SGC, to IPI. and mid SGC. and terminates by leaving the tcctllm. This ccl1 appears to correspond to Type XV 01‘ Rlcck and Schcllart.” (by) .4 Lariant of type b pyriform cell (Fig. 18C) has dcntlritic branches reaching SFGS, and its axon hranchcs in IPI. and then descends and leaves the tcctllnl. (c) Tqpc “c” pyriform has the distinctive characteristic of possessing an axon which originates deeply nca~ the sonu (in SAC) and dots not form a loop in IPL but instead it leaves the tcctum after giving a collateral branch which ascends into deep SGC (Fig. IXDI.
This neuron has ;I soma located in either SPV or SAC’ and ;I wide spreading dcndritic arborization conlined to SAC and SGC. The dendrites are mostly smooth with only occasional spines. A thin process was ohscrvcd. leaving a dendrite and descending to WV. but we arc not completely certain of its axonal nature. .An identical ccl1 was illustrated by Romeskie and Sharmah” (Fig. 4D), and Potter.”
This ccl1 has a fairly similar appearance to that shown by Ramcin y Cajal’” and Vanegas ct trl.,h’ with onI> slight variations. It differs from that shown by Ram& y Cajal 5X in Barhus fhiatilis. in that in Gymnotids the radial process of this ccl1 maintains its hirsute appearance even in the superficial layers. This ccl1 has ;I soma with an irregular contour, located at the Lcntricutar aspect of SPV, and possesses a verticall! ascending process surrounded by a meshwork for-med by fine hairlike processes; some of which are longer than the others and protrude away from the meshwork. This apical process reaches SM where it appL~ars to widen into an end foot upon reaching the peal surface. The cell depicted by Vanegas et al.,69 rcfct-red to as an “epcndymal supporting cell” appears to form a cylindrical shaped radial process Mhich progressively widens along its ascent. without prcscntinp intermittently the longer filamentous appcndagcs observed in our material. .4 summary of Gymnotid tectal cells, the laminar diztllhtttion of their dendrites and axons. and the
fish: a Golgi
‘ii
study
laminar distribution of their known extrinsic is presented in Fig. 19 and Table 3.
afYcrcnt\
DISCUSSIO’V The tectum is generally consider& to ol-ganl/c orienting responses of the eyes and body to scnsorh (predominantly visual) input. In Gymnotid fish ~hc nature of both the sensory input and the motoroutput is different from that of most other teteo\ts. Despite these apparently major difl’crenccs. the tccturn displays a remarkable conservatism in it\ \tt-ucture. The discussion below focuses on rhe cvolutionary. functional and dcvclopmcntal implication\ of tectal morphology in thcsc tish. The dominant sensory input to Lhc tcclum 01’ high-frequency Gymnotids is electroscnsor! rathclthan visual. Whereas the retinal Input is dcnsc onI> in deep SO and adjacent upper third of SF(iS. the toral input is moderate in SAC. nuss~\c in Xi< and still substantial in the lower half of SFGS. Since most tectal neurons have dcndritcs uithin the tc~ral recipient zone we assume that the) can hc dit-ccIt> influenced by electrosensory input. The ImpcJrtancc of this toral input is reflected In the cucctlcnr dc\~clopment of SGC and proliferation of cdl rypc\ 111thl\ layer. The decline in retinal input IS not, hov,c\cr. paralleled by an equivalent decrease in the thickness of the SO and SFGS. These two ta!,ct-\ occupk 1623% of the tectal thickness. whereas in o~h fish with poorly developed vision they con\tittttc bunts 1420% of the tectum.” Perhaps the toral input to SFGS can occupy the synaptic targets nc)t-mall> occupied by the retinal input (see sccrion on dc\elopment). Many different toral cell ry~>ch contrlhutc to the torotectal projection’.““’ and. con\iticring the precise laminar or sublaminar dlstribtrtion or‘ mo\t dendritic bushes in the tcctum. II i\ IiLcl! that different toral neurons project to diytinct lam~nac OI sublaminae of the tectum; a prcccdcnt for the \uhlaminar distribution of tectal afTcrcnt\ c‘\i~bt\ in the Thus the parallel protectum of amphibians.“,‘” cessing of electrosensory input k+hich IKC‘III-\ 111~hc TS’ of Gymnotids is likely to continue 111the Icctum. although with the addition of Lisuat inli>rmaric>n to some of the channels. The motor system of high frcqucnch (is mnot~& i\ also modified with respect to: (a) hod> mo\cmcnt\. (b) cyc movements, and (c) electric organ cIIsch;Irgc\ (a) Gymnotid fish move forward or backuard~ b\ creating the appropriate undulation in the ;ln;lt lin which runs the full length of their hod). This motor pattern is presumably dcrivcd from rhc pr~rn~t~\c body oscillation which gcneratcs s\vimminf 111to\\cl vertebrates.” It differs from the usual \v, 1111 ~;IIWII generator in that the oscillation can pt-occcrl l‘tron~ caudal to rostra1 (during backward swimming). end it is usually uncoupled from osclllation~ 01‘ the. hod\ and tail. This uncoupling is probabtl \crh ~mport;~n~ since bending the body or tail change\ the \h;lpc 01
236
SM
so
SAC SPV
i
ax
SPV
SGC
SAC
SAC SPV
E
s PV
-F
The optic tectum
of Gymnotid
fish: a Golgi
137
study
IPL
SPV
H
I
I-IF. 17. (.A) Type al pyriform of SPV with intrinsic axonal plexus m IPL and SFGS. (B) Type b pyriform with axonal rnmilications in IPL and mid SGC. (C) Type h pyriform ccl1 with presynaptic dendrites. (D) Type f pyrlform has a very extensive horizontal arbor in mid SGC, and an axon (ax) ramifying higher in IPL. (E) Type cc pyriform of SPV with wide dendritic arbor and owrlapping axonal plexus in mid SW’. lnscrt In t E) shows candelabra type pyriform. (F) Type i pyriform with wide dendritic tree and atonal ramllication in IPL and soma In SGC. (G) Type d pyriform in deep SGC. Note axonal loop In IPL. and then descending trajectory of the axon into SAC. Ascending dendrite enters SM. (H) Type e pyriform axon courses horizontally in deep SGC. Dendritic tree has an arbor in SAC and deep SGC and ;I second ramification in SFGS. (I) Type J pyriform dendritic tree confined to deep layers. similar to Type XV of Meek and Schellart. Bar in Fig. 17A-I: 2pm. Bar in (E) insert: 50pm.
the electric organ dipole and can thus influence clectrolocation.~~ Tcctal outflow in Gymnotids must thcrclbre control a very different spinal swim generator. t b) Eye movements have been noted in .!+EHHU/HN/U.but not ,4prc~~~~~us.’ We have recently obscrvctl cyc movements in Apteronotids (Maler. unpubli+cd obscr\ ations). but these were so small that the) \+crc readily seen only under an operating mlcroscopc. These cyc movements were most promincnt when the animal had been treated with stimulator! drups as part of neuropharmacological in\chtigations and WC concur with Bastian’ as to their paucity under normal conditions. Recent work has dcmonstratcd that eye movement commands arc convl~!cd to the tcctum via the stratum marginale.‘“.“ but the SM is well-developed in Aptrronotus despite tbc rcduccd mobility of the eyes: furthermore the Jcvcll>pmcnt of SM in .4ptcwmotus may still be correlated with visual input, since it becomes thinner in the, C:~LIC~~II fourth of the tectum where the retinal
input is also greatly diminished.” We can interpret these facts in two ways. Electrosensory and visual input interact in the Apteronotid tectum and. as Bastian’ has pointed out, eye movements would drastically change the correlation of these maps. Thus the analysis of electrosensory input may need to take into account even the minute eye movements of these fish: note that this explanation dovetails nicely with the reduction of SM in the caudal tectum, a region of poor visual input. Alternatively, it is possible that other neural systems unrelated to eye movements have taken over the torus longitudinal&SM pathway (ii High-frequency Gymnotids can change the frequency of their electric organ discharge during social interactions.” The best studied of these frequency shifts is the jamming avoidance response (JAR)” which shifts the fish’s frequency away from that of a neighboring conspecific. A particular combination of spatial and temporal information from electroreceptors is required to drive the JAR, and
23X
E. SAS and 1.. MALFK
C
B
SPV D
SAC
\,
8, ‘\ ,, :,*I, ’
SPV
‘1’,i)
)
4 sc
IPL
a
s PV
Fig. 18. Pyriform cells with efferent axons. (A) Type a projection type pyriform cell with axon collaterals in SFGS and an axon (ax) leaving via SPV. (B) This type b pyrifonn cell seems like a Type XV pyriform cell of Meek and Schellart with a dendritic tree confined to deep SGC, and an axonal loop in IPL with collaterals in mid SGC and an efferent axon via SPV. (C) Type bi pyriform with dendritic tree reaching SFGS, and an axon forming a loop and giving collaterals in IPL and then leaving the tectum. (D) Type c pyriform cell has an axon in SAC. which leaves the tectum after giving a collateral to deep SGC.
both anatomicaPE and physiologica13,29 studies have shown that the TS is essential for the temporal comparisons underlying the JAR. It now appears that this information is conveyed to the tectum which contains cells with the information needed to drive the JAR.29 Heiligenberg has speculated that the JAR may require the tectum because the JAR has evolved from an orienting response. Whether this is the case or not, these results imply that Gymnotid tectal circuitry is carrying out transformations unique to high-frequency Gymnotid fish. Comparatiw
aspects of‘ tectal organization
Despite the different sensory and motor abilities of Gymnotid fish, their tectal neurons are generally similar to those of other teleosts; the similarities and differences will be discussed below. Stratum marginale. Although this layer is almost devoid of neuronal somata, two cell types are found in Gymnotids, and were described only in two other
species of teleosts,58,60 and in the skate, Ruja.” The axons of these interneurons perhaps constitute the presynaptic elements in flattened vesicles reported in Holocentrus.3’ Stratum opticum. The horizontal cells of this layer (Type III of Meek and Schellartso) have similar morphology as those identified in other teleosts 36.50.60.64.69
Stratum fibrosum et griseum super@iale. Pyramidal cells (Type I of Meek and Schellartso) are the major neuronal type of SFGS, and there appear to be various subtypes, not shown in other teleosts. The horizontal and bipolar cells of SFGS are similar to those of other teleosts, but noticeably few in number. In most teleosts (with the exception of Holocentrus) pyramidal cells are mostly found deep in SFGS; in Apteronotus they form clusters at the SOjSFGS boundary and are individually spaced in mid and deep SFGS. Perhaps this corresponds to the segregation of retinal afferents to SFGS. The optic
Round cell of SO Flask shape cell of SO displaced pyramids of SFGS
Horizontal cells of SFGS types a,b Bipolars of SFGS Pyramids of SFGS
Bipolar types: a,b,c,d,e Fusiforms of SGC Horizontal of SGC Aspinous pyramid of SGC Cell of SGC with ascending axon Pyriform types: aii,di,i Pyriform type “a” with efferent axon Candelabra type pyriform Large multipolar type “a” Medium-sized multipolar types: a,b,c,d
SFGS
SGC
Round Glioform
Cell types
so
Lamina
of dendritic branches
Candelabra type pyriform Large multipolar types: a,b,c,d Medium-sized multipolar types: a.b,c.d,e Bipolars of SFGS Horizontal of SFGS Medium multipolars of SAC
Bipolar of SFGS Horizontal of SFGS Bipolar of SGC, type “d” Large fusifonns of SGC Spinous pyramid of SGC Aspinous pyramid of SGC Large multipolar types: c,d Pyriform types: ai,b,d,h Horizontal cells of SFGS, types: a,b Bipolars of SFGS Pyramids of SFGS (optical tier) Pyriform types: a,b,d,g,h Pyriform types: a and bi with efferent Large multipolar type “d” Medium multipolar types: a,b,c,d,e Bipolar of SGC types: a,c,d.e Fusiform of SGC Bipolar types: a,b,c,d,e Fusiforms of SGC Horizontal of SGC Aspinous pyramid of SGC Cell of SGC with ascending axon Pyriform types: ai,aii,b,c,d,e,f,g,i Pyriform type “a” with efferent axon axon
~~~____
2. The constituents
-Round cell of SM 4lioform of SM ---Pyramidal cell of SFGS -Pyriform cell types: b,d -Pyriform type “a” with efferent axon -Cell of SGC with ascending axon Round cell of SO
Origin
Table
Intrinsic
axon
semicircularis
Torus
Pyriform types: aii(IPL),b(mid SGC and IPL), c(mid SGC), d(deep SGC), f(IPL), i(IPL) Pyriforms with efferent axon types: b and bi(IPLa mid SGC), and c(deep SGC) Medium size multipolar types: cd Bipolars of SFGS Pyramidal of SFGS and SO Medium multipolars of SAC
of SGC
Horizontal
axon
b,d
(sparse)
types:
Retina
multipolar
axon
longitudinalis
(very dense)
Extrinsic
Retina Torus semicircularis
Retina
Torus
Origin of axonal terminal fields
Cell of SGC with ascending Bipolars of SGC types: a,d
Medium
Type “b” pyriforms Type “a” pyriform with efferent
Cell of SGC with ascending Horizontal of SO Horizontals of SFGS
of SFGS
cell of SM
Small bipolar
Round
of each lamina
tier
of
the
Ciymnolid
superficial
SF(;S. other
in
tree
SFGS; w”““’ density basilar
input.
cell
sqregatcd
this arbor
OnI!
in Romcskie to terminate
Pyramidal
10 those lrith x+ors
tnisaligned
pyramids
wre
in other
and
(xc
Functtonal
effrren\
axon.
cells OI’SC;~‘.
grcatcr
hpolat-
llletllloncd
bul
pyrll‘~xn~
the bipolat-
WC.
and medium-hi/cd
and there appca~- to he a
()I‘ these cull type\ Prcsumahlq
khan descrthai
fusil’ot-m
;LYO~ (Tbiw same
sho\vn
of Meek
characteristic5
in other
to prc$xt
input
ccl1 of’ XC’
XII
in
tcleosts.
111
thus I-clatc‘s 10 the prcr-
cessing of the larpc clcctrosensor~
the
cells v.tlh
Ill :3/wY~~to/tr.v all tt1c aho\c
tcleo\ts.
crook
cells. I‘u~tlorm multtpola~
domina\c
large
ccntralc
and
Lartctl
The
ccvirrdc
cllhrfrfl
griswm
;~xon. pyramidal
horizontal.
cells are pi-cscnt. multipolars
crook
kctum. I‘unctic~nal
Aspect\).
tbpcs of the stratum
shepherd‘s
15tt h
more l’requcn~ 111
impot-(ant
tcleost5 NC as Ihllous:
ol‘othcr cells \\ith
at-c
Ictc’ost\
01‘ lhcit- apical.
y/.\c111)1 c.c,trtr.trlc trurl .strtrlrrt,l
The neurw-tal
wet-k. IS or in mtd
c:~udalmost
have
I<
111 mod
In our malcrt;tt
relativcl>
may
dendrite
arbor
in IPI.
centers
1;lt-
to reach
tiers. M htle pyramtd\
\entraltnost
implications
ctthcr
are not tnentioncd.
misaligmncnt
allwing
and Sharma’h
aligned
and dtstal basilar
.Strrrfl,tu
dilTcrcnt
Input
one
cells dcpictcd
misaligned
other
only
shown
medialmost.
