Candida albicans VAC8 is required for vacuolar inheritance and normal hyphal branching

Hyphal growth is prevalent during most Candida albicans infections. Current cell division models, which are based on cytological analyses of C. albicans, predict that hyphal branching is intimately linked with vacuolar inheritance in this fungus. Here we report the molecular validation of this model, showing that a specific mutation that disrupts vacuolar inheritance also affects hyphal division. The armadillo repeat-containing protein Vac8p plays an important role in vacuolar inheritance in Saccharomyces cerevisiae. The VAC8 gene was identified in the C. albicans genome sequence and was resequenced. Homozygous C. albicans vac8Delta deletion mutants were generated, and their phenotypes were examined. Mutant vac8Delta cells contained fragmented vacuoles, and minimal vacuolar material was inherited by daughter cells in hyphal or budding forms. Normal rates of growth and hyphal extension were observed for the mutant hyphae on solid serum-containing medium. However, branching frequencies were significantly increased in the mutant hyphae. These observations are consistent with a causal relationship between vacuolar inheritance and the cell division cycle in the subapical compartments of C. albicans hyphae. The data support the hypothesis that cytoplasmic volume, rather than cell size, is critical for progression through G1.     

Vascular clearance of blastospore and pseudomycelial phase Candida albicans.

Blastospore phase and pseudomycelial phase Candida albicans were infused at a constant rate into the proximal aorta of rabbits and simultaneous quantitative blood cultures were obtained from the abdominal aorta and inferior vena cava. Arteriovenous differences were greater with pseudomycelial phase C. albicans at all concentrations tested. Rates of clearance of C. albicans as blastospores or with pseudomycelia yielded mean T one-half values of 22 seconds and 17 seconds, respectively. Similarly, hepatic clearance of pseudomycelial phase C. albicans was more efficient. Prior immunization with heat-killed Candida albicans had no effect on the vascular clearance of either pseudomycelial phase or blastospore phase C. albicans.     

The G1 cyclin Cln3p controls vacuolar biogenesis in Saccharomyces cerevisiae

How organelle biogenesis and inheritance is linked to cell division is poorly understood. In the budding yeast Saccharomyces cerevisiae the G(1) cyclins Cln1,2,3p control initiation of cell division. Here we show that Cln3p controls vacuolar (lysosomal) biogenesis and segregation. First, loss of Cln3p, but not Cln1p or Cln2p, resulted in vacuolar fragmentation. Although the vacuoles of cln3delta cells were fragmented, together they occupied a large space, which accounted for a significant fraction of the overall cell size increase in cln3delta cells. Second, cytosol prepared from cells lacking Cln3p had reduced vacuolar homotypic fusion activity in cell-free assays. Third, vacuolar segregation was perturbed in cln3delta cells. Our findings reveal a novel role for a eukaryotic G(1) cyclin in cytoplasmic organelle biogenesis and segregation.     

A comparison of volume growth during bud and mycelium formation in Candida albicans: a single cell analysis

When stationary phase cells of the dimorphic yeast Candida albicans are diluted into fresh medium at pH 4.5 (low pH), they synchronously form ellipsoidal buds, but when diluted into the same medium at pH 6.7 (high pH), they synchronously form elongate mycelia. Using a perfusion chamber to monitor single cells, we have compared the rates of volume growth between budding and mycelium-forming cells. Results are presented which demonstrate that: (1) after release from stationary phase into medium of low or high pH, each original sphere grows in volume to the time of initial evagination, but does not grow subsequently; (2) successive budding on the original mother cell occurs without interruption resulting in continuous volume growth; however, an interruption in volume growth of the initial bud (B1) occurs before it in turn evaginates; and (3) the rate of volume growth of the first bud at low pH is identical to the rate of volume growth of the mycelium at high pH even though the surface to volume ratios are quite different. The last result is unexpected and is therefore considered in relation to cell wall deposition.     

Patterns of asexual reproduction in <Emphasis Type="Italic">Nannochloris bacillaris</Emphasis> and <Emphasis Type="Italic">Marvania geminata</Emphasis> (Chlorophyta,Trebouxiophyceae)

