Growth and the inducibility of mycelium formation in Candida albicans: a single-cell analysis using a perfusion chamber

In Candida albicans, cells actively growing in the budding form cannot be immediately induced to form a mycelium until they enter stationary phase. However, if exponential phase cells are starved for a minimum of 10 to 20 min, they are inducible. Using a video-monitored perfusion chamber, we found that starved cells were able to form mycelia regardless of their position in the budding cycle. When starved exponential cells were released into fresh nutrient medium at high temperature and pH, conditions conducive to mycelium formation, unbudded cells evaginated after an average lag period of 75 min and then grew exclusively in the mycelial form. Depending upon the volume, or maturity, of the bud, budded cells entered two different avenues of outgrowth leading to mycelium formation. If the daughter bud was small, growth resumed by apical elongation of the bud, leading to a 'shmoo' shape which tapered into an apical mycelium. If the daughter bud was large, the cell underwent a sequence of evaginations: first, the mother cell evaginated after an average period of 75 min; then the daughter bud evaginated 40 min later. Both evaginations then grew in the mycelial form. In this latter sequence, the evagination on the mother cell was positioned non-randomly, occurring in the majority of cells adjacent to the bud. All buds undergoing evagination contained a nucleus, but roughly 20% of buds undergoing apical elongation did not.     

Temporal and spatial differences in cell wall expansion during bud and mycelium formation in Candida albicans

The infectious yeast Candida albicans is capable of growing in either a budding or mycelium form, depending upon the pH of the supporting medium. By monitoring the position of polylysine-coated beads firmly attached to the wall of growing cells, the zones of expansion for the surface of the cell wall have been mapped for the alternative growth forms. Both spatial and temporal differences are demonstrated to exist. During roughly the first two-thirds of bud growth, a very small, highly active apical zone accounts for roughly 70% of surface expansion. The remaining 30% is due to general expansion. When a bud reaches approximately two-thirds of its final surface area, the apical zone shuts down, and subsequent expansion is completed by the general mechanism. During mycelial growth, at least 90% of expansion is due to a small, highly active apical growth zone, and less than 10% is due to the general mechanism. In contrast to budding cells, the apical zone of the growing mycelium never shuts down as long as growth continues in the mycelial form. These distinct temporal and spatial differences in expansion are considered in terms of the regulation of alternative phenotypes in Candida.     

The dependency of nuclear division on volume in the dimorphic yeast Candida albicans

When stationary phase cells of the dimorphic yeast Candida albicans are induced to synchronously form mycelia, over 90% of the cells undergo nuclear division. However, when stationary phase cells are induced to synchronously form buds, less than half undergo nuclear division even though all form buds. The majority of cells which do not undergo nuclear division form buds with volumes below a threshold value and the majority of cells which do undergo nuclear division form buds with volumes above this threshold value. In this report, we have investigated the possibilities that cells which form small buds do not attain a particular mass threshold. Cell cultures were examined for DNA replication, dry weight, and protein content during synchronous bud and during synchronous mycelium formation. Evidence is presented which indicates that the lack of nuclear division in over half of a budding population is due to low daughter cell volumes or to low surface areas, and not to their failure to attain a mass threshold or to replicate their DNA. The dependency of nuclear division on daughter cell volume is discussed.     

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.     

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.     

Symmetric cell division in pseudohyphae of the yeast Saccharomyces cerevisiae.

Laboratory strains of Saccharomyces cerevisiae are dimorphic; in response to nitrogen starvation they switch from a yeast form (YF) to a filamentous pseudohyphal (PH) form. Time-lapse video microscopy of dividing cells reveals that YF and PH cells differ in their cell cycles and budding polarity. The YF cell cycle is controlled at the G1/S transition by the cell-size checkpoint Start. YF cells divide asymmetrically, producing small daughters from full-sized mothers. As a result, mothers and daughters bud asynchronously. Mothers bud immediately but daughters grow in G1 until they achieve a critical cell size. By contrast, PH cells divide symmetrically, restricting mitosis until the bud grows to the size of the mother. Thus, mother and daughter bud synchronously in the next cycle, without a G1 delay before Start. YF and PH cells also exhibit distinct bud-site selection patterns. YF cells are bipolar, producing their second and subsequent buds at either pole. PH cells are unipolar, producing their second and subsequent buds only from the end opposite the junction with their mother. We propose that in PH cells a G2 cell-size checkpoint delays mitosis until bud size reaches that of the mother cell. We conclude that yeast and PH forms are distinct cell types each with a unique cell cycle, budding pattern, and cell shape.     

