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The effects of light intensity and light period on the development of thallus form in the marine red ALGA Pleonosporium squarrulosum (Harvey) Abbott (Rhodophyta: Ceramiales). II. Cell enlargement
J. e.qo. mcrr. Bial. Ecol., 1975, Vol. 19, pp. 165-l 76; (6, North-Holland
Publishing Company
THE EFFECTS OF LIGHT 1NTENSITY AND LIGHT PERIOD ON THE DEVELOPMENT OF THALLUS FORM IN THE MARINE RED ALGA PLEONOSPORIUM
SQUARRULOSUM
(RHODOPHYTA: CERA~LES).
(Harvey) Abbott
II. CELL ENLARGEMENT
STEVEN N. MURRAY Department of Biulogiccd Science, Cnlijkwzin State University, F44ilertctn, Ct~l~fornia~U.S.A. and PETERS. DIXON Depurtment ofPopulation and Environmentnl Biolog.~, iJniversit.v of California, Irvine, CnliJbmia, U.S.A. Abstract: Analyses of patterns of cell enlargement of regenerates of Ple[~n~sporilint s~tu~rr~~~~)sut~~ (Harvey) Abbott grown under light periods of 16L-8D and SL-16D and light intensities of 269, 538, 1076, and 1614 lux have been made. These show that light intensity, and to a mnch greater degree, light period significantly affect the magnitude of cell elongation for main axes and tirstorder IateraI axes; for main axes, such was primarily by an increase in size of the basipetal parts 01 ceils.
INTRODUCTION
In order to understand the morphological variation of a florideophycean taxon, one must know something concerning the effects of diverse ecological conditions on growth. The form of an algal thalius is determined by the interaction of three processes, namely; cell division, cell enlargement, and cell differentiation, and the effect of environmental conditions on the form of Florideophyceae may be best determined by analyses of the responses of these processes. The general principles of thallus development have been outlined by Dixon (1958, 1960,1963a, b, 1966, 1970,197l) and it has been shown that in the Florideophyceae, particularly the simple uniseriate Ceramiaceae, cell division and cell enlargement exert by far the greatest influence on thallus form. Relatively little is known of the rates of division of apical cells of Florideophyceae under different environmental conditions; however, it appears that apical cells of primary axes undergo l-3 divisions per day (Konrad-Hawkins, 1964a, b; Dixon & Richardson, 1970; Duffield, Waaland & Cleland, 1972; Waaland & Cleland, 1972; Murray & Dixon, 1973) and that the rate of division in certain taxa is influenced by light (Dixon & Richardson, 1970; Murray & Dixon, 1973). The relation of cell enlargement to the development of thallus 165
STEVEN N. MURRAY
166
form has been discussed based largely
by Dixon
on field data,
complex
patterns
Analyses
of cell elongation
patterns
PETER S. DIXON
(1971) for several florideophycean
has treated
of enlargement
AND
in detail
and has provided
the magnitude,
taxa; this work, orientation,
a basis for experimental
under different laboratory
illumination
and study.
treatments
have been given for GrifJithsia pacijica (Waaland & Cleland, 1972). Murray & Dixon (1973) have already determined the effects of illumination on the rates of division of apical cells of main axes of Pleonosporium squarrulosum (Harvey) Abbott. The present contribution represents a sequel to that study and is concerned with the effects of light period and light intensity on cell enlargement.
MATERIALS AND METHODS
Regenerates of P. squarrulosum were grown under experimental light-dark periods of 16 h light-8 h dark (16L-SD) and 8 h light-l 6 h dark (8L-16D) for 2 1 consecutive 24-h days. Light intensities of 269, 538, 1076, and 1614 lux were used at each lightperiod treatment. At the end of experiments, the regenerates were fixed in 3-4 “<, formaldehyde-sea water, made into semi-permanent glycerine-jelly preparations, and analysed with respect to the enlargement of cells of main and first-order lateral axes. Seven to twelve replicates were analysed for each experimental treatment. (See Murray & Dixon, 1973, for details.) Although the enlargement of axial cells of P. squarrufosum is three-dimensional, by far the greatest degree of enlargement is consistently in overall cell length, and so this measure was chosen for comparing the effects of experimental treatments on the enlargement of axial cells. Cell lengths were obtained for each axial cell as the distance between its pit connections with immediately acropetal and basipetal cells; patterns of cell enlargement were then determined for experimental plants by plotting cell length against segment number. Plots were made for both main and lateral axes of the plants. In order to carry out a statistical analysis for all except regenerates grown under 269 lux, the lengths of the 30&h, 40th, and 50th cells from the apex of the main axis were pooled for regenerates receiving a similar experimental treatment. These data were then analysed
by analyses
of variance
for cases with disproportionate
subclass size (see, Steel & Torrie, 1960). For regenerates grown under 269 lux illumination, replicates were too few or growth was insufficient for statistical treatment of the data. Intracellular patterns of the enlargement of cells of the main axes were also compared between regenerates grown under different experimental treatments. Measurements of individual axial cells were recorded in terms of basipetal and acropetal components. Basipetal components were measured from the pit connection for,med by each axial cell during the production of its single lateral initial (cf., Murray & Dixon, 1973) and its basipetally-orientated pit connection with the axial cell immediately below. Similarly, acropetal components were determined by measuring from the point of lateral initiation to the acropetally-orientated pit connection. The effects of light intensity
THALLUS
FORM
IN A RED
ALGA
167
and light period on patterns of intracellular enlargement were tested by the same statistical technique after pooling basipetal/acropetal enlargement ratios for the 30th. 40&h, and 50th cells from the apex for regenerates receiving common experimental treatments; results from regenerates receiving 269 lux illumination treatments were again not analysed. I 300 8L-160
16L-8D
t
ioow
200
t
300 -
I076 Ix
200
-
100 1614 Ix Apex IO
20
30
40
50 SEGMENT
Apex to
20
30
40
50
NUMBER
regenerates of Pleonosporium grown under experimental light treatments: A, B, C, D = 8L-16D; E, F, G, H -= 16L-SD; A, E = 269 lux; B, F = 538 lux; C, G = 1076 lux; D, H = 1614 lux.
