Metabolite compartmentation in Saccharomyces cerevisiae.

Uninduced cultures of Saccharomyces cerevisiae exhibit high basal levels of allantoinase, allantoicase, and ureidoglycolate hydrolase, the enzymes responsible for degrading allantoin to urea. As a result, these activities increase only 4- to 8-fold upon induction, whereas the urea-degrading enzymes, urea carboxylase and allophanate hydrolase, have very low basal levels and routinely increase 30-fold on induction. Differences in the inducibility of these five enzymes were somewhat surprising because they are all part of the same pathway and have the same inducer, allophanate. Our current studies reconcile these observations. S. cerevisiae normally contained up to 1 mM allantoin sequestered in a cellular organelle, most likely the vacuole. Separation of the large amounts of allantoin and the enzymes that degrade it provide the cell with an efficient nitrogen reserve. On starvation, sequestered allantoin likely becomes accessible to these degradative enzymes. Because they are already present at high levels, the fact that their inducer is considerably removed from the input allantoin is of little consequence. This suggests that at times metabolite compartmentation may play an equal role with enzyme induction in the regulation of allantoin metabolism. Metabolism of arginine, another sequestered metabolite, must be controlled both by induction of arginase and compartmentation because arginine serves both as a reserve nitrogen source and a precursor of protein synthesis. The latter function precludes the existence of high basal levels of arginase.     

Addition of basic amino acids prevents G-1 arrest of nitrogen-starved cultures of Saccharomyces cerevisiae.

Arginase-minus mutants of Saccharomyces cerevisiae were arrested in growth and accumulated at the unbudded G-1 stage of the cell cycle when starved for nitrogen. If, however, arginine was added to the culture medium at the time of starvation, growth ceased but the cells did not collect at the unbudded G-1 stage. We suggest that arginine addition prevented the cells from collecting at the G-1 stage by starving them for histidine and lysine, thereby inhibiting synthesis of proteins needed to complete the cell cycle.     

Cell size specific binding of the fluorescent dye calcofluor to budding yeast

The yeast Saccharomyces cerevisiae cell surface outside of the bud scars displayed an increasing fluorescence intensity with increasing cell size (volume), where fluorescence was due to irreversible binding of the fluorescent dye calcofluor. The increase in fluorescence intensity appeared to be due to an increase in the density of fluorescence per unit surface area of the cell. Exposure time measurements from a photomicroscope were used to quantitate fluorescence intensity on individual cells. The cell size dependent increase in fluorescence intensity was displayed by unbudded cells from stationary phase populations, and unbudded and parent cells from exponentially growing populations. Abnormally large cells generated during the arrest of cell division with alpha-factor or restrictive temperature for cdc3, 8, 13, 24, and 28 cell division cycle mutants, displayed significantly greater fluorescence intensity compared to the smaller cells generated during the arrest of division for cdc25, 33, and 35 mutant strains. Fluorescence intensity on newly emerging buds was broadly dependent on both the size of the bud, and the size of the parent cells on which the buds were growing.     

Basic amino acid inhibition of cell division and macromolecular synthesis in Saccharomyces cerevisiae.

Growth of Saccharomyces cerevisiae on poor nitrogen sources such as allantoin or proline was totally inhibited by addition of a non-degradable basic amino acid to the medium. Cells treated with lysine contained greatly reduced quantities of histidine and arginine. Conversely, lysine and histidine were severely reduced in arginase-deficient cells treated with arginine. When all three basic amino acids were present in the culture medium, growth was normal suggesting that synthesis of all three basic amino acids was decreased by an excess of any one of them. Inhibition of growth was accompanied by a fivefold increase in the observed ratio of budded to unbudded cells. These morphological changes suggested that DNA synthesis was inhibited. Consistent with this suggestion, addition of a basic amino acid to the culture medium substantially reduced the ability of the cells to incorporate [14C]uracil into alkali-resistant, trichloroacetic acid-precipitable material. RNA and protein synthesis, although decreased, were less sensitive to the effects of such additions.     