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.     

The temporal regulation of protein synthesis during synchronous bud or mycelium formation in the dimorphic yeast Candida albicans

When stationary phase cells of the dimorphic yeast Candida albicans are diluted into fresh medium at 37°C at either pH 4.5 or pH 6.5, they evaginate at exactly the same time and with the same synchrony. However, they then grow in the budding yeast form at the former pH and in the elongate mycelium form at the latter pH. Three phases of protein synthesis are distinguished for cells forming either buds or mycelia: an initial 50-min period (phase I) during which total cell protein remains constant and the rate of incorporation of labeled amino acid into protein is virtually zero; a second period (phase II) during which there is a slow but constant increase in both total cell protein and the rate of incorporation; and a third period (phase III) during which there is a dramatic increase in both total cell protein and the rate of incorporation. The transition from phase I to phase II occurs at the same time for cells forming either buds or mycelia, but the transition from phase II to phase III occurs 20 to 30 min later in the mycelium than in the bud forming population, the same temporal difference observed for phenotypic commitment. The polypeptides synthesized during phases II and III were first analyzed by one-dimensional polyacrylamide gel electrophoresis. The patterns are similar for the two phenotypes. The major polypeptides synthesized during phase II are also synthesized during phase III, but in addition, a group of at least four new major polypeptides appear during phase III for both phenotypes. The minor polypeptides synthesized during phase III were also compared between the two phenotypes by two-dimensional polyacrylamide gel electrophoresis. The patterns, including roughly 200 distinguishable polypeptides, were similar. The similarities in the patterns of protein synthesis and the delay in the onset of phase III in mycelium forming cells are discussed in terms of phenotypic commitment. From these considerations, alternate hypotheses for the regulation of fungal dimorphism, in particular, and cell divergence, in general, are proposed.     

Differences in actin localization during bud and hypha formation in the yeast Candida albicans

Stationary phase cells of Candida albicans can form either a bud or a hypha, depending upon the pH of the medium into which they are released. At low pH, cells form an ellipsoidal bud and at high pH, cells form an elongated hypha. By staining cells with rhodamine-conjugated phalloidin, we have compared the dynamics of actin localization during the formation of buds and hyphae. Before evagination, actin granules were distributed throughout the cytoplasmic cortex in both budding and hypha-forming cells. Just before evagination, actin granules clustered at the site of evagination, then filled the early evagination in both budding and hypha-forming cells. With continued bud growth, the actin granules then redistributed throughout the cytoplasmic cortex. In marked contrast, with continued hyphal growth, the majority of actin granules clustered at the hyphal apex. This distinct difference in actin granule localization may be related to the distinct differences in the expansion zones of the cell wall recently demonstrated between growing buds and hyphae. The spatial and temporal dynamics of the large neck actin granules and of actin fibres are also described.     

The ukb1 gene encodes a putative protein kinase required for bud site selection and pathogenicity in Ustilago maydis

Morphogenesis and pathogenesis are closely associated aspects of the life cycle of the fungal pathogen Ustilago maydis. In this fungus, the dimorphic switch from budding to filamentous growth coincides with the transition from non-pathogenic to pathogenic growth on maize. We have cloned and characterized the ukb1 gene that encodes a putative serine/threonine protein kinase with a role in budding and filamentous growth. Mutants defective in ukb1 were altered in bud site selection and produced lateral buds at a greater frequency than wild-type cells. Dikaryotic cells defective in ukb1 were capable of colonizing host tissue and growing with a filamentous morphology in planta. However, the mutants were incapable of inducing tumor formation and they failed to complete sexual development. In addition, the ukb1 gene influenced the ability of colonies to form aerial mycelia in response to environmental stimuli. Overall, the discovery of ukb1 reinforces the connection between morphogenesis and pathogenesis in U. maydis.     