Fig. 1. The
syuarrdosum
patterns of main axis cell elongation for representative
STEVEN
168
N. MURRAY
AND
PETER
S. DIXON
RESULTS AND DISCUSSION
The pattern of thallus development in many Florideophyceae is highly controlled with respect to cell division and cell enlargement. As has been indicated previously (Dixon, 1971; Murray & Dixon, 1973), cells in florideophycean filaments, with only a few exceptions, are produced in a linear series by successive apical cell divisions, so that in mature thalli the relative positions of axial cells within filaments may be employed for age comparisons. MAIN
AXES
The patterns of elongation of the cells of the main axes of P. ~~~~r~~~~~~~under the experimental light treatments are given in Fig. I for representative regenerates; clearly light period affects cell elongation profiles. Additionally, comparison of the data (~5, Fig. I, Table I) for regenerates grown under 269 lux show a reduction in cell elongation for both 8L-16D and 16L-8D photoperiods. Cell elongation is interpreted to be sensitive to the low light intensity (269 lux) in much the same manner as the rates of apical cell division (Murray & Dixon, 1973); cell elongation is, however, much more clearly affected by light period. A statistical comparison such as outlined above on pooled data does not allow for differences in rates of apical cell division which would affect the ages of equivalently-positioned axial cells of different experimental plants. Differencesin the rates ofdivision ofapical cells of the main axes of experimental P. ~q~ffrr~~~~~~regenerates have been reported earher (Murray & Dixon, 1973); by far the greatest effect of light on cell division was in regenerates grown TABLE
1
Increase in length (pm) of the 30th, 40th, and 50th cells of main axes of regenerates various experimental conditions of illumination: means and 5 S.D. Illumination conditions
30th crll ______ 2
50th cell
40th cell
5.S.D.
.t‘
grown under
+S.D.
.i?
_: S.1).
269 iux* SL-I 6D 16L-8D
44 126
_ .._
SO I.56
_
II0 218
538 Iux 8L-16D l6L-SD
133 144
12 I8
I89 258
22 28
216 339
29 32
1076 lux 8L--16D 16L-8D
122 145
22 34
I88 226
29 62
263 359
28 93
1614 lux 8L-I 60 I H.-SD
130 162
I5 24
216 258
I6 38
288 410
35 57
* Data for 269 lux are taken from representative
regenerates.
THALLUS
FORM
IN
A RED
ALGA
169
500
400
I
,
T
I’ I
<’
50th CELL
f
300
200
100
-C 9 40th
i y
He’ : _I’
300
;---________F
2 x :
CELL
200
0 z W 5
100
-I
300 30th
CELL
200 _--________
__--
___a---
-3
T
3
IOk
I$14
100
5~8
LIGHT INTENSITY (LUX) Fig. 2. Enlargement of the 30th, 40th and 50th axial cells of regenerates of Pleonosporium s9uarrulosun1 grown under experimental light treatments: means and confidence limits at P = 0.05: ~~~ 8L-16D; ---16L-8D.
STEVEN
170
N.
MURRAY
AND
under 269 lux and this could not be included ages of axial cells for experimental cell division do not result
data of Murray
material
(1973) discussed
different
S. DIXON
in the present analysis.
P. squarrulosum
& Dixon
in interpretations
PETER
from those
Estimates
may be obtained
of the
from the
earlier. These data, however, given
here and really
do not
represent a significant improvement in methodology because the ages of cells can still not be precisely set. The true ages of cells can only be determined by constant daily monitoring (see, Waaland & Cleland, 1972) or by marking techniques (see, Waaland, Waaland & Cleland, 1972). Such techniques are far more precise but since quantitative data on the effects of environmental factors on cell enlargement are almost totally lacking for Florideophyceae, our results represent a useful starting point for further investigations. The magnitudes of enlargement of the 30th, 40ih, and 50th axial cells of these regenerates grown under experimental illumination conditions are given in Table I and Fig. 2. Analysis of variance (Table II) indicates that light intensity did not affect cell elongation at the 30th cell level (P > 0.05) but became a significant factor at the level ofthe40th (0.05 > P > 0.01) and 50&h(0.01 > P >O.OOl ) cells. Light period was found to significantly (P < 0.001 ) affect cell elongation in comparisons of all levels and it represented by far the most important effect: elongation differences became more pronounced as cells aged (Table II, Fig. 2). Since for the experimental treatments used the effect of light intensity appeared to be minimal for regenerates receiving > 269 lux, the data for these light intensity treatments TABLE
II
Analysis of variance of cell elongation at the 30th. 40th, and 50th cell levels for regenerates of Pleonosporiun~ syuarrulosum grown under experimental conditions of illumination greater than 269 lux: method for disproportionate subclass numbers (Steel & Torrie, 1960): *** P 0.001, ** 0.01 > P > 0.001,* 0.05 3. P 0.01.n.s. P _'0.05. Source of variation
D.f.
