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Modulation of cytoskeletal organization during insect follicle cell morphogenesis
TISSUE 019X6
& CELL Longman
1986 18 (5) 741-752 Group
UK
Ltd
A. J. WATSON* and E. HUEBNERt
MODULATION OF CYTOSKELETAL ORGANIZATION DURING INSECT FOLLICLE CELL MORPHOGENESIS Keywords:
Folliclc
ABSTRACT. changes
in lateral
involved
in
orientation skeletal cylindrical
of
patent
m hoth
follicle area
dynamics
shrinkage. cplthelium
in
follicle
ccl1
addition
to
junctional
don.
address:
of Zoology, Ontario.
:Author
Cell
Canada to
Science
University N6A
whom
Laboratones,
of Western
Depart-
Ontario,
Lon-
5B7. correspondence
should
be
addressed Recewed
48
12 May
juvcmle
mlcrofdament
folhclc apical
Promment follicle
is present
microfilament ccllr.
The
hormone for
the
cyto-
beneath
lateral
the
cells.
In
of microtuhands
arc not
vitcllogemc
in the suhplasmalemmal microvilli.
vitellogenesi\ stimulated
formatlon
the
follicle
distribution
cells and the apical during
cytoskelcton.
A well-developed
vitellogemc
a dispcraed
are
abundance,
revealed
stage\.
hand of microfilaments cells
relative
muoscopy
c~ten~wc
elements
(NA’K’] of
The
changes
cmpha\ize a
patent
a third
ATPaw folhcle
ccl1 ccl1
Rhodnius
The Rhodnius prolixus follicular epithelium undergoes a programmed sequence of morphological alterations during oogensis (Huebner and Injeyan, 19Sl). These changes are a significant component of follicle cell morphogenesis. Cell shape and cell to cell contacts vary from tall columnar, tightly apposed cells during pre-vitellogenesis to decreased cell height, irregular shape and reduced cell to cell contact during vitellogenesis (Huebner and Anderson, 1972; Huebner and Injeyan, 1981; Watson, 1984). This transformation from a tightly packed epithelium to one with large extracellular spaces is known as ‘patency’ and provides the pathway for extraovarian yolk precursors to reach the oocyte (Davey *Present
follicle
modulation.
Introduction
ment
planes. vitcllogenic
to adjacent
in lateral
the
microtubules and
cells contain
a prominent
connecting
arrangement
and
orientated
or apical
contain
in
to post-wtcllogenic
and cross-sectional
and in the projectlons
and
clcctron
involves
Cytoskeletal
investigating
microtuhule
prc-vitellogcmc
prc-vitellogcnic
component.
cell
mlcrotuhulcs
oogcnesis
cpithelium.
hy
transmlarion
longitudinally
vitellogenic
longitudmal
in cytoskelctal
and
non-patent
cells do howcvcr
follicle
tuhuhn.
Rlrodnrus
a patent
ah assessed
pre-follicular of
the
lateral
in the
casentlal
the
vitellogeneais.
during
creating
change
of
from
arrangement
plasmalemma
abundant
cell shape.
immunofluorcscence
organization
oogencais.
morphogenesis
ccl1 shape
and
contrast
cytoskcleton, cell
follicle
this
Antl-tuhuhn
hulcs
cells.
Follicle
1986.
141
and Huebner, 1974; Davey, 19X1; Telfer ef al., 1982). Cytoskeletal elements play important roles in morphogenetic processes linked to cell shape modification (Cohen, 1979a. b). The Rho&us follicle provides an ideal system to analyse the events and control of epithelial cell shape during the follicle differentiation, overall epithelium permeability and epithelial morphogenesis. Only two studies (Huebner, 1976; Abu-Hakima and Davey , 1977~) have considered the role of the follicle cell cytoskeleton in mediating the cell shape changes associated with ‘patency’. Although the presence of microtubules and microfilaments in Rhodnius follicle cells is established (Huebner and Anderson, 1970; Huebner, 1976; AbuHakima and Davey, 1977c), a detailed analysis of their developmental changes and involvement in follicle cell morphogenesis and differentiation has not been done. Studies investigating cytoskeletal mediated cell shape control usually utilize tissue culture cell or isolated cell systems rather
WATSON
742
than intact tissues (Osborn and Weber, 1977; Wolosewick and Porter, 1979; Albertini et al., 1984). Difficulties in the application of the specialized methods required for cytoskeletal isolation of intact tissues are principally responsible. With the recent development of methods adapting immunocytochemical localization of cytoskeletal proteins to paraffin and plastic embedded tissue sections (Bussolati er al., 1980; Rodning et al., 1980; Kramer, 1981; Hogan and Smith, 1982), it is now possible to reassess and extend our knowledge of the role of the follicle cell cytoskeleton during the cell shape changes associated with follicle cell differentiation and ‘patency’. Through the integration of anti-tubulin immunofluorescence methods with normal microscopy, this transmission electron paper will characterize the relative abundance, orientation and dynamics of the follicle cell microtubule and microfilament cytoskeleton within all follicle cell developmental stages. In particular the variation in cytoskeletal organization between the patent, lateral vitellogenic follicle cells and the nonpatent, apical vitellogenic follicle cells is presented. Materials and Methods Animals were maintained at 27°C in high established using routinely humidity methods (Huebner and Anderson, 1972). Only mated adult females were used, and these animals were fed regularly at appropriate intervals to obtain ovarioles at all specific stages of oogenesis. Prior to fixation, the ovaries were dissected and separated into the seven individual ovarioles by desheathing each ovariole in Rhodnius saline (Maddrell, 1969). Transmission electron microscopy
Ovarioles were pre-fixed 1 hr at 4°C in either a modified Karnovsky’s fixative (Huebner and Anderson, 1972) or a modification of Luftig et al. (1977), microtubule stabilization fixative, containing 3.0% glutaraldehyde in PHEM buffer (Schliwa and Van Blerkom, 1981), pH 6.9, 1 mM GTP. Several fixations also included the addition of 0.5% w/v tannic acid (TA) and 0.05% w/v Saponin (Maupin and Pollard, 1983). Following a buffer wash, ovarioles were
AND HUEBNER
post-fixed for 15 min in 0.5% w/v osmium tetroxide (0~0~) in 0.1 M sodium cacodylate buffer, pH 7.2 (Maupin-Szamier and Pollard, 1978). Following rapid dehydration in a cold ethanol series, the ovarioles were infiltrated and embedded in an EponAraldite mixture (Anderson and Ellis, 1965). Semithin and thin sections were cut with a Sorvall MT2-B ultramicrotome. Semithin sections were stained in 1.0% toluidine blue in 1.0% borax. Thin sections were routinely stained and examined in an AEI6B or 801s electron microscope at 60 kV. Immunofluorescence methods Fixations
For paraffin embedding, ovarioles were fixed in 3.0% paraformaldehyde, 0.5% glutaraldehyde in PHEM buffer (Schliwa and Van Blerkom, 1981) pH 6.9+1 PM GTP for 1 hr, followed by ethanol dehydration, and the routinely processed for paraffin embedding in Tissue Prep 56.5”C”* (Humason, 1979). Ovarioles embedded in EponAraldite (processed as already described) (Anderson and Ellis, 1965), were fixed with l,O% paraformaldehyde in PHEM buffer (Schliwa and Van Blerkom, 1981), pH 6.9++,~M GTP for 1 hr. Paraffin sections (5-10 pm) were cut with a Jung rotary microtome. The sections were mounted on albumin-coated glass slides, deparaffinized in toluene, hydrated and placed in Dulbeccos phosphate-buffered saline (PBS). Plastic sections (l-2 pm) were cut with a Sorvall Porter-Blum MT2-B ultramicrotome and heat fixed on glass slides. The embedding media was removed by exposure to saturated NaOH in absolute ethanol for 30 min (Lane and Europa, 1965; Bussolati et al., 1980). The slides were then washed in 100% ethanol and hydrated to PBS. Antisera
The primary (1’) antibodies used were: (1) rabbit anti-tubulin against chicken embryo brain tubulin (Miles Laboratories), 1: 10 dilution; (2) rabbit anti-tubulin against sea urchin tubulin (gift from Dr. Keiji Fujiwara, Department of Anatomy, Harvard Medical School), 1: 50 dilution. The secon*‘%ademark
Fisher Scientific
FOLLICLE CELL MORPHOGENESIS
dary antibody for all experiments was a fluorescein conjugated goat anti-rabbit IgG (Miles Laboratories) 1: 16 dilution. Immunofluorescence
tests
Routine indirect immunofluorescence procedures were applied (Weber and GroschelStewart, 1974; Osborn and Weber, 1982), as follows; tissue sections were first incubated for 1 hr at 37°C in a 1.0% w/v bovine serum albumin (BSA) type V, (Sigma Chemical Co.) in PBS to minimize non-specific staining. The sections were then incubated for 1 hr at 37°C with one of the 1” antibodies, followed by extensive washings in PBS. The sections were finally incubated in the 2°C antibody for an additional hour. Following this step the sections were washed in PBS, mounted with 50% glycerol in PBS, coversliped and examined with a Zeiss photomicroscope II equipped with epi-fluorescence optics. Fluorescence light micrographs were taken on Kodak Tri-X Pan 135 film at IS0 1000, and developed in Acufine developer (Acufine Inc.).