1hu\
the basilar
forms
SGC.‘”
This
subtypes
tclcosts
usually
limited proximal
the
The deepcl
reach
elcctroscnsor~
In other
and ,,4I,‘)
tiers)
the
,II
rn~d SGC and f’or deep SC;C‘) xcording
the arbor. similar S(;C,‘”
deep
with
iz prcatcst
in .-lptero/to/rr.,.“~,“’
pyxmidal
laminarty
or
correla(cs
which
tn
dcntlrttic
mid
in
this
(electroscnsory
(IPL.
the
ramifies
houndxy tier<
depths to
fish
ccl1 ramitics
the qui\;tlent
“” presumably
01‘ retinal
SO/SFC;S
pyramidal
whereas
to th14 layer.
\btth
shcphcrd’h
and Schcllart’“)
Ci!mnotiJ\.
;I\
hax rh<~
This ccl1 has hecn repclrted
(0 n. ~lrc~h~il;imicua. _” torus sc’illtctt-cLtI.iris.”
and n. i\thmi.“’ .Anothcr with
I‘usii’orm
a deep polar
wrrcspond
cell V.;IS ohscr\cd axon
altering
to the pro.jcction
in (;!mnc~ttd~.
SAC‘. Thih cclt ma> ccl1 Type
YI
of Clcck
and Schcllart‘”
,tnd to ;I SOIIIC‘LLhat s1m11;11ccl1 draa n
by
\+ith
Lcghissa.“:
I‘rotn
the basilar
The
Larious
Gymnntids
XC
bipolar
and
arc tither
hipolar
rostrocaudal the multipolar
shafi
FIN.
estcnt
lot:
in ~11s
cc‘11 01‘
hq the aptcat and one’ tn SO SFCiS
or an a171cal ;~rhot- tn
desccndtng
M;IS obser\cd
cells of’ !X(
prcwn(
GIII hc ground. (~\o~d
located
tn SC;C‘ SAC
and ;I basilar
one c;tsc fhc axon The
1’1 trl.. “” and
The
dendrites
the o(hct-
SO’SM
type\
to the bipolar
(‘I (II.“’ The pcrikary:t
or fusifi>rrn. basilar
cell
bear a rcscmblartcc
01‘ FIN. 3 01‘ Vancgaa Schrocdcr
a\011 ort$nattng
;I descending
5hafi.
are
tn(o SAC’. In
entcrtng l’ound
01‘ [hc lectum;
deep XC’. tn Ihc
and togcthcr
cells. arc the prevalent
ncuromtl
MhOIc htth tcpcs
in the caudalmost Icctum 01‘ lp/~~~~~u~~~~/~.\. The difTcrencc\ \vith hipolar reporrcd in olhcr studtc5 arc.
242
f
SAS and I.. MALIK
the longer vertical extent of the dendritic shafts and the greater diversity of bipolars encountered in our material. In Gymnotids, the multipolar cells of SGC and SAC form a more varied population than those shown in perciform teleost.hY goldfish,5”.h” other teleostean optic tectumjh and squirrelfish.““ These invcstigators point to two subtypes of large multipolar cells; one with a preferential horizontal spread but possessing one ascending branch to SFGS, and the other with a preferential vertical orientation reaching SO. These two types do not appear to cover all the different varieties of multipolar cells reported in frog4” and birds,5’ each projecting to specific target areas. In other teleosts the medium-sized multipolars are usually represented as having a medium width arbor confined either to the adjacent parts of SGC/SFGS, or to deep SGC and adjacent SAC. In our Golgi material we were able to observe all the projection multipolar cell types corresponding to ganglionic cells of layers 6 and 7 reported by Lizir c’t al. in the frog,J” using the cobalt method. The large multipolar neurons of Gymnotids are oriented as follows: (i) in the horizontal plane; (ii) mainly in the horizontal plane with usually one vertical component (see also section on Functional correlations), (iii) in both horizontal and vertical planes. Within the third group there are variations according to: (a) the layers they contribute via their dendritic branches: (b) the retinorecipient layer they reach via their single or multiple ascending dendrites (SO or SFGS); (c) the characteristic manner of termination in the visuorecipient layers SO and SFGS which may be via a single terminal branch, serial tufts. or bifurcating and spreading horizontally, and (d) the width of the dendritic arbor in SGC and SAC. The large multipolar cell with a horizontally oriented soma greatly resembles the fusiform ganglionic cell projecting rostrally of Liz&r et u/.,~” while the triangular multipolar is similar to Ram6n y Cajal’s.s” Fig. l45b cell. which he describes as a ganglionic cell with thick protoplasmic expansions, possessing an efferent axon. The large ovoid multipolar cell of SAC with a lumpy surface. bears a certain resemblance to the Meek and SchellarP’ Type XIII? cell. and to a ganglion cell of layer 6 in the frog. 4” This cell was shown by the latter authors to project to contralateral rhombencephalic levels via the tecto-bulbo-spinal tract, and respond to small moving objects. Lgzlr cutul.” suggested that the large ganglionic neurons of layer 6 in frog are probably responsible for orienting responses to prey. The multipolar cell of SAC with a round soma displaying filiform appendages, and a chiefly horizontal dendritic orientation, with usually a single ascending dendrite towards more superficial layers, is a projection neuron with an axon leaving the tectum via its deep aspect. A similar cell is present in goldfish,hO and in the frog optic tectum, where it was shown to project to the contralateral rhomben-
cephalon.“’ The only diff‘crencc IS the more tromplctc impregnation of the ascending dendrite in Romcskir: and Sharmn’s”” material, ‘ A large multipolar cell of deep SGC 1> ;! t>p~cal example of a horizontal cell confined to the deep layers. This neuron possesses a wide horizontal dendritic tield in SGC which receives elcctroscnsor\ input, and another small field in the SGCi’SAC’ border. It is comparable to cell “d” in Fig. I46 of Ram6n y CajaP in Barbus.$uu’rttilis. The rest of the multipolar cells have a medium-sized soma and arc more frequent in SGC than in SAC. The multipolar cells of SGC probably correspond to the ganglionic cells of layer 7 in frog. 4” These cells were shown to receive dimming and event detector types of retinal information, and to project to ipsilateral spinal cord.4o Chung et ~1.“’ proposed that these neurons arc probably involved in the escape behavior of the frog, when turning away from a threat. Afferents to the neuropil of SGC were reported from ipsilateral telencaphalon to mid SGC, and from contralateral optic tectum to the SGCjSAC border by Ito c’f trl..” Meek,” and Vanegas and Ito,‘” among others. In birds and frogs, cells of SGC have been reported to contribute to the descending tectofugal pathways,‘?.4os9 thus pointing to the importance of these deep layer cells in the initiation of orienting behavior of the animal in response to multimodal sensory stimuli via these descending tectofugal pathways to premotor areas of the lower brain stem. One cell type of SGC appears to be unique to Ap?cvonotus and Eigenmunniu this is the cell with an ascending axon to SO. A remarkably similar cell type has been identified in birds by Ram6n y Cajal.5” The basilar dendritic arbor of this cell would allow it to sample the electrosensory input to SGC while its ascending axon would permit it to influence the pyramidal cells which receive a dominant retinal input. Interestingly the axonal plexus was asymmetric with respect to the dcndritic arbors. Strutitm
peril~entricularr
This deepest layer of the optic tectum houses the various interneuron and projection types of pyriform cells. In Gymnotids eight main varieties of pyriform cells with intrinsic axons can be distinguished, two types without an apparent axon and four projection types of pyriforms. The dendritic contributions to the various layers arc too diverse to build a classification upon them; but they cannot be disregarded due to their functional implications. In Gymnotids the apical dendrite may have: (a) a single terminal apical arbor; (b) contribute via horizontal or oblique branches to different combinations of two layers, and (c) contribute to almost all the layers. The surface of the apical shaft is either smooth. nodose, spinous in specific laminae, or bears only a sparse amount of spines, according to the pyriform cell type. The somata of some pyriform cells may also bear a small number of spines. No mention of these
morphological tectal
difkrenccs
Tlpcs
clcctroscnsory
Golgi
and
c
the tcctum;
usually
Some recognired
three
as follows:
(I
others
notids.
main
by
patterns
that
as
pyriform
axons
can ramify
is
SFGS:
(b)
in
displaced
and
patterns
have been reported
ctTcrcnL
pyriform
of
the
Equivalent
in the goldfish.‘“.“‘-“”
types
identified
and frogJ”
in
also
are
in
its
clcctroscnsor)
localion
and
iological
studier
that
it
is
system
elcctrocommunication; of the Gymnotid
involved
dem(mstratcd
in
and elcctroscnsory predominantly spond thi\.’
’
pyramidal
The
corrclatcs.
Most
point
that
;I
rctlnal
Input
\+ill
input.
Deep
tcctal
01.
may
~XYI
not
he
moving
found onl!
that
fish’s
similar
\+a
able
till\
IC;ISI
<)I’ Rose
some
and
14A
plrilorm the
\ISLI;II
pyramidal
cases
partially
and
16B.
cell “Type input cc‘lls
type.
When
jammed
with
the
visual response
intracellular
of SGC
that
It is possible
cells
tcctal
is
units
at to
and SAC‘
and one variety
l7D).
these most
lost their
cells correspond
respectively) to
For
and
objects.
have shown
multipolars (Fig.
The
derived the visual
since dendrite
its
(cattish) useful
charactcri\tlc poldli\h
(\cc‘
PI-L.~uniabl\
b).
stud)
b;1w
and
tkpc
lhis
wilt
In comparing
ol‘thc
tiitTercnccs
pi-cl\c
10 bc
11
01’ nc‘uIona1 Ii;15
~111 oricntln~
in c)thcr
tcIco~I~
\+tilcli
ltik
liiducc
IS
circuitr): disrup(ed location
and loru\
an
compared
tecluni.
tc\cl.
conipatiblc
Mill
hbpcrapparcnl
Iihcl) ttial cmci-y al the
;Znothct-
c~ol\cd
\\lth
the
po\\ihllit!
i\
~1 [ha1 it\ Icct;il
mot-c
\l;iblc
alloy the ~cctum IO used for orlcntalion
this would the circultr! and nicrel~
IO Itic
It is of c‘ouI-5c
11~5
circuilr)
\cnilcIrcul;iris
by the rcmarh.;lhle
in tcctal circuitr\
microscopical
Ihc toral
output
i’lcclrosen~c~r\
l‘rotn
stimuli
the Icctuni
of the torus.“““.’
electron that
that
to
one is struck
conscrvatlzni more
~niphes
I‘hc
d~tl’~_~n~
communicallon)
ha\ e~ol\cJ
respond
11,
I-cllcs.
ol‘Gymnntidz trophy
t>pc
cvc~ltitloii
(personal
that the JAR
I‘uiiclioii
cIcc~romo~oI
ni;i~’
the
;~nd
Rt,mc\klc
pas\ivct\
IO clcaniinc
Hciligenberg
response cell
;I smgle
lllol-ptlolo~~.
ccl1
01‘ this
large
11 111 boLh
II\ original
b> the clcctro\cnsor! altcrin F II\
:I
ltiarure
and ~LIISC Gyninotids
systonis.
and
cell I! p’c i\ cspcc~all~
allo\+\ us to idcntll‘\
and
wan
01’ ;I jammln~
cells
latrc~-
The
I‘urthcr-
for Ihc JAR.“
to the slsn
pyrlform
teleosts~nonelcctrosensory.
orienting
at ;I frcqucncy
restore
ob.jects.
multisensory
f”
may
Bastian’
simultaneous
Helligenbcrg”’
thcsc
large and medium-sired (l;tg
was
interesting
suggcstcd
always
metal
of either
discharge
to moving
01‘
SAC)
input.’
only
;I
clcctrosrnsory
many of these units
sonic
to
We there-
electroreccptors lo
system
oun.
den-
to
Ii).
01 the pa--
to the lcc(tim.
to bc essential
rc\poncl
ascending
physiological
receive
response
and
by visual
organ
In
(clcctrosensory)
can
and the response
or objects
electric
to the fish.5
input
(SGC
clcctroscnsory
rcbponsl\‘cncs~.
basilar
projccl
man!
to
)x1-1\
OCC’LII-\111
analy\l\
and tha(
both
has hecn usurped
functional
coll~‘ag~~c‘s”~ “I h;l\c
one \tagc of this
(Fig.
without
OI- Ic+ than
the animal
appears
;I
M hcthcr
grcatcr
ditl’crcnt
cells
Fig.
tlctcrminc
bctwccn
which
multipolar”’
to
01‘ ;I neighhol-lng
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from
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maps
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ing
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anti
ircs(c;IrcJi
244
F. SAS and L.
activity.“,“” Competition for synaptic targets is one of several mechanisms which probably operates to ensure a proper topography for this maprR and may in fact be a mechanism generally used during development to organize neuronal connectivity.35,‘h” If two retinas project to one tectum, either naturally or as a consequence of experimental manipulation, the terminals of the two retinas will occupy disjunct patches of the tectum (see for example Refs 4, 21 and 45; or Ref. 16a for a good review). Retinal efferents to the tectum terminate in three dimensions, but developmental studies have concentrated on only two and have generally ignored the third one-tectal depth. The work of Grubergz4 does suggest that under experimental conditions, non-retinal (somatosensory) input might be able to compete with retinal input for synaptic targets. Since the toral input to SFGS occupies patches disjunct from those of the retinal input to this layer, we propose that these two inputs (TS and retina) compete for synaptic targets in SFGS, and that SFGS is well-developed because TS input has replaced the deficient retinal input. A surprising consequence of this hypothesis is that different sensory inputs can “use” the same tectal circuitry (see Discussion above). In lower vertebrates the retina and tectum continue to grow in the adult animal, and the optic fiber terminals must continually shift their sites of termination across the tectum.‘5,5”“,66,67In Gymnotid fish this problem is further compounded by the need to maintain the congruence of the dominant electro-
MAL~K
sensory map with the visual maps.“’ The cicctrosensory system also changes with the animal growth. Up to about 10-12cm body length, the number ot electroreceptors continues to increase,” as does the electrosensory lateral line lobe and TS (Malcr. unpublished observations). This suggests that the torotectal map may also require continual readjustment. After the animal reaches 12 cm body length the number of electroreceptors remains constant.~ ‘? although the animal can continue to grow to ~~11 OVCI 20cm. Therefore, after 12 cm body length the distance between electroreceptors starts increasing;’ il the retina and tectum continue to grow after the fish has reached this body length it might rcquirc other types of synaptic rearrangements to maintam congruence of retina, tectum and the torotectal map. It is fairly simple to partially destroy the Gymnotid electroreceptor ganglion,“’ TS. or retina and it may even be possible to substitute a larger eye toi- the Apteronotus eye (from some species of Eigenttum~icr with large eyes, for example). Apteronotid fish may prove to be an interesting system for the study of synaptic competition and remodeling in the third dimension of the tectum.
Acknowledgements-The authors wish to thank C. E. Carr for some of the Apteronofus Golgi material, W. Heiligenberg and G. Rose for helpful comments on the physiological aspects of this study, B. Goodwin for typing the manuscript and Bill Ellis for photographic assistance. This work was supported by the Medical Research Council of Canada.