Sum of squares
Mean square
30th cell Light period Light intensity Interaction Error
2 2 46
6408 1357 I092 21421
6408 679 546 466
40th cell Light period Light intensity Interaction Error
1 2 2 48
321.52 7983 2425 57565
32152 3991 1212 II99
I 2
150535 39497 I840 115421
150535 19748 920 2815
50th cell Light period Light intensity Interaction Error
L
41
F
13.76***
I .46 n.s. 1.17 n.s.
26.78*** 3.33* 1.01 11.5.
53.47*** 7.01** 0.33 n.s.
THALLUS
FORM
IN A RED
were pooled for each cell ‘age’ and regression treatments
lines calculated
(Fig. 3). There is a greater rate of increase
ates grown under longer 9 = - 173.12+ lO.74Xfor
Ill
ALGA
for the two light-period
in cell size with ageforregener-
(I 6L-8D) illumination. The regression equations 16L-8D and 9 = -60.77+6.36Xfor 8L-16D.whers
the length of axial cells and X the axial segment
are: ?is
number.
16L-80
8L- 16D
1
i 30 SEGMENI-
Fig. 3. Regression and
16L-RD
C----)
lines for regenerates light periods:
I
I
40
50
NUMBER
of Pkonosporirmr
means of pooled
sqmrrulosrotr grown under 8L-16D
light intensity
data
(538,
1076,
1614
(
)
ILIX) Or
each cell ‘age‘.
The significant effects of light period and light intensity on cell e~ongatj~~n in P~~o~us~?~r~u~ ~~~~~~~~~~z/~ contrast with results of D&field, Waaland & Cleland ( 1972) and Waaland & Cleland (1972) for Gri’thsia pacijicn where 300 ft-c ( % 3230 lux) and 4Oft-c (Z 4301~~) and 16L-8D, 12L-12D and SL-16D light periods did not markedly affect the rate of cell elongation. A developmental effect of light intensity on “shoot” cells was also found; under higher light intensities (300 ft-c) these cells became predominantly nodal i.e., they produced lateral branch initials. In Pleonospnrim squarrulosum, each axial shoot cell gives rise to a single lateral branch and so there is no differential development from which the effects of primary lateral production would become apparent. A greater production of 3rd order laterals was, however. apparent for most regenerates receiving the longer light period. Dixon (1971) has given evidence for the effect of a lateral filament on cell enlargement within the parent filament for Florideophyceae such as Gr~~t~~s~~pac(fica where each segment cell does
172
STEVEN
not have the same branching
N.
MURRAY
AND
characteristics;
PETER
analysis
S. DIXON
of the effects of environmental
parameters on cell elongation in the main axes of G. pacijica could be complicated the additional variable of differential branching of shoot cells. LATERAL
Analysis
by
AXES
of enlargement
of cells of first order laterals
(Fig. 4) show comparable
patterns to those described above for main axes. Elongation was uniformly less pronounced under the 8L-16D light period as compared with 16L-8D. Jn addition, reduction in cell size is apparent when comparisons are made between regenerates
150 1 16L_
269 Ix
-
-’
1
1
x
a
k 150 E P- 100i
SEGMENT
NUMBER
Fig. 4. The patterns of first-order lateral axis cell elongation for representative regenerates of Pleonosporium squarrulosum grown under experimental light treatments: A, B, C, D : SL-16D: E, F, G, H = 16L-SD; A, E = 269 lux; B, F : 538 lux; C, G = 1076 lux; D, H 7 1614 lux.
THALLUS
receiving
FORM
IN
A RED
173
ALGA
269 lux and those grown under higher light intensities;
variations
in enlarge-
ment profiles as a function among regenerates receiving
of light intensity were minimal for each light period light intensities greater than 269 lux.
PATTERNS
ELONGATION
Analysis
OF INTRACELLULAR
of intracellular
elongation
patterns
for a number
of Florideophyceae.
as indicated by using pit connections formed between parent axial cells and their pericentral-cell derivatives, have shown asymmetric patterns of intracellular growth (Dixon, 1971). In such thalli, pericentral cells are formed when axial cells are young and in a position just a few cells removed from their apical cell origin. At the time of pericentral cell formation, the pit connection is positioned approximately midway along the length of the parent axial cell, so that differential patterns of intracellular elongation with cell age may be determined by treating separately the elonpaSEGMENT
NO
LENGTH
./,, :. P
;.
j ,.
: j
: i
Total cell
,:’
39
106
259
IN MICRONS
Acropetol
17
Basipetal
22
29
77
36
223
100 urn
Fig. 5. The
intracellular
pattern
of elongation
of main
axis cells of Pleonosporium
syuarrulosurn.
174
STEVEN
N.
MURRAY
AND
PETER
S. DIXON
TABLE 111 Ratio
of basipetal/acropetal grown under
for the 30th, 40th, and 50th cells of main axes of regenerates conditions of illumination; means and LS.D. 40th cell
30th cell
Illumination conditions 269
elongation experimental
F
_AS.D.
.i
SOth cell S.D.
