Nature and timing of some sporulation-specific protein changes in Saccharomyces cerevisiae.

During meiosis and spore formulation in Saccharomyces cerevisiae, changes that occur in a/alpha diploids, but not in isogenic nonsporulating a/a diploids, have been detected in cellular polypeptides. These were found by the technique of prelabeling growing cells with 35SO4(2-) and suspending them in sulfur-free sporulation medium. Under the conditions used, about 400 polypeptides were detected by two-dimensional gel electrophoresis, and 45 were altered during sporulation; of these, 21 changes were specific to a/alpha strains. These alterations were mainly due to the appearance of new polypeptides or to marked increases in the concentrations of a few polypeptides produced during vegetative growth. They could have been due either to modifications of existing polypeptides present in growing cells or to de novo synthesis of new gene products. They occurred at characteristic times during sporulation; whereas the majority of changes took place early (within the first 6 h in sporulation conditions), there were several changes characterizing the later stages of sporulation. Ten of the 35SO4(2-)-labeled polypeptides were also labeled with 32P in the presence of [32P]orthophosphate; of these, three were previously found to be sporulation specific. One of these was phosphorylated at all stages of sporulation and was labeled when [32P]orthophosphate was added either during growth of the culture of 1 h after transfer to sporulation medium. Another was labeled in the same way by adding 32P at either time, so that by 7 h in sporulation medium it was phosphorylated, but was dephosphorylated by 24 h. The third sporulation-specific peptide was labeled in extracts prepared at 7 h in sporulation medium (but not at 24 h) when [32P]-orthophosphate was added during presporulation growth, but not when [32P]-orthophosphate was added 1 h after transfer of the culture to sporulation medium. This polypeptide appeared early during sporulation; it is probably phosphorylated as it appears and is dephosphorylated at some time between 7 h and 24 h of sporulation.     

Remarks on the modifications of cell wall during the sporulation of Saccharomyces cerevisiae Hansen (author's transl)]

Evolution of cell wall during sporulation was studied by means of scanning electron microscopy and by immunological techniques. Experiments were done simultaneously with a strain a/alpha able to sporulate and a strain alpha/alpha unable to sporulate. Under such conditions it was possible to clarify whether the changes observed were related to the sporulation or to the culture conditions. Cell wall structure modifications during sporulation were not obvious morphologically but have been revealed by immunological methods. During vegetative growth, antigenic sites of strains a/alpha and alpha/alpha were different. During incubation in the sporulation medium, antigenic structure of the cell wall was modified. Some antigenic sites seem to be specific of sporulation.     

Two-dimensional protein patterns during growth and sporulation in Saccharomyces cerevisiae.

Proteins synthesized by Saccharomyces cerevisiae in presporulation and sporulation media were compared by using sporulating (a/alpha) and nonsporulating (a/a and alpha/alpha) yeast strains. Total cellular proteins were labeled with [35S]methionine and analyzed by two-dimensional polyacrylamide gel electrophoresis. Autoradiograms and/or fluorograms showed some 700 spots per gel. Nine proteins were synthesized by a/alpha cells which were specific to vegetative, log-phase conditions. During incubation in sporulation medium, sporulating (a/alpha) cells synthesized 11 proteins not present in vegetatively growing cell. These same 11 proteins, however, were synthesized by nonsporulating (a/a and alpha/alpha) cells on sporulation medium as well. Nonsporulating diploids (a/a and alpha/alpha) were also examined with the electron microscope at various times during their incubation in sporulation medium. Certain cellular responses found to be unique to meiotic yeast cells in previous studies were exhibited by the nonsporulating controls. The degree to which all cell types (a/alpha, a/a, and alpha/alpha) were committed to sporulation was also determined by shifting cells from sporulation medium to vegetative medium. Some commitment to the meiotic pathway was observed in both the a/alpha and the a/a, alpha/alpha cells