REFERENCES
1. Allon N. and Wollberg Z. (1978) Responses of cells in the superior colliculus of the squirrel monkey to auditory stimuli. Brain Res. 159, 321-330. integration of sensory information in the optic tectum of the w,edkty 2. Bastian J. (1982) Vision and electroreception: electric fish Apteronotus albifrons. J. camp. Physiol. 147, 287-297. 3. Bastian J. and Heiligenberg W. (1980) Neural correlates of the jamming avoidance response in Eigenmannia. J. wmp. Physiol. 136, 135-152. of ocular dominance patches in dually innervated tectum 4. Boss V. and Schmidt J. T. (1984) Activity and the formation of goldfish. J. Neurosci. 12, 2891-2905. 5. Bullock T. H. (1982) Electroreception. Ann. Rev. Neurosci. 5, 121-170. 6. Carr C. E., Maler L., Heiligenberg W. and Sas E. (1981) Laminar organization of the afferent and efferent systems of the torus semicircularis of gymnotiform fish: morphological substrates for parallel processing in the electrosensory system. J. camp. Neurol. 203, 649670. 7. Carr C. E., Maler L. and Sas E. (1982) Peripheral organization and central projections of the electrosensory nerves in Gymnotiform fish. J. camp. Neural. 211, 139-153. 8. Carr E. C. and Maler L. (1985) A Golgi study of the cell types of the dorsal torus semicircularis of the electric fish Eigenmannia: functional and morphological diversity in the midbrain. J. camp. Neurol. 235, 2077240. 9. Chalupa L. M. and Rhoades R. W. (1977) Responses of visual, somatosensory and auditory neurons in the golden hamster’s superior colliculus. J. Physiol., Lond. 270, 595-626. of optic afferents in the amphibian 10. Chung S. H., Bliss T. V. P. and Keating M. J. (1974) The synaptic organization tectum. Proc. R. Sot. Lond. (Biot.) 187, 421. 11. Contestabile A. (1976) Laminar acetylcholinesterase localization in the optic tectum of five seawater teleosts. Experimentia 32, 625-627. organization of monkey superior colhculus. J. Neurophysiol. 35, 12. Cynader M. and Berman N. (1972) Receptive-field 187-201. 13. Driiger U. C. and Hubel D. H. (1975) Responses to visual stimulation and relationship between visual, auditory and somatosensory inputs in mouse superior colliculus. J. Neurophysiol. 38, 690-713. 14. Druian B. D., Diaz Barges J. M. and Brzin M. (1973) Histochemical and cvtochemical localization of acetvlchohnesterase in retina and optic tectum of teleost fish. ban. J. Biochem. 57, 43: 15. Easter S. S. and Stuermer C. A. D. (1984) An evaluation of the hypothesis of shifting terminals in goldfish optic tectum. J. Neurosci. 4, 1052-1063. 15a. Fawcett J. W. and O’Leary D. D. M. (1985) The role of electrical activity in the formation of topographic maps in the nervous system. Trends Neurosci. 8, 201.-206.
236
E. SAS and L. MALEK
54. Northmore D. P. M., Williams B. and Vanegas H. (1983) The teleostean torus longitudinals: responses related to eye movements, visuotopic mapping, and functional relations with the optic tectum. J. camp. Ph,vsiol. 150, 39- 50. 55. Northmore D. P. M. (1984) Visual and saccadic activity in the goldfish torus longitudinalis. .I. conzp. Pl~.vsrol 155. 333-340. 56. Oswald R. E., Schmidt J. T., Norden J. J. and Freeman J. A. (1980) Localization of alphabungarotoxin sites to (he goldfish retinotectal projection. Brain Res. 187, 113. 57. Potter H. D. (1969) Structural characteristics of cell and fiber populations in the optic tectum of the frog (Rcma cutesbeianu). J. camp. Neurol. 136, 203-232. 58. Cajal S. R. (1955) Histologic du SystPme Nerveux de I’homme et des VertPbrt%, Vol. II, pp. 217 -226. Consejo Superior de Investigaciones cientificas, Madrid. 58a. Reh T. A. and Constantine-Paton M. (1984) Retinal ganglion cell terminals change their projection sites during larval development of Rana pipiens. J. Neurosci. 4, 442457. 59. Reiner A. and Karten H. J. (1982) Laminar distribution of the cells of origin of the descending tectofugal pathways in the pigeon (Columba litlia). J. camp. Neural. 204, 165-187. 60. Romeskie M. and Sharma S. C. (1979) The goldfish optic tectum. A Golgi study. Neuroscience 4, 625-642. 61, Rose G. and Heiligenberg W. (1984) Neural correlates of the jamming avoidance response: df.-sign-specific neurons in the optic tectum of the electric fish Eigenmannia. Sot. Neurosci. Absfr. 10, 403. 62. Sas E. and Maler L. (1984) Retinofugal organization in two Gymnotids, Eigenmannia uirescens and Sfernarchus. Sot. Neurosci. Abstr. 10, 459. 63. Sas E. and Maler L. (1986) Retinofugal projections in a weakly electric Gymnotid fish (Apteronotus leptorhynchus). Neuroscience 18, 247-259. 63a. Scheich H. and Ebbesson S. 0. E. (1983) Multimodal torus in the weakly electric fish Eigenmannia. In .4dcances IW Anatomy, Embryology and Cell Biology, Vol. 82, pp. 168. Springer, Berlin. 64. Schroeder D. M.. Vanegas H. and Ebbesson S. 0. E. (1980) The cytoarchitecture of the optic tectum of the squirrel fish. Holocentrus. J. camp. Neural. 191, 337-351. 64a. Sharma S. C. and Romeskie M. (1984) In Comparative Neurology of the Optic Tectum (ed. Vanegas H.), pp. 163 183. Plenum, New York. 65. Stein B. E., Magalhaes-Castro B. and Kruger L. (1975) Superior colliculus: visuotopic-somatotopic overlap. Science 189, 224226. 66. Straznicky K. and Gaze R. M. (1971) The growth of the retina in Xenopus laevis: an autoradiographic study. J. Embr.yol. exp. Morphol. 26, 67-79. 67. Straznicky K. and Gaze R. M. (1972) The development of the tectum in Xenopus laeuis: an autoradiographic study, J. Embryol. exp. Morphol. 28, 87-115. 68. Szabo T. and Fessard A. (1974) Physiology of electroreceptors. In Handbook of SensoryPhysiology (ed. Fessard A.), Vol. III, pp. 59-124. Springer, Berlin. 69. Vanegas H., Laufer M. and Amat J. (1974) The optic tectum of a perciform teleost. I. General configuration and cytoarchitecture. J. camp. Neural. 154, 43-60. 70. Vanegas H. and Ito H. (1983) Morphological aspects of the teleostean visual system: a review. Brain Res. Ret’. 6, 117 137. 71. Witovsky P., Powell C. and Brunken W. J. (1980) Some aspects of the organization of the optic tectum of the skate Raja. Neuroscience 5, 1989-2002. 72. Zakon H. H. (1984) Postembryonic changes in the peripheral electrosensory system of a weakly electric fish: addition of receptor organs with age. J. camp. Neural. 228, 557-570. (Accepted
IO October 1985)
of Anatomy.
Faculty
of Health Sciences, University of Ottawa. Ott;twa. Ontario KlH 8M5. Canada
451 Smjth
Rnxi.
Abstract Golg~. Nissl, Bielschowsky and cholinesterase techniques have been used to analyze the optic tectum of the ~cakly clcctric teleost tish Ei~mnranniu rirrscens and Aprcronorus keprorh~nc~huc. Six layer\ r~rc rcad~ly dlstlnguished: a fairly thick stratum marginale. a narrow stratum opticum and stratum librosum et grlseum supcrficiale. a well-developed stratum griseum centrale, a stratum album centralc and ii compact stratum prrivcntriculare. Fifty-six neuronal types are present. In regard to comparative aspects of tectai organization. it became apparent that although most neuron~~l rqpcs are similar to those reported m other telcostean fish, there are certain obvious differences such 35: ti) pyramidal ccl1 somata not confined to stratum fihrosum et griseum superficiale, but also clustered in tlte aci~acent stratuni opticurn. presenting stratified or diffuse basilar dendritic arbors: and a change from vertlcai IO oblique and almost horizontal neuronal orientation in the ventral and caudal &turn. (ii) The presence of pyramidal cells with aligned and misaligned apical and basal dendritic tieids. (ii)) PI cell of
The cbptio tectum of lower vertebrates as well as the superior colliculus of mammals arc important targets for highly topographical visual and multisensory input\. which convcrgc upon tectal neurons. This complex sensory information is fed via descending tcctol’ugal pathways to motor centers of the lower blain stem and spinal cord, thus resulting in the orienting hchavior of the animal towards stationary or moving objects. The deep tcctal layers have been shown to contrihutc to the des~~n~iing tcctofugal pathways presumably rcsponsiblc for the motor responses in frog, .‘N birds.“’ fish” and mammals.” in most vcrtcbratcs the tcctal celis in the superficial lavers rcceivc topographically organized visual 4i.Wh2.711Nhich is completely or partially inpui. 111-1: crossed according to the species, whereas the dcqx~r laycrb rcccive a wide variety of other sensory
.~llr/~~r~r~,r,cio,f.\ : IPI_, Inner plexiform laqcr; JAR, Jamming ;i\ oitiance response: SAC. Stratum album centrale: St GS. Stratum fihrosum et griscum supcrficiale; SGC, Stratum grismm ccnt~tk: SM. Stratum marginale: SO. St!-atum opt~cum: SP\‘. Stratum pcriventricuiare~ TS.
-rcbrtis w3nicircuktris
modalities,
including
auditory’.‘5 ” and somatctBesides these ubiquitous nonvisual sensory inputs. certain species have devclopcd special sensory organs, such as: heat sensors in rattlesnakes and pythons.‘h.‘2 electroreceptors in various teleosts.hx chemoscnsitivc finrays in the tclcost and these non-visual modalities Prionotus carolinus.‘b will also be represented in the tectum. Although a few superficial tectal units receive only visual and other deeper units only unimodal non-visual input. in most vertebrates the overwhelming majority of deep tectal neurons reccivc visual and ~~t~iti~n(~~i~~i sensory information. The visual and non-visual inputs to the tcctum at-c generally in topographic register (visual and Inl‘rared heat sensory input.2h.S’ visual and auditory information,*‘,” visual and somatosensory input” ‘_ ‘l”‘). and this alignment is dependent upon proper scnsorb input? Taking into account the above informatlon pointing to the large variety of sensory modalities converging upon tectal neurons also receiving visual input, it is not surprising to find that the clectrosensory system of Gymnotids reaches the tcctum‘.“““’ and that this input is also in topogr~~phi~ register wtth sensory,9.‘?,‘2.1h.17.19.30.hS
216
I?, SAS and
L.
MAL~K
Table 1. Thickness of the tectal lamina expressed as a percentage of the total tectal thickness Ap~eronotu.s
Eigenmmnia
Mid
Caudal
Mid
Caudal
18 18 31 15 IX
15 20 34 II 20
14 14 39 II 22
23 20 37 II 9
22 16 40 13 9
16 16 42 I1 15
100
77
72
100
64
54
Rostrai
SM SO/SFGS SGC SAC SPV Total
Rostra1
Measurements were made at rostra], mid and caudal levels and the bottom line (total) is percentage of tectal thickness in comparison with the thickest (rostra]) portion. These measurements were made at the dorsolateral aspect of the tectum; the percentages are somewhat different at the dorsomedial and ventrolateral aspects. Note that the caudal tectum is more drastically reduced in Apferonotusthan Eigenmunnia; this correlates with the reduced retinal input in the former species.“’
the visual input. 2,6 These two sensory modalities appear to converge on the same tectal cells, since Bastian’ reported that many cells of the optic tectum in Gymnotids gave good responses to both visual and electrosensory stimuli. Many other deep t&al cells of high-frequency Gymnotids are responsive to only electrosensory input and may be specialized to analyze electrosensory input related to communication.6’ The aim of this work is to compare the anatomical organization of the Gymnotid tectum with those of other non-electrosensory teleosts, and to correlate it with recent electrophysiological results in Gymnotid fish. METHODS
Rapid Golgi and Golgi-Kopsch material was drawn from a large collection prepared by Maler,4s and new additional material was prepared from 10 small Apteronotus lepforhynchus intracardially perfused with buffered aldehydes4* and stained with Valverde’s rapid Golgi method. Bielschowsky, cresyl violet and cholinesterase? material was also drawn from a previously prepared collection. Wheat germ agglutinin conjugated to horseradish peroxidase (Sigma Chemicals) was iontophoresed into the torus semicircularis of four ApteronotusIeptorhynchus,using pipettes broken to 10-20 pm. A Midgard constant current source was used with currents of 050.8 PA for 3-8 min. After 3-4 days’ survival times, the animals were perfused with 1.25% glutaraldehyde-1% paraformaldehyde in phosphate buffer, followed by 20% sucrose in buffer and sectioned the next day at 40 pm on a freezing microtome. The sections were treated according to the procedure of Mesulams’ and counterstained with neutral red. RESULTS
of Vanegas et al.,@ since this corresponds closely to the laminar pattern of Gymnotids, although the scheme of Meek and SchellartSo is used to designate the cell types, when found to be comparable. The laminar pattern and cellular morphology are generally similar in both species of Gymnotid and a We adopted the nomenclature
(see Fig. 1) for the tectal laminae,
distinction between Eigenmannia and Apteronotus will only be made where differences have been noted. Cytoarchitectonics of the gymnotid optic tectum
In general the Gymnotid tectum conforms to the teleost plan50,69as seen in Nissl, reduced silver and cholinesterase preparations (Fig. 1). From surface to depth the layers are: stratum marginale (SM), stratum opticum (SO), stratum fibrosum et griseum superficiale (SFGS), stratum griseum centrale (SGC), stratum album centrale (SAC) and stratum periventriculare (SPV). The SM and the deeper layers, SGC and SAC, are better developed than the thinner SO and SFGS (see Table 1). Acetylcholinesterase histochemistry (Fig. KY). There
is a dense band of cholinesterase in SO which extends slightly upwards into SM and downwards into superficial SFGS. A second band is present in deep SFGS. More moderate staining is also seen in mid SGC and somewhat more intense in SPV. The laminar distribution is similar to that found in other teleosts,‘i,‘4.‘6 but it is less complex in SO and SFGS, presumably due to the relatively poor development of these layers. In SO and SFGS the cholinesterase is present as patches. The patches in SO are aligned with and connected to those in SFGS. A patchy distribution of cholinesterase has been described for the mammalian superior colliculus mid gray layer,” but does not appear to have been seen in other teleosts. Toral a&rents to the rectum (Fig. ZA). A large toral input to the Gymnotid tectum has been demonstrated.6*638Recently we have repeated these studies using a more sensitive tracer (wheat germ agglutinin conjugated to horseradish peroxidase). Although our description6 was correct in terms of its topographical organization, we now62,63find that this projection is even more massive than previously suspected; because this result is so important for the functional correlation of our Golgi results, we include it in this paper.
Fig. I. Photomicrographs of transverse sections through the optic tcctum. (A) Bielschowsky stain shows laminar distribution of axonal plexuses. (B) Ntssl stained section illustrates the layers of the tectum: SM. stratum marginale: SO, stratum opticum: SFGS. stratum tibrosum et griseum superficiale; IPL. mner plexiform layer: SGC. stratum griseum centralc: SAC. stratum alhum centrale: SPV. stratum periventriculare. Tectal laminae in (A) and (B) are aligned. (C) Specific laminar distribution of acetylcholinesterase in the tectum of Apteronotus. Bar: 50 nm.