.r
S.,).
lux* 2.0 3.3
SL--lbD l6L-8D
2.6 3.1
3.5 3 .:
5.38 lux 8L -16D 16L-8D 1076
0.5 0.7
3.4 4.9
0.5 0.6
3.9 4.5
0.5 0 .6
3.0 ?.I
0.4 0.6
3.6 4.2
0.5 0.6
3.7 4.6
0.5 0.5
3.0 3.5
0.5 0.7
3.9 4.3
0.6 0.6
4. I 4.x
0.5
lux
XL-16D 16l..-8D I614
3.1 3.5
lux
XL-l6D l6L-8D * Data
for 269 Iux are taken
from
representative
0.x
plants
Analysis of variance of basipetalKacropetal elongation ratios at the 30th, 40th, and 50th cell levels for regenerates of Pleonosporiu~r~ sqrrarrrrlmrm grown under experimental conditions of illumination greater than 269 Iux: method for disproportionate subclass numbers (Steel & Torric. 1960): ratios have been inverted and transformed to arcsine values in order to stabilirc the variance\. *** p 0.05. 0.001, ** 0.01 -. P ’ 0.001, * 0.05 ’ P 0.01, 1l.S. P Source ot variation
D.f
Sum oi squares
Mean square
30th cell Light period Light intensity Interaction Error
2 2
46
49. IO 18.96 17.84 593.15
49. IO 9.48 8.92 12.89
3.81
1.b.
0.74 n.5. 0.69 I1.S.
40th cell Light period Light intensity Interaction Error
145.56 14.31 24.04 5.71
25.49*** 2.51 n.5.
2 48
145.56 28.61 48.07 274. I9
2 2 41
90.79 14.01 7.09 188.59
90.79 7.01 3.55 4.60
19.74*** I .52 n.s. 0.77 n.s.
2
3.21*
50th cell Light period Light intensity Interaction Error
THALLUS
tion
of cell portions
acropetal
‘marker’.
The great majority
basipetal
intracellular
Pleonosporizrm
manifested
IN
A RED
and basipetal
to the pericentral
of Florideophyceae
elongation
as axial
I7
ALGA
show a marked
cells mature
(Dixon,
cell pit-connection predominance 1971,
1973).
of For
squarrulosum,
basipetally
were determined
FORM
the elongation of axial cells with age is also large11 (Fig. 5). Basipetal/acropetal ratios of intracellular elongation
(Table
III) for the 30th, 40th, and 50th axial cells of regenerates
subjected to experimental transformation to arcsin-
light treatments. Analyses of variance of the data after ’ values for all plants receiving > 269 lux were made to test whether the previously observed effects of light on the magnitude of axial cell elongation affected the established basipetal to acropetal growth pattern; these analyses (Table IV) indicate that the longer I6 h light period significantly increz\ed the relative basipetal elongation; the effects of light period on cell elongation art‘. therefore, primarily manifested in an increased rate of basipetal elongation.
ACKNOWLEDGEMFNTS
Partial assistance for this work was gained from a California State University. Fullerton, Faculty Research stipend (SNM). We are grateful to Kathryn Heath for preparation of the illustrations.
REFERENCES DIXON, I’. S., 1958. The morpholcgy, ecology and taxonomy of certain Florideae. Bv. $?~.ujI. Buli.. Vol. I, pp. 32-33. DIXON, P. S., 1960. Studies on marine algae of the British Isles: Crrtr,uirorr sll//rrlel~o~!/fi~i,rul,r (Kutr.) Silva. J. MT. hiol. Ass. U.K., Vol. 39, pp. 375-390. DIXON, P. S., 1963a. The Rhodophyta: some aspects of their hiologq. Ocrtrno/z iu tlrc, YPCI. edited by J. P. Harding and N. Tebble, Systematic Association, London, pp. 51 -62. DIXON, P. S., 1966. On the form of the thallus in the Florideophyceae. In, Tre&s i/l /~/trut /r~orplu~qenesis, edited by E. G. Cutter, Longmans, Green & Co., London, pp. 45-63. DIXON, P. S., 1970. The Rhodophyta, some aspects of their biology. II. Ocrtrr~oyr. ,2lc1r. Bfr~l. ,l/~/r. Rer.. Vol. 8, pp. 307-352. DIXON, P. S.. 1971. Cell enlargement in relation to the development of thallus form in Florldeophyceae. Br. ph~~col. J., Vol. 6, pp. l95--205. DIXON, P. S., 1973. Biology qf’the Rhodophyrtr. Oliver and Boyd, Edinburgh, 285 pp. DIXON, P. S. & W. N. RICHARDSON, 1970. Growth and reproduction in red algae in relation to light and dark cycles. Ann. N.Y. Acod. Sri., Vol. 175, pp. 764-777. DUFFIELU, E. C. S., S. D. WAALAND & R. CLELAND, 1972. Morphogcnesis in the red alga. Gritirthsilr pcrcificu. Regeneration from single cells. Plntzfcr, Vol. 105, pp. lSSLl95. KONRAD-HAWKINS, E., 1964a. Developmental studies on regenerates of Ctr/[ithrrrtrnion YOS~II~~I Harvey. Part. 1. The development of a typical regenerate. Proroplasmtr, Vol. 58, pp. 42-59. KONRAD-HAWKINS, E., 1964b. Developmental studies on regenerates of Ctrllithtrr~~nir~z roscuvr Harvey. Part II. Analysis of apical growth. Regulation of growth and form. Profopkrsnro, Vol. 58. pp. 60-74.
