GROWTH-CONTROLLED OSCILLATION IN ACTIVITY OF HISTONE H1 KINASE DURING THE CELL CYCLE OF CHLAMYDOMONAS REINHARDTII (CHLOROPHYTA)1

Synchronous cultures of the cell wall-less mutant Chlamydomonas reinhardtii Dangeard cw 15 were grown under different mean irradiances and different illumination regimes, which produced cell cycles that differed in the number of daughter cells released from one mother cell, in the length of the cell cycle, and in the growth rate. During the cell cycle, the cells reached several commitment points whose number and timing differed according to the particular pattern of the cell cycle. The cell volume was used as a growth parameter and increased in a stepwise manner. Each of the steps consisted of periods of both fast and slow growth. Growth usually stopped when the cells attained a volume twice that of the preceding step. Reaching particular commitment points was coupled with the position of these points in the enlargement of cell volume. Changes in the activity of histone H1 kinase were noted during the cell cycles of all experimental variants, and the activities were compared with the timing of various commitment points. It was found that kinase activity varied markedly within a single cell cycle, attaining maximal values when the cellular volume had doubled. Each peak in kinase activity slightly preceded the commitment to an individual sequence of reproductive events. In addition to the oscillations related to cell growth, a peak of kinase activity always occurred toward the end of the cell cycle when multiple rounds of DNA replication, mitosis, and cell division occurred.     

REGULATION OF GROWTH PROCESSES DURING THE CELL CYCLE OF THE CHLOROCOCCAL ALGA SCENEDESMUS QUADRICAUDA UNDER A DNA REPLICATION BLOCK

The kinetics of two growth parameters (total RNA and total protein accumulation) was followed in synchronized cultures of the chlorococcal alga Scenedesmus quadricauda ( Turp.) Bréb. under conditions of inhibited DNA replication in the presence of 5-fluorodeoxyuridine (25 mg.L^-1). In the control culture, growth processes occurred in several steps with a decreasing rate of accumulation of RNA and protein amount approximately at each doubled value of the preceding step. Oscillations in the rate of growth processes in the control culture were temporally related to the initiation of individual reproductive steps. At each doubling, the cell became committed to triggering a sequence of reproductive processes, starting with DNA replication and ending with protoplast fission. Three commitment points were attained in the control culture and, consequently, three replication rounds of DNA followed by three nuclear divisions and three protoplast fissions occurred during one cell cycle. If 5-fluorodeoxyuridine (FdUrd) was added at the beginning of the cell cycle, no reproductive processes occurred, and the cells remained uninuclear with one genome and did not divide. RNA accumulation did not seem to be affected by the presence of FdUrd for at least one cell cycle, and three or four doublings in the amount of RNA occurred during this period. Protein accumulation was even more independent of reproductive processes in the cell and continued for a period of about two or three cell cycles, attaining six doublings at the end of this period. Therefore, oscillations in the rate of protein or RNA accumulation remained even if reproductive processes were inhibited .     

Variety of cell cycle patterns in the alga Scenedesmus quadricauda (Chlorophyta) as revealed by application of illumination regimes and inhibitors

In the course of the cell cycles of synchronous cultures of the chlorococcal alga Scenedesmus quadricauda, the following were monitored: total protein and RNA accumulation as a measure of growth processes, the timing of the commitment points at which the cells trigger the sequence of reproductive processes (DNA replication, nuclear and cellular division) and the course of the reproductive processes. The synchronous cultures were grown either under various lighting regimes, or in the temporary presence of specific inhibitors of either proteosynthesis (cycloheximide) or DNA replication (5-fluorodeoxyuridine). By adjusting the length of the light period, the cell cycle could be manipulated. Cell cycle patterns could be altered to give different numbers of sequences of reproductive processes. The extent of their mutual overlap could be influenced and the number of daughter cells produced could be altered. Schematic illustrations of various cell cycle patterns and comparisons with those of higher plants and other algal species are presented.     

