Cell size and budding during starvation of the yeast Saccharomyces cerevisiae.

When starved for nitrogen, cells of the yeast Saccharomyces cerevisiae produced abnormally small cells. Nonetheless, during starvation, only cells of a size characteristic of growing cells were capable of initiating a bud. Even when growth was severely limited, some event(s) in G1 required growth to a critical size for completion.     

G1 cyclins regulate proliferation of the budding yeast Saccharomyces cerevisiae.

The eukaryotic cell cycle is regulated at two points, the G1-S and G2-M boundaries. The molecular basis for these regulatory activities has recently been elucidated, in large part by the use of molecular and genetic analyses using unicellular yeast. The molecular characterization of cell-cycle regulation has revealed striking functional conservation among evolutionarily diverse cell types. For many eukaryotic cells, regulation of cell proliferation occurs primarily in the G1 interval. The G1 regulatory step, termed START, requires the activation of a highly conserved p34 protein kinase by association with a functionally redundant family of proteins, the G1 cyclins. Here we review studies using the genetically tractable budding yeast Saccharomyces cerevisiae, which have provided insight into the role of G1 cyclins in the regulation of START.     

Sterol homeostasis in the budding yeast, Saccharomyces cerevisiae

Lipid related diseases, such as obesity, type 2 diabetes, and atherosclerosis are epidemics in developed civilizations. A common underlying factor among these syndromes is excessive subcellular accumulation of lipids such as cholesterol and triglyceride. The homeostatic events that govern these metabolites are understood to varying degrees of sophistication. We describe here the utilization of a genetically powerful model organism, budding yeast, to identify and characterize novel aspects of sterol and lipid homeostasis.     

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.     

The relationship between cell size and cell division in the yeast Saccharomyces cerevisiae.

Cell numbers in synchronous cultures of yeast cultured at fast growth rates increase from N to 2N after the first division and from 2N to 4N after the second division. At these fast growth rates, there are equal numbers of parents and daughters. In contrast, at slow growth rates the cell number increases from N to 2N after one division and from 2N to 3N rather than 4N after the second division. Moreover, the percentage of daughters increases with decreasing growth rate. Thus, slowly growing cultures actually consist of two sub-populations having different cell cycle transit times. These observations are predicted if a yeast cell requires a critical size before a particular cell cycle event can be completed and that after completion of this event cell division occurs following a period of time independent of growth rate.     

Aging and senescence of the budding yeast Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae has a limited life span, defined by the number of times an individual cell divides. Longevity in this organism involves a genetic component. Several morphological and physiological changes are associated with yeast aging and senescence. One of these, an increase in generation time with age, provides a 'biomarker' for the aging process. This increase in generation time has revealed the operation of a 'senescence factor(s)', which is likely to be a product of age-specific gene expression. The Cell Spiral Model indicates coordination of successive cell cycles to be inherent in the determination of life span. It is proposed that life expectancy depends on the function of a stochastic trigger during aging that sets in motion a programme leading to cell senescence and death.     

Spindle dynamics and cell cycle regulation of dynein in the budding yeast, Saccharomyces cerevisiae

We have used time-lapse digital- and video-enhanced differential interference contrast (DE-DIC, VE-DIC) microscopy to study the role of dynein in spindle and nuclear dynamics in the yeast Saccharomyces cerevisiae. The real-time analysis reveals six stages in the spindle cycle. Anaphase B onset appears marked by a rapid phase of spindle elongation, simultaneous with nuclear migration into the daughter cell. The onset and kinetics of rapid spindle elongation are identical in wild type and dynein mutants. In the absence of dynein the nucleus does not migrate as close to the neck as in wild-type cells and initial spindle elongation is confined primarily to the mother cell. Rapid oscillations of the elongating spindle between the mother and bud are observed in wild-type cells, followed by a slower growth phase until the spindle reaches its maximal length. This stage is protracted in the dynein mutants and devoid of oscillatory motion. Thus dynein is required for rapid penetration of the nucleus into the bud and anaphase B spindle dynamics. Genetic analysis reveals that in the absence of a functional central spindle (ndcl), dynein is essential for chromosome movement into the bud. Immunofluorescent localization of dynein-beta- galactosidase fusion proteins reveals that dynein is associated with spindle pole bodies and the cell cortex: with spindle pole body localization dependent on intact microtubules. A kinetic analysis of nuclear movement also revealed that cytokinesis is delayed until nuclear translocation is completed, indicative of a surveillance pathway monitoring nuclear transit into the bud.     