176
STEVEN N. MURRAY
AND
PETER S. DIXON
MURRAY, S. N. & P. S. DIXON, 1973. The effect of light intensity and light period on the development of thallus form in the marine red alga Pleonosporium squnrrulosurn (Harvey) Abbott (Rhodophyta: Ceramiales). 1. Apical cell division main axes. J. exp. mar. Biol. Ecol., Vol. 13, pp. 15-27. STEEL, R. C. D. & J. H. TORRIE, 1960. Principles and procedures qfstatistics. McGraw-Hill Book Co. Inc., New York, 481 pp. WAALAND, S. D. & R. CLELAND, 1972. Development in the red alga Grififh’rhsicr ptrcificcr. Control by internal and external factors. Planta, Vol. 105, pp. 196-204. WAALAND, S. D., J. R. WAALAND & R. CLELAND, 1972. A new pattern of plant cell elongation: bipolar band growth. J. Cell Biol., Vol. 172, pp. 184-190.
Publishing Company
THE EFFECTS OF LIGHT 1NTENSITY AND LIGHT PERIOD ON THE DEVELOPMENT OF THALLUS FORM IN THE MARINE RED ALGA PLEONOSPORIUM
SQUARRULOSUM
(RHODOPHYTA: CERA~LES).
(Harvey) Abbott
II. CELL ENLARGEMENT
STEVEN N. MURRAY Department of Biulogiccd Science, Cnlijkwzin State University, F44ilertctn, Ct~l~fornia~U.S.A. and PETERS. DIXON Depurtment ofPopulation and Environmentnl Biolog.~, iJniversit.v of California, Irvine, CnliJbmia, U.S.A. Abstract: Analyses of patterns of cell enlargement of regenerates of Ple[~n~sporilint s~tu~rr~~~~)sut~~ (Harvey) Abbott grown under light periods of 16L-8D and SL-16D and light intensities of 269, 538, 1076, and 1614 lux have been made. These show that light intensity, and to a mnch greater degree, light period significantly affect the magnitude of cell elongation for main axes and tirstorder IateraI axes; for main axes, such was primarily by an increase in size of the basipetal parts 01 ceils.
INTRODUCTION
In order to understand the morphological variation of a florideophycean taxon, one must know something concerning the effects of diverse ecological conditions on growth. The form of an algal thalius is determined by the interaction of three processes, namely; cell division, cell enlargement, and cell differentiation, and the effect of environmental conditions on the form of Florideophyceae may be best determined by analyses of the responses of these processes. The general principles of thallus development have been outlined by Dixon (1958, 1960,1963a, b, 1966, 1970,197l) and it has been shown that in the Florideophyceae, particularly the simple uniseriate Ceramiaceae, cell division and cell enlargement exert by far the greatest influence on thallus form. Relatively little is known of the rates of division of apical cells of Florideophyceae under different environmental conditions; however, it appears that apical cells of primary axes undergo l-3 divisions per day (Konrad-Hawkins, 1964a, b; Dixon & Richardson, 1970; Duffield, Waaland & Cleland, 1972; Waaland & Cleland, 1972; Murray & Dixon, 1973) and that the rate of division in certain taxa is influenced by light (Dixon & Richardson, 1970; Murray & Dixon, 1973). The relation of cell enlargement to the development of thallus 165
STEVEN N. MURRAY
166
form has been discussed based largely
by Dixon
on field data,
complex
patterns
Analyses
of cell elongation
patterns
PETER S. DIXON
(1971) for several florideophycean
has treated
of enlargement
AND
in detail
and has provided
the magnitude,
taxa; this work, orientation,
a basis for experimental
under different laboratory
illumination
and study.
treatments
have been given for GrifJithsia pacijica (Waaland & Cleland, 1972). Murray & Dixon (1973) have already determined the effects of illumination on the rates of division of apical cells of main axes of Pleonosporium squarrulosum (Harvey) Abbott. The present contribution represents a sequel to that study and is concerned with the effects of light period and light intensity on cell enlargement.