Unequal division in Saccharomyces cerevisiae and its implications for the control of cell division

The budding yeast, Saccharomyces cerevisiae, was grown exponentially at different rates in the presence of growth rate-limiting concentrations of a protein synthesis inhibitor, cycloheximide. The volumes of the parent cell and the bud were determined as were the intervals of the cell cycle devoted to the unbudded and budded periods. We found that S. cerevisiae cells divide unequally. The daughter cell (the cell produced at division by the bud of the previous cycle) is smaller and has a longer subsequent cell cycle than the parent cell which produced it. During the budded period most of the volume increase occurs in the bud and very little in the parent cell, while during the unbudded period both the daughter and the parent cell increase significantly in volume. The length of the budded interval of the cell cycle varies little as a function of population doubling time; the unbudded interval of the parent cell varies moderately; and the unbudded interval for the daughter cell varies greatly (in the latter case an increase of 100 min in population doubling time results in an increase of 124 min in the daughter cell's unbudded interval). All of the increase in the unbudded period occurs in that interval of G1 that precedes the point of cell cycle arrest by the S. cerevisiae alpha-mating factor. These results are qualitatively consistent with and support the model for the coordination of growth and division (Johnston, G. C., J. R. Pringle, and L. H. Hartwell. 1977. Exp. Cell. Res. 105:79-98.) This model states that growth and not the events of the DNA division cycle are rate limiting for cellular proliferation and that the attainment of a critical cell size is a necessary prerequisite for the "start" event in the DNA-division cycle, the event that requires the cdc 28 gene product, is inhibited by mating factor and results in duplication of the spindle pole body.     

Automated spectrophotometric assay for cell division regulation in yeast

A spectrophotometric assay is presented for monitoring the regulation of cell division by the polypeptide alpha-factor in cultures of living cells of Saccharomyces cerevisiae yeast. This assay is simple, automated, and may have wider application in the study of other eucaryotic cells that do not require anchorage for cell growth. The kinetics of absorbance change were monitored continuously over time in yeast cell cultures that were mixed and aerated in cuvettes fitted with top-loading propeller stirrers. The absorbance doubling time. TD(Abs), was identical to the cell number doubling time in the absence of cell division arrest by alpha-factor. alpha-Factor lengthened the TD(Abs) during division arrest. At pH 5.8, 10(5) 381G cells/ml, the Khalf-maximal was 250 +/- 50 nM alpha-factor for the TD(Abs) increase during arrest, with a maximum increase of five-fold. After a period of time the TD(Abs) abruptly shortened. This is defined as the spectrophotometric recovery time (RTspec) and was compared to the time of recovery that is due to the reinitiation of cell division monitored by bud emergence (RTBE). RTBE occurred 40 +/- 5 min prior to RTspec when recovery was spontaneous or was artificially induced by the removal of alpha-factor (pH 5.8, 381G). The difference between RTBE and RTspec was independent of alpha-factor concentration between 0.05 and 1 microM and cell concentration between 1 and greater than or equal to 25 x 10(5) cells/ml (pH 5.8, 381G) but was both pH and cell strain dependent. At pH 5.8 and 2.7 the recovery from arrest occurred by inactivation of alpha-factor. The TD(Abs) increase during arrest appears to be due to an alpha-factor-induced inhibition of net cell mass increase, an effect that has not been reported previously. Evidence is presented that this process is also correlated with the formation of cell projections.     

GPA1Val-50 mutation in the mating-factor signaling pathway in Saccharomyces cerevisiae.

The GPA1 gene of Saccharomyces cerevisiae encodes a protein that is highly homologous to the alpha subunit of mammalian hetrotrimeric G proteins and is essential for haploid cell growth. A mutation of the GPA1 protein, GPA1Val-50, in which Gly-50 was replaced by valine, could complement the growth defect of a GPA1 disruption, gpal::HIS3. However, cells with gpa1::HIS3 expressing the GPA1Val-50 protein were supersensitive to alpha-factor in a short-term incubation but resumed growth after long-term incubation even after exposure to high concentrations of alpha-factor. The former phenotype associated with GPA1Val-50 is recessive, and the latter phenotype is dominant to GPA1+. The supersensitivity of GPA1Val-50 to alpha-factor was dependent on STE2 and STE4, which demonstrates that this GPA1Val-50-produced phenotype requires the mating-factor receptor and the beta subunit of the G protein. The double mutant of sst2-1 GPA1Val-50 recovered from division arrest, which suggested that SST2 is not required for recovery of the GPA1Val-50 mutant.     

Expression of the BAR1 gene in Saccharomyces cerevisiae: induction by the alpha mating pheromone of an activity associated with a secreted protein.