Fig. 2. Photomicrographs of transverase sections of optic tectum. (A) Following horseradish peroxidase injection into the torus semicircularis, note sublaminar segregation of toral input in SAC, mid SGC, and a patchy termination of tufts in SFGS (arrows). (B) Horseradish peroxidase filled retinotectal afferents in superficial SO, SO/SFGS border, mid and deep SFGS, mid SGC and SACSPV interface. The retinal projection is only dense at SOjSFGS boundary. This material was taken from our companion paperO) to assist the reader. Bars: 50 pm.
SFGS
SGC
f’SM
SFGS
C
Fig. 5. Camera lucida drawing of pyramidal cell types. Pyramidal cell in (A) has a semiovoid soma. a stratified basilar dendrite and an axon (ax) which forms a “descending” loop in SGC. (B) Two pyramidal cells that form part of a cluster, one has a semiovoid spinous soma, with a basilar arbor confined to SFGS. the second cell shown in dotted lines is a pyramidal cell with fusiform soma with the basilar arbor in mid SGC. (BI) Insert shows an example of a pyramidal cell with two apical dendrites, and a lack of basilar trunk. (B2) Insert is an example of assymmetric pyramidal cell. (C) Pyramidal cell with inverted pyramidal shape, has stratified basilar arborizations in mid and adjacent deep SGC. The axon descends without a recurrent loop. (D) Pyramid with fusiform, sparsely spinous soma, and a diffuse pattern of the basilar dendrite. The axon forms a small “ascending” loop hefore descending to ramify within its basilar dcndritlc field. Arrows indicate axon. Insert in (D) shows detail of somatic spines of a pyramidal cell. Bar for (A. B, C and D): 25 pm. Bar for (BI) also applies for (82) insert: 50 /irn.
219
The
optic
tectum of Gymnotid
fish: a Golgi
t.lg. 3. Camera lucida drawings of Golgi- Kopsch preparations. intcrneurons: (A) glioform cell; (B) horizontal cell with round 3 /tm.
Tor,ll tibcrs end in moderate numbers within SAC and deep SGC. as previously noted. They form a very dense (crminal field in the mid cellular layer of SGC uhich continues unabated through the inner plexiI’orm laqer (IPL). Small tufts of terminals continue Into SFGS; where they reach into approximately the middle of this lamina. These tufts in SFGS (Fig. 2A) l’orm ;i \cry regular array and the terminal patches arc ncvcr in the neuropil below the cell clusters 01 superficial SFGS’SO border (see below). Thus, the clectroscnsory input to SFGS is in patches disjunct fr-om I hc retinal input. which preferentially terminateh upon the cell clusters (Fig. 2B).
A description of the neuronal types and composltinn of the neuropil of each layer will follow. .S/~r//rr/~ mwgide. As in other teleosts the stratum marginale contains the densely packed parallel fibers nhich arise from the cells of the torus longitudln;~lis.7ii One cell type with a round soma and a ~cond glioform cell type (Fig. 3) have been seen in the SRI: both types of neurons are very sparsely distributed. The cell with a round soma has one or IV,O thin dendrites which run horizontally within SM and scarcely branch. These dendrites rarely bear hplnous processes; a fine axon originates from the ticndriric shaft and courses horizontally. The plioform neuron has a characteristically fusiform anti rugged soma, with several thin dendrites which branch rcpcatedly within a small volume of
A
study
Two types of stratum marginale (SM) soma. .Arrow indicates axon (ax). Bar
SM. The dendrites spine.
have small nodosities
and a rare
Strufutn opticurn. SO contains a sparse population of horizontal cells as well as the somata of pyramidal cells displaced upwards from SFGS; the latter cell type will be discussed with the SFGS pyramid. The horizontal cells are of two distinct types (Fig. 4). One type has a small rounded soma and thin dendrites which branch sparsely within SO. This ccl1 has been observed in other teleosts, and corresponds to Type III (a. b, or c) of Meek and Shellart.i” The other horizontal cell has a flask-shaped soma with its narrow portion pointing to SFGS and giving rise to two dendrites which ramify entirely within SFGS. Typically the dendritic arbor is histratified with one set of branches just below SO and the other roughly in the middle of SFGS; the distal dendritic branches bear fine spines. An axon usually arises from the thicker dendrite and it descends into SFGS; but its further distribution is unknown. This cell type is probably Type III (e) of Meek and Shellart.“’ Stratun~,fihroswn et grisrum suprrficialc. The SFGS contains the somata of pyramidal, bipolar and horizontal cells. The pyramidal cells are by far the predominant cell type of this lamina and this category includes numerous subtypes.
The soma of these cells can assume a scmiovoid. fusiform. pyramidal or inverted pyramidal shape. and according to the subtype and location of the somata.
SM
FIN. 4. Projection drawings of horizontal cells of SO. Axons (ax) are indicated by arrows Bar for (A) and (B): 25 /urn. Bar in (C) 50 ilrn. This and following figures are drawings from rapid Golgi preparation\ unless otherwise specified.
317 ---
E. SAS
and L.
it may possess a significant number of spines. The presence of somatic spines was not reported in other studies of teleost tectum. The somata of pyramidal cells are scattered throughout the depth of SFGS. At the boundary of SFGS and SO. however. they tend to form clusters of two or three cells; it is these clustered pyramids which can intrude into SO. Although we have not studied this point systematically, it is clear that each cluster can contain more than one pyramidal subtype (see Fig. SB). Typically every pyramidal cell has in addition to its apical dendrite within SM, at least two other tiers of dendritic arborizations. A superficial tier in the uppermost portion of SFGS at the SO boundary, and a second tier at SFGSjSGC border. When a third dendritic tier is present, it reaches mid SGC (layer 314 of Meek and Shellarts’). For the most part the dendritic tiers within SFGS and SGC he on the same vertical axis; although on some occasions we found pyramidal cells with the arbors in SFGS and SGC misaligned. Such asymmetric pyramidal cells have not previously been described, and since the morphologic asymmetry may have functional significance, we will describe them separately.
Symmetrical pyramidal cells (Tjjpe I qf Meek and Shellart 50) Most pyramidal cells have an apical dendritic shaft ramifying in SM, a basilar dendritic shaft arborizing in SFGS and SGC, and an axon whose terminal field overlaps that of the basilar dendrites. Exceptions to this rule are: (a) the pyramidal cell with two apical dendrites and no basilar arbor, similar to Ramon y Cajal’s” cell “G” (Fig. 146); (b) the pyramidal cells with a basilar dendritic tier in SFGS, but none in mid SGC, and (c) pyramidal cells without a basilar tier in superficial SFGS, but rather raimfying in SGC. The more common type of pyramidal cell has a narrow thorny dendritic tier in SFGS just below SO. This dendritic arbor may arise directly from the soma, from the apical dendrite or from direct or recurrent branches of the basilar dendrite, but it always has the same appearance and is usually less than IOOpm in width. Because these dendrites ramify in that part of SFGS receiving the densest retinal input,h3 we will refer to it as the optic dendritic tier of the pyramidal cells (Fig. 2B). In some cases, especially in Apteronotus, this optic dendritic arbor is apparently lacking; but then the dendritic trunk passing through the retinoreceptive region of SFGS, is very rich in spines. Perhaps this pyramidal subtype receives less visual input than those pyramids with an optic dendritic tier. The apical dendrites have a small number of spines as they pass through SFGS, they usually bifurcate in SO and give rise to an extensive exuberantly spiny arbor in SM. The apical trees have thick, only slightly tapering dendrites which arborize over 20&4.50~m
MALEK
and overlap extensively with the amcal irccs OI adjacent pyramids. The basilar dendritic tree always has one dendrittc arbor either in SFGSjSGC border, or in the inner plexiform layer (IPL), and may have an additional arborization in mid SGC. Mostly these hasilat arborizations are horizontally stratified, but rn one pyramidal cell subtype the basilar dendrite ramifies diffusely downward from SFGS to mid XX’. The basilar dendritic branches are much thinner than the apical dendrites and are only sparsely spiny. Because the basilar dendrites overlap so extensively m IPL. it is difficult to estimate their horizontal spread, but this is probably at least 200-3OOpm. and is far grcatcr than the spread of the optic dendritic tier. The deeper branches of the basilar dendritic tree are in a position to receive electrosensory input from the torus semicircularis (TS) (see Fig. 2A), and will bc described as the electrosensory dendritic tier. One variety of pyramidal cell deserves special mention-this is the pyramidal cell with the triangular soma which is very frequently found in the Apteronotid fish. This pyramidal subtype differs from the others in the following features: (a) the optic dendritic tier is lacking; (b) the soma gives off two thick apical dendritic branches which inittally run horizontally along the SMjSO boundary; (c) the tertiary branches of the apical tree are obliquely oriented, and arborize over partially overlapping territories within SM; (d) the basilar dendrite ramifies within mid SGC (electrosensory tier). This cell type has been described in the goldfish by Romeskie and Sharma. 6” The pyramidal cell axon usually arises from the basilar dendrite, but can also originate from the soma or the apical dendritic trunk. The axonal plexus of a pyramidal cell is always vertically aligned with its dendritic tiers. Although the axon of a pyramidal cell may dcsccnd to deep SGC, it usually describes a loop and ascends to form a horizontal terminal plexus in exactly those strata of SFGS and SGC where its basilar dendrite ramifies. On a few occasions short delicate nodous collaterals were observed at the turn of the loop, when the axon descended deep into SGC, thus pointing to a clear difference in the axonal pattern of a subtype of pyramids. Asymmetric pyramidal cells (Fig. 5) Some pyramidal cells were found with the optic dendritic tier not aligned with the electrosensory dendritic tier. No other distinguishing features of the dendrite or axon appears to be present; however the asymmetry of the dendritic fields is striking and may relate to functional attributes (see Discussion). The asymmetric pyramid has not been described previously, but the other SFGS pyramids have been reported in numerous other teleosts. The pyramidal cell’s basilar dendritic arbor in IPL has been illustrated in the goldfish, ” but has not otherwise been
SM This
(a)
neuron
incidental
spine.
one side
of
spinous The
I[
descends
ramifies
soma
dendrltic
P
IPl
is
/ +\ ax
at
IPL
arhorlration
telcost:
within
mid
typically SGC
only
the
has ken
deepel
noted.
01‘ lhc
icnglh
boundal->
is
MCII dcvclopod
(IPI.).
diversity
of neuronal
bell
fusiform.
us
a
Lo arc
ported
in other
;I striking
types
A
prcscnr
in
Ci~mnotid~.
strata.
and
Xi(‘)
p! r:tmldal.
\ariet!
;I\
an ;IWII
nc‘uron M lth
gangl~<>n~c
;I
of multipolar.
01‘ niultipolai-
Itian
tliow
and surprisin~l!
to
and ;15 ;I deep
c‘
pl riform.
telcost<.
;I\ \i\ell
S
consl\tlns
wider in
rcscmblancc
7(‘)
The
undescribed
SO.
neurons
&Y-
Its o\in dendritlc
(mid
border).
horirontal.
heretofore
ascending
(Fig.
intcrmcdlate SAC
modcratclg
after si\~ng ott‘collalur;lls
deep cellular
(SGC
small
scmlcii-cular
within
to SGC
neuropll
lield
pi-c\ Iou\
cell has
;I small
formin, (I
and
spine.
7H).
axon ramilics
a mid
th~nncr
arc
the
SFGS
bipolar. an)
bt-anchcs
ticld. and descends
Iaycr
lat-gc
branching
and
a( the XC‘
supcrticial
in
sccondar)
;I
ha\
sparscl>
Iypc of‘ horizontal
ticld. The
ccII
thlcl,
horirontall)
branches
This
described
single
cell type (Fig.
exhlblts
and
Lbhcrc II
c)nly J rare or~cntcd dcndrltlc
twice
(c) A third spinous
liclci.
soma
(11~‘
horder
of horvonk~l
;I
nodohitics
1‘~
of this
horizontal
dritic
type The
;I
Icast
laniinai-
(‘I-0111
an
from
IMO \parscl>
narro\\
the SFGS’SGC‘
and
trunk.
and prcscnt len$h
or
ulth
;II-IW\
7A).
second
rounded
W~~I
shal‘t
one
;I
ccl1 originates
towards
(Fig. A
(b)
gi\cs
forming
of this
rounded
dcndritlc
and
the cell
branches.
axon
The
has ;I small A single
~mc
ccl/\
rcbear
rc‘pc~r~cd
111
the frog.“’ This
cell type possesses
occasional or~entcd spinous ar!
spine:
and
in the vertical dcndritic
originates
shortly
ax011 course
A
IS
and
given off‘which
\\;I\ not
forming
at the SFGSWX
dclicalcl~
bifurcates.
dcndt-ites
two
confined
spinous into
(Fig.
The
SGC 6A).
large
and SAC
and
SGC: class.
cell gives rise to dendrite
The
multipolar
cells
of Mech and Shcllart.“’
along
dendrite coursing
the opposite
dcsccnds
bound-
boundary.
bipolar
from
imprqnatcd)
-
soma with an
polar
one at the SO:‘SFGS
(FIN. 6H). Another
ascending
an
round
slender
from the ascending for a short distance
could be followed St
small
plant
fields.
and the other
axon
;I
two
thus
SGC
they
Al-c
boundary hill
in the straltmi
(Types
most and
Ol‘kll
the uhua1 I~>cation of the
and XIII,
li~~llld
Ic\s frequcntl!
bc considcrcd album
Xlll
ccnlralc.
SOI~~;I n11l
togcthcr
Ill
SAC‘
III ciccp ;I\ otrc
and in c‘;~li bc \~,~rcd
c‘;I\c’
which pole.
an
(its further
Allhotigh SGC
lhc
p!raniids
with a$ccnding
of
XC
and
lhe
ayon to SO arc multipolar-\.
ccl1 01‘ the>
224
SFGS-
/i
SAC
f ax
SPV
A
\
5M
so
CSAC
The optic tectum of (rqmnotid
will
hc discussed
The
soma
LISU;III~ Sonic
of
separately the
located of them
at the end of this
medium-sized
in SGC
cells
and less frequently
rcscmblc
ccl1 Types
IX
drites.
seclion.
multipolar
is
in SAC.
Four
mediutn-strcd
he designated (a) Thts
The
apical
\+ithin
dcndrires
dendrite
r>pc
“b”
in SGC.
u,hich
ascends
to SFGS.
dcnJr_iIic
shaft
arccnd\
towards
been noted. both
species
especially was
not
of
(c) Type scvcral
“c”
type
frequency
of this
nat-rob
ccl] (Fig.
tine.
of this
leave the
in SGC
modcratcly
:I short
towards
number
deep
illustrated
(Fig.
l4D).
The
alon onI!
tn S(i<’
is vet-1 rare:
dcndritc
SO.
:I
iI hits
gt\es ;t few lint
These
locall!
dcndritch
111deep 111uppc~.
c;trr\
spincx.
ccl] \\~th similar bk
onI\ :I
The
and gi\c< ;t rccurrcnl
onI!