Non-flagellated vegetative green algae of the Trebouxiophyceae propagate mainly by autosporulation. In this manner, the mother cell wall is shed following division of the protoplast in each round of cell division. Binary fission type Nannochloris and budding type Marvania are also included in the Trebouxiophyceae. Phylogenetic trees based on the actin sequences of Trebouxiophyceae members revealed that the binary fission type Nannochloris bacillaris and the budding type Marvania geminata are closely related in a distal monophyletic group. Our results suggest that autosporulation is the ancestral mode of cell division in Trebouxiophyceae. To elucidate how non-autosporulative mechanisms such as binary fission and budding evolved, we focused on the cleavage of the mother cell wall. Cell wall development was analyzed using a cell wall-specific fluorescent dye, Fluostain I. Exfoliation of the mother cell wall was not observed in either N. bacillaris or M. geminata. We then compared the two algae by transmission electron microscopy with rapid freeze fixation and freeze substitution; in both algae, the mother cell wall was cleaved at the site of cell division, but remained adhered to the daughter cell wall. In N. bacillaris, the cleaved mother cell wall gradually degenerated and was not observed in the next cell cycle. In contrast, M. geminata daughter cells entered the growth phase of the next cell cycle bearing the mother and grandmother cell walls, causing the uncovered portion of the plane of division to bulge outward. Such a delay in the degeneration and shedding of the mother cell wall probably led to the development of binary fission and budding.     

The interrelationship of cell growth and division in haploid and diploid cells of Saccharomyces cerevisiae

The coordination of cell growth and division has been examined in isogenic haploid and diploid strains of Saccharomyces cerevisiae. The average cell volume of the haploid and diploid cells was unaffected by a range of environmental conditions and generation times. For most environments and generation times the mean cell volume of diploid cells was between 1.52 and 1.83 of the haploid cell volume. Both haploid and diploid cell volumes were reduced drastically when the cells were grown in the chemostat with glucose as the limiting substrate. In this environment diploid cells have the same mean cell volume as haploid cells. Diploid cells are more elongated than haploid cells, and the characteristic shape (eccentricity) of the cells is unaffected by all environmental conditions and generation times tested. Mother cell volume increased during the cell cycle, although the pattern of this increase was affected by the environmental conditions. Under most growth conditions detectable mother cell volume increase occurred only during the budding phase, whereas under conditions of carbon limitation detectable increase only occurred during the unbudded phase. A consequence of this result is that the mean cell volume of haploids at bud initiation is relatively constant in all environments, including carbon limitation. This suggests that there is a critical size for bud initiation for haploids which is constant and independent of environmental conditions. The results for diploids are more complex. Coordination of growth and division in haploid cells can be explained by a simple model initially developed for prokaryotes by Donachie. A modification of this model is proposed to account for the results with diploids.     

Simultaneous production of buds on mother and daughter cells of Saccharomyces cerevisiae in the presence of hydroxyurea

Individual budding yeast cells, Saccharomyces cerevisiae, enclosedin small culture chambers were observed through two buddingcycles to examine their behavior during growth and division.In the nutrient medium (YHG medium), the duration of the buddingcycles was 77 min for mother cells and 90 min for daughter cells;a 13-min time lag between the two durations. Continuous exposureof cells to 16 or 32 mM hydroxyurea extended the duration ofthe cycles and increased the volume of the cells, resultingin the formation of abnormally large and equal-sized mother-daughterpairs. Each cell of these pairs subsequently produced buds simultaneously.Stained cell nuclei showed simultaneous nuclear division. Thissynchronous budding on mother-daughter pairs was repeated inthe next budding cycle. The coordination of growth with divisionis discussed in relation to these results. (Received August 11, 1979; )     

Bud-Localization of CLB2 mRNA Can Constitute a Growth Rate Dependent Daughter Sizer

Maintenance of cellular size is a fundamental systems level process that requires balancing of cell growth with proliferation. This is achieved via the cell division cycle, which is driven by the sequential accumulation and destruction of cyclins. The regulatory network around these cyclins, particularly in G₁, has been interpreted as a size control network in budding yeast, and cell size as being decisive for the START transition. However, it is not clear why disruptions in the G₁ network may lead to altered size rather than loss of size control, or why the S-G₂-M duration also depends on nutrients. With a mathematical population model comprised of individually growing cells, we show that cyclin translation would suffice to explain the observed growth rate dependence of cell volume at START. Moreover, we assess the impact of the observed bud-localisation of the G₂ cyclin CLB2 mRNA, and find that localised cyclin translation could provide an efficient mechanism for measuring the biosynthetic capacity in specific compartments: The mother in G₁, and the growing bud in G₂. Hence, iteration of the same principle can ensure that the mother cell is strong enough to grow a bud, and that the bud is strong enough for independent life. Cell sizes emerge in the model, which predicts that a single CDK-cyclin pair per growth phase suffices for size control in budding yeast, despite the necessity of the cell cycle network around the cyclins to integrate other cues. Size control seems to be exerted twice, where the G₂/M control affects bud size through bud-localized translation of CLB2 mRNA, explaining the dependence of the S-G₂-M duration on nutrients. Taken together, our findings suggest that cell size is an emergent rather than a regulatory property of the network linking growth and proliferation.     