We have demonstrated and partially characterized the genetic control and pheromonal regulation of a soluble activity, produced only by mating-type a cells, that inhibits the action of the alpha mating pheromone, alpha-factor, on mating-type a cells. This activity was found to be associated with a heat-stable protein and to be secreted by MATa BAR1, mat alpha 2 BAR1, and mat alpha 1 mat alpha 2 BAR1 strains, but not by MAT alpha BAR1, MATa/MAT alpha BAR1, mat alpha 1 BAR1, or MATa barl strains, demonstrating that it is under the control of both the MAT alpha 2 and the BAR1 genes. Secretion of this activity was also found to be stimulated to as much as five times the basal level by exposure of the cells to alpha-factor. This stimulation was maximal after 6 h at a pheromone concentration of approximately 2 U/ml. An assay for this activity was developed by using a refined, quantitative assay for alpha-factor. The pheromone activity of samples added to wells in an agar plate was related to the size of the halo of growth inhibition produced in a lawn of mutant cells that are abnormally sensitive. The alpha-factor-inhibiting activity was related to a reduction of the halo size when active samples were added to the lawn. Although the assay for alpha-factor was found to be relatively insensitive to pH over a range of several units, the alpha-factor-inhibiting activity displayed a sharp pH optimum at approximately 6.5. The properties of this activity have important implications concerning the role of the BAR1 gene product in recovery of mating-type a cells from cell division arrest by alpha-factor.     

Identification and Characterization of a Mutation Affecting the Division Arrest Signaling of the Pheromone Response Pathway in Saccharomyces Cerevisiae

Mating pheromones, a- and alpha-factors, arrest the division of cells of opposite mating types, alpha and a cells, respectively. I have isolated a sterile mutant of Saccharomyces cerevisiae that is defective in division arrest in response to alpha-factor but not defective in morphological changes and agglutinin induction. The mutation was designated dac2 for division arrest control by mating pheromones. The dac2 mutation was closely linked to gal1 and was different from the previously identified cell type nonspecific sterile mutations (ste4, ste5, ste7, ste11, ste12, ste18 and dac1). Although dac2 cells had no phenotype in the absence of pheromones, they showed morphological alterations and divided continuously in the presence of pheromones. As a result, dac2 cells had a mating defect. The dac2 mutation could suppress the lethality caused by the disruption of the GPA1 gene (previously shown to encode a protein with similarity to the alpha subunit of mammalian G proteins). In addition, dac2 cells formed prezygotes with wild-type cells of opposite mating types, although they could not undergo cell fusion. These results suggest that the DAC2 product may control the signal for G-protein-mediated cell-cycle arrest and indicate that the synchronization of haploid yeast cell cycles by mating pheromones is essential for cell fusion during conjugation.     

Growth and the cell cycle of the yeast Saccharomyces cerevisiae. II. Relief of cell-cycle constraints allows accelerated cell divisions

For cells of the yeast Saccharomyces cerevisiae, conditions which limit S phase or nuclear division allow steady-state division kinetics without significant effects on growth. Such cells become unusually large. When large proliferating cells were released from any one of several conditions which slowed progress through the DNA-division sequence, they underwent a period of accelerated division with a cell cycle devoid of a G1 interval, as evidenced by low proportions of unbudded cells and shifted execution points for the 'start' cell cycle step. We interpret these results to mean that when released from conditions slowing the DNA-division sequence these large cells continue for several cell doublings to accumulate mass fast enough to eliminate the need for a G1 interval. The results support the conclusion that the yeast G1 interval is the for most part only an interval of growth.     

Kinetic evidence for a critical rate of protein synthesis in the Saccharomyces cerevisiae yeast cell cycle

The kinetics of cell cycle initiation were measured at pH 2.7 for cells that had been arrested at the "start" step of cell division with the polypeptide pheromone alpha-factor. Cell cycle initiation was induced by the removal of alpha-factor. The rate at which cells completed start was identical to the rate of subsequent bud emergence. After short times of prearrest with alpha-factor (e.g. 5.2 h), the kinetics of bud emergence were biphasic, indicative of two subpopulations of cells that differed by greater than 10-fold in their rates of cell cycle initiation. The subpopulation that exhibited a slow rate of cell cycle initiation is comprised of cells that resided in G1 prior to start at the time of removal of alpha-factor, whereas the subpopulation that initiated the cell cycle rapidly is comprised of cells that had reached and become blocked at start. A critical concentration of cycloheximide was found to reintroduce slow budding cells into a population of 100% fast budding cells, suggesting that the two subpopulations differ with respect to attainment of a critical rate of protein synthesis that is necessary for the performance of start. Cycloheximide and an increase in the time of prearrest with alpha-factor had opposite effects on both the partitioning of cells between the two subpopulations and the net rate of protein synthesis per cell, consistent with this conclusion. Cell cycle initiation by the subpopulation of fast budding cells required protein synthesis even though the critical rate of protein synthesis had been achieved during arrest. It is concluded that alpha-factor inhibits the synthesis of and/or inactivates specific proteins that are required for the performance of start, but alpha-factor does not prevent attainment of the critical rate of protein synthesis.     