MATERIALS AND METHODS
Regenerates of P. squarrulosum were grown under experimental light-dark periods of 16 h light-8 h dark (16L-SD) and 8 h light-l 6 h dark (8L-16D) for 2 1 consecutive 24-h days. Light intensities of 269, 538, 1076, and 1614 lux were used at each lightperiod treatment. At the end of experiments, the regenerates were fixed in 3-4 “<, formaldehyde-sea water, made into semi-permanent glycerine-jelly preparations, and analysed with respect to the enlargement of cells of main and first-order lateral axes. Seven to twelve replicates were analysed for each experimental treatment. (See Murray & Dixon, 1973, for details.) Although the enlargement of axial cells of P. squarrufosum is three-dimensional, by far the greatest degree of enlargement is consistently in overall cell length, and so this measure was chosen for comparing the effects of experimental treatments on the enlargement of axial cells. Cell lengths were obtained for each axial cell as the distance between its pit connections with immediately acropetal and basipetal cells; patterns of cell enlargement were then determined for experimental plants by plotting cell length against segment number. Plots were made for both main and lateral axes of the plants. In order to carry out a statistical analysis for all except regenerates grown under 269 lux, the lengths of the 30&h, 40th, and 50th cells from the apex of the main axis were pooled for regenerates receiving a similar experimental treatment. These data were then analysed
by analyses
of variance
for cases with disproportionate
subclass size (see, Steel & Torrie, 1960). For regenerates grown under 269 lux illumination, replicates were too few or growth was insufficient for statistical treatment of the data. Intracellular patterns of the enlargement of cells of the main axes were also compared between regenerates grown under different experimental treatments. Measurements of individual axial cells were recorded in terms of basipetal and acropetal components. Basipetal components were measured from the pit connection for,med by each axial cell during the production of its single lateral initial (cf., Murray & Dixon, 1973) and its basipetally-orientated pit connection with the axial cell immediately below. Similarly, acropetal components were determined by measuring from the point of lateral initiation to the acropetally-orientated pit connection. The effects of light intensity
THALLUS
FORM
IN A RED
ALGA
167
and light period on patterns of intracellular enlargement were tested by the same statistical technique after pooling basipetal/acropetal enlargement ratios for the 30th. 40&h, and 50th cells from the apex for regenerates receiving common experimental treatments; results from regenerates receiving 269 lux illumination treatments were again not analysed. I 300 8L-160
16L-8D
t
ioow
200
t
300 -
I076 Ix
200
-
100 1614 Ix Apex IO
20
30
40
50 SEGMENT
Apex to
20
30
40
50
NUMBER
regenerates of Pleonosporium grown under experimental light treatments: A, B, C, D = 8L-16D; E, F, G, H -= 16L-SD; A, E = 269 lux; B, F = 538 lux; C, G = 1076 lux; D, H = 1614 lux.
Fig. 1. The
syuarrdosum
patterns of main axis cell elongation for representative
STEVEN
168
N. MURRAY
AND
PETER
S. DIXON
RESULTS AND DISCUSSION
The pattern of thallus development in many Florideophyceae is highly controlled with respect to cell division and cell enlargement. As has been indicated previously (Dixon, 1971; Murray & Dixon, 1973), cells in florideophycean filaments, with only a few exceptions, are produced in a linear series by successive apical cell divisions, so that in mature thalli the relative positions of axial cells within filaments may be employed for age comparisons. MAIN
AXES
The patterns of elongation of the cells of the main axes of P. ~~~~r~~~~~~~under the experimental light treatments are given in Fig. I for representative regenerates; clearly light period affects cell elongation profiles. Additionally, comparison of the data (~5, Fig. I, Table I) for regenerates grown under 269 lux show a reduction in cell elongation for both 8L-16D and 16L-8D photoperiods. Cell elongation is interpreted to be sensitive to the low light intensity (269 lux) in much the same manner as the rates of apical cell division (Murray & Dixon, 1973); cell elongation is, however, much more clearly affected by light period. A statistical comparison such as outlined above on pooled data does not allow for differences in rates of apical cell division which would affect the ages of equivalently-positioned axial cells of different experimental plants. Differencesin the rates ofdivision ofapical cells of the main axes of experimental P. ~q~ffrr~~~~~~regenerates have been reported earher (Murray & Dixon, 1973); by far the greatest effect of light on cell division was in regenerates grown TABLE
1
Increase in length (pm) of the 30th, 40th, and 50th cells of main axes of regenerates various experimental conditions of illumination: means and 5 S.D. Illumination conditions
30th crll ______ 2
50th cell
40th cell
5.S.D.
.t‘
grown under
+S.D.
.i?
_: S.1).
269 iux* SL-I 6D 16L-8D
44 126
_ .._
SO I.56
_
II0 218
538 Iux 8L-16D l6L-SD
133 144
12 I8
I89 258
22 28
216 339
29 32
1076 lux 8L--16D 16L-8D
122 145
22 34
I88 226
29 62
263 359
28 93
1614 lux 8L-I 60 I H.-SD
130 162
I5 24
216 258
I6 38
288 410
35 57
* Data for 269 lux are taken from representative
regenerates.
THALLUS
FORM
IN
A RED
ALGA
169
500
400
I
,
T
I’ I
<’
50th CELL
f
300
200
100
-C 9 40th
i y
He’ : _I’
300
;---________F
2 x :
CELL
200
0 z W 5
100
-I
300 30th
CELL
200 _--________
__--
___a---
-3
T
3
IOk
I$14
100
5~8
LIGHT INTENSITY (LUX) Fig. 2. Enlargement of the 30th, 40th and 50th axial cells of regenerates of Pleonosporium s9uarrulosun1 grown under experimental light treatments: means and confidence limits at P = 0.05: ~~~ 8L-16D; ---16L-8D.
STEVEN
170
N.
MURRAY
AND
under 269 lux and this could not be included ages of axial cells for experimental cell division do not result
data of Murray
material
(1973) discussed
different
S. DIXON
in the present analysis.