143
cells, although microfilaments are present at the basal cell end, seen in cross-section next to the cross-sectioned microtubules (Fig. 1). Previtellogenic cells
The columnar, tightly apposed. previtellogenic follicle cell epithelium shows a bright anti-tubulin fluorescence pattern restricted to the lateral cell edges (Fig. 4). Longitudinal sections particularly those near or grazing the cell membrane reveal abundant bands of longitudinally orientated microtubules (Fig. 3). The microtubules are concentrated in the middle or nuclear region of the cells (Figs 4, 5). Cross-sections in the apical and basal area of previtellogenic cells contain fewer microtubules (Fig. 6). The results suggest that the longitudinally arranged microtubules encircle the cell circumference in the form of a cylinder. Microfilament bands are not abundant within pre-vitellogenic cells, however a subplasmalemmal band, parallel to the basal lamina is present in the basal area (Fig. 7).
Control
Vitellogenic cells
Usual controls were conducted to assess the background fluorescence imparted to the tissue from the fixation and embedding methods, plus the non-specific binding of the antibodies (Osborn and Weber, 1982). A check of the tubulin labelling in the microtubule rich trophic core and trophic cords (Huebner and Anderson, 1970) was also conducted as an in situ positive control.
The pre-vitellogenic follicle cells, remain tightly apposed until vitellogenesis is initiated. With the onset of vitellogenesis and the gradual formation of the extracellular spaces (patency), dramatic changes in the microtubular and microfilamentous organization of the lateral fohicle cells occurs. Anti-tubulin immunofluorescence of midvitellogenic follicles shows that the apical follicle cells display a distinctly different fluorescence distribution from the lateral follicle cells (Fig. 8). Bright longitudinal bands of fluorescence along the lateral cell edges (similar to that observed within the pre-vitellogenic follicle cells), are present within the columnar, tightly apposed apical follicle cells (Fig. 8). The patent lateral follicle cells do not show a bright linearly orientated fluorescence within their cytoplasm. Instead, the fluorescence is confined to discrete, thin, anastamosing strands throughout the cell cytoplasm (Figs 8, 11, 12). The use of thinner plastic sections greatly increases the resolution and clearly shows this pattern of anti-tubulin fluorescence (Fig. II). Longitudinal cell sections of apical vitellogenic follicle cells reveal dense bands of long microtubules extending the
Results Prefollicular cells
Anti-tubulin immunofluorescence of the pre-follicular cells revealed a bright band of fluorescence along the lateral cell edges and a second band at the basal end of the cells resting on the basal lamina. Transmission electon microscopy verified this fluorescence pattern coincides with the locations of microtubules (Figs 1, 2). Along the lateral cell edges groups of short longitudinally orientated microtubules are present (Fig. 2). Microtubules orientated at right angles to the lateral microtubules are arranged in the basal ends of those cells resting on the basal lamina (Fig. 1). Microfilamentous regions are not prominent within these
744
WATSON AND HUEBNER
entire cell length (Fig. 10). The orientation in the apical cells remains similar to what was observed in the pre-vitellogenic follicle cells. Examination of a variety of section
planes through the apical follicle cells substantiates this pattern if distribution (Fig. 9). Longitudinal sections of the cell cortex dramatically reveal the abundance of long
Expianation of figures
Abbreviations used in figures: AP. apical vitellogenic follicle cells; B, basal lamina; LF, lateral vitellogenic follicle cell; M, mitochondria; MF, microfilaments; MT, microtubules; NU, nucleus; 0, oocyte, P, plasma membrane; PF, prefollicular tissue. Fig. 1. Shows the cross-sectional profiles of microtules (arrows) with associated microfilaments concentrated at the basal ends of pre-follicular cells adjacent to the basal lamina. x 136,ooO. Fig. 2. Longitudinal profiles of microtubules arc isolated along the lateral cell edges of the pre-follicular cells. X70,000. Fig. 3. This section of the cell cortex reveals the dense array of longitudinally orientated microtubules just under the plasmalemma of pre-vitellogenic follicle cells. ~37,000. Fig. 4. Fluorescent micrograph of an Epon-Araldite embedded tissue section shows the bright lateral lines of anti-tubulin fluorescence observed in pre-vitellogenic follicle cells. X1000. Fig. 5. Microtubules (arrow) are organized along the lateral edges of the nuclear area of pre-vitellogenic follicle cells. ~32,000. Fig 6. Microtubules become less numerous in the poles of these cells, as shown by this cross-section through the basal end of a pre-vitellogenic cell. ~20,000. Fig. 7. A microfilamentous area is present, parallel to the basal lamina in a pre-vitellogenic follicle cell. Tannic acid fixation. x45$00. Fig. 8. Anti-tubulin immunofluorescence of a Spm paraffin section, comparing fluorescence pattern between adjacent lateral and apical vitellogenic follicle cells. x700.
the
Fig. 9. Cross-section with large numbers of microtubules (arrows) orientated longitudinally in the apical vitellogenic follicle cells. ~28,000. Fig. 10. This TEM displays the length and close opposition of the prominent microtubules within the apical vitellogenic follicle cells. x 160,000. Fig. 11. This Epon-Araldite section shows a delicate irregular pattern of fluorescence in the patent lateral follicle cells. x750. Fig. 12. Anti-tubulin immunofluorescence, revealing the overall diffuse, fluorescent pattern observed within patent lateral follicle cells as seen in a paraffin section. X900. Fig. 13. Numerous microtubules (arrows) in both longitudinal and cross-section profile are observed in this longitudinal TEM section of a patent lateral follicle cell. x25,OCO. Fig. 14. The exclusion of ribosomes and other cell organelles by the subplasmalemmal of microfilaments is revealed in this TEM. ~32.0GO. Fig. 15. The anti-tubulin lateral follicle cells. X900.