Mutants of Saccharomyces cerevisiae unresponsive to cell division control by polypeptide mating hormone

Temperature-sensitive mutations that produce insensitivity to division arrest by alpha-factor, a mating pheromone, were isolated in an MATa strain of Saccharomyces cerevisiae and shown by complementation studies to difine eight genes. All of these mutations (designated ste) produce sterility at the restrictive temperature in MATa cells, and mutations in seven of the genes produce sterility in MAT alpha cells. In no case was the sterility associated with these mutations coorectible by including wild-type cells of the same mating type in the mating test nor did nay of the mutants inhibit mating of the wild-type cells; the defect appears to be intrinsic to the cell for mutations in each of the genes. Apparently, none of the mutants is defective exclusively in division arrest by alpha-factor, as the sterility of none is suppressed by a temperature-sensitive cdc 28 mutation (the latter imposes division arrest at the correct cell cycle stage for mating). The mutants were examined for features that are inducible in MATa cells by alpha-factor (agglutinin synthesis as well as division arrest) and for the characteristics that constitutively distinguish MATa from MAT alpha cells (a-factor production, alpha-factor destruction). ste2 Mutants are defective specifically in the two inducible properties, whereas ste4, 5, 7, 8, 9, 11, and 12 mutants are defective, to varying degrees, in constitutive as well as inducible aspects. Mutations in ste8 and 9 assume a polar budding pattern unlike either MATa or MAT alpha cells but characteristic of MATa/alpha cells. This study defines seven genes that function in two cell types (MATa and alpha) to control the differentiation of cell type and one gene, ste2, that functions exclusively in MATa cells to mediate responsiveness to polypeptide hormone.     

A sweet sensor for size-conscious bacteria

Bacteria, like eukaryotic cells, regulate their size by coordinating cell growth and division, growing faster and becoming larger when nutrients are more plentiful. Weart et al. (2007) now identify an enzyme in a glucolipid pathway that inhibits assembly of the key cell division protein FtsZ, but only during high nutrient conditions. Delaying cell division during rapid growth allows bacterial cells to become larger.     

Proteases and chaperones are the most abundant proteins in the parasitophorous vacuole of Plasmodium falciparum-infected erythrocytes

After invasion of erythrocytes, the human malaria parasite Plasmodium falciparum resides within a parasitophorous vacuole (PV) which forms an interface between the host cell cytosol and the parasite surface. This vacuole protects the parasite from potentially harmful substances, but allows access of essential nutrients to the parasite. Furthermore, the vacuole acts as a transit compartment for parasite proteins en route to the host cell cytoplasm. Recently we developed a strategy to biotin label soluble proteins of the PV. Here, we have paired this strategy with a high-throughput MALDI-TOF-MS analysis to identify 27 vacuolar proteins. These proteins fall into the following main classes: chaperones, proteases, and metabolic enzymes, consistent with the expected functions of the vacuole. These proteins are likely to be involved in several processes including nutrient acquisition from the host cytosol, protein sorting within the vacuole, and release of parasites at the end of the intraerythrocytic cycle.     

Induced synchrony in Cryptococcus neoformans after release from G2-arrest

Cryptococcus neoformans was grown first to OD 4 under moderate aeration, then diluted 2.5 times with fresh medium, and grown under limited aeration for 5 h. Oxygen concentration decreased from 5-6 mg l(-1) to 1.5 mg l(-1) 1 h after the shift to limited aeration, and remained at a similar level thereafter. In all the eleven strains examined the shift caused unbudded G(2)-arrest in more than half of the cells. In three strains more than 80% of the cells were arrested in unbudded G(2), and, therefore they were selected for synchrony experiments. After being shifted to extensive aeration again, the cells resumed growth by synchronous budding, followed by synchronous nuclear division. This method has turned out to be a good tool to prepare synchronized culture in C. neoformans, especially when a large amount of synchronized cells is needed. This is worthy of attention, since synchronous cultures after release from G(2)-arrest have not been reported yet in any yeast species.     