Roles of the CDC24 gene product in cellular morphogenesis during the Saccharomyces cerevisiae cell cycle

Temperature-sensitive yeast mutants defective in gene CDC24 continued to grow (i.e., increase in cell mass and cell volume) at restrictive temperature (36 degrees C) but were unable to form buds. Staining with the fluorescent dye Calcofluor showed that the mutants were also unable to form normal bud scars (the discrete chitin rings formed in the cell wall at budding sites) at 36 degrees C; instead, large amounts of chitin were deposited randomly over the surfaces of the growing unbudded cells. Labeling of cell-wall mannan with fluorescein isothiocyanate-conjugated concanavalin A suggested that mannan incorporation was also delocalized in mutant cells grown at 36 degrees C. Although the mutants have well-defined execution points just before bud emergence, inactivation of the CDC24 gene product in budded cells led both to selective growth of mother cells rather than of buds and to delocalized chitin deposition, indicating that the CDC24 gene product functions in the normal localization of growth in budded as well as in unbudded cells. Growth of the mutant strains at temperatures less than 36 degrees C revealed allele-specific differences in behavior. Two strains produced buds of abnormal shape during growth at 33 degrees C. Moreover, these same strains displayed abnormal localization of budding sites when growth at 24 degrees C (the normal permissive temperature for the mutants); in each case, the abnormal pattern of budding sites segregated with the temperature sensitivity in crosses. Thus, the CDC24 gene product seems to be involved in selection of the budding site, formation of the chitin ring at that site, the subsequent localization of new cell wall growth to the budding site and the growing bud, and the balance between tip growth and uniform growth of the bud that leads to the normal cell shape.     

Bud emergence is gradually delayed from S to G2 with progression of growth phase in Cryptococcus neoformans

The G2 index of the yeast Cryptococcus neoformans determined by laser scanning cytometer was 2-3 times higher than the budding index during transition to the stationary phase of the culture, indicating that buds emerged in the G2 phase of the cell cycle. To clarify whether buds also emerge in G2 during exponential growth of the culture, DNA content for each cell was measured with a fluorescence microscope equipped with a photomultiplier. The DNA content of cells having tiny buds varied rather widely, depending on growth phases and strains used. Typically, buds of C. neoformans emerged soon after initiation of DNA synthesis in the early exponential phase. However, bud emergence was delayed to G2 during transition to the stationary phase, and in the early stationary phase budding scarcely occurred, although roughly half of the cells completed DNA synthesis. Thus, the timing of budding in C. neoformans was actually shifted to later cell cycle points with progression of the growth phase of the culture.     

The roles of bud-site-selection proteins during haploid invasive growth in yeast

In haploid strains of Saccharomyces cerevisiae, glucose depletion causes invasive growth, a foraging response that requires a change in budding pattern from axial to unipolar-distal. To begin to address how glucose influences budding pattern in the haploid cell, we examined the roles of bud-site-selection proteins in invasive growth. We found that proteins required for bipolar budding in diploid cells were required for haploid invasive growth. In particular, the Bud8p protein, which marks and directs bud emergence to the distal pole of diploid cells, was localized to the distal pole of haploid cells. In response to glucose limitation, Bud8p was required for the localization of the incipient bud site marker Bud2p to the distal pole. Three of the four known proteins required for axial budding, Bud3p, Bud4p, and Axl2p, were expressed and localized appropriately in glucose-limiting conditions. However, a fourth axial budding determinant, Axl1p, was absent in filamentous cells, and its abundance was controlled by glucose availability and the protein kinase Snf1p. In the bud8 mutant in glucose-limiting conditions, apical growth and bud site selection were uncoupled processes. Finally, we report that diploid cells starved for glucose also initiate the filamentous growth response.     