immunoflourescent
band
pattern of a paraffin cross-section of patent
Fig. 16. This cross-section TEM show microtubule (arrows) distribution within the patent lateral cells. Note there are both cross-section and longitudinal profiles of microtubules. x30.000
WATSON
microtubules (Fig. 10). These dense accumulations of microtubules in the apical follicle cells are greater than those of any other follicle cell stage or substage. They are also the longest microtubules observed at any follicle cell stage. The combination of their length and large numbers makes them the predominant cytoplasmic feature of the apical follicle cells. The microtubules of the apical vitellogenic follicle cells, as in pre-vitellogenic cells, are concentrated in the nuclear region of the cell. Although some of the microtubules extend into the basal and apical ends of these cells, their arrangement becomes less regular. This accounts for the diffuse and irregular antitubulin fluorescence seen in apical and basal areas of the cells (Fig. 8). The patent lateral follicle cells contain numerous microtubules (Figs 13, 16). However, in sharp contrast with the apical vitellogenic cells. these microtubules are shorter and not parallel, but rather irregularly arranged so various microtubule section planes are seen in any cell section (Figs 17, 18). The immunofluorescence staining pattern confirms this (Figs 11, 12, 15). The lateral (unlike apical) vitellogenic follicle cells also contain extensive microfilament arrays. These microfilaments are organized into a subplasmalemmal band as clearly revealed in the tannic acid-Saponin fixation (Fig. 14). Microfilaments are also concentrated within the lateral arms connecting adjacent patent cells (Fig. 21). As the extracellular spaces enlarge during late vitellogenesis these arms become more ex-
Figs 17. IX. The patency Fig.
19.
The
fluorescence Fig.
irregular
IS depicted
20.
A few
Discussion The formation of a patent follicular epithelium is an essential developmental event during oogenesis within many insect and vertebrate species (Anderson, 1969; Perry and Gilbert, 1979; Dumont, 1972; Telfer et al., 1982; Abraham et al., 1984). This process provides a pathway for yolk proteins synthesized at extraovarian sites to reach the oolemma for pinocytic incorporation. The associated cell shape changes in the lateral follicle cells are developmentally
orientation
anti-tubulin
of muotuhules
magnification
follicle
are found
(arrows)
electron
immunofluorescence
the post-vitellogenic microtubules
IIUEBNEK
tensive with microtubules becoming a common constitutent as well. The apical projections of the patent lateral follicle cells, which maintain oocyte-follicle cell contact during vitellogenesis also contain dense microfilament bands (Fig. 22). Following vitellogenesis the lateral cells increase their cell volume and form a tightly packed epithelium. Anti-tubulin immunofluorescence results show a diffuse fluorescence around the lateral and basal cell extremities (Fig. 19). The few microtubules found in these cells are parallel to the basal lamina whereas some are localized along the lateral cell edges beneath the plasmalemma (Fig. 20). Clearly, there is an alteration in the number and orientation of the microtubules during this last phase of follicle cell morphogenesis. Microfilamentous areas are not prominent with only a few areas present along the lateral cell edges.
in these higher
within
AND
pattern cells.
in hasal
in lateral
reveals
follicle
cells during
x IIO,(NK), ~350,000.
micrographs. a
basal
dtstribution
of
X%0.
ends of the post-vitcllogenic
folhclc
cells.
the
neighhouring
X6O.OCa. Fig. patent Fig.
21.
Dense
lateral 22.
XhS,OOO.
array
follicle
The
of microfilaments
cells.
within
lateral
arms
connecting
X35.000.
microfilaments
wthin
a apical
projection
of
a patent
lateral
follicle
cell.
WATSON
regulated and arise due to the integration of at least three separate cellular processes. These included: (1) [Na+K+] ATPase induced follicle cell shrinkage. mediated by juvenile hormone (JH) (Abu-Hakima and Davey, 1975, 1977a, 1979; Huebner and Injeyan, 1980; Ilenchuk and Davey, 1983); (2) disassembly and reorganization of the septate and gap junctions along the lateral follicle cell membranes (Huebner and Injeyan, 1981); and (3) cytoskeletal reorganization within the lateral follicle cells correlated with the onset of vitellogenesis. Of these three cellular processes, the cytoskeletal involvement is the least studied. A cytoskeletal role in patency was initially suggested by Huebner (1976) and Abu-Hakima and Davey (1977b), since cytoskeletal disruptors, cytochalasin B and colchicine inhibited the juvenile hormone (JH) induced patency response. Huebner and Anderson (1970, 1972) and AbuHakima and Davey (1977~) described the ultrastructural presence of microtubules and microfilaments in Rhodnius follicle cells. No study has compared the changes in arrangement and abundance of these cytoskeletal elements in follicle cell differentiation during oogenesis in detail, and also utilized immunofluorescence to provide a clear view of the overall changes. The immunofluorescence and TEM results both substantiate that the initiation of patency is correlated with a microtubular reorganization in the lateral follicle cells. This is reflected in a change from the highly organized cylindrically arranged microtubules of the pre-vitellogenic cells to the random pattern observed with the midvitellogenic, lateral follicle cells. Huebner and Anderson (1972) first reported that the vitellogenic apical, follicle cells remain columnar and tightly apposed during patency. The results from our study suggest that the maintenance of a well-organized cylindrically orientated microtubular cytoskelton precludes any possible cell shape change. The vitellogenic, lateral follicle cells decrease in cell height at the onset of patency (Abu-Hakima and Davey, 1977a). This decrease in height is correlated with the reorganization of microtubules in the lateral follicle cells reported here. The formation of a random distribution of microtubules
AND HLJEI~h’L‘Ef<
would greatly decrease the resistance an organized cylindrical arrangement of microtubules would produce against a change in cell height or volume. The microtubules arranged randomly could still support the new cell shape but at the same time would not inhibit any inward movement of the cell boundaries associated with cell shrinkage. The overall process of cell shrinkage by [Na’K+) ATPase mediated pumping of fluid out of the cell (Davey. 1981) would therefore be restrained until the microtubular cytoskeleton becomes rearranged. The conclusion that microtubules play a key role in the dynamics of lateral follicle cell shape in Rhodnius is supported by extensive literature in other eukaryote systems which demonstrate that microtubules maintain and modulate cell shape (Burnside, 1973; Barrett and Dawson, 1974; Tucker and Meats, 1976; Beckerle and Porter, 1983; Frixione, 1983; Albertini et al., 1984; Roos et al., 1984). The formation of prominent microfilamentous bundles within the patent lateral follicle cells. indicates they also contribute to the modulation of cell shape and in particular the formation of the lateral connections between neighbouring lateral follicle cells. Microfilaments are often transitory ceil structures as exemplified by the formation of the contractile ring or cleavage furrow of mitotic cells (Fujiwara rt al. lY78; Schroeder, 1981). Microfilaments can also form the main cytoskeletal constituents of very stable cell structures such as the intestinal brush border (Mooseker. 1976; Hirokawa et a/., 1982) or the sterocilia of the cochlear hair cells (Tilney and Saunders, 1983: Tilney et al., 1Y83). The production of a subplasmalemmal band of microfilaments within the lateral follicle cells could function similar to a contractile ring by producing an inward contractile force that contributes to the formation of the irregular cell shape. The scarcity of dense microfilamentous arrays within the pre-vitellogenic and apical vitellogenic follicle cells shows they are not essential for the maintenance of the columnar shape. The juvenile hormone (JH) mediated cell shape changes of the lateral follicle cells in Rhodnius involve a more complex interaction of cellular processes than generally assumed. JH either directly or indirectly