Isolation and characterization of Candida albicans morphological mutants derepressed for the formation of filamentous hypha-type structures.

Several Candida albicans morphological mutants were obtained by a procedure based on a combined treatment with nitrous acid plus UV irradiation and a double-enrichment step to increase the proportion of mutants growing as long filamentous structures. Altered cell morphogenesis in these mutants correlated with an altered colonial phenotype. Two of these mutants, C. albicans NEL102 and NEL103, were selected and characterized. Mutant blastoconidia initiated budding but eventually gave rise to filamentous hypha-type formations. These filaments were long and septate, and they branched very regularly at positions near septa. Calcofluor white (which is known to bind chitin-rich areas) stained septa, branching zones, and filament tips very intensely, as observed under the fluorescence microscope. Wild-type hybrids were obtained by fusing protoplasts of strain NEL102 with B14, another morphological mutant previously described as being permanently pseudomycelial, indicating that genetic determinants responsible for the two altered phenotypes are different. The mutants characterized in this work seemed to sequentially express the morphogenic characteristics of C. albicans, from blastoconidia to hyphae, in the absence of any inducer. Further characterization of these strains could be relevant to gain understanding of the genetic control of dimorphism in this species.     

The size of the nucleus increases as yeast cells grow

It is not known how the volume of the cell nucleus is set, nor how the ratio of nuclear volume to cell volume (N/C) is determined. Here, we have measured the size of the nucleus in growing cells of the budding yeast Saccharomyces cerevisiae. Analysis of mutant yeast strains spanning a range of cell sizes revealed that the ratio of average nuclear volume to average cell volume was quite consistent, with nuclear volume being approximately 7% that of cell volume. At the single cell level, nuclear and cell size were strongly correlated in growing wild-type cells, as determined by three different microscopic approaches. Even in G1-phase, nuclear volume grew, although it did not grow quite as fast as overall cell volume. DNA content did not appear to have any immediate, direct influence on nuclear size, in that nuclear size did not increase sharply during S-phase. The maintenance of nuclear size did not require continuous growth or ribosome biogenesis, as starvation and rapamycin treatment had little immediate impact on nuclear size. Blocking the nuclear export of new ribosomal subunits, among other proteins and RNAs, with leptomycin B also had no obvious effect on nuclear size. Nuclear expansion must now be factored into conceptual and mathematical models of budding yeast growth and division. These results raise questions as to the unknown force(s) that expand the nucleus as yeast cells grow.     

The regulation of nuclear migration and division during pseudo-mycelium outgrowth in the dimorphic yeast Candida albicans.

The relationships of the first nuclear division during pseudo-mycelial outgrowth in the infectious yeast Candida albicans to pseudo-mycelial length and DNA replication have been investigated. Evidence is presented that the first nuclear division does not occur until the pseudo-mycelium grows to a minimum length equal to or greater than the diameter of the mother cell and until the cells pass through a minimum time period of approx. 150 min which probably reflects the time necessary to complete nuclear DNA replication. Evidence is also presented that pseudo-mycelial outgrowth and nuclear migration occur independently of DNA replication, and that nuclear migration is probably regulated by the length rather than by the volume of the growing pseudomycelium. Similarities to the requirements for nuclear division during budding in Saccharomyces are discussed, and a model for nuclear migration is proposed.     

Vacuolar dynamics in synchronously budding yeast

Summary A simple and rapid method for obtaining synchronously budding cultures of Saccharomyces cerevisiae is described. Synchronous cultures were started with homogeneous cell fractions isolated from exponentially growing cultures by isopycnic centrifugation in osmotically inactive media. The technique of fractionation is based on changes of cell density throughout the budding cycle. These changes are correlated with vacuolar changes observed in the light and electron microscope. During bud initiation the large vacuoles in late budding cells shrink and fragment into small vacuoles. Simultaneously the density of the cells increases. Later stages of the budding cycle are characterized by the distribution of the small vacuoles between mother and daughter cell, followed by their fusion and expansion, and by a decreasing density of the cells. The relative changes in cell density and dry weight and in the content of different macromolecules during the budding cycle suggest a cyclic change between utilization of endogenous and exogenous substrates. This is discussed in terms of a cyclic consumption and accumulation of vacuolar pools.     

Regulation of cell size in the yeast Saccharomyces cerevisiae.