P. squarrulosum
& Dixon
in interpretations
PETER
from those
Estimates
may be obtained
of the
from the
earlier. These data, however, given
here and really
do not
represent a significant improvement in methodology because the ages of cells can still not be precisely set. The true ages of cells can only be determined by constant daily monitoring (see, Waaland & Cleland, 1972) or by marking techniques (see, Waaland, Waaland & Cleland, 1972). Such techniques are far more precise but since quantitative data on the effects of environmental factors on cell enlargement are almost totally lacking for Florideophyceae, our results represent a useful starting point for further investigations. The magnitudes of enlargement of the 30th, 40ih, and 50th axial cells of these regenerates grown under experimental illumination conditions are given in Table I and Fig. 2. Analysis of variance (Table II) indicates that light intensity did not affect cell elongation at the 30th cell level (P > 0.05) but became a significant factor at the level ofthe40th (0.05 > P > 0.01) and 50&h(0.01 > P >O.OOl ) cells. Light period was found to significantly (P < 0.001 ) affect cell elongation in comparisons of all levels and it represented by far the most important effect: elongation differences became more pronounced as cells aged (Table II, Fig. 2). Since for the experimental treatments used the effect of light intensity appeared to be minimal for regenerates receiving > 269 lux, the data for these light intensity treatments TABLE
II
Analysis of variance of cell elongation at the 30th. 40th, and 50th cell levels for regenerates of Pleonosporiun~ syuarrulosum grown under experimental conditions of illumination greater than 269 lux: method for disproportionate subclass numbers (Steel & Torrie, 1960): *** P 0.001, ** 0.01 > P > 0.001,* 0.05 3. P 0.01.n.s. P _'0.05. Source of variation
D.f.
Sum of squares
Mean square
30th cell Light period Light intensity Interaction Error
2 2 46
6408 1357 I092 21421
6408 679 546 466
40th cell Light period Light intensity Interaction Error
1 2 2 48
321.52 7983 2425 57565
32152 3991 1212 II99
I 2
150535 39497 I840 115421
150535 19748 920 2815
50th cell Light period Light intensity Interaction Error
L
41
F
13.76***
I .46 n.s. 1.17 n.s.
26.78*** 3.33* 1.01 11.5.
53.47*** 7.01** 0.33 n.s.
THALLUS
FORM
IN A RED
were pooled for each cell ‘age’ and regression treatments
lines calculated
(Fig. 3). There is a greater rate of increase
ates grown under longer 9 = - 173.12+ lO.74Xfor
Ill
ALGA
for the two light-period
in cell size with ageforregener-
(I 6L-8D) illumination. The regression equations 16L-8D and 9 = -60.77+6.36Xfor 8L-16D.whers
the length of axial cells and X the axial segment
are: ?is
number.
16L-80
8L- 16D
1
i 30 SEGMENI-
Fig. 3. Regression and
16L-RD
C----)
lines for regenerates light periods:
I
I
40
50
NUMBER
of Pkonosporirmr
means of pooled
sqmrrulosrotr grown under 8L-16D
light intensity
data
(538,
1076,
1614
(
)
ILIX) Or
each cell ‘age‘.
The significant effects of light period and light intensity on cell e~ongatj~~n in P~~o~us~?~r~u~ ~~~~~~~~~~z/~ contrast with results of D&field, Waaland & Cleland ( 1972) and Waaland & Cleland (1972) for Gri’thsia pacijicn where 300 ft-c ( % 3230 lux) and 4Oft-c (Z 4301~~) and 16L-8D, 12L-12D and SL-16D light periods did not markedly affect the rate of cell elongation. A developmental effect of light intensity on “shoot” cells was also found; under higher light intensities (300 ft-c) these cells became predominantly nodal i.e., they produced lateral branch initials. In Pleonospnrim squarrulosum, each axial shoot cell gives rise to a single lateral branch and so there is no differential development from which the effects of primary lateral production would become apparent. A greater production of 3rd order laterals was, however. apparent for most regenerates receiving the longer light period. Dixon (1971) has given evidence for the effect of a lateral filament on cell enlargement within the parent filament for Florideophyceae such as Gr~~t~~s~~pac(fica where each segment cell does
172
STEVEN
not have the same branching
N.
MURRAY
AND
characteristics;
PETER
analysis
S. DIXON
of the effects of environmental
parameters on cell elongation in the main axes of G. pacijica could be complicated the additional variable of differential branching of shoot cells. LATERAL
Analysis
by
AXES
of enlargement
of cells of first order laterals
(Fig. 4) show comparable
patterns to those described above for main axes. Elongation was uniformly less pronounced under the 8L-16D light period as compared with 16L-8D. Jn addition, reduction in cell size is apparent when comparisons are made between regenerates
150 1 16L_
269 Ix
-
-’
1
1
x
a
k 150 E P- 100i
SEGMENT
NUMBER
Fig. 4. The patterns of first-order lateral axis cell elongation for representative regenerates of Pleonosporium squarrulosum grown under experimental light treatments: A, B, C, D : SL-16D: E, F, G, H = 16L-SD; A, E = 269 lux; B, F : 538 lux; C, G = 1076 lux; D, H 7 1614 lux.
THALLUS
receiving
FORM
IN
A RED
173
ALGA
269 lux and those grown under higher light intensities;
variations
in enlarge-
ment profiles as a function among regenerates receiving
of light intensity were minimal for each light period light intensities greater than 269 lux.
PATTERNS
ELONGATION
Analysis
OF INTRACELLULAR
of intracellular
elongation
patterns
for a number
of Florideophyceae.
as indicated by using pit connections formed between parent axial cells and their pericentral-cell derivatives, have shown asymmetric patterns of intracellular growth (Dixon, 1971). In such thalli, pericentral cells are formed when axial cells are young and in a position just a few cells removed from their apical cell origin. At the time of pericentral cell formation, the pit connection is positioned approximately midway along the length of the parent axial cell, so that differential patterns of intracellular elongation with cell age may be determined by treating separately the elonpaSEGMENT
NO
LENGTH
./,, :. P
;.
j ,.