t’O1 I.I(‘L
.i,
F: (‘FCL.1. MOKPliOtiENESIS
coordinates the rearrangement of the microtubular and microfilamentous elements of the lateral follicle cell cytoskeleton; the disassembly and rearrangement of cell junctions (I Iuebner and Injeyan, 1981) and finally [ Na’ K-1 ATPase cell shrinkage (Davey. IYXI). The details of the dynamics of the follicle cell cytoskeleton during oogenesis, elucidated 111this paper, add to our understanding of the overall process of follicle cell ditferentiation. These results have also verified that the Nl&ni~s follicular epithelium
provides a suitable model system to \tud? the role of cy,toskeletal organization in the modulation ot cell shape in a differentiating tissue. Acknowledgements We thank Dr K. FuJiwara for kindl! \upplying the sea urchin anti-tubulin and W. Sigurdson and G. Kelly for helpful comments. Research was supported I>! NSERC grants to E.H. and an NSF.KC‘ Post-graduate Scholarship to A.W
752
WATSON
AND HUEBNEK
Hogan, D. L. and Smith. G. H. lYX2. Unconventional application of standard light and electron immunocytochemical analysis to aldehyde-fixed Araldite embedded tissues. J. Hisrochem. Cyrochem.. 30, 1301-1306. Huebner. E. 1976. Experimental modulation of the folhcular epithelium of Rhodnius oocytes by juvende hormone and other agents. J. Cell Biol 70, 25la. Huebner, E. and Anderson. E. 1970. The effects of vinblaatine sulfate on the microtuhular organization of the ovary of Rhodnius prohxuv. J. Ccl/ Biol.. 46, 191-198. Huebner. E. and Anderson. E. 1972. A cytological study of the ovary of Rhodniux prolixu.~. I. The ontogeny of the follicular epithelium. J Morph.. 136, 459-494. Huebner, E. and Injeyan. II. S. 1980. Patency of the follicular epithelium in Rhodnius pro/i.rus: a reexamination of the hormone response and technique refinement. Can. J. Zool.. 58, 1617-1625. Huebner, E. and Injeyan. II. S. 1981. Follicular modulation during oocyte development in an insect: formation and modification of septatc and gap junctions. Drvl. Biol.. 83, 101-I 13. Humason. G. L. 1979. Animal Tissue Techniques. 4th edn.. 661 pp. W. H. Freeman, San Francisco. Ilenchuk, T. T. and Davey. K. G. 1983. Juvenile hormone increases ouabain-binding capacity of microsomal prepartions from vitellogenic follicle cells. Can. J. Biochem. CeU BioL. 61, 826-831. Kramer, J. M. 1981 Immunofluorexent localization of PGK-I and PGK-2 coenzymcs with specific cells of the mouse testis. L)ev/. Biol., 87, 30-36. Lane. B. P. and Europa, D. L. 1965. Differential staining of ultrathin sections of Epon embedded tissues for light mwoxopy. J. Hittochern. C:vtochrm.. 13, 579. Luftig. R B.. McMillan. P. W.. Wcathcrbcc. J. A. and Weihing. R. R. lY77. lncrcased visualization of microtubules by an improved fixation proccdurc. J. Hurochrm. Cytochem. 25, 175-187. Maddrell, S. H. P. 1969. Secretion by the Malpighian tub&s of Rhodnm. The movements of ions and water. J. up. Bml.. 51, 71-97. Maupin-Szamier, P. and Pollard. T. D. 197X. Actin filament destruction by osmium tetroxide. J. Cell Biol., 77, 837-852. Maupin, P. and Pollard, T. D. 1983. Improved preservation and staining of Hela cell actin filaments, clathrin coated membranes and other cytoplasmic structures by tannic acid-glutaraldehydc-saponin fixation. J. Cell Biol., %, 51-62. Mooseker, M. S. 1976. Brush border motihty, microvillar contraction in Triton-treated brush horders isolated from intestinal epithelium. J. Cell Biol.. 71, 417-432. Osborn, M. and Weher, K. 1977. The detergent resistent cytoskeleton of twuc culture cells includes the nucleus and the microfilament bundles. Expl. Cell Res., 106, 339-350. Osborn, M. and Weber. K. 1982. Immunofluorescence and lmmunocytochemical procedures with affmity purified antibodies: Tubulin containing structures. In Methods in Cel[ Biology; Ihe Cytmkeleton (cd. L Wilson), Vol. 24, Part A. pp. 97-132. Academic Press. Toronto. Perry. M. M. and Gilbert. A. B. 1979. Yolk transport in the ovarian folhclc of the hen (Gollus domesticus): lipoprotein-like partlclcs at the periphery of the oocyte in the rapid growth phase. J. Cell. Sci.. 39. 257-272. Rodning, C. B.. Erlandscn. S. L., Coutler, D. H. and Wilson, I. D. 1980. Immunoh~stochemical localization of IgA antigens in sections embedded in epoxy resin. J Hiskrhem. Cymchem.. 28, 199-205. Roes. V. P.. Brabander, M. and DeMay, J. lYX4. Indirect immunofluorebcence of mlcrotubules in Dictyortelium discoideum. A study wth polyclonal and monoclonal antibodies to tubulins. Expl. Cell Res.. 151, 1X?-193. Schliwa, M. and Van Blerkom, J. 19X1. Structured interaction of cytoskeletal components. J. Cell Biol., 80,222-235. Schroeder. T. E. 1981. The origin of cleavage forces in dividing eggs. A mechanism in two steps. Expl. Cell Res.. 134, 231-240. Telfer, W. H., Huebner, E. and Smith, D. S. 1982. The cell biology of vitellogcnic follicles in Hyalophoru and Rhodnius. In /rwct Uitrastrucrure (eds R. C. King and H. Akai), Vol. 1. pp. llbl49. Plenum Press. New York. Tilney, L. G. and Saunders, J. C. 19X3. Actin filaments. stereocilia. and hair cells of the bird cochlea. I. Length. number, width and distribution of stereocilia of each hair cell are related to the position of the hau cell on the cochlea. J. Cell Bio[. 96, X07-821. Tilney. L. G.. Egelman, E. H.. Derosier, D. J. and Saunders. J. C. 19X3. Actin filaments sterocilia and hair cells of the bird cochlea. II. Packing of actin filaments in the stereociliar and in the cuticular pIare and what happens to the organization when the stereocilia arc bent. J. Cell Biol., 96, X22-834. Tucker. J. B. and Meats, M. 1976. Microtubules and control of insect egg shape. J. Cell Biol.. 71, 207-217. Watson, A. J. 1984. The dynamics of the Rhodnius prolixus follicle cell cytoskeleton: ultrastructure and immunocytochemistry. M.Sc. thesis. Dept. of Zoology. University of Manitoba. Winnipeg, Manitoba. 146 pp. Weber. K. and Groschel-Stewart. U. 1974. Antibody to myosin. The specific visualization of myosin containing filaments in non-muscle cells. Proc. mtn. Acad. Sci. U.S.A., 71, 4561-4564. Wolosewick, J. J. and Porter, K. R. 1979. Microtrabecular lattice of the cytoplasmic ground substance. Artifact or reality. J. Cell Biol.. 82, 114-139.