;I\OII
collalcral
appcarancc
Kome\htc
it
dcndrita
br:tnching
of long-stcmmcd
in IPL
SGC‘.
been
XD)
which
ticcp SI:GS
,~nc! was
one side. that ramil)
and adjacent ;t plexus
S
W~:I
diztancc
cell (Fig. soma
This
ovoid rami-
ih an eaoccdingI>
high-frequency has never
dondrtte and then
appears
and
ha\
Sharma’“’
to be unique
the apical
may
and
sensor!
tectal input.
collaterals
hale
not
in
SC;<‘.
is \cry
common
Gytnnotid of other
dccpcr SGC‘.
i>
numerous
ot
ccl] type has a bipolar field
(Fig.
has a multipolar spinous,
radiating
A vcr!
neuron
tclcosts
mid
in
and
This
ha\c ;I role
OE)
The
ctrcumscribed also laden uith tn
IPL
soma
SFGS.
dcn-
axon
and
The
at-iscs
clthcr
it
ncuroli
to
the
clcctroli~und
bc tii\pl;tccd
an irt-cguI;tr
ct~ntoui.
IO 1%tth
and spine\ dendritic
tree’ r;tmtfic\
arca in deep SGC‘. spines.
Since
thih
is t!l~tcall>
somelime\ ha
basilar
and tinally
tclcost. fish.
cell body
can
soma
lower
OLII- kno~+lcdgc.
to Gymnot~d
excrcsccnces $ptny
to
in anolhcr
specificall\
but
ccl1 I\ pc 111 both
but.
been dcscribcd
sotna
from
common
Gqmnotids
the
dendritic XF)
to
“d”
in mid the
itt
1(> deep
This
an
apical
leaves
in the tcctutn
and
The
dendrite
in the caudal tectum.
A variant
configuration Lvitlt
high
rcportcd
axon
have
arises
local
neuronal
prevalent
amphibians.
axon latter
SFGS:
This
XC) basilar
branches
the
to ascend
modcrvtc forms
branches
from
and an ascending
SFCiS
vet-lically
branchlcts
arises
spheroid
SGC.
tout-SC’ hort/oncall>
ascend
II cell in the frog.”
prominent
The
it
SGC.
in SFGS.
The
Type (Fig.
spinous as
in
and may thus
a small
and a more
gives fatrly
sparsely
:I
and
have not been identified.
neurons Mith
ramifies
spinous.
resembles
perikarya
fying
some
ccl]
(d) Type
XH) lbith
dendrite
perpendicular
SW
local collaterals
(b)
which
gives
arc moderately
cell (ypc strongly thorn!
gtbtng this
oriental
(Fig.
apical
and also ramifies
cell type is seen to enter tcctum:
soma
;I prominent
dendrite
SGC
after
stna]]
they will
which
most
predon-
in SGC:
a. b. c and d.
cell has an ovotd dircctcd
cells with
are found
as types
contour.
larerally
multipolar
dendrites
of
while
obserccd
vertical
rug&
\omc
SGC. of
and X of Meek
and Schellart.5’ inantI)
lish. ;I G~>l,y ~~uci>
accndc
SFGS. forms
The
to ramit\
Ihen ;t small
fr<>ni
lhc
hort/onLall:,
continue\ bouquet
5om;t
obct- :I
;tp~c:tl dendrite.
01
Ihrottgh
tn SM. the
The apical
I:. 5~s
SFGS
SFGS
MID SGC
SAC
and L.
MALER SFGS
Yr
SFGS
The optic tectum
of Gymnotid
lish: ;I Golgi
rtudy
SO SFGS
”
:
b Fig. 9. Bipolar cells of SGC. (A) Type “a” bipolar with an asymmetric basilar dendrite. and an axon (a\-) with collaterals in SGC which appears to leave the tectum. (B) Type “b” bipolar with soma in deep SGC‘. (C and F) Type “c” bipolars are present in different suhlaminac of SGC. (D) 1 ypc “d” bipolar with soma m superficial third of SGC. (E) This cell is a bipolar variant of type “b” medium size multipolar: it5 axon also ascend\ to SFGS, and the soma lies in mid SGC. Laminae a\ indicated in the adjacent fi_eurc.t<;) Infrequent type “e” bipolar cell with soma in superficial SGC, shows an asymmetric apxal arbor m SFGS. Bar for (A,B,C,D and E): 25pm. Bar in (F). (G): 501lm.
dcndrltc and ascends to SO after giving some collaterals in SFGS. This axon is found to extend over ;I ~idcr area than the dendritic trees. therefore only part of the axonal plexus is aligned with the dcndritic arbor. The thick longer axonal branch possibly leaves the tectum via SO. On numerous occasions the axon of the ccl1 has been observed crossing the proximal segment of the apical trunk of the pyramidal cell of SF
Two pyramidal cell types are found in SGC: one is heavily invcstcd with spines and the other has a non-spinous basilar arbor in SGC and only a sparse amount of spines in the apical arbor at SO,!SM bordt_Y.
The somata of this ccl1 type is typically pyramidal m shape and is located in midcellular or adjacent deep sublamina of SGC. It has a basilar dendritic tree which ramifies widely within SGC; occasionally dendritic branches are given off at right-angles to this horizontal arbor to ramify downwards within deep SGC. The apical dendritic tree gives off two horizontal at-hors one in mid SGC and a second at SO. The
dcndritic tiers in SGC arc richly endov.cd \vith spines. The apical dendritic trunk has a small number (~1 spines except when it passes through SO. uherc it is bare. Its terminal branches in SO are moderately spinous. The axon Icaves the basilar dendrite and dcsccnds towards SAC. but it has not been fully impregnated. Ramon y CajalTh (Fig. 146b) is the only author who has described pyramidal cells of SGC with an efrerent axon in the tclcost tcctum. but his illustration doe\ not indicate whcthcr these cells arc spiny.
Thcsc pyramids have ;I very planar. non-spinous basilar dendritlc tree with wide horizontal spread in SGC. The sotna is located in SGC and gives rise to an apical dendrite which divides at the SOXM boundary. The peculiarity of this pyramidal cell. IS the lack of spines or appendages in the basilar arbor. while possessing a moderately spinous dendritic ticld in SO!SM border. The tine and smooth appearance of the basilar branches makes the idcntitication of the axon difficult.
Bipolar cells xc vertically
oriented
neurons
which
are not homogeneously distributed through the depth of SGC since particular types are found at specific depths in this layer. (a) Type “a” has an ovoid soma located in deep SGC. with an apical dendrite which terminates forming a small nodous, scarcely spinous arbor in SFGS. The basilar dendrite is oriented towards one side of the soma and has a sparse arbor in deep and adjacent mid SGC. The axon arises from a dendrite at the SGCiSFGS border and courses downwards giving some collaterals in SGC; it passes through SAC, and it appears to leave the tectum (Fig. 9A). (b) Type “b” bipolar has an elongated soma in deep SGC (Fig. 9B). and two polar dendrites. The basilar trunk forms a confined, delicately spinous arbor in SAC. whereas the apical arbor bifurcates in mid SGC. The axon of this cell was not impregnated. This neuron is comparable to cell “b”. Fig. I2 of Schroeder et ~1.~’ (c) Type “c“ bipolar was observed as frequently in mid as in deep SGC (Fig. 9C and F); the elongated soma gives rise to a thick short and smooth apical process. which bifurcates and forms a moderately spinous narrow arbor in SFGS. The axon arises from the basilar aspect of the cell and was observed descending into SAC. This is probably a projection neuron of SGC. In Eigenmannia both types “b” and “c” bipolars have a more spherical soma than in Apteronotus. A comparable cell is shown by Vanegas et al.“’ (Fig. 3, cell “d”); Ram6n y Caja15* (cell “b”. Fig. 146); and Meek and Schellart.‘” (d) Type “d” bipolar has an ovoid soma in the upper third of SGC: it presents a few thorny spines (Fig. 9D) and gives rise to a single thick basilar trunk with a sparse arborization in mid and deep SGC. The short apical dendrite is thick and breaks up into a bouquet of nodous branches with few spines, that spread in SFGS and SO or SOiSM border. The apical and basilar arbors of this subtype arc wider than those of the previous type of bipolars. The axon originates from the basilar dendrite at mid SGC level, and appears to take an ascending course. We have not encountered a description of this cell type in the literature of teleost tectum. (e) Type “e” bipolar cell (Fig. 9G) was infrequently observed; the soma is located close to the SGCjSFGS border, with a basilar dendrite which descends and ramifies in deep SGC forming a cone-shaped sparsely spinous delicate arbor. The apical dendrite arborizes in the SGCjSFGS border, having its branchlets oriented towards one side. The axon of this cell was not impregnated. This neuron perhaps is analogous to bipolar cell “e”. Fig. 10 of Schroeder et al.,w and cell “b”, Fig. 3 of Vanegas er uI.,~” with the varient that their cells have symmetrical dendritic trees. Fus$orm
cell
The large fusiform cell with the shepherd’s axon (Fig. 19B) has the same characteristics
crook as de-
scribed in other teleosts, Type XII cell 01 Llcch and Schellart.” fusiform vertical cell of Romcskic .tnd Sharma.“’ fusiform with shepherd’s crook .!\on 0:’ Schroeder r/ ~1.~’ and cell “a cross” of Ramon 1 Cajal.5x The very elongated soma is locatcd throughout the length of SGC and gives rise to LUO thick\ polar dendrites. The basal dendritic shaft arhorircs in a horizontal fashion at the SACjSGC border: whereas the apical shaft ascends, giving r15c to ;I dendritic tier in SGC and a more superficial one at the SFGS/SO border. The axon originate> from the apical trunk high in SGC and turns down towards SAC. Another large fusiform cell has its efferent axon originating from the basal pole of the soma (Fig. IOA), and possesses a thick, nodous and wider apical arbor at the SOjSM border than the fusiform with the shepherd’s crook axon. This neuron has combined characteristics of Types Ilb and XI of Meek and Schellart.50 The axon is not shown in the drawings of these authors. Horizontal
cells of stratum griseum centrale
Type “a” horizontal cell has a rounded soma, giving rise to one or two sparsely spinous dendrites which ramify only sporadically in the horizontal plane of SGC (Fig. 11). The axon arises from the soma and appears to course within the plane of one of its dendrites. Ram6n y Cajal’s’* horizontal cell (Fig. 164, cell “d”), Vanegas et a1.69(Fig. 7) and Meek and Schellart’s’” Type V, seem comparable to the Gymnotid variety. Type “b” small horizontal cell has an octopus-shaped soma and fairly spinous confined dendritic field at different levels of SGC. After a short trajectory, the axon bifurcates into two small slightly beaded branchlets. These are probably small interneurons of SGC (Fig. 11C and D). Stratum
album centrule
The SAC is chiefly a fibrous layer containing scattered large multipolar cells, a few medium-sized multipolars, and a small number of pyriform cells displaced from SPV. According to the preferential orientation of the dendrites, the large multipolar cells of SAC, can be divided in: (ai and aii) Cells with a chiefly horizontal dendritic spread (Fig. 12A,B). (b) Cells with a predominantly horizontal arbor, and one vertically oriented dendrite (Fig. 13). (c and d) Cells with a substantial vertical dendritic component, in addition to the major horizontal tree (Fig. 14A,B and C). Some of these cells can be found displaced upwards to deep SGC. (a,) This cell has a widespread dendritic field in deep SGC. The soma has a peculiar flask shape, and gives rise to a descending dendrite with a characteristic widening before it bifurcates in SAC. These dendrites have a nodous sinuous contour and are non-spinous. The axon was impregnated for a short distance ascending in SGC (Fig. 12A).
SFGS
MID
SGC
\
DEEP
SGC
mid SGC
\, SAC
SPV
A
(a, ) This dcndritic a fa\
cell generates
tree at the XC.
branches
reaching
drltes are moderately
an extensive
SAC interface. down
to SW.
(Fig.
12B).
A
similar
only for ;I short
cc11 type
described for both. teleost (Schroeder cell
“b”)
and
Thcsc den-
spinous. An axon arises from
the cell body and could bo fotlowcd distance
horixon(al and also has
amphibian
tcctum
(bl This large multipolar dendritic
and Marc
Sharma.“”
Discussion).
istic of this neuron
(Fig.
13) has ;I
processes. and a wide and deep SGC.
An importanl
is that in addition
character-
it posscs~s ;I
we have only been able to
this process to the IPLiSFGS
border.
The
in SAC.
13: Vanegas
Fig.
rccentt!
1’1trl..“’ Fig!. I2 c’t (I/..“’
and teavcs ~hc It‘ctum
collaterals
al‘tcr
Th~j
ccl1
type has been described in other teteos;ts (Komcskic
intraceltut;ir
(L6Gr
of SAC
tietd in SAC
is sparsely spinous.
single ascending dendrite; follow
recurrent
this neuron recording
(c) This multipolar large triangular
round soma with tine hair-like horizontal
off
has been
t-I& 4E).
*hich
axon descends to SPV giving
to scvcral dendrites
or (I/..‘“’ Fig.
has been identiticd
and
filled
ccl1 (Fig.
\4ilh
I-IA)
(!t>~call!
thick
spine laden
reach SO to form
The
horirontul h:i\c
;I
apical
SAC‘ and EC.
ha\ ;I
dendri~c~. Tv.o
dcndritcs
cul-vitincalThe
~XUII
:rp~cal
small hcrI;LItb arranged L~IW gi\c
branchcs in mid Xc‘.
wictc
h> (\ec
sparseI> spinou\ cell hod! giving 1-1s~‘
tufts: rhesc tuft? arc nodosc and ont! nous.
dye”’
7).
sparhcly
\p~-
oft‘ spinou\
Two ba\al dcndritc\
asccnding ;~sccncis
courxc to
S
through \\hc‘t-c if
I-. S4\
c
and 1.. MAIJH
Fig.
SAC
t I. (A and R) Horizontal cells of WC. Bar for both liguresr 25 pm. (C and D) Flask-shaped cells of SGC
Bar in (C): 2Spm.
forms a loop and then descends to exit the tectum. This cell corresponds to Type XIII, of Meek and Schellart,‘” and Ram6n y CajaI’s” ceil with thick protoplasmic expansions (Fig. 145b). A fairly similar cell has an ovoid soma with irregular lumpy contour. A variation of the triangular multipolar, has a large candelabra shape dendritic tree; the basilar dendrites are very spinous, while the shorter branches have a nodose appearance. The longer ascending dendrites bifurcate at SFGS (Fig. 14B). (d) Another large multipolar cell (Fig. 14C) gives rise to two or three widely spreading horizontal dendrites with wavy nodose appearance. From these dendritic trunks a series of vertically oriented branches take off, which break up into delicately nodose tufts at the SFGS/SO border. The axon leaves the ventral aspect of the soma and descends into SAC. This cell type has been described by Ram& y Caja15* (Fig. 145a), and by Meek and Schellart% as Type XIII cell.
Bar in Fig. D: 50pm.
small
ax, axon
Medium -size ~luitip~i~r~qf stratum album centrafe These neurons can have a predol~iIlant vertical orientation (Types e and f), or be (Types g, h. i) confined to the deeper layers. (Type e) This multipolar neuron has a mediumsized soma (Fig. 15B) with a wide dendritic field which is formed by obliquely ascending dendrites, These dendrites give off vertically ascending branches which terminate mostly in SGC, although a few branchlets may reach SO. ‘The dendrites are thin, nodose and sparsely spinous. The axon of this cell was not impregnated. A similar cell type has been described in the frog.4O (Type f) This neuron has an ovoid soma in SAC which gives rise to an axon with collaterals f~lluwing a recurrent trajectory. A thick ascending dendrite reaches the IPL/SFGS border after giving two or three oblique branchlets along its course, while a thinner descending dendrite forms a small field in SAC (Fig. 15A).