Cell growth and division processes are differentially sensitive to cadmium in<Emphasis Type="Italic">Scenedesmus quadricauda</Emphasis>

The effect of cadmium on growth processes (accumulation of RNA, proteins and cell volume), cell cycle reproductive events (DNA replication, mitosis, protoplast fission and daughter-cell formation) and the regulatory activity of histone H1 kinases were monitored in synchronized cultures of the chlorococcal alga Scenedesmus quadricauda. Distinct dosage-dependent inhibitory effects of cadmium ions were found in individual growth and reproductive processes. At concentration of about 60 mumol/L CdCl2, the growth processes were slowed down after about half of the cell cycle but the cells grew to the same or larger size than did untreated cells. At higher concentration, the growth became progressively inhibited, being completely blocked above 240 mumol/L. Total RNA accumulation was the most sensitive growth process. Each of the reproductive events was a target for cadmium ions with increasing sensitivity in the following order: DNA replication, mitosis, protoplast fission and daughter cell formation. Throughout the entire experiment, the activity of "mitosis-specific" histone H1 kinases was negligible in the cadmium (60 mumol/L CdCl2) treated cultures, whilst that of the control culture varied, peaking just prior to nuclear divisions. The activity of "growth-associated" histone H1 kinases was not affected by cadmium ions. No effect was found if cadmium was present during the precommitment period. The longer the period in the presence of cadmium, the stronger inhibition of reproductive events.     

Uncoupling of chloroplast reproductive events from cell cycle division processes by 5-fluorodeoxyuridine in the algaScenedesmus quadricauda

Summary FdUrd (5-fluorodeoxyuridine), a specific inhibitor of thymidylate synthase, was used to study the relationship between reproductive processes in chloroplast and nucleocytoplasmic compartments of the chlorococcal algaScenedesmus quadricauda. The courses of DNA replication and nuclear division in both the compartments were followed in populations synchronised by the alternation of light and dark periods. DAPI-staining of DNA-containing structures was used for their visualisation and quantification. In contrast with cellular reproductive events, those in chloroplasts were not substantially affected by the presence of FdUrd (25 g/ml). It was shown that FdUrd specifically blocked nucDNA replication but not ptDNA replication. Thus, cells which had attained commitment to ptDNA replication, fission of pt-nuclei and chloroplast kinesis triggered and terminated these processes while the corresponding cellular processes were blocked. The courses of reproductive processes in chloroplasts were also substantially unaffected in cells grown in the presence of FdUrd for the whole cell cycle. This provided evidence that attainment of commitment to and termination of the entire sequence of reproductive events, including chloroplast fission, were controlled by different mechanisms than the reproductive processes in the nucleocytoplasmic compartment.Abbreviations DAPI 4,6-diamidino-2-phenylindole - ptDNA DNA of chloroplast nuclei - nucDNA DNA in cell nuclei - FdUrd 5-fluorodeoxyuridine     

Effect of irradiance on the course of RNA synthesis in the cell cycle ofScenedesmus quadricauda

In synchronous populations ofScenedesmus quadricauda the RNA amount in the cells increases in waves: periods of a high rate of RNA synthesis alternate with periods of a low rate in the course of the cell cycle. Each wave usually leads to the doubling of the RNA amount per cell. In cells growing under normal conditions the waves of RNA synthesis seem to be linked with consecutive rounds of DNA replication. The pattern of RNA synthesis in the course of the cell cycle, however, does not change, if DNA replication is prevented by application of 5-fluoro-deoxyuridine. In darkness the rate of RNA synthesis drops to zero and thereafter the RNA amount per cell decreases. In cells which have been induced to cellular division RNA synthesis may become restored in the dark in newly formed daughter cells. The lowering of RNA amount and its new increase during the dark period become more pronounced with increasing irradiance in the previous light period as well as with its increasing length. In the period of protoplast fissions RNA synthesis is arrested even if the cells divide in the light; whether a similar inhibition occurs during mitoses is not clear.     

Microtubule organization in the apical cell of Sphacelaria (Phaeophyceae) and its related protoplast

The growth of the filamentous brown alga Sphacelaria depends on a large, strongly polarized, apical cell. The protoplast derived from this cell can be distinguished in a heterogeneous suspension by cytological markers, so it is possible to study development of the cytoskeleton during protoplast isolation and the first steps of regeneration. In the initial cell, microtubules show an asymmetric distribution along the axis; they are mainly located at the distal part around the physodes. After protoplast isolation, this polarity initially seems to be maintained; subsequently, the microtubules radiate from the two centrioles and spread out to the plasmalemma. This experimental model is suitable for investigating the development of the polarity of the initial cell, and the sequence of the first morphogenetic events leading to protoplast regeneration.     

Blue light delays commitment to cell division in Chlamydomonas reinhardtii

In this study, we describe the effect of red and blue light on the timing of commitment to cell division in Chlamydomonas reinhardtii. The time point and cell size after which cells can complete their cell cycle with one division round were determined for cultures that were exposed to various red and blue light periods. We show that the commitment point of cells grown in blue light is shifted to a later time point and a larger cell size, when compared with cells grown in red light. This shift was reduced when cultures were exposed to shorter blue light periods. Furthermore, this shift occurred only when exposure to blue light started before the cells attained a particular size. We conclude that the critical cell size for cell division, which is the cell size at which commitment to cell division is attained, is dependent on spectral composition.     