The SPA2 protein of yeast localizes to sites of cell growth

A yeast gene, SPA2, was isolated with human anti-spindle pole autoantibodies. The SPA2 gene was fused to the Escherichia coli trpE gene, and polyclonal antibodies were prepared to the fusion protein. Immunofluorescence experiments indicate that the SPA2 gene product has a sharply polarized distribution in yeast cells. In budded cells the SPA2 protein is present at the tip of the bud; in unbudded cells, it is localized to one edge of the cell. When a-cells are induced to form schmoos with alpha-factor, the SPA2 protein is found at the tip of the schmoo. These areas of SPA2 localization correspond to cellular sites expected to be involved in bud formation and/or cell growth. The SPA2 antigen is present in a-cells, alpha-cells, and a/alpha-diploid cells, but is absent in mutant cells in which the SPA2 gene has been disrupted. spa2 mutant cells are viable, but display defects in the direction and control of cell growth. Compared to wild-type cells, spa2 mutant cells have slightly altered budding patterns. Entry into stationary phase is impaired for spa2 mutants, and mutants with one particular allele, spa2-7, form multiple buds under nutrient-limiting conditions. Thus, SPA2 is a newly identified yeast gene that is involved in the direction and control of cell division, and whose gene product localizes to the site of cell growth.     

Yeast-phase cell cycle of the polymorphic fungus Wangiella dermatitidis.

The yeast-phase cell cycle of Wangiella dermatitidis was studied using flow microfluorimetry and the deoxyribonucleic acid (DNA) synthesis inhibitor hydroxyurea (HU). Exposure of exponential-phase yeastlike cells to 0.1 M HU for 3 to 6 h resulted in the arrest of the cells in DNA synthesis and produced a nearly homogeneous population of unbudded cells. Treatment of the yeast-phase cells with HU for 9 h or longer resulted in the accumulation of the cells predominantly as budded forms having either a single nucleus in the mother cell or a single nucleus arrested in the isthmus between the mother cell and the daughter bud. Exposure of unbudded stationary-phase cells to 0.1 M HU resulted in the accumulation of the cells in the same phenotypes. Analysis by flow microfluorimetry and cell counts of HU-inhibited mithramycin-stained cells indicated that the eventual progress of HU-inhibited cells from unbudded to the two budded forms was due to the limited continuation of the growth sequence of the cell cycle even in the absence of DNA synthesis, nuclear division, and in some cases nuclear migration. On the basis of these observations and the results of flow microfluorimetric analysis of exponential-phase cells, a map of the yeast-phase cell cycle was constructed. The cycle appears to consist of two independent sequences of events, a budding growth sequence and a DNA division sequence. The nuclear division cycle of yeast-phase cells growing exponentially with a 4.5-h generation time is composed of a G1 interval of 148 min, as S phase of 16 min, and a G2 plus M interval of 107 min.     

Alpha-factor inhibition of the rate of cell passage through the "start" step of cell division in Saccharomyces cerevisiae yeast: estimation of the division delay per alpha-factor.receptor complex

A highly sensitive, kinetically unambiguous assay for alpha-factor-induced delay of cell passage through the "start" step of cell division in yeast is presented. The assay employs perfusion with periodic microscopy to monitor the bud emergence kinetics on the 20% of cells within an exponentially growing population which exist prior to the alpha-factor execution point of start. The t1/2 for cell passage through start by this population of cells is 31 min in the absence of alpha-factor. The inhibition constant, KI, represents the alpha-factor concentration which produces a 50% inhibition of this rate and is equal to 2 X 10(-10) M. A second assay for maximal cell division arrest by alpha-factor on whole populations of cells is presented. This assay shows a maximum cell division arrest time of 125 +/- 5 h at saturating alpha-factor, and a K50 (that is, an alpha-factor concentration which produces a half-maximal response) of 2.5 X 10(-8) M. Both assays were performed in the effective absence of alpha-factor inactivation. Values of the dissociation constant KD and total number of receptors per cell which specifically mediate cell division arrest or delay were estimated to be 2.5 X 10(-8) M and 10(4), respectively. These estimates, along with the quantitative dose-response data for division arrest which are presented here, are consistent with each receptor.alpha-factor complex which is present on the cell at equilibrium producing a 43 +/- 10 s delay of cell passage through start. Surprisingly, this number is constant within twofold over the entire range of cellular division arrest responses to alpha-factor, that is, from a 1.9-fold inhibition of the rate of cell passage through start at 0.17 nM alpha-factor to a 125 +/- 5 h maximum arrest at saturating alpha-factor concentrations of greater than 170 nM. The possible significance of this observation toward the mechanism of alpha-factor-induced cell division arrest is discussed.