The optic tcctum of Gymnotid
IPL
fish a
232
A
SFV
-_
(‘fhpc
g) This
\tcllats
mcdium-siLcd
appearance
nc>n-spinous
hr !nchlets
111;I layered
fashion.
co~~,c‘~ in SAC‘
I)
course
tv;mclllcth.
spheroid
horiconlal
The
c,irr I<\ on1\
lint
(Fig.
dcndritic
mod-
in mid
in Xc‘.
(Fig.
16H).
sonia
gives
to
tvio
horizontal
of
arbor
il
shol-ter
dcndritic
amount
SAC‘
trot
tint
Iong
is confind
was incon--
axon
IK).
ascending
SGC:
presenting
tier\
mid SGC
and descend\ (c) Thi\
~II;I
arc the chicl‘ constituents
of this
p! preform cells arc also present Ior
convcnicncc
thq
Th~~ire arc eight ;1\on5. four
will
;dso
with
ctfercnt
hut
ascending
small
branch&),
with
cells
axons.
hcrc.
two types
do ,iot appear to ha\c an axon and ;I candelabra ccl1 \zh~~ Iv
fine ;IYO~ like
idcntilicd I
with
process
in SAC
~n\cstipators
have not
illustration\
ol’iill the
(;\lnnotitis.
and did not she\+ somatic
pyriform
p11‘~cncc ,II- ;tb~ncc
of
I~K;I~I~~~\. it i\ dltTicu/t ,,u~ matcrI;il
with
cell varieties
dcndritic
spines
in
typIcal
to make exact comparison\
thox
spccics
of other
ol
of tclcosts.
avoids
the
(g) The
(Schrocdcr
\mooth
in
round
~ma
amount
rn~tl WC‘.
Upon
brc,lh\
up into
gi\cs an ascending reaching
;I l’airl~
which
reach ah far branch
Irom
SO.
the
ascending
bifurcation.
rcachcs
~~vcrl;tpping
it\ dcndritic
Another
,o~;I
111 XC‘
.~rboi- In \tipcl-licial (h) The
or
This
dclldritic ‘The
“b”
it
the
in SFGS
emerges
(Fig.
I7A).
type has the dendritic
branch
branch
;IXOII
pyril‘orm narrow
usually
IO the
ha\c Tao
a wide field in mid SGC field
in
reaches
ascends and forms
II y~\c,s ;I collatci-al
cells in SPV.
;i5ccndin~
SFGS.
A
single
SM.
a loop. to IPL.
spine\ othcl-
at M hich point and c~dciccnd-
;i
tclc‘osts
ati
with
rescmblc
SI’V
(i) Thib
Thus 17(‘).
(Schrocdcr
(‘I (I/.“‘)
dendrites.
Sonic
;~~;on;il cells
p>riform
ccl1 of mid an asccndinf
this
and
subl;i\er
forms
uruall)
;I f:tir-ly
brancheh
and
dcndritic
tree in
breaks
l\idc
ramities
horvontal oni’
withln (I+$.
up
cell tape dot\ ,I similar W;I~
not
cell 111
report&
of these
to
p) I-iform partialI>
and Schcll;~t-t.” ~&IS :I \01n;1 ulth
dcndt-Itc MIth almost
the aplcal
I‘rom IPI.
SGC
The
nunibcr
c\crc4ccncc\ and
and (>ti1\ ;i Ii‘M splncs
of S<;(‘
,,riginatcx
;i small
raniification5.
of Meek
L;~I;III
base.
boundary
presenting
one: or tM0 spines.
In
proce\\
;I \cr>
at It\
carrIc5
neuron.
no spine\ in mid KC.
numbcl
Ifoloc~cvrr~r,.v the axon h;i\
has
is indented
;kxon (Fig.
XIV
111011
19).
dcndritc
intrinsic Type
;I\OII
ha> ;I daunt)
niodcr-ate
has an a\on-like
cell of
to this
habc
ccl1
the
raniItic\
In our material.
houquct
ha\c pre\! naptlc cells
and
and at the SO ‘SFGS
to
hroadc\t
ccllh.
ccl1 type‘ in
%I)
\omctimcs
typical
mod-
p> riform
cell of SC;{‘
(Fig.
ascending
as-
piLc> otl
the
the
111
the
I7D) with
Fig.
QI~;I
shaft
p>r~form
comparable
;I confined
appear
of
a plexus
a wider
;I dcndritic
shaft
point
forms
pyriform
and forms
lacks
Iramilications,
rclaticcly
J
arbor of this
bvith
v+hile ;I
which
near
whcrc
into
branchlcts
border.
axon
of qncs
deep and
dendritic
of spiny
and
.I short
and onlv
formtng
arbor.
pyr-Iform
which
for
bundle.
SPV
among
SF<;S.
been idcntitied
The
layer\. tylx
1na1n dcndritic ,Incl
this
dendrite
SAC
but
The
IPL
\arict>
11’1.
IPL.
\vidu arbor
dendrite SAC.
as the SFGS:SO
cntcrs
in SPV.
profundum.
01 \pines in SPV.
Gn!rle
(.lii)
ccl1 is found album
\trat imi
in
tier’\? in mid
).
dcndritic
SGC
(F:ig.
(‘I trl..“’
~crrucou~ t!17c’ ofp)riform
mid
\vh~ch reaches deep SM.
som;i.
in
The
dcndritic
4
spine\.
(hi
(.II) 7‘h1\
in
111 IPL tree
I7H
till (OI-
hpinous
and another
elTcrcnt
is smooth
sm;111 p!r-ifor-m
dcndritic
not
t1111\ ml-cl>
the
the previous
supcl-ficially
of
in
soma
of yncs
two sparscl\
arboriation
Lnllkc
numhcr
cell type has a smooth it
in the SI‘CiS
smooth
been imprcgnatcd
in SGC.
hranchcs
in tMc>
17(i).
remains
(FIN.
111
branchlct\
has ;I smooth
in SAC
in SAC
dendrite
types.
in
ot- the
haa
spinous
spin!
found
spines.
awn
clthcr
;I loop in IPI
uhlch
It forms arbor-
spiny
(FilJ-.
It hax ;I moderate
deep to
ccnding
horl/ontal
provided
y%nou\
it terminates
cell of SPV
pyrilhrm
or
that
certainty.
pi-~IOLIX
This
type
have yet to
and
tn mid
ramification\
befhrc
deep XC
coursing
erately
intrinsic
SPL
to an aaccnding
or
HYO~ forms
width
The
(f)
plexus
sparscl)
rise
of its
dendrite,
where
SPV.
The
Into
SAC‘.
Sonic
and SG<‘.
be described
thpe\ of pyriform
I!Ix~
lamina.
in SAC
in
spines.
ccl1 is located
spines most
p>ril’orm
distance
cells and pericpcnd~mal
I‘uund
somatic
is only
pike5
and Sf:GS
of SM.
deep half
X3<‘. types of pyiform
soma
and giving
a medium \ arious
It5 dcn-
and axonal
pyriform
its
in S.4C.
and
cell
two
dendrite
type “d”
or
dendrite.
to
pyriform arbor
wIthin
l7B).
SCiC.
((1) The
2
The
origin
and
The
with
SFGS.
The
ramitia
(Fig.
one or
has
dcndritic (Fif.
thpc‘ “c” pi-esents
cell of SAC
ad_iaccnt deep SGC.
plc‘lcl> inlpwgnatcd
The l7E)
has both the dcndritic
at IPL
which
SGC
axon
;I tuft
nodous
branch in mid
The
dcndritc
The
field
SGC.
mild
211 ltlzlgniticant
~tcmmc1.1 \pincs.
recurrent
(c)
asymmetricall\
dendrites
into
111 deep SC;C
long
ing dritic
nndous
SC<‘.
ascending
The
cell has a
delicate
IbA).
breaking
:~~on cour\cs
S:\l . and
to
a semicircular
boat-shaped
\p~nou,
l~~ngcr branch
thicl,cr
which
forming
(Fig.
( f\ pc 11)This
(.I‘hpc
multipolar rise
deep and adjacent
t~eld 111MC‘.
L,I.,IIcI~
giving
IICI-.
01’ thc\c the
17b)
in IPI
\haI‘t bil’urc;itc\.
plant
l‘hc
,i\c)n
\ccondar-> of It\ 0v.n
E. SAS and L. MALEK
SFGS
SFGS SFGS
M SGC
\
&
a
sic
A
sac
:
Fig. 15. (A,B) Medium-sized
Fig. 16. (A,B,C)
SGC
ax
Medium-sized
multipolars
multipolars
of SAC with a preferential axon.
vertical
of SAC with dendrites 50pm. ax, axon.
ramifying
SPV
orientation.
mainly
Bar: 25 pm. ax.
in deep layers.
Bar:
The optic tectum
of Gymnotid
SAC’. The dendritic shaft is fairly smooth through deep SGC. and then it gives spinous branchlets in mid SW‘ and IPL. One tine dendrite ascends to SM and carrlcs a moderate amount of fine long-stemmed spines. The axon originates at IPL; where it gives a few branches and then, it takes a long recurrent cout~se and leaves the tcctum via SPV (Fig. 18A). (b) This projection pyriform cell type (Fig. 18B) has the soma located in SAC. with dendrites ramiI\ins appropriately deep in SAC and SGC, but do not cntcr SFGS. This subtype dots give off local collaterals at the height of the axonal loop in SGC, to IPI. and mid SGC. and terminates by leaving the tcctllm. This ccl1 appears to correspond to Type XV 01‘ Rlcck and Schcllart.” (by) .4 Lariant of type b pyriform cell (Fig. 18C) has dcntlritic branches reaching SFGS, and its axon hranchcs in IPI. and then descends and leaves the tcctllnl. (c) Tqpc “c” pyriform has the distinctive characteristic of possessing an axon which originates deeply nca~ the sonu (in SAC) and dots not form a loop in IPL but instead it leaves the tcctum after giving a collateral branch which ascends into deep SGC (Fig. IXDI.
This neuron has ;I soma located in either SPV or SAC’ and ;I wide spreading dcndritic arborization conlined to SAC and SGC. The dendrites are mostly smooth with only occasional spines. A thin process was ohscrvcd. leaving a dendrite and descending to WV. but we arc not completely certain of its axonal nature. .An identical ccl1 was illustrated by Romeskie and Sharmah” (Fig. 4D), and Potter.”
This ccl1 has a fairly similar appearance to that shown by Ramcin y Cajal’” and Vanegas ct trl.,h’ with onI> slight variations. It differs from that shown by Ram& y Cajal 5X in Barhus fhiatilis. in that in Gymnotids the radial process of this ccl1 maintains its hirsute appearance even in the superficial layers. This ccl1 has ;I soma with an irregular contour, located at the Lcntricutar aspect of SPV, and possesses a verticall! ascending process surrounded by a meshwork for-med by fine hairlike processes; some of which are longer than the others and protrude away from the meshwork. This apical process reaches SM where it appL~ars to widen into an end foot upon reaching the peal surface. The cell depicted by Vanegas et al.,69 rcfct-red to as an “epcndymal supporting cell” appears to form a cylindrical shaped radial process Mhich progressively widens along its ascent. without prcscntinp intermittently the longer filamentous appcndagcs observed in our material. .4 summary of Gymnotid tectal cells, the laminar diztllhtttion of their dendrites and axons. and the
fish: a Golgi
‘ii
study
laminar distribution of their known extrinsic is presented in Fig. 19 and Table 3.
afYcrcnt\
DISCUSSIO’V The tectum is generally consider& to ol-ganl/c orienting responses of the eyes and body to scnsorh (predominantly visual) input. In Gymnotid fish ~hc nature of both the sensory input and the motoroutput is different from that of most other teteo\ts. Despite these apparently major difl’crenccs. the tccturn displays a remarkable conservatism in it\ \tt-ucture. The discussion below focuses on rhe cvolutionary. functional and dcvclopmcntal implication\ of tectal morphology in thcsc tish. The dominant sensory input to Lhc tcclum 01’ high-frequency Gymnotids is electroscnsor! rathclthan visual. Whereas the retinal Input is dcnsc onI> in deep SO and adjacent upper third of SF(iS. the toral input is moderate in SAC. nuss~\c in Xi< and still substantial in the lower half of SFGS. Since most tectal neurons have dcndritcs uithin the tc~ral recipient zone we assume that the) can hc dit-ccIt> influenced by electrosensory input. The ImpcJrtancc of this toral input is reflected In the cucctlcnr dc\~clopment of SGC and proliferation of cdl rypc\ 111thl\ layer. The decline in retinal input IS not, hov,c\cr. paralleled by an equivalent decrease in the thickness of the SO and SFGS. These two ta!,ct-\ occupk 1623% of the tectal thickness. whereas in o~h fish with poorly developed vision they con\tittttc bunts 1420% of the tectum.” Perhaps the toral input to SFGS can occupy the synaptic targets nc)t-mall> occupied by the retinal input (see sccrion on dc\elopment). Many different toral cell ry~>ch contrlhutc to the torotectal projection’.““’ and. con\iticring the precise laminar or sublaminar dlstribtrtion or‘ mo\t dendritic bushes in the tcctum. II i\ IiLcl! that different toral neurons project to diytinct lam~nac OI sublaminae of the tectum; a prcccdcnt for the \uhlaminar distribution of tectal afTcrcnt\ c‘\i~bt\ in the Thus the parallel protectum of amphibians.“,‘” cessing of electrosensory input k+hich IKC‘III-\ 111~hc TS’ of Gymnotids is likely to continue 111the Icctum. although with the addition of Lisuat inli>rmaric>n to some of the channels. The motor system of high frcqucnch (is mnot~& i\ also modified with respect to: (a) hod> mo\cmcnt\. (b) cyc movements, and (c) electric organ cIIsch;Irgc\ (a) Gymnotid fish move forward or backuard~ b\ creating the appropriate undulation in the ;ln;lt lin which runs the full length of their hod). This motor pattern is presumably dcrivcd from rhc pr~rn~t~\c body oscillation which gcneratcs s\vimminf 111to\\cl vertebrates.” It differs from the usual \v, 1111 ~;IIWII generator in that the oscillation can pt-occcrl l‘tron~ caudal to rostra1 (during backward swimming). end it is usually uncoupled from osclllation~ 01‘ the. hod\ and tail. This uncoupling is probabtl \crh ~mport;~n~ since bending the body or tail change\ the \h;lpc 01
236
SM
so
SAC SPV
i
ax
SPV
SGC
SAC
SAC SPV
E
s PV
-F
The optic tectum
of Gymnotid
fish: a Golgi
137
study
IPL
SPV
H
I
I-IF. 17. (.A) Type al pyriform of SPV with intrinsic axonal plexus m IPL and SFGS. (B) Type b pyriform with axonal rnmilications in IPL and mid SGC. (C) Type h pyriform ccl1 with presynaptic dendrites. (D) Type f pyrlform has a very extensive horizontal arbor in mid SGC, and an axon (ax) ramifying higher in IPL. (E) Type cc pyriform of SPV with wide dendritic arbor and owrlapping axonal plexus in mid SW’. lnscrt In t E) shows candelabra type pyriform. (F) Type i pyriform with wide dendritic tree and atonal ramllication in IPL and soma In SGC. (G) Type d pyriform in deep SGC. Note axonal loop In IPL. and then descending trajectory of the axon into SAC. Ascending dendrite enters SM. (H) Type e pyriform axon courses horizontally in deep SGC. Dendritic tree has an arbor in SAC and deep SGC and ;I second ramification in SFGS. (I) Type J pyriform dendritic tree confined to deep layers. similar to Type XV of Meek and Schellart. Bar in Fig. 17A-I: 2pm. Bar in (E) insert: 50pm.