Effect of Growth Rate on the Macromolecular Composition of Prototheca zopfii, a Colorless Alga Which Divides by Multiple Fission

Prototheca zopfii, a eukaryote that divides by multiple fission, was investigated to determine how growth rate controls daughter cell number. The macromolecular composition, cell size, and number of nuclei per cell were determined in cultures during balanced growth in various media. Cellular mass, ribonucleic acid (RNA), deoxyribonucleic acid (DNA), carbohydrate, and nuclear number increased as positive linear functions of growth rate, whereas nuclear ploidy remained constant with a value of 0.098 pg of DNA/nucleus. The ratios of RNA to protein, protein to mass, and carbohydrate to mass were unaffected by growth rate, whereas the ratios of DNA to protein and RNA to DNA could be expressed as curvilinear functions of growth rate, the former negative and the latter positive. The dependency of normalized gene dosage (DNA/protein) on growth rate appeared as a distinguishing feature of multiple fission. Determination of the normalized rates of protein and RNA synthesis revealed that both increase linearly with growth rate. It is concluded that Prototheca zopfii may exist in a number of physiological states which are characterized by a unique size and macromolecular composition and which are dictated by growth rate.     

ADAPTATION OF CERATIUM FURCA AND GONYAULAX POLYEDRA (DINOPHYCEACE) TO DIFFERENT TEMPERATURES AND IRRADIANCES: GROWTH RATES AND CELL VOLUMES1

Growth rates and cell volumes of Ceratium furca Ehrenberg and Gonyaulax polyedra Stein were determined during the log phase of growth in cultures which had been extensively adapted to one of three temperatures and five irradiances. At each temperature, curves for the growth rate vs. irradiance for both species had light-limited and light-saturated regions. Three properties of these curves characterized the response of each species to temperature: the light-saturated growth rate, the irradiance at which growth became light-saturated and the compensation irradiance for growth. For both species, the first two properties generally decreased with declining growth temperature, while the compensation irradiance declined for Ceratium but had a V-shaped response pattern for Gonyaulax. The light-saturated growth rates were generally higher for Ceratium than for Gonyaulax, while the irradiance at which growth became saturated and the compensation irradiance were lower for Ceratium. The changes in cell volume associated with the irradiance and temperature of growth were very different for Ceratium and Gonyaulax. The cell size of Gonyaulax increased as irradiance and temperature decreased, while cell volumes of Ceratium did not change with temperature but were smallest at the highest and lowest growth irradiances. In general, the growth rate patterns were similar for Ceratium and Gonyaulax, while those for cell size were different. The maximum growth rate, the irradiance at which growth became saturated, the compensation irradiance, and the cell volume all showed that Ceratium grew at the same rate or faster than Gonyaulax over the entire range of irradiances and temperatures examined.     

The Demography of Colony Fission from 1878–1970 Among the Hutterites of North America

Periodic colony fision has been characteristic ofHutterite society for more than 100 years. From 1878–1970 fission occurred an average of every 14–15 years when colonies attained a size of 166 persons. Emigrating groups were comprised of35%–55% of the mother colony's population. Between founding and fission, daughter populations grew at an average rate of 4.3% per year. Over time, fissioning size and length of fission cycles decreased, but the size of new daughter colonies and rate of population growth remained constant through 1960. Demographic analysis suggested that the model of fission followed by the Hutterites has not always focused on even division of the mother colony into two equal-sized groups, but rather that they have had a fairly constant conceptual model of the size that new colonies should be. As fissioning size decreased over time the proportionate size of new colonies increased, maintaining the absolute size nearly constant since 1900. These findings suggest a number of questions for further investigation.     

Fission yeast cells grow approximately exponentially

How the rate of cell growth is influenced by cell size is a fundamental question of cell biology. The simple model that cell growth is proportional to cell size, based on the proposition that larger cells have proportionally greater synthetic capacity than smaller cells, leads to the prediction that the rate of cell growth increases exponentially with cell size. However, other modes of cell growth, including bilinear growth, have been reported. The distinction between exponential and bilinear growth has been explored in particular detail in the fission yeast Schizosaccharomyces pombe. We have revisited the mode of fission yeast cell growth using high-resolution time-lapse microscopy and find, as previously reported, that these two growth models are difficult to distinguish both because of the similarity in shapes between exponential and bilinear curves over the two-fold change in length of a normal cell cycle and because of the substantial biological and experimental noise inherent to these experiments. Therefore, we contrived to have cells grow more than twofold, by holding them in G2 for up to 8 h. Over this extended growth period, in which cells grow up to 5.5-fold, the two growth models diverge to the point that we can confidently exclude bilinear growth as a general model for fission yeast growth. Although the growth we observe is clearly more complicated than predicted by simple exponential growth, we find that exponential growth is a robust approximation of fission yeast growth, both during an unperturbed cell cycle and during extended periods of growth.     