Structural heterogeneity in populations of the budding yeast Saccharomyces cerevisiae.

Bud scar analysis integrated with mathematical analysis of DNA and protein distributions obtained by flow microfluorometry have been used to analyze the cell cycle of the budding yeast Saccharomyces cerevisiae. In populations of this yeast growing exponentially in batch at 30 degrees C on different carbon and nitrogen sources with duplication times between 75 and 314 min, the budded period is always shorter (approximately 5 to 10 min) than the sum of the S + G2 + M + G1* phases (determined by the Fried analysis of DNA distributions), and parent cells always show a prereplicative unbudded period. The analysis of protein distributions obtained by flow microfluorometry indicates that the protein level per cell required for bud emergence increases at each new generation of parent cells, as observed previously for cell volume. A wide heterogeneity of cell populations derives from this pattern of budding, since older (and less frequent) parent cells have shorter generation times and produce larger (and with shorter cycle times) daughter cells. A possible molecular mechanism for the observed increase with genealogical age of the critical protein level required for bud emergence is discussed.     

Phosphorylation of the GTS1 gene product of the yeast Saccharomyces cerevisiae and its effect on heat tolerance and flocculation

The GTS1 gene from the yeast Saccharomyces cerevisiae showed pleiotropic effects on yeast phenotypes, including an increase of heat tolerance in stationary-phase cells and an induction of flocculation. Here, we found that the GTS1 product, Gts1p, was partially phosphorylated at some serine residue(s) in cells grown on glucose. Studies using mutants of protein kinase A (PKA) and CDC25, the Ras-GTP exchange activator, showed that PKA positively regulated the phosphorylation level of Gts1p. Overexpression of Gts1p in a mutant with attenuated PKA activity did not show any increase of heat tolerance and partially decreased flocculation inducibility, suggesting that phosphorylation of Gts1p is required for induction of these phenomena.     

The dynamics of chromosome movement in the budding yeast Saccharomyces cerevisiae

Nuclear DNA movement in the yeast, Saccharomyces cerevisiae, was analyzed in live cells using digital imaging microscopy and corroborated by the analysis of nuclear DNA position in fixed cells. During anaphase, the replicated nuclear genomes initially separated at a rate of 1 micron/min. As the genomes separated, the rate of movement became discontinuous. In addition, the axis defined by the segregating genomes rotated relative to the cell surface. The similarity between these results and those previously obtained in higher eukaryotes suggest that the mechanism of anaphase movement may be highly conserved. Before chromosome separation, novel nuclear DNA movements were observed in cdc13, cdc16, and cdc23 cells but not in wild-type or cdc20 cells. These novel nuclear DNA movements correlated with variability in spindle position and length in cdc16 cells. Models for the mechanism of these movements and their induction by certain cdc mutants are discussed.     

SDC25, a CDC25-like gene which contains a RAS-activating domain and is a dispensable gene of Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the CDC25 gene product activates adenylate cyclase through RAS1 and RAS2 gene products. We have recently described the cloning of a DNA fragment which suppresses the cdc25 mutation but not ras1, ras2, or cdc35 mutations. This fragment contains a 5'-truncated open reading frame which shares 47% identity with the C-terminal part of the CDC25 gene. We named the entire gene SDC25. In this paper, we report the cloning, sequencing, and characterization of the complete SDC25 gene. The SDC25 gene is located on the chromosome XII close to the centromere. It is transcribed into a 4-kb-long mRNA that contains an open reading frame of 1,251 codons. Homology with the CDC25 gene extends in the N-terminal part, although the degree of similarity is lower than in the C-terminal part. In contrast with the C-terminal part, the complete SDC25 gene was found not to suppress the CDC25 gene defect. A deletion in the N-terminal part restored the suppressing activity, a result which suggests the existence of a regulatory domain. The SDC25 gene was found to be dispensable for cell growth under usual conditions. No noticeable phenotype was found in the deleted strain.     