the electric organ dipole and can thus influence clectrolocation.~~ Tcctal outflow in Gymnotids must thcrclbre control a very different spinal swim generator. t b) Eye movements have been noted in .!+EHHU/HN/U.but not ,4prc~~~~~us.’ We have recently obscrvctl cyc movements in Apteronotids (Maler. unpubli+cd obscr\ ations). but these were so small that the) \+crc readily seen only under an operating mlcroscopc. These cyc movements were most promincnt when the animal had been treated with stimulator! drups as part of neuropharmacological in\chtigations and WC concur with Bastian’ as to their paucity under normal conditions. Recent work has dcmonstratcd that eye movement commands arc convl~!cd to the tcctum via the stratum marginale.‘“.“ but the SM is well-developed in Aptrronotus despite tbc rcduccd mobility of the eyes: furthermore the Jcvcll>pmcnt of SM in .4ptcwmotus may still be correlated with visual input, since it becomes thinner in the, C:~LIC~~II fourth of the tectum where the retinal
input is also greatly diminished.” We can interpret these facts in two ways. Electrosensory and visual input interact in the Apteronotid tectum and. as Bastian’ has pointed out, eye movements would drastically change the correlation of these maps. Thus the analysis of electrosensory input may need to take into account even the minute eye movements of these fish: note that this explanation dovetails nicely with the reduction of SM in the caudal tectum, a region of poor visual input. Alternatively, it is possible that other neural systems unrelated to eye movements have taken over the torus longitudinal&SM pathway (ii High-frequency Gymnotids can change the frequency of their electric organ discharge during social interactions.” The best studied of these frequency shifts is the jamming avoidance response (JAR)” which shifts the fish’s frequency away from that of a neighboring conspecific. A particular combination of spatial and temporal information from electroreceptors is required to drive the JAR, and
23X
E. SAS and 1.. MALFK
C
B
SPV D
SAC
\,
8, ‘\ ,, :,*I, ’
SPV
‘1’,i)
)
4 sc
IPL
a
s PV
Fig. 18. Pyriform cells with efferent axons. (A) Type a projection type pyriform cell with axon collaterals in SFGS and an axon (ax) leaving via SPV. (B) This type b pyrifonn cell seems like a Type XV pyriform cell of Meek and Schellart with a dendritic tree confined to deep SGC, and an axonal loop in IPL with collaterals in mid SGC and an efferent axon via SPV. (C) Type bi pyriform with dendritic tree reaching SFGS, and an axon forming a loop and giving collaterals in IPL and then leaving the tectum. (D) Type c pyriform cell has an axon in SAC. which leaves the tectum after giving a collateral to deep SGC.
both anatomicaPE and physiologica13,29 studies have shown that the TS is essential for the temporal comparisons underlying the JAR. It now appears that this information is conveyed to the tectum which contains cells with the information needed to drive the JAR.29 Heiligenberg has speculated that the JAR may require the tectum because the JAR has evolved from an orienting response. Whether this is the case or not, these results imply that Gymnotid tectal circuitry is carrying out transformations unique to high-frequency Gymnotid fish. Comparatiw
aspects of‘ tectal organization
Despite the different sensory and motor abilities of Gymnotid fish, their tectal neurons are generally similar to those of other teleosts; the similarities and differences will be discussed below. Stratum marginale. Although this layer is almost devoid of neuronal somata, two cell types are found in Gymnotids, and were described only in two other
species of teleosts,58,60 and in the skate, Ruja.” The axons of these interneurons perhaps constitute the presynaptic elements in flattened vesicles reported in Holocentrus.3’ Stratum opticum. The horizontal cells of this layer (Type III of Meek and Schellartso) have similar morphology as those identified in other teleosts 36.50.60.64.69
Stratum fibrosum et griseum super@iale. Pyramidal cells (Type I of Meek and Schellartso) are the major neuronal type of SFGS, and there appear to be various subtypes, not shown in other teleosts. The horizontal and bipolar cells of SFGS are similar to those of other teleosts, but noticeably few in number. In most teleosts (with the exception of Holocentrus) pyramidal cells are mostly found deep in SFGS; in Apteronotus they form clusters at the SOjSFGS boundary and are individually spaced in mid and deep SFGS. Perhaps this corresponds to the segregation of retinal afferents to SFGS. The optic
Round cell of SO Flask shape cell of SO displaced pyramids of SFGS
Horizontal cells of SFGS types a,b Bipolars of SFGS Pyramids of SFGS
Bipolar types: a,b,c,d,e Fusiforms of SGC Horizontal of SGC Aspinous pyramid of SGC Cell of SGC with ascending axon Pyriform types: aii,di,i Pyriform type “a” with efferent axon Candelabra type pyriform Large multipolar type “a” Medium-sized multipolar types: a,b,c,d
SFGS
SGC
Round Glioform
Cell types
so
Lamina
of dendritic branches
Candelabra type pyriform Large multipolar types: a,b,c,d Medium-sized multipolar types: a.b,c.d,e Bipolars of SFGS Horizontal of SFGS Medium multipolars of SAC
Bipolar of SFGS Horizontal of SFGS Bipolar of SGC, type “d” Large fusifonns of SGC Spinous pyramid of SGC Aspinous pyramid of SGC Large multipolar types: c,d Pyriform types: ai,b,d,h Horizontal cells of SFGS, types: a,b Bipolars of SFGS Pyramids of SFGS (optical tier) Pyriform types: a,b,d,g,h Pyriform types: a and bi with efferent Large multipolar type “d” Medium multipolar types: a,b,c,d,e Bipolar of SGC types: a,c,d.e Fusiform of SGC Bipolar types: a,b,c,d,e Fusiforms of SGC Horizontal of SGC Aspinous pyramid of SGC Cell of SGC with ascending axon Pyriform types: ai,aii,b,c,d,e,f,g,i Pyriform type “a” with efferent axon axon
~~~____
2. The constituents
-Round cell of SM 4lioform of SM ---Pyramidal cell of SFGS -Pyriform cell types: b,d -Pyriform type “a” with efferent axon -Cell of SGC with ascending axon Round cell of SO
Origin
Table
Intrinsic
axon
semicircularis
Torus
Pyriform types: aii(IPL),b(mid SGC and IPL), c(mid SGC), d(deep SGC), f(IPL), i(IPL) Pyriforms with efferent axon types: b and bi(IPLa mid SGC), and c(deep SGC) Medium size multipolar types: cd Bipolars of SFGS Pyramidal of SFGS and SO Medium multipolars of SAC
of SGC
Horizontal
axon
b,d
(sparse)
types:
Retina
multipolar
axon
longitudinalis
(very dense)
Extrinsic
Retina Torus semicircularis
Retina
Torus
Origin of axonal terminal fields
Cell of SGC with ascending Bipolars of SGC types: a,d
Medium
Type “b” pyriforms Type “a” pyriform with efferent
Cell of SGC with ascending Horizontal of SO Horizontals of SFGS
of SFGS
cell of SM
Small bipolar
Round
of each lamina
tier
of
the
Ciymnolid
superficial
SF(;S. other
in
tree
SFGS; w”““’ density basilar
input.
cell
sqregatcd
this arbor
OnI!
in Romcskie to terminate
Pyramidal
10 those lrith x+ors
tnisaligned
pyramids
wre
in other
and
(xc
Functtonal
effrren\
axon.
cells OI’SC;~‘.
grcatcr
hpolat-
llletllloncd
bul
pyrll‘~xn~
the bipolat-
WC.
and medium-hi/cd
and there appca~- to he a
()I‘ these cull type\ Prcsumahlq
khan descrthai
fusil’ot-m
;LYO~ (Tbiw same
sho\vn
of Meek
characteristic5
in other
to prc$xt
input
ccl1 of’ XC’
XII
in
tcleosts.
111
thus I-clatc‘s 10 the prcr-
cessing of the larpc clcctrosensor~
the
cells v.tlh
Ill :3/wY~~to/tr.v all tt1c aho\c
tcleo\ts.
crook
cells. I‘u~tlorm multtpola~
domina\c
large
ccntralc
and
Lartctl
The
ccvirrdc
cllhrfrfl
griswm
;~xon. pyramidal
horizontal.
cells are pi-cscnt. multipolars
crook
kctum. I‘unctic~nal
Aspect\).
tbpcs of the stratum
shepherd‘s
15tt h
more l’requcn~ 111
impot-(ant
tcleost5 NC as Ihllous:
ol‘othcr cells \\ith
at-c
Ictc’ost\
01‘ lhcit- apical.
y/.\c111)1 c.c,trtr.trlc trurl .strtrlrrt,l
The neurw-tal
wet-k. IS or in mtd
c:~udalmost
have
I<
111 mod
In our malcrt;tt
relativcl>
may
dendrite
arbor
in IPI.
centers
1;lt-
to reach
tiers. M htle pyramtd\
\entraltnost
implications
ctthcr
are not tnentioncd.
misaligmncnt
allwing
and Sharma’h
aligned
and dtstal basilar
.Strrrfl,tu
dilTcrcnt
Input
one
cells dcpictcd
misaligned
other
only
shown
medialmost.
1hu\
the basilar
forms
SGC.‘”
This
subtypes
tclcosts
usually
limited proximal
the
The deepcl
reach
elcctroscnsor~
In other
and ,,4I,‘)
tiers)
the
,II
rn~d SGC and f’or deep SC;C‘) xcording
the arbor. similar S(;C,‘”
deep
with
iz prcatcst
in .-lptero/to/rr.,.“~,“’
pyxmidal
laminarty
or
correla(cs
which
tn
dcntlrttic
mid
in
this
(electroscnsory
(IPL.
the
ramifies
houndxy tier<
depths to
fish
ccl1 ramitics
the qui\;tlent
“” presumably
01‘ retinal
SO/SFC;S
pyramidal
whereas
to th14 layer.
\btth
shcphcrd’h
and Schcllart’“)
Ci!mnotiJ\.
;I\
hax rh<~
This ccl1 has hecn repclrted
(0 n. ~lrc~h~il;imicua. _” torus sc’illtctt-cLtI.iris.”
and n. i\thmi.“’ .Anothcr with
I‘usii’orm
a deep polar
wrrcspond
cell V.;IS ohscr\cd axon
altering
to the pro.jcction
in (;!mnc~ttd~.
SAC‘. Thih cclt ma> ccl1 Type
YI
of Clcck
and Schcllart‘”
,tnd to ;I SOIIIC‘LLhat s1m11;11ccl1 draa n
by
\+ith
Lcghissa.“:
I‘rotn
the basilar
The
Larious
Gymnntids
XC
bipolar
and
arc tither
hipolar
rostrocaudal the multipolar
shafi
FIN.
estcnt
lot:
in ~11s
cc‘11 01‘
hq the aptcat and one’ tn SO SFCiS
or an a171cal ;~rhot- tn
desccndtng
M;IS obser\cd
cells of’ !X(
prcwn(
GIII hc ground. (~\o~d
located
tn SC;C‘ SAC
and ;I basilar
one c;tsc fhc axon The
1’1 trl.. “” and
The
dendrites
the o(hct-
SO’SM
type\
to the bipolar
(‘I (II.“’ The pcrikary:t
or fusifi>rrn. basilar
cell
bear a rcscmblartcc
01‘ FIN. 3 01‘ Vancgaa Schrocdcr
a\011 ort$nattng
;I descending
5hafi.
are
tn(o SAC’. In
entcrtng l’ound
01‘ [hc lectum;
deep XC’. tn Ihc
and togcthcr
cells. arc the prevalent
ncuromtl
MhOIc htth tcpcs
in the caudalmost Icctum 01‘ lp/~~~~~u~~~~/~.\. The difTcrencc\ \vith hipolar reporrcd in olhcr studtc5 arc.
242
f
SAS and I.. MALIK
the longer vertical extent of the dendritic shafts and the greater diversity of bipolars encountered in our material. In Gymnotids, the multipolar cells of SGC and SAC form a more varied population than those shown in perciform teleost.hY goldfish,5”.h” other teleostean optic tectumjh and squirrelfish.““ These invcstigators point to two subtypes of large multipolar cells; one with a preferential horizontal spread but possessing one ascending branch to SFGS, and the other with a preferential vertical orientation reaching SO. These two types do not appear to cover all the different varieties of multipolar cells reported in frog4” and birds,5’ each projecting to specific target areas. In other teleosts the medium-sized multipolars are usually represented as having a medium width arbor confined either to the adjacent parts of SGC/SFGS, or to deep SGC and adjacent SAC. In our Golgi material we were able to observe all the projection multipolar cell types corresponding to ganglionic cells of layers 6 and 7 reported by Lizir c’t al. in the frog,J” using the cobalt method. The large multipolar neurons of Gymnotids are oriented as follows: (i) in the horizontal plane; (ii) mainly in the horizontal plane with usually one vertical component (see also section on Functional correlations), (iii) in both horizontal and vertical planes. Within the third group there are variations according to: (a) the layers they contribute via their dendritic branches: (b) the retinorecipient layer they reach via their single or multiple ascending dendrites (SO or SFGS); (c) the characteristic manner of termination in the visuorecipient layers SO and SFGS which may be via a single terminal branch, serial tufts. or bifurcating and spreading horizontally, and (d) the width of the dendritic arbor in SGC and SAC. The large multipolar cell with a horizontally oriented soma greatly resembles the fusiform ganglionic cell projecting rostrally of Liz&r et u/.,~” while the triangular multipolar is similar to Ram6n y Cajal’s.s” Fig. l45b cell. which he describes as a ganglionic cell with thick protoplasmic expansions, possessing an efferent axon. The large ovoid multipolar cell of SAC with a lumpy surface. bears a certain resemblance to the Meek and SchellarP’ Type XIII? cell. and to a ganglion cell of layer 6 in the frog. 4” This cell was shown by the latter authors to project to contralateral rhombencephalic levels via the tecto-bulbo-spinal tract, and respond to small moving objects. Lgzlr cutul.” suggested that the large ganglionic neurons of layer 6 in frog are probably responsible for orienting responses to prey. The multipolar cell of SAC with a round soma displaying filiform appendages, and a chiefly horizontal dendritic orientation, with usually a single ascending dendrite towards more superficial layers, is a projection neuron with an axon leaving the tectum via its deep aspect. A similar cell is present in goldfish,hO and in the frog optic tectum, where it was shown to project to the contralateral rhomben-
cephalon.“’ The only diff‘crencc IS the more tromplctc impregnation of the ascending dendrite in Romcskir: and Sharmn’s”” material, ‘ A large multipolar cell of deep SGC 1> ;! t>p~cal example of a horizontal cell confined to the deep layers. This neuron possesses a wide horizontal dendritic tield in SGC which receives elcctroscnsor\ input, and another small field in the SGCi’SAC’ border. It is comparable to cell “d” in Fig. I46 of Ram6n y CajaP in Barbus.$uu’rttilis. The rest of the multipolar cells have a medium-sized soma and arc more frequent in SGC than in SAC. The multipolar cells of SGC probably correspond to the ganglionic cells of layer 7 in frog. 4” These cells were shown to receive dimming and event detector types of retinal information, and to project to ipsilateral spinal cord.4o Chung et ~1.“’ proposed that these neurons arc probably involved in the escape behavior of the frog, when turning away from a threat. Afferents to the neuropil of SGC were reported from ipsilateral telencaphalon to mid SGC, and from contralateral optic tectum to the SGCjSAC border by Ito c’f trl..” Meek,” and Vanegas and Ito,‘” among others. In birds and frogs, cells of SGC have been reported to contribute to the descending tectofugal pathways,‘?.4os9 thus pointing to the importance of these deep layer cells in the initiation of orienting behavior of the animal in response to multimodal sensory stimuli via these descending tectofugal pathways to premotor areas of the lower brain stem. One cell type of SGC appears to be unique to Ap?cvonotus and Eigenmunniu this is the cell with an ascending axon to SO. A remarkably similar cell type has been identified in birds by Ram6n y Cajal.5” The basilar dendritic arbor of this cell would allow it to sample the electrosensory input to SGC while its ascending axon would permit it to influence the pyramidal cells which receive a dominant retinal input. Interestingly the axonal plexus was asymmetric with respect to the dcndritic arbors. Strutitm
peril~entricularr
This deepest layer of the optic tectum houses the various interneuron and projection types of pyriform cells. In Gymnotids eight main varieties of pyriform cells with intrinsic axons can be distinguished, two types without an apparent axon and four projection types of pyriforms. The dendritic contributions to the various layers arc too diverse to build a classification upon them; but they cannot be disregarded due to their functional implications. In Gymnotids the apical dendrite may have: (a) a single terminal apical arbor; (b) contribute via horizontal or oblique branches to different combinations of two layers, and (c) contribute to almost all the layers. The surface of the apical shaft is either smooth. nodose, spinous in specific laminae, or bears only a sparse amount of spines, according to the pyriform cell type. The somata of some pyriform cells may also bear a small number of spines. No mention of these
morphological tectal
difkrenccs
Tlpcs
clcctroscnsory
Golgi
and
c
the tcctum;
usually
Some recognired
three
as follows:
(I
others
notids.
main
by
patterns
that
as
pyriform
axons
can ramify
is
SFGS:
(b)
in
displaced
and
patterns
have been reported
ctTcrcnL
pyriform
of
the
Equivalent
in the goldfish.‘“.“‘-“”
types
identified
and frogJ”
in
also
are
in
its
clcctroscnsor)
localion
and
iological
studier
that
it
is
system
elcctrocommunication; of the Gymnotid
involved
dem(mstratcd
in
and elcctroscnsory predominantly spond thi\.’