& CELL Longman
1986 18 (5) 741-752 Group
UK
Ltd
A. J. WATSON* and E. HUEBNERt
MODULATION OF CYTOSKELETAL ORGANIZATION DURING INSECT FOLLICLE CELL MORPHOGENESIS Keywords:
Folliclc
ABSTRACT. changes
in lateral
involved
in
orientation skeletal cylindrical
of
patent
m hoth
follicle area
dynamics
shrinkage. cplthelium
in
follicle
ccl1
addition
to
junctional
don.
address:
of Zoology, Ontario.
:Author
Cell
Canada to
Science
University N6A
whom
Laboratones,
of Western
Depart-
Ontario,
Lon-
5B7. correspondence
should
be
addressed Recewed
48
12 May
juvcmle
mlcrofdament
folhclc apical
Promment follicle
is present
microfilament ccllr.
The
hormone for
the
cyto-
beneath
lateral
the
cells.
In
of microtuhands
arc not
vitcllogemc
in the suhplasmalemmal microvilli.
vitellogenesi\ stimulated
formatlon
the
follicle
distribution
cells and the apical during
cytoskelcton.
A well-developed
vitellogemc
a dispcraed
are
abundance,
revealed
stage\.
hand of microfilaments cells
relative
muoscopy
c~ten~wc
elements
(NA’K’] of
The
changes
cmpha\ize a
patent
a third
ATPaw folhcle
ccl1 ccl1
Rhodnius
The Rhodnius prolixus follicular epithelium undergoes a programmed sequence of morphological alterations during oogensis (Huebner and Injeyan, 19Sl). These changes are a significant component of follicle cell morphogenesis. Cell shape and cell to cell contacts vary from tall columnar, tightly apposed cells during pre-vitellogenesis to decreased cell height, irregular shape and reduced cell to cell contact during vitellogenesis (Huebner and Anderson, 1972; Huebner and Injeyan, 1981; Watson, 1984). This transformation from a tightly packed epithelium to one with large extracellular spaces is known as ‘patency’ and provides the pathway for extraovarian yolk precursors to reach the oocyte (Davey *Present
follicle
modulation.
Introduction
ment
planes. vitcllogenic
to adjacent
in lateral
the
microtubules and
cells contain
a prominent
connecting
arrangement
and
orientated
or apical
contain
in
to post-wtcllogenic
and cross-sectional
and in the projectlons
and
clcctron
involves
Cytoskeletal
investigating
microtuhule
prc-vitellogcmc
prc-vitellogcnic
component.
cell
mlcrotuhulcs
oogcnesis
cpithelium.
hy
transmlarion
longitudinally
vitellogenic
longitudmal
in cytoskelctal
and
non-patent
cells do howcvcr
follicle
tuhuhn.
Rlrodnrus
a patent
ah assessed
pre-follicular of
the
lateral
in the
casentlal
the
vitellogeneais.
during
creating
change
of
from
arrangement
plasmalemma
abundant
cell shape.
immunofluorcscence
organization
oogencais.
morphogenesis
ccl1 shape
and
contrast
cytoskcleton, cell
follicle
this
Antl-tuhuhn
hulcs
cells.
Follicle
1986.
141
and Huebner, 1974; Davey, 19X1; Telfer ef al., 1982). Cytoskeletal elements play important roles in morphogenetic processes linked to cell shape modification (Cohen, 1979a. b). The Rho&us follicle provides an ideal system to analyse the events and control of epithelial cell shape during the follicle differentiation, overall epithelium permeability and epithelial morphogenesis. Only two studies (Huebner, 1976; Abu-Hakima and Davey , 1977~) have considered the role of the follicle cell cytoskeleton in mediating the cell shape changes associated with ‘patency’. Although the presence of microtubules and microfilaments in Rhodnius follicle cells is established (Huebner and Anderson, 1970; Huebner, 1976; AbuHakima and Davey, 1977c), a detailed analysis of their developmental changes and involvement in follicle cell morphogenesis and differentiation has not been done. Studies investigating cytoskeletal mediated cell shape control usually utilize tissue culture cell or isolated cell systems rather
WATSON
742
than intact tissues (Osborn and Weber, 1977; Wolosewick and Porter, 1979; Albertini et al., 1984). Difficulties in the application of the specialized methods required for cytoskeletal isolation of intact tissues are principally responsible. With the recent development of methods adapting immunocytochemical localization of cytoskeletal proteins to paraffin and plastic embedded tissue sections (Bussolati er al., 1980; Rodning et al., 1980; Kramer, 1981; Hogan and Smith, 1982), it is now possible to reassess and extend our knowledge of the role of the follicle cell cytoskeleton during the cell shape changes associated with follicle cell differentiation and ‘patency’. Through the integration of anti-tubulin immunofluorescence methods with normal microscopy, this transmission electron paper will characterize the relative abundance, orientation and dynamics of the follicle cell microtubule and microfilament cytoskeleton within all follicle cell developmental stages. In particular the variation in cytoskeletal organization between the patent, lateral vitellogenic follicle cells and the nonpatent, apical vitellogenic follicle cells is presented. Materials and Methods Animals were maintained at 27°C in high established using routinely humidity methods (Huebner and Anderson, 1972). Only mated adult females were used, and these animals were fed regularly at appropriate intervals to obtain ovarioles at all specific stages of oogenesis. Prior to fixation, the ovaries were dissected and separated into the seven individual ovarioles by desheathing each ovariole in Rhodnius saline (Maddrell, 1969). Transmission electron microscopy
Ovarioles were pre-fixed 1 hr at 4°C in either a modified Karnovsky’s fixative (Huebner and Anderson, 1972) or a modification of Luftig et al. (1977), microtubule stabilization fixative, containing 3.0% glutaraldehyde in PHEM buffer (Schliwa and Van Blerkom, 1981), pH 6.9, 1 mM GTP. Several fixations also included the addition of 0.5% w/v tannic acid (TA) and 0.05% w/v Saponin (Maupin and Pollard, 1983). Following a buffer wash, ovarioles were
AND HUEBNER
post-fixed for 15 min in 0.5% w/v osmium tetroxide (0~0~) in 0.1 M sodium cacodylate buffer, pH 7.2 (Maupin-Szamier and Pollard, 1978). Following rapid dehydration in a cold ethanol series, the ovarioles were infiltrated and embedded in an EponAraldite mixture (Anderson and Ellis, 1965). Semithin and thin sections were cut with a Sorvall MT2-B ultramicrotome. Semithin sections were stained in 1.0% toluidine blue in 1.0% borax. Thin sections were routinely stained and examined in an AEI6B or 801s electron microscope at 60 kV. Immunofluorescence methods Fixations
For paraffin embedding, ovarioles were fixed in 3.0% paraformaldehyde, 0.5% glutaraldehyde in PHEM buffer (Schliwa and Van Blerkom, 1981) pH 6.9+1 PM GTP for 1 hr, followed by ethanol dehydration, and the routinely processed for paraffin embedding in Tissue Prep 56.5”C”* (Humason, 1979). Ovarioles embedded in EponAraldite (processed as already described) (Anderson and Ellis, 1965), were fixed with l,O% paraformaldehyde in PHEM buffer (Schliwa and Van Blerkom, 1981), pH 6.9++,~M GTP for 1 hr. Paraffin sections (5-10 pm) were cut with a Jung rotary microtome. The sections were mounted on albumin-coated glass slides, deparaffinized in toluene, hydrated and placed in Dulbeccos phosphate-buffered saline (PBS). Plastic sections (l-2 pm) were cut with a Sorvall Porter-Blum MT2-B ultramicrotome and heat fixed on glass slides. The embedding media was removed by exposure to saturated NaOH in absolute ethanol for 30 min (Lane and Europa, 1965; Bussolati et al., 1980). The slides were then washed in 100% ethanol and hydrated to PBS. Antisera