: j
: i
Total cell
,:’
39
106
259
IN MICRONS
Acropetol
17
Basipetal
22
29
77
36
223
100 urn
Fig. 5. The
intracellular
pattern
of elongation
of main
axis cells of Pleonosporium
syuarrulosurn.
174
STEVEN
N.
MURRAY
AND
PETER
S. DIXON
TABLE 111 Ratio
of basipetal/acropetal grown under
for the 30th, 40th, and 50th cells of main axes of regenerates conditions of illumination; means and LS.D. 40th cell
30th cell
Illumination conditions 269
elongation experimental
F
_AS.D.
.i
SOth cell S.D.
.r
S.,).
lux* 2.0 3.3
SL--lbD l6L-8D
2.6 3.1
3.5 3 .:
5.38 lux 8L -16D 16L-8D 1076
0.5 0.7
3.4 4.9
0.5 0.6
3.9 4.5
0.5 0 .6
3.0 ?.I
0.4 0.6
3.6 4.2
0.5 0.6
3.7 4.6
0.5 0.5
3.0 3.5
0.5 0.7
3.9 4.3
0.6 0.6
4. I 4.x
0.5
lux
XL-16D 16l..-8D I614
3.1 3.5
lux
XL-l6D l6L-8D * Data
for 269 Iux are taken
from
representative
0.x
plants
Analysis of variance of basipetalKacropetal elongation ratios at the 30th, 40th, and 50th cell levels for regenerates of Pleonosporiu~r~ sqrrarrrrlmrm grown under experimental conditions of illumination greater than 269 Iux: method for disproportionate subclass numbers (Steel & Torric. 1960): ratios have been inverted and transformed to arcsine values in order to stabilirc the variance\. *** p 0.05. 0.001, ** 0.01 -. P ’ 0.001, * 0.05 ’ P 0.01, 1l.S. P Source ot variation
D.f
Sum oi squares
Mean square
30th cell Light period Light intensity Interaction Error
2 2
46
49. IO 18.96 17.84 593.15
49. IO 9.48 8.92 12.89
3.81
1.b.
0.74 n.5. 0.69 I1.S.
40th cell Light period Light intensity Interaction Error
145.56 14.31 24.04 5.71
25.49*** 2.51 n.5.
2 48
145.56 28.61 48.07 274. I9
2 2 41
90.79 14.01 7.09 188.59
90.79 7.01 3.55 4.60
19.74*** I .52 n.s. 0.77 n.s.
2
3.21*
50th cell Light period Light intensity Interaction Error
THALLUS
tion
of cell portions
acropetal
‘marker’.
The great majority
basipetal
intracellular
Pleonosporizrm
manifested
IN
A RED
and basipetal
to the pericentral
of Florideophyceae
elongation
as axial
I7
ALGA
show a marked
cells mature
(Dixon,
cell pit-connection predominance 1971,
1973).
of For
squarrulosum,
basipetally
were determined
FORM
the elongation of axial cells with age is also large11 (Fig. 5). Basipetal/acropetal ratios of intracellular elongation
(Table
III) for the 30th, 40th, and 50th axial cells of regenerates
subjected to experimental transformation to arcsin-
light treatments. Analyses of variance of the data after ’ values for all plants receiving > 269 lux were made to test whether the previously observed effects of light on the magnitude of axial cell elongation affected the established basipetal to acropetal growth pattern; these analyses (Table IV) indicate that the longer I6 h light period significantly increz\ed the relative basipetal elongation; the effects of light period on cell elongation art‘. therefore, primarily manifested in an increased rate of basipetal elongation.
ACKNOWLEDGEMFNTS
Partial assistance for this work was gained from a California State University. Fullerton, Faculty Research stipend (SNM). We are grateful to Kathryn Heath for preparation of the illustrations.
REFERENCES DIXON, I’. S., 1958. The morpholcgy, ecology and taxonomy of certain Florideae. Bv. $?~.ujI. Buli.. Vol. I, pp. 32-33. DIXON, P. S., 1960. Studies on marine algae of the British Isles: Crrtr,uirorr sll//rrlel~o~!/fi~i,rul,r (Kutr.) Silva. J. MT. hiol. Ass. U.K., Vol. 39, pp. 375-390. DIXON, P. S., 1963a. The Rhodophyta: some aspects of their hiologq. Ocrtrno
176
STEVEN N. MURRAY
AND
PETER S. DIXON
MURRAY, S. N. & P. S. DIXON, 1973. The effect of light intensity and light period on the development of thallus form in the marine red alga Pleonosporium squnrrulosurn (Harvey) Abbott (Rhodophyta: Ceramiales). 1. Apical cell division main axes. J. exp. mar. Biol. Ecol., Vol. 13, pp. 15-27. STEEL, R. C. D. & J. H. TORRIE, 1960. Principles and procedures qfstatistics. McGraw-Hill Book Co. Inc., New York, 481 pp. WAALAND, S. D. & R. CLELAND, 1972. Development in the red alga Grififh’rhsicr ptrcificcr. Control by internal and external factors. Planta, Vol. 105, pp. 196-204. WAALAND, S. D., J. R. WAALAND & R. CLELAND, 1972. A new pattern of plant cell elongation: bipolar band growth. J. Cell Biol., Vol. 172, pp. 184-190.