’
pyramidal
The
corrclatcs.
Most
point
that
;I
rctlnal
Input
\+ill
input.
Deep
tcctal
01.
may
~XYI
not
he
moving
found onl!
that
fish’s
similar
\+a
able
till\
IC;ISI
<)I’ Rose
some
and
14A
plrilorm the
\ISLI;II
pyramidal
cases
partially
and
16B.
cell “Type input cc‘lls
type.
When
jammed
with
the
visual response
intracellular
of SGC
that
It is possible
cells
tcctal
is
units
at to
and SAC‘
and one variety
l7D).
these most
lost their
cells correspond
respectively) to
For
and
objects.
have shown
multipolars (Fig.
The
derived the visual
since dendrite
its
(cattish) useful
charactcri\tlc poldli\h
(\cc‘
PI-L.~uniabl\
b).
stud)
b;1w
and
tkpc
lhis
wilt
In comparing
ol‘thc
tiitTercnccs
pi-cl\c
10 bc
11
01’ nc‘uIona1 Ii;15
~111 oricntln~
in c)thcr
tcIco~I~
\+tilcli
ltik
liiducc
IS
circuitr): disrup(ed location
and loru\
an
compared
tecluni.
tc\cl.
conipatiblc
Mill
hbpcrapparcnl
Iihcl) ttial cmci-y al the
;Znothct-
c~ol\cd
\\lth
the
po\\ihllit!
i\
~1 [ha1 it\ Icct;il
mot-c
\l;iblc
alloy the ~cctum IO used for orlcntalion
this would the circultr! and nicrel~
IO Itic
It is of c‘ouI-5c
11~5
circuilr)
\cnilcIrcul;iris
by the rcmarh.;lhle
in tcctal circuitr\
microscopical
Ihc toral
output
i’lcclrosen~c~r\
l‘rotn
stimuli
the Icctuni
of the torus.“““.’
electron that
that
to
one is struck
conscrvatlzni more
~niphes
I‘hc
d~tl’~_~n~
communicallon)
ha\ e~ol\cJ
respond
11,
I-cllcs.
ol‘Gymnntidz trophy
t>pc
cvc~ltitloii
(personal
that the JAR
I‘uiiclioii
cIcc~romo~oI
ni;i~’
the
;~nd
Rt,mc\klc
pas\ivct\
IO clcaniinc
Hciligenberg
response cell
;I smgle
lllol-ptlolo~~.
ccl1
01‘ this
large
11 111 boLh
II\ original
b> the clcctro\cnsor! altcrin F II\
:I
ltiarure
and ~LIISC Gyninotids
systonis.
and
cell I! p’c i\ cspcc~all~
allo\+\ us to idcntll‘\
and
wan
01’ ;I jammln~
cells
latrc~-
The
I‘urthcr-
for Ihc JAR.“
to the slsn
pyrlform
teleosts~nonelcctrosensory.
orienting
at ;I frcqucncy
restore
ob.jects.
multisensory
f”
may
Bastian’
simultaneous
Helligenbcrg”’
thcsc
large and medium-sired (l;tg
was
interesting
suggcstcd
always
metal
of either
discharge
to moving
01‘
SAC)
input.’
only
;I
clcctrosrnsory
many of these units
sonic
to
We there-
electroreccptors lo
system
oun.
den-
to
Ii).
01 the pa--
to the lcc(tim.
to bc essential
rc\poncl
ascending
physiological
receive
response
and
by visual
organ
In
(clcctrosensory)
can
and the response
or objects
electric
to the fish.5
input
(SGC
clcctroscnsory
rcbponsl\‘cncs~.
basilar
projccl
man!
to
)x1-1\
OCC’LII-\111
analy\l\
and tha(
both
has hecn usurped
functional
coll~‘ag~~c‘s”~ “I h;l\c
one \tagc of this
(Fig.
without
OI- Ic+ than
the animal
appears
;I
M hcthcr
grcatcr
ditl’crcnt
cells
Fig.
tlctcrminc
bctwccn
which
multipolar”’
to
01‘ ;I neighhol-lng
cornpat-isons
Include
system
must
rczponsc
(i~mnot~i
rcquirc\
tot21
Gymnot~d\
of p)r-
has hccn malnl!
that
and his
ticipating cells
I\ ith
the JAR
that
Sharma.“”
have not
have
by
to stimulate
ob.jects
types
which cell’s
responsive
intra-
contirmcd
the torus.
input
modilied
units
;Ir(iticiul
from
pyramidal
objects
tectal plastic
the
an
cells
units
direct
providing
hc moditiablc
to electrozcnsory
corre-
studies
tier)
input
Bastian
tish
semicirculari~.
Tcctal
\\III hc
corrclalion
has a frcqucnc~
the torus
stimulus
are
units
have
several
of
pyramidal
~II-L’L~ clcctrosensory
rc\pond
and
tilling
It-ccx (electrosensory
li)~-c predict
input.‘.“’
the physiological
tc) the
have
A
filling.“’
avoltlancc
jamming
Heiligcnbcrg
more the tcctum
visual
tcctal units
visual
cells
dye
demonstrate
but
rctined
dritiz
and
results
cells.
these
and
between
to visual
that
phqs-
have shown
functions.‘.”
Superficial
responsive
SFGS
Our
amitial hccn
input.’
recording
recent tcctum
interactions
suggested
to
cellular
both
complex
tentalively
is used for both clectro-
the
stimulus
temporal
tree.
and
\timlul~’
awa? from
of its bode. The
01‘ mo\inF
frcqucnq
own.‘s
make
the dcndritic
of ;I high-frecluenq
dcmonstratcd
tiara.
X.4) \\hlch
recording
the ability
jamming
Gvmnotids.
of
l7~~1hlc cell5 ~lth
results.
to
conspccific.‘”
The
present
i(z
LL\O scnti-
I\vo
IFis.
of clcctrocommunicat~~~n
(JAR)
Nn~or//~
the axis control
to
dcndritlc
ax011
to enable ;I mot-c rhorou&
respect
shift
Icast
the p>ramidaI
of inrraccllular
Analysis
axonnl
one
at
and elcctroscnsor~
morphological
with
three
results:
which
studich.“’
and elcctrosensor>
h!
an axxnding
from
the precise
our
Gym-
in the follow-
one
or (c) in SAC.
r~~r~k~.\rrr.\.” goldfish.“”
cells
In
optic
combination
have been
authors.“.5”,h”,M.h’l
cell
asymmetric
and the cell with
of these cells
some
intrinsic
axons
ofSC;C‘.
cells
y Cajal.‘”
suggest
thcsc
tinding
morphological
the visual
results
for
rcquircd
with
sc\eral (:I)
pyriform
our
are displaced
Our
;I
arc in rcgi\rer.’
howcvcr
tields
substrates
circuitry.
as Ram&
casts
mctcrs.’
thus
(2) an ansc. and (3) centrifuge.
the pyriform
laminac:
tectal
all
axonal
) a cross:
cell types
~ublaminae
local collaterals
such
Rcccnt studies have shown arc in fact cf~rent.~‘.~.‘.~“.“4
reco!niLcd
In some receptive
giving
considcrcd
while
Pqriform
clearly leaving
cells
to the internal
authors
inlcrncurons.
axons
after
aI\0 contributing
are
were observed
pyriform
cells. for their
maps
bc cxpectcd from
would
a.b,bi
projection
ing
in other
arc found
studios.
add on lhc c.1rcu1Ir!
Icctal
I-CI;III~ UIIand
commiinication.
01 that
from and
De~clopmcnt amphibiarl
has
of the rctlnotcclal hccn
;iii
arc2
map
01‘ li\h
01‘ in Icnzc
anti
ircs(c;IrcJi
244
F. SAS and L.
activity.“,“” Competition for synaptic targets is one of several mechanisms which probably operates to ensure a proper topography for this maprR and may in fact be a mechanism generally used during development to organize neuronal connectivity.35,‘h” If two retinas project to one tectum, either naturally or as a consequence of experimental manipulation, the terminals of the two retinas will occupy disjunct patches of the tectum (see for example Refs 4, 21 and 45; or Ref. 16a for a good review). Retinal efferents to the tectum terminate in three dimensions, but developmental studies have concentrated on only two and have generally ignored the third one-tectal depth. The work of Grubergz4 does suggest that under experimental conditions, non-retinal (somatosensory) input might be able to compete with retinal input for synaptic targets. Since the toral input to SFGS occupies patches disjunct from those of the retinal input to this layer, we propose that these two inputs (TS and retina) compete for synaptic targets in SFGS, and that SFGS is well-developed because TS input has replaced the deficient retinal input. A surprising consequence of this hypothesis is that different sensory inputs can “use” the same tectal circuitry (see Discussion above). In lower vertebrates the retina and tectum continue to grow in the adult animal, and the optic fiber terminals must continually shift their sites of termination across the tectum.‘5,5”“,66,67In Gymnotid fish this problem is further compounded by the need to maintain the congruence of the dominant electro-
MAL~K
sensory map with the visual maps.“’ The cicctrosensory system also changes with the animal growth. Up to about 10-12cm body length, the number ot electroreceptors continues to increase,” as does the electrosensory lateral line lobe and TS (Malcr. unpublished observations). This suggests that the torotectal map may also require continual readjustment. After the animal reaches 12 cm body length the number of electroreceptors remains constant.~ ‘? although the animal can continue to grow to ~~11 OVCI 20cm. Therefore, after 12 cm body length the distance between electroreceptors starts increasing;’ il the retina and tectum continue to grow after the fish has reached this body length it might rcquirc other types of synaptic rearrangements to maintam congruence of retina, tectum and the torotectal map. It is fairly simple to partially destroy the Gymnotid electroreceptor ganglion,“’ TS. or retina and it may even be possible to substitute a larger eye toi- the Apteronotus eye (from some species of Eigenttum~icr with large eyes, for example). Apteronotid fish may prove to be an interesting system for the study of synaptic competition and remodeling in the third dimension of the tectum.
Acknowledgements-The authors wish to thank C. E. Carr for some of the Apteronofus Golgi material, W. Heiligenberg and G. Rose for helpful comments on the physiological aspects of this study, B. Goodwin for typing the manuscript and Bill Ellis for photographic assistance. This work was supported by the Medical Research Council of Canada.
REFERENCES
1. Allon N. and Wollberg Z. (1978) Responses of cells in the superior colliculus of the squirrel monkey to auditory stimuli. Brain Res. 159, 321-330. integration of sensory information in the optic tectum of the w,edkty 2. Bastian J. (1982) Vision and electroreception: electric fish Apteronotus albifrons. J. camp. Physiol. 147, 287-297. 3. Bastian J. and Heiligenberg W. (1980) Neural correlates of the jamming avoidance response in Eigenmannia. J. wmp. Physiol. 136, 135-152. of ocular dominance patches in dually innervated tectum 4. Boss V. and Schmidt J. T. (1984) Activity and the formation of goldfish. J. Neurosci. 12, 2891-2905. 5. Bullock T. H. (1982) Electroreception. Ann. Rev. Neurosci. 5, 121-170. 6. Carr C. E., Maler L., Heiligenberg W. and Sas E. (1981) Laminar organization of the afferent and efferent systems of the torus semicircularis of gymnotiform fish: morphological substrates for parallel processing in the electrosensory system. J. camp. Neurol. 203, 649670. 7. Carr C. E., Maler L. and Sas E. (1982) Peripheral organization and central projections of the electrosensory nerves in Gymnotiform fish. J. camp. Neural. 211, 139-153. 8. Carr E. C. and Maler L. (1985) A Golgi study of the cell types of the dorsal torus semicircularis of the electric fish Eigenmannia: functional and morphological diversity in the midbrain. J. camp. Neurol. 235, 2077240. 9. Chalupa L. M. and Rhoades R. W. (1977) Responses of visual, somatosensory and auditory neurons in the golden hamster’s superior colliculus. J. Physiol., Lond. 270, 595-626. of optic afferents in the amphibian 10. Chung S. H., Bliss T. V. P. and Keating M. J. (1974) The synaptic organization tectum. Proc. R. Sot. Lond. (Biot.) 187, 421. 11. Contestabile A. (1976) Laminar acetylcholinesterase localization in the optic tectum of five seawater teleosts. Experimentia 32, 625-627. organization of monkey superior colhculus. J. Neurophysiol. 35, 12. Cynader M. and Berman N. (1972) Receptive-field 187-201. 13. Driiger U. C. and Hubel D. H. (1975) Responses to visual stimulation and relationship between visual, auditory and somatosensory inputs in mouse superior colliculus. J. Neurophysiol. 38, 690-713. 14. Druian B. D., Diaz Barges J. M. and Brzin M. (1973) Histochemical and cvtochemical localization of acetvlchohnesterase in retina and optic tectum of teleost fish. ban. J. Biochem. 57, 43: 15. Easter S. S. and Stuermer C. A. D. (1984) An evaluation of the hypothesis of shifting terminals in goldfish optic tectum. J. Neurosci. 4, 1052-1063. 15a. Fawcett J. W. and O’Leary D. D. M. (1985) The role of electrical activity in the formation of topographic maps in the nervous system. Trends Neurosci. 8, 201.-206.
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