The primary (1’) antibodies used were: (1) rabbit anti-tubulin against chicken embryo brain tubulin (Miles Laboratories), 1: 10 dilution; (2) rabbit anti-tubulin against sea urchin tubulin (gift from Dr. Keiji Fujiwara, Department of Anatomy, Harvard Medical School), 1: 50 dilution. The secon*‘%ademark
Fisher Scientific
FOLLICLE CELL MORPHOGENESIS
dary antibody for all experiments was a fluorescein conjugated goat anti-rabbit IgG (Miles Laboratories) 1: 16 dilution. Immunofluorescence
tests
Routine indirect immunofluorescence procedures were applied (Weber and GroschelStewart, 1974; Osborn and Weber, 1982), as follows; tissue sections were first incubated for 1 hr at 37°C in a 1.0% w/v bovine serum albumin (BSA) type V, (Sigma Chemical Co.) in PBS to minimize non-specific staining. The sections were then incubated for 1 hr at 37°C with one of the 1” antibodies, followed by extensive washings in PBS. The sections were finally incubated in the 2°C antibody for an additional hour. Following this step the sections were washed in PBS, mounted with 50% glycerol in PBS, coversliped and examined with a Zeiss photomicroscope II equipped with epi-fluorescence optics. Fluorescence light micrographs were taken on Kodak Tri-X Pan 135 film at IS0 1000, and developed in Acufine developer (Acufine Inc.).
143
cells, although microfilaments are present at the basal cell end, seen in cross-section next to the cross-sectioned microtubules (Fig. 1). Previtellogenic cells
The columnar, tightly apposed. previtellogenic follicle cell epithelium shows a bright anti-tubulin fluorescence pattern restricted to the lateral cell edges (Fig. 4). Longitudinal sections particularly those near or grazing the cell membrane reveal abundant bands of longitudinally orientated microtubules (Fig. 3). The microtubules are concentrated in the middle or nuclear region of the cells (Figs 4, 5). Cross-sections in the apical and basal area of previtellogenic cells contain fewer microtubules (Fig. 6). The results suggest that the longitudinally arranged microtubules encircle the cell circumference in the form of a cylinder. Microfilament bands are not abundant within pre-vitellogenic cells, however a subplasmalemmal band, parallel to the basal lamina is present in the basal area (Fig. 7).
Control
Vitellogenic cells
Usual controls were conducted to assess the background fluorescence imparted to the tissue from the fixation and embedding methods, plus the non-specific binding of the antibodies (Osborn and Weber, 1982). A check of the tubulin labelling in the microtubule rich trophic core and trophic cords (Huebner and Anderson, 1970) was also conducted as an in situ positive control.
The pre-vitellogenic follicle cells, remain tightly apposed until vitellogenesis is initiated. With the onset of vitellogenesis and the gradual formation of the extracellular spaces (patency), dramatic changes in the microtubular and microfilamentous organization of the lateral fohicle cells occurs. Anti-tubulin immunofluorescence of midvitellogenic follicles shows that the apical follicle cells display a distinctly different fluorescence distribution from the lateral follicle cells (Fig. 8). Bright longitudinal bands of fluorescence along the lateral cell edges (similar to that observed within the pre-vitellogenic follicle cells), are present within the columnar, tightly apposed apical follicle cells (Fig. 8). The patent lateral follicle cells do not show a bright linearly orientated fluorescence within their cytoplasm. Instead, the fluorescence is confined to discrete, thin, anastamosing strands throughout the cell cytoplasm (Figs 8, 11, 12). The use of thinner plastic sections greatly increases the resolution and clearly shows this pattern of anti-tubulin fluorescence (Fig. II). Longitudinal cell sections of apical vitellogenic follicle cells reveal dense bands of long microtubules extending the
Results Prefollicular cells
Anti-tubulin immunofluorescence of the pre-follicular cells revealed a bright band of fluorescence along the lateral cell edges and a second band at the basal end of the cells resting on the basal lamina. Transmission electon microscopy verified this fluorescence pattern coincides with the locations of microtubules (Figs 1, 2). Along the lateral cell edges groups of short longitudinally orientated microtubules are present (Fig. 2). Microtubules orientated at right angles to the lateral microtubules are arranged in the basal ends of those cells resting on the basal lamina (Fig. 1). Microfilamentous regions are not prominent within these
744
WATSON AND HUEBNER
entire cell length (Fig. 10). The orientation in the apical cells remains similar to what was observed in the pre-vitellogenic follicle cells. Examination of a variety of section
planes through the apical follicle cells substantiates this pattern if distribution (Fig. 9). Longitudinal sections of the cell cortex dramatically reveal the abundance of long
Expianation of figures
Abbreviations used in figures: AP. apical vitellogenic follicle cells; B, basal lamina; LF, lateral vitellogenic follicle cell; M, mitochondria; MF, microfilaments; MT, microtubules; NU, nucleus; 0, oocyte, P, plasma membrane; PF, prefollicular tissue. Fig. 1. Shows the cross-sectional profiles of microtules (arrows) with associated microfilaments concentrated at the basal ends of pre-follicular cells adjacent to the basal lamina. x 136,ooO. Fig. 2. Longitudinal profiles of microtubules arc isolated along the lateral cell edges of the pre-follicular cells. X70,000. Fig. 3. This section of the cell cortex reveals the dense array of longitudinally orientated microtubules just under the plasmalemma of pre-vitellogenic follicle cells. ~37,000. Fig. 4. Fluorescent micrograph of an Epon-Araldite embedded tissue section shows the bright lateral lines of anti-tubulin fluorescence observed in pre-vitellogenic follicle cells. X1000. Fig. 5. Microtubules (arrow) are organized along the lateral edges of the nuclear area of pre-vitellogenic follicle cells. ~32,000. Fig 6. Microtubules become less numerous in the poles of these cells, as shown by this cross-section through the basal end of a pre-vitellogenic cell. ~20,000. Fig. 7. A microfilamentous area is present, parallel to the basal lamina in a pre-vitellogenic follicle cell. Tannic acid fixation. x45$00. Fig. 8. Anti-tubulin immunofluorescence of a Spm paraffin section, comparing fluorescence pattern between adjacent lateral and apical vitellogenic follicle cells. x700.