DAYLENGTH AND LIGHT RESPONSES IN GROWTH AND FERTILITY OF GLOSSOPHORA KUNTHII (PHAEOPHYTA,DICTYOTALES) FROM PACIFIC SOUTH AMERICA1

Excised ligulae of Glossophora kunthii (C. Ag.) J. Ag. were cultured in photoperiods of 4–24 h and photon fluence rates of 10–75 μmol.m^?2.s^?1. Daylength interacted with irradiance on the growth of the ligulae. Maximal growth of primary ligulae occurred in long-day regimens with high irradiances suggesting an effect of irradiance on photosynthesis and growth. In contrast, growth of secondary ligulae was greatest in short-day regimes. Differences were significant at the highest irradiance tested. Differentiation of tetrasporangia on the ligulae is a short-day photoperiodic response. Daylengths of 8.5 h or less induced a sharp increase in numbers of fertile ligulae and tetrasporangia attaining maturity. Interruptions of the dark period decreased the development of tetrasporangia; the number of interruptions had a cumulative inhibitory effect. Differentiation of reproductive structures was influenced by interactions of photoperiod and irradiance. Maximum numbers of tetrasporangia were formed at short-day regimes and low irradiances; differentiation was completely inhibited at long-day conditions and high irradiance.     

Effect of assimilate supply on the growth of individual cucumber fruits

The effects of assimilate supply on the growth of individual fruits during different stages of fruit development were analysed in cucumber ( Cucumis sativus L. cv. Corona). The assimilate supply was varied by maintaining different numbers of fruits per plant or maintaining different irradiances. The growth rate of a cucumber fruit strongly increased with increasing assimilate supply, but its growing period was not noticeably affected. At a low assimilate supply both cell number and cell size were reduced. Increasing the assimilate supply at different stages of fruit development showed that the early development of a cucumber fruit was not crucial for setting its growth potential. A small number of cells, due to a low assimilate supply, during early fruit development, was to a great extent compensated by an increased expansion rate of individual cells. It is concluded that cell number is not an important determinant of fruit size in cucumber, although fruit size is often positively correlated with cell number. In the early stages of fruit development the effect of irradiance on the fruit growth rate depends on the presence of an earlier developed fruit because of dom-inance between fruits. In later stages of fruit development, a decrease in irradiance reduced the growth rate of all fruits relatively to the same extent independent of age or presence of other fruits.     

Response of Tradescantia albiflora to growth irradiance: Change versus changeability

Most chloroplasts undergo changes in composition, function and structure in response to growth irradiance. However, Tradescantia albiflora, a facultative shade plant, is unable to modulate its light-harvesting components and has the same Chl a/Chl b ratios and number of functional PS II and PS I reaction centres on a Chl basis at all growth irradiances. With increasing growth irradiance, Tradescantia leaves have the same relative amount of chlorophyll—proteins of PS II and PS I, but increased xanthophyll cycle components and more zeaxanthin formation under high light. Despite high-light leaves having enhanced xanthophyll cycle content, all Tradescantia leaves acclimated to varying growth irradiances have similar non-photochemical quenching. These data strongly suggest that not all of the zeaxanthin formed under high light is necessarily non-covalently bound to major and minor light-harvesting proteins of both photosystems, but free zeaxanthin may be associated with LHC II and LHC I or located in the lipid bilayer. Under the unusual circumstances in light-acclimated Tradescantia where the numbers of functional PS II and PS I reaction centres and their antenna size are unaltered during growth under different irradiances, the extents of PS II photoinactivation by high irradiances are comparable. This is due to the extent of PS II photoinactivation being a light dosage effect that depends on the input (photon exposure, antenna size) and output (photosynthetic capacity, non-radiative dissipation) parameters, which in Tradescantia are not greatly varied by changes in growth irradiance.This revised version was published online in October 2005 with corrections to the Cover Date.     