For cells of the yeast Saccharomyces cerevisiae, the size at initiation of budding is proportional to growth rate for rates from 0.33 to 0.23 h-1. At growth rates lower than 0.23 h-1, cells displayed a minimum cell size at bud initiation independent of growth rate. Regardless of growth rate, cells displayed an increase in volume each time budding was initiated. When abnormally small cells, produced by starvation for nitrogen, were placed in fresh medium containing nitrogen but with different carbon sources, they did not initiate budding until they had grown to the critical size characteristic of that medium. Moreover, when cells were shifted from a medium supporting a low growth rate and small size at bud initiation to a medium supporting a higher growth rate and larger size at bud initiation, there was a transient accumulation of cells within G1. These results suggest that yeast cells are able to initiate cell division at different cell sizes and that regulation of cell size occurs within G1.     

Volume growth of daughter and parent cells during the cell cycle of Saccharomyces cerevisiae a/alpha as determined by image cytometry.

The pattern of volume growth of Saccharomyces cerevisiae a/alpha was determined by image cytometry for daughter cells and consecutive cycles of parent cells. An image analysis program was specially developed to measure separately the volume of bud and mother cell parts and to quantify the number of bud scars on each parent cell. All volumetric data and cell attributes (budding state, number of scars) were stored in such a way that separate volume distributions of cells or cell parts with any combination of properties--for instance, buds present on mothers with two scars or cells without scars (i.e., daughter cells) and without buds--could be obtained. By a new method called intersection analysis, the average volumes of daughter and parent cells at birth and at division could be determined for a steady-state population. These volumes compared well with those directly measured from cells synchronized by centrifugal elutriation. During synchronous growth of daughter cells, the pattern of volume increase appeared to be largely exponential. However, after bud emergence, larger volumes than those predicted by a continuous exponential increase were obtained, which confirms the reported decrease in buoyant density. The cycle times calculated from the steady-state population by applying the age distribution equation deviated from those directly obtained from the synchronized culture, probably because of inadequate scoring of bud scars. Therefore, for the construction of a volume-time diagram, we used volume measurements obtained from the steady-state population and cycle times obtained from the synchronized population. The diagram shows that after bud emergence, mother cell parts continue to grow at a smaller rate, increasing about 10% in volume during the budding period. Second-generation daughter cells, ie., cells born from parents left with two scars, were significantly smaller than first-generation daughter cells. Second- and third-generation parent cells showed a decreased volume growth rate and a shorter budding period than that of daughter cells.     

Effect of Reversible Inhibition of Deoxyribonucleic Acid Synthesis on the Yeast Cell Cycle

Hydroxyurea (HU) preferentially inhibited deoxyribonucleic acid (DNA) replication and division in Saccharomyces cerevisiae. Growth, ribonucleic acid synthesis, and protein synthesis were less sensitive to this drug. Upon addition of HU, cells underwent one cycle of budding and the nuclei migrated into the necks between the mother cells and buds. Neither the nucleus nor the cells divided. Removal of HU allowed immediate resumption of DNA synthesis. Nuclear division, budding, and cell division occurred 1.5, 2, and 4 hr, respectively, after HU was removed. If protein synthesis was blocked at the time HU was removed, budding and cell division did not occur. These results were interpreted to indicate that HU prevents accumulation of the potential to initiate a new cell cycle.     

Growth cycle of daughter and mother cells ofSaccharomyces cerevisiae

Maximum values of specific rate of RNA synthesis, specific growth rate and a critical cell size determined by the surface to volume ratioS/V =1.0 are the factors which control the onset of budding in daughter cells. The increased rate of RNA synthesis is due not only to daughter cells but also to all buds formed on mother cells.     

Filament ring formation in the dimorphic yeast Candida albicans

Stationary phase cultures of Candida albicans inoculated into fresh medium at 37 degrees C synchronously from buds at pH 4.5 and mycelia at pH 6.5. During bud formation, a filament ring forms just under the plasma membrane at the mother cell-bud junction at roughly the time of evagination. A filament ring also forms in mycelium-forming cells, but it appears later than in a budding cell and it is positioned along the elongating mycelium, on the average 2 microns from the mother cell-mycelium junction. Sections of filament rings in early and late budding cells and in mycelia appear similar. Each contains approximately 11 to 12 filaments equidistant from one another and closely associated with the plasma membrane. In both budding and mycelium-forming cells, the filament ring disappears when the primary septum grows inward. The close temporal and spatial association of the filament ring and the subsequent chitin-containing septum suggests a role for the filament ring in septum formation. In addition, a close temporal correlation is demonstrated between filament ring formation and the time at which cells become committed to bud formation at pH 4.5 and mycelium formation at pH 6.5. The temporal and spatial differences in filament ring formation between the two growth forms also suggest a simple model for the positioning of the filament ring.