the
Fig. 9. Cross-section with large numbers of microtubules (arrows) orientated longitudinally in the apical vitellogenic follicle cells. ~28,000. Fig. 10. This TEM displays the length and close opposition of the prominent microtubules within the apical vitellogenic follicle cells. x 160,000. Fig. 11. This Epon-Araldite section shows a delicate irregular pattern of fluorescence in the patent lateral follicle cells. x750. Fig. 12. Anti-tubulin immunofluorescence, revealing the overall diffuse, fluorescent pattern observed within patent lateral follicle cells as seen in a paraffin section. X900. Fig. 13. Numerous microtubules (arrows) in both longitudinal and cross-section profile are observed in this longitudinal TEM section of a patent lateral follicle cell. x25,OCO. Fig. 14. The exclusion of ribosomes and other cell organelles by the subplasmalemmal of microfilaments is revealed in this TEM. ~32.0GO. Fig. 15. The anti-tubulin lateral follicle cells. X900.
immunoflourescent
band
pattern of a paraffin cross-section of patent
Fig. 16. This cross-section TEM show microtubule (arrows) distribution within the patent lateral cells. Note there are both cross-section and longitudinal profiles of microtubules. x30.000
WATSON
microtubules (Fig. 10). These dense accumulations of microtubules in the apical follicle cells are greater than those of any other follicle cell stage or substage. They are also the longest microtubules observed at any follicle cell stage. The combination of their length and large numbers makes them the predominant cytoplasmic feature of the apical follicle cells. The microtubules of the apical vitellogenic follicle cells, as in pre-vitellogenic cells, are concentrated in the nuclear region of the cell. Although some of the microtubules extend into the basal and apical ends of these cells, their arrangement becomes less regular. This accounts for the diffuse and irregular antitubulin fluorescence seen in apical and basal areas of the cells (Fig. 8). The patent lateral follicle cells contain numerous microtubules (Figs 13, 16). However, in sharp contrast with the apical vitellogenic cells. these microtubules are shorter and not parallel, but rather irregularly arranged so various microtubule section planes are seen in any cell section (Figs 17, 18). The immunofluorescence staining pattern confirms this (Figs 11, 12, 15). The lateral (unlike apical) vitellogenic follicle cells also contain extensive microfilament arrays. These microfilaments are organized into a subplasmalemmal band as clearly revealed in the tannic acid-Saponin fixation (Fig. 14). Microfilaments are also concentrated within the lateral arms connecting adjacent patent cells (Fig. 21). As the extracellular spaces enlarge during late vitellogenesis these arms become more ex-
Figs 17. IX. The patency Fig.
19.
The
fluorescence Fig.
irregular
IS depicted
20.
A few
Discussion The formation of a patent follicular epithelium is an essential developmental event during oogenesis within many insect and vertebrate species (Anderson, 1969; Perry and Gilbert, 1979; Dumont, 1972; Telfer et al., 1982; Abraham et al., 1984). This process provides a pathway for yolk proteins synthesized at extraovarian sites to reach the oolemma for pinocytic incorporation. The associated cell shape changes in the lateral follicle cells are developmentally
orientation
anti-tubulin
of muotuhules
magnification
follicle
are found
(arrows)
electron
immunofluorescence
the post-vitellogenic microtubules
IIUEBNEK
tensive with microtubules becoming a common constitutent as well. The apical projections of the patent lateral follicle cells, which maintain oocyte-follicle cell contact during vitellogenesis also contain dense microfilament bands (Fig. 22). Following vitellogenesis the lateral cells increase their cell volume and form a tightly packed epithelium. Anti-tubulin immunofluorescence results show a diffuse fluorescence around the lateral and basal cell extremities (Fig. 19). The few microtubules found in these cells are parallel to the basal lamina whereas some are localized along the lateral cell edges beneath the plasmalemma (Fig. 20). Clearly, there is an alteration in the number and orientation of the microtubules during this last phase of follicle cell morphogenesis. Microfilamentous areas are not prominent with only a few areas present along the lateral cell edges.
in these higher
within
AND
pattern cells.
in hasal
in lateral
reveals
follicle
cells during
x IIO,(NK), ~350,000.
micrographs. a
basal
dtstribution
of
X%0.
ends of the post-vitcllogenic
folhclc
cells.
the
neighhouring
X6O.OCa. Fig. patent Fig.
21.
Dense
lateral 22.
XhS,OOO.
array
follicle
The
of microfilaments
cells.
within
lateral
arms
connecting
X35.000.
microfilaments
wthin
a apical
projection
of
a patent
lateral
follicle
cell.
WATSON
regulated and arise due to the integration of at least three separate cellular processes. These included: (1) [Na+K+] ATPase induced follicle cell shrinkage. mediated by juvenile hormone (JH) (Abu-Hakima and Davey, 1975, 1977a, 1979; Huebner and Injeyan, 1980; Ilenchuk and Davey, 1983); (2) disassembly and reorganization of the septate and gap junctions along the lateral follicle cell membranes (Huebner and Injeyan, 1981); and (3) cytoskeletal reorganization within the lateral follicle cells correlated with the onset of vitellogenesis. Of these three cellular processes, the cytoskeletal involvement is the least studied. A cytoskeletal role in patency was initially suggested by Huebner (1976) and Abu-Hakima and Davey (1977b), since cytoskeletal disruptors, cytochalasin B and colchicine inhibited the juvenile hormone (JH) induced patency response. Huebner and Anderson (1970, 1972) and AbuHakima and Davey (1977~) described the ultrastructural presence of microtubules and microfilaments in Rhodnius follicle cells. No study has compared the changes in arrangement and abundance of these cytoskeletal elements in follicle cell differentiation during oogenesis in detail, and also utilized immunofluorescence to provide a clear view of the overall changes. The immunofluorescence and TEM results both substantiate that the initiation of patency is correlated with a microtubular reorganization in the lateral follicle cells. This is reflected in a change from the highly organized cylindrically arranged microtubules of the pre-vitellogenic cells to the random pattern observed with the midvitellogenic, lateral follicle cells. Huebner and Anderson (1972) first reported that the vitellogenic apical, follicle cells remain columnar and tightly apposed during patency. The results from our study suggest that the maintenance of a well-organized cylindrically orientated microtubular cytoskelton precludes any possible cell shape change. The vitellogenic, lateral follicle cells decrease in cell height at the onset of patency (Abu-Hakima and Davey, 1977a). This decrease in height is correlated with the reorganization of microtubules in the lateral follicle cells reported here. The formation of a random distribution of microtubules
AND HLJEI~h’L‘Ef<