Polarized growth controls cell shape and bipolar bud site selection in Saccharomyces cerevisiae

We examined the relationship between polarized growth and division site selection, two fundamental processes important for proper development of eukaryotes. Diploid Saccharomyces cerevisiae cells exhibit an ellipsoidal shape and a specific division pattern (a bipolar budding pattern). We found that the polarity genes SPA2, PEA2, BUD6, and BNI1 participate in a crucial step of bud morphogenesis, apical growth. Deleting these genes results in round cells and diminishes bud elongation in mutants that exhibit pronounced apical growth. Examination of distribution of the polarized secretion marker Sec4 demonstrates that spa2Delta, pea2Delta, bud6Delta, and bni1Delta mutants fail to concentrate Sec4 at the bud tip during apical growth and at the division site during repolarization just prior to cytokinesis. Moreover, cell surface expansion is not confined to the distal tip of the bud in these mutants. In addition, we found that the p21-activated kinase homologue Ste20 is also important for both apical growth and bipolar bud site selection. We further examined how the duration of polarized growth affects bipolar bud site selection by using mutations in cell cycle regulators that control the timing of growth phases. The grr1Delta mutation enhances apical growth by stabilizing G(1) cyclins and increases the distal-pole budding in diploids. Prolonging polarized growth phases by disrupting the G(2)/M cyclin gene CLB2 enhances the accuracy of bud site selection in wild-type, spa2Delta, and ste20Delta cells, whereas shortening the polarized growth phases by deleting SWE1 decreases the fidelity of bipolar budding. This study reports the identification of components required for apical growth and demonstrates the critical role of polarized growth in bipolar bud site selection. We propose that apical growth and repolarization at the site of cytokinesis are crucial for establishing spatial cues used by diploid yeast cells to position division planes.     

Role of cell division in branching morphogenesis and differentiation of the embryonic pancreas

A new culture system for the embryonic pancreas enables the formation of a branched organ in vitro. In such cultures, each terminal branch originates as a small bud and the number of buds and of terminal branches increases progressively with the expansion of the culture. However buds can also be resorbed during growth. The normal labelling index of cells in incipient buds ("tips") is greater than between buds ("dips") suggesting that budding may be driven by a local increase of cell division. Consistent with this, treatments that reduce cell division repress the formation of buds and branches. It is not possible to initiate budding in isolated endodermal epithelium by treatment with fibroblast growth factor, although this does increase the degree of differentiation of exocrine cells. Cultures in which cell division is completely inhibited by aphidicolin treatment will produce more endocrine cells than usual and inhibit the differentiation of exocrine cells. Consistent with this it is found that in untreated cultures the division of endocrine precursors cannot be detected by BrdU labelling whereas the division of exocrine precursors is frequent. It is concluded that cell division is necessary for bud formation in the embryonic pancreas and that the growth factors required for this normally come from the mesenchyme. Cell division is also necessary for exocrine differentiation. Endocrine cells, however, can arise from undifferentiated progenitors without cell division.     

Conservation of mechanisms controlling entry into mitosis: budding yeast wee1 delays entry into mitosis and is required for cell size control

BACKGROUND: In fission yeast, the Wee1 kinase delays entry into mitosis until a critical cell size has been reached; however, a similar role for Wee1-related kinases has not been reported in other organisms. SWE1, the budding yeast homolog of wee1, is thought to function in a morphogenesis checkpoint that delays entry into mitosis in response to defects in bud morphogenesis. RESULTS: In contrast to previous studies, we found that budding yeast swe1 Delta cells undergo premature entry into mitosis, leading to birth of abnormally small cells. Additional experiments suggest that conditions that activate the morphogenesis checkpoint may actually be activating a G2/M cell size checkpoint. For example, actin depolymerization is thought to activate the morphogenesis checkpoint by inhibiting bud morphogenesis. However, actin depolymerization also inhibits bud growth, suggesting that it could activate a cell size checkpoint. Consistent with this possibility, we found that actin depolymerization fails to induce a G2/M delay once daughter buds pass a critical size. Other conditions that activate the morphogenesis checkpoint block bud formation, which could also activate a size checkpoint if cell size at G2/M is monitored in the daughter bud. Previous work reported that Swe1 is degraded during G2, which was proposed to account for failure of large-budded cells to arrest in response to actin depolymerization. However, we found that Swe1 is present throughout G2 and undergoes hyperphosphorylation as cells enter mitosis, as found in other organisms. CONCLUSIONS: Our results suggest that the mechanisms known to coordinate entry into mitosis in other organisms have been conserved in budding yeast.     