Lipid droplet de novo formation and fission are linked to the cell cycle in fission yeast

Cells sequester neutral lipids in bodies called lipid droplets. Thus, the formation and breakdown of the droplets are important for cellular metabolism; unfortunately, these processes are difficult to quantify. Here, we used time-lapse confocal microscopy to track the formation, movement and size changes of lipid droplets throughout the cell cycle in fission yeast Schizosaccharomyces pombe. In theory, the number of lipid droplets in these cells must increase for daughter cells to have the same number of droplets as the parent at a reference point in the cell cycle. We observed stable droplet formation events in G2 phase that were divided evenly between de novo formation of nascent droplets and fission of preexisting droplets. The observations that lipid droplet number is linked to the cell cycle and that droplets can form via fission were both new discoveries. Thus, we scrutinized each fission event for multiple signatures to eliminate possible artifacts from our microscopy. We augmented our time-lapse confocal microscopy with electron microscopy, which showed lipid droplet 'intermediates': droplets shaped like dumbbells that are potentially in transition states between two spherical droplets. Using these complementary microscopy techniques and also dynamic simulations, we show that lipid droplets can form by fission.     

The Effect of Light on the Structure and Organization of Lemna Peroxisomes

The effect of light on a number of Lemna minor enzyme activitieswas investigated. The levels of activity of glycolate oxidase,catalase and RuBPCase increased with increasing irradiance,paralleling the increase in Lemna growth rate. In contrast withresults obtained for other species, no glycolate oxidase activitycould be detected in etiolated Lemna fronds or when these weretreated with light or glycolate, in vivo or in vitro, for upto 24 h. The number of peroxisome profiles per cell section was determinedin Lemna grown under different light conditions. When frondswere grown under dim light, the number of peroxisome profilesper cell section appeared to increase with increasing irradiance,although no further increase in the peroxisome number was apparentwhen the fronds were grown under higher irradiances. The levelof glycolate oxidase activity per peroxisome was shown to increasewith increasing irradiance, whereas that of catalase remainedrelatively constant, indicating that differential addition ofenzymes to pre-existing peroxisomes is possible. Peroxisomes from Lemna grown under high irradiance were subjectedto serial sectioning and examined under the electron microscope.Some peroxisomes were found to have a three dimensional structuresuggesting either fission and/or fusion or branching of theseorganelles, supporting the hypothesis of a peroxisomal reticulum.The dynamic relationship between the various shapes is discussed. Key words: Peroxisomes, glycolate oxidase, catalase     

Points of commitment to reproductive events as a tool for analysis of the cell cycle in synchronous cultures of algae

Methods for determining the points of commitment for cell division are described for species of green algae dividing by multiple fission, both forming coenobia (Scenedesmus quadricauda) and releasing single daughter cells (Chlamydomonas eugametos, Scenedesmus armatus). The timing of commitment points was followed in detail in synchronous cultures of S. quadricauda grown under various light intensities, illumination regimes, and temperatures. The pre-commitment periods were rate limiting, while the post-commitment periods remained more or less constant under various light intensity. Temperature, on the other hand, affected both periods in a similar manner and they were prolonged with decreasing temperature.     

Macromolecular syntheses and the course of cell cycle events in the chlorococcal algascenedesmus quadricauda under nutrient starvation: Effect of sulphur starvation

Daughter cells of the chlorococcal algaScenedesmus quadricauda were incubated under photosynthesizing conditions in a sulphur-free medium. The course of the cell cycle under these conditions was changed in daughter cells which differed in their stage of development. In absence of sulphur, advanced daughter cells with two nuclei and 2 or 4 genomes passed a cycle identical with that of control in sulphur containing medium. Each cell yielded eight binuclear daughter cells. With less advanced daughter cells (one nucleus and 1 or 2 genomes) restriction of RNA synthesis occurred near to the end of the cell cycle and protein synthesis ceased two hours later (practically at the time of the protoplast fission). The last round of DNA replication found in the control culture was not initiated in sulphur-starved culture and uninuclear daughter cells with one genome were released. If the daughter cells coming from the starved populations were kept further in the sulphur-free medium, macromolecular syntheses were dramatically restricted. Only photosynthesis continued to produce starch at a similar rate as in normally grown cells. Thus, a very large amount of starch accumulated. Supported by these reserves, starved cells refed with sulphur passed an entire cell cycle in the dark and divided into eight daughter cells. In sulphur-supplied cells, both in the dark and in light, RNA, protein and DNA synthesis started without any delay in a similar way as in the control culture. Competition for sulphur reserves occurred between the growth and division processes; the former were preferred in the light and the latter in the dark.