would greatly decrease the resistance an organized cylindrical arrangement of microtubules would produce against a change in cell height or volume. The microtubules arranged randomly could still support the new cell shape but at the same time would not inhibit any inward movement of the cell boundaries associated with cell shrinkage. The overall process of cell shrinkage by [Na’K+) ATPase mediated pumping of fluid out of the cell (Davey. 1981) would therefore be restrained until the microtubular cytoskeleton becomes rearranged. The conclusion that microtubules play a key role in the dynamics of lateral follicle cell shape in Rhodnius is supported by extensive literature in other eukaryote systems which demonstrate that microtubules maintain and modulate cell shape (Burnside, 1973; Barrett and Dawson, 1974; Tucker and Meats, 1976; Beckerle and Porter, 1983; Frixione, 1983; Albertini et al., 1984; Roos et al., 1984). The formation of prominent microfilamentous bundles within the patent lateral follicle cells. indicates they also contribute to the modulation of cell shape and in particular the formation of the lateral connections between neighbouring lateral follicle cells. Microfilaments are often transitory ceil structures as exemplified by the formation of the contractile ring or cleavage furrow of mitotic cells (Fujiwara rt al. lY78; Schroeder, 1981). Microfilaments can also form the main cytoskeletal constituents of very stable cell structures such as the intestinal brush border (Mooseker. 1976; Hirokawa et a/., 1982) or the sterocilia of the cochlear hair cells (Tilney and Saunders, 1983: Tilney et al., 1Y83). The production of a subplasmalemmal band of microfilaments within the lateral follicle cells could function similar to a contractile ring by producing an inward contractile force that contributes to the formation of the irregular cell shape. The scarcity of dense microfilamentous arrays within the pre-vitellogenic and apical vitellogenic follicle cells shows they are not essential for the maintenance of the columnar shape. The juvenile hormone (JH) mediated cell shape changes of the lateral follicle cells in Rhodnius involve a more complex interaction of cellular processes than generally assumed. JH either directly or indirectly
t’O1 I.I(‘L
.i,
F: (‘FCL.1. MOKPliOtiENESIS
coordinates the rearrangement of the microtubular and microfilamentous elements of the lateral follicle cell cytoskeleton; the disassembly and rearrangement of cell junctions (I Iuebner and Injeyan, 1981) and finally [ Na’ K-1 ATPase cell shrinkage (Davey. IYXI). The details of the dynamics of the follicle cell cytoskeleton during oogenesis, elucidated 111this paper, add to our understanding of the overall process of follicle cell ditferentiation. These results have also verified that the Nl&ni~s follicular epithelium
provides a suitable model system to \tud? the role of cy,toskeletal organization in the modulation ot cell shape in a differentiating tissue. Acknowledgements We thank Dr K. FuJiwara for kindl! \upplying the sea urchin anti-tubulin and W. Sigurdson and G. Kelly for helpful comments. Research was supported I>! NSERC grants to E.H. and an NSF.KC‘ Post-graduate Scholarship to A.W
752
WATSON
AND HUEBNEK
Hogan, D. L. and Smith. G. H. lYX2. Unconventional application of standard light and electron immunocytochemical analysis to aldehyde-fixed Araldite embedded tissues. J. Hisrochem. Cyrochem.. 30, 1301-1306. Huebner. E. 1976. Experimental modulation of the folhcular epithelium of Rhodnius oocytes by juvende hormone and other agents. J. Cell Biol 70, 25la. Huebner, E. and Anderson. E. 1970. The effects of vinblaatine sulfate on the microtuhular organization of the ovary of Rhodnius prohxuv. J. Ccl/ Biol.. 46, 191-198. Huebner. E. and Anderson. E. 1972. A cytological study of the ovary of Rhodniux prolixu.~. I. The ontogeny of the follicular epithelium. J Morph.. 136, 459-494. Huebner, E. and Injeyan. II. S. 1980. Patency of the follicular epithelium in Rhodnius pro/i.rus: a reexamination of the hormone response and technique refinement. Can. J. Zool.. 58, 1617-1625. Huebner, E. and Injeyan. II. S. 1981. Follicular modulation during oocyte development in an insect: formation and modification of septatc and gap junctions. Drvl. Biol.. 83, 101-I 13. Humason. G. L. 1979. Animal Tissue Techniques. 4th edn.. 661 pp. W. H. Freeman, San Francisco. Ilenchuk, T. T. and Davey. K. G. 1983. Juvenile hormone increases ouabain-binding capacity of microsomal prepartions from vitellogenic follicle cells. Can. J. Biochem. CeU BioL. 61, 826-831. Kramer, J. M. 1981 Immunofluorexent localization of PGK-I and PGK-2 coenzymcs with specific cells of the mouse testis. L)ev/. Biol., 87, 30-36. Lane. B. P. and Europa, D. L. 1965. Differential staining of ultrathin sections of Epon embedded tissues for light mwoxopy. J. Hittochern. C:vtochrm.. 13, 579. Luftig. R B.. McMillan. P. W.. Wcathcrbcc. J. A. and Weihing. R. R. lY77. lncrcased visualization of microtubules by an improved fixation proccdurc. J. Hurochrm. Cytochem. 25, 175-187. Maddrell, S. H. P. 1969. Secretion by the Malpighian tub&s of Rhodnm. 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Academic Press. Toronto. Perry. M. M. and Gilbert. A. B. 1979. Yolk transport in the ovarian folhclc of the hen (Gollus domesticus): lipoprotein-like partlclcs at the periphery of the oocyte in the rapid growth phase. J. Cell. Sci.. 39. 257-272. Rodning, C. B.. Erlandscn. S. L., Coutler, D. H. and Wilson, I. D. 1980. Immunoh~stochemical localization of IgA antigens in sections embedded in epoxy resin. J Hiskrhem. Cymchem.. 28, 199-205. Roes. V. P.. Brabander, M. and DeMay, J. lYX4. Indirect immunofluorebcence of mlcrotubules in Dictyortelium discoideum. A study wth polyclonal and monoclonal antibodies to tubulins. Expl. Cell Res.. 151, 1X?-193. Schliwa, M. and Van Blerkom, J. 19X1. Structured interaction of cytoskeletal components. J. Cell Biol., 80,222-235. Schroeder. T. E. 1981. The origin of cleavage forces in dividing eggs. A mechanism in two steps. Expl. Cell Res.. 134, 231-240. Telfer, W. H., Huebner, E. and Smith, D. S. 1982. The cell biology of vitellogcnic follicles in Hyalophoru and Rhodnius. In /rwct Uitrastrucrure (eds R. C. King and H. Akai), Vol. 1. pp. llbl49. Plenum Press. New York. Tilney, L. G. and Saunders, J. C. 19X3. Actin filaments. stereocilia. and hair cells of the bird cochlea. I. Length. number, width and distribution of stereocilia of each hair cell are related to the position of the hau cell on the cochlea. J. Cell Bio[. 96, X07-821. Tilney. L. G.. Egelman, E. H.. Derosier, D. J. and Saunders. J. C. 19X3. Actin filaments sterocilia and hair cells of the bird cochlea. II. Packing of actin filaments in the stereociliar and in the cuticular pIare and what happens to the organization when the stereocilia arc bent. J. Cell Biol., 96, X22-834. Tucker. J. B. and Meats, M. 1976. Microtubules and control of insect egg shape. J. Cell Biol.. 71, 207-217. Watson, A. J. 1984. The dynamics of the Rhodnius prolixus follicle cell cytoskeleton: ultrastructure and immunocytochemistry. M.Sc. thesis. Dept. of Zoology. University of Manitoba. Winnipeg, Manitoba. 146 pp. Weber. K. and Groschel-Stewart. U. 1974. Antibody to myosin. The specific visualization of myosin containing filaments in non-muscle cells. Proc. mtn. Acad. Sci. U.S.A., 71, 4561-4564. Wolosewick, J. J. and Porter, K. R. 1979. Microtrabecular lattice of the cytoplasmic ground substance. Artifact or reality. J. Cell Biol.. 82, 114-139.