Regulation of proliferation by the budding yeast Saccharomyces cerevisiae

Mutations in the budding yeast Saccharomyces cerevisiae define regulatory activities both for the mitotic cell cycle and for resumption of proliferation from the quiescent stationary-phase state. In each case, the regulation of proliferation occurs in the prereplicative interval that precedes the initiation of DNA replication. This regulation is particularly responsive to the nutrient environment and the biosynthetic capacity of the cell. Mutations in components of the cAMP-mediated effector pathway and in components of the biosynthetic machinery itself affect regulation of proliferation within the mitotic cell cycle. In the extreme case of nutrient starvation, cells cease proliferation and enter stationary phase. Mutations in newly defined genes prevent stationary-phase cells from reentering the mitotic cell cycle, but have no effect on proliferating cells. Thus stationary phase represents a unique developmental state, with requirements to resume proliferation that differ from those for the maintenance of proliferation in the mitotic cell cycle.     

AUT1, a gene essential for autophagocytosis in the yeast Saccharomyces cerevisiae.

Autophagocytosis is a starvation-induced process responsible for transport of cytoplasmic proteins to the vacuole. In Saccharomyces cerevisiae, autophagy is characterized by the phenotypic appearance of autophagic vesicles inside the vacuole of strains deficient in proteinase yscB. The AUT1 gene, essential for autophagy, was isolated by complementation of the sporulation deficiency of a diploid aut1-1 mutant strain by a yeast genomic library and characterized. AUT1 is located on the right arm of chromosome XIV, 10 kb from the centromere, and encodes a protein of 310 amino acids, with an estimated molecular weight of 36 kDa. Cells carrying a chromosomal deletion of AUT1 are defective in the starvation-induced bulk flow transport of cytoplasmic proteins to the vacuole. aut1 null mutant strains are completely viable but show decreased survival rates during starvation. Homozygous delta aut1 diploid cells fail to sporulate. The selective cytoplasm-to-vacuole transport of aminopeptidase I is blocked in logarithmically growing and in starved delta autl cells. Deletion of the AUT1 gene had no obvious influence on secretion, fluid phase endocytosis, or vacuolar protein sorting. This supports the idea of autophagocytosis as being a novel route transporting proteins from the cytoplasm to the vacuole.     

The GTS1 gene product facilitates the self-organization of the energy metabolism oscillation in the continuous culture of the yeast Saccharomyces cerevisiae

To study the role of the GTS1 gene in the energy metabolism oscillation in continuous cultures of yeast from the physical aspect, time-series data of dissolved oxygen oscillations were analyzed by transforming them into power spectra and by creating two-dimensional trajectories using time delay embedding technique. We found that the wild-type cells organized themselves into a stable limit cycle oscillation and that the GTS1-deleted mutant, gts1Delta, usually showed transient oscillations whose power spectra resembled those of 1/f noise. Thus, we suggested that GTS1 plays an important role in the self-organization of the energy metabolism oscillation.     

Lipid rafts in protein sorting and cell polarity in budding yeast Saccharomyces cerevisiae

Cellular membranes contain many types and species of lipids. One of the most important functional consequences of this heterogeneity is the existence of microdomains within the plane of the membrane. Sphingolipid acyl chains have the ability of forming tightly packed platforms together with sterols. These platforms or lipid rafts constitute segregation and sorting devices into which proteins specifically associate. In budding yeast, Saccharomyces cerevisiae, lipid rafts serve as sorting platforms for proteins destined to the cell surface. The segregation capacity of rafts also provides the basis for the polarization of proteins at the cell surface during mating. Here we discuss some recent findings that stress the role of lipid rafts as key players in yeast protein sorting and cell polarity.