Bud8p and Bud9p, proteins that may mark the sites for bipolar budding in yeast

The bipolar budding pattern of a/alpha Saccharomyces cerevisiae cells appears to depend on persistent spatial markers in the cell cortex at the two poles of the cell. Previous analysis of mutants with specific defects in bipolar budding identified BUD8 and BUD9 as potentially encoding components of the markers at the poles distal and proximal to the birth scar, respectively. Further genetic analysis reported here supports this hypothesis. Mutants deleted for BUD8 or BUD9 grow normally but bud exclusively from the proximal and distal poles, respectively, and the double-mutant phenotype suggests that the bipolar budding pathway has been totally disabled. Moreover, overexpression of these genes can cause either an increased bias for budding at the distal (BUD8) or proximal (BUD9) pole or a randomization of bud position, depending on the level of expression. The structures and localizations of Bud8p and Bud9p are also consistent with their postulated roles as cortical markers. Both proteins appear to be integral membrane proteins of the plasma membrane, and they have very similar overall structures, with long N-terminal domains that are both N- and O-glycosylated followed by a pair of putative transmembrane domains surrounding a short hydrophilic domain that is presumably cytoplasmic. The putative transmembrane and cytoplasmic domains of the two proteins are very similar in sequence. When Bud8p and Bud9p were localized by immunofluorescence and tagging with GFP, each protein was found predominantly in the expected location, with Bud8p at presumptive bud sites, bud tips, and the distal poles of daughter cells and Bud9p at the necks of large-budded cells and the proximal poles of daughter cells. Bud8p localized approximately normally in several mutants in which daughter cells are competent to form their first buds at the distal pole, but it was not detected in a bni1 mutant, in which such distal-pole budding is lost. Surprisingly, Bud8p localization to the presumptive bud site and bud tip also depends on actin but is independent of the septins.     

Asymmetrical division of Saccharomyces cerevisiae.

The unequal division model proposed for budding yeast (L. H. Hartwell and M. W. Unger, J. Cell Biol. 75:422-435, 1977) was tested by bud scar analyses of steady-state exponential batch cultures of Saccharomyces cerevisiae growing at 30 degrees C at 19 different rates, which were obtained by altering the carbon source. The analyses involved counting the number of bud scars, determining the presence or absence of buds on at least 1,000 cells, and independently measuring the doubling times (gamma) by cell number increase. A number of assumptions in the model were tested and found to be in good agreement with the model. Maximum likelihood estimates of daughter cycle time (D), parent cycle time (P), and the budded phase (B) were obtained, and we concluded that asymmetrical division occurred at all growth rates tested (gamma, 75 to 250 min). D, P, and B are all linearly related to gamma, and D, P, and gamma converge to equality (symmetrical division) at gamma = 65 min. Expressions for the genealogical age distribution for asymmetrically dividing yeast cells were derived. The fraction of daughter cells in steady-state populations is e-alpha P, and the fraction of parent cells of age n (where n is the number of buds that a cell has produced) is (e-alpha P)n-1(1-e-alpha P)2, where alpha = IN2/gamma; thus, the distribution changes with growth rate. The frequency of cells with different numbers of bud scars (i.e., different genealogical ages) was determined for all growth rates, and the observed distribution changed with the growth rate in the manner predicted. In this haploid strain new buds formed adjacent to the previous buds in a regular pattern, but at slower growth rates the pattern was more irregular. The median volume of the cells and the volume at start in the cell cycle both increased at faster growth rates. The implications of these findings for the control of the cell cycle are discussed.     

Immunoferritin labeling shows de novo synthesis of surface components in buds of a prokaryote belonging to morphotype IV of theBlastocaulis-Planctomyces group

Indirect immunoferritin labeling provided evidence for the de novo synthesis of antigenic cell-surface components of the daughter cell (bud) of a freshwater isolate belonging to morphotype IV of theBlastocaulis-Planctomyces group of budding and nonprosthecately appendaged prokaryotes. The cell surfaces of the buds produced by immunoferritin-labeled mother cells remained unlabeled through development to flagellated swarmers. Double-labeling experiments verified the de novo synthesis of cell-surface antigens over the entire bud, and also showed a labeling pattern indicative of intercalation of newly formed sites on the surface of the mother cell during the later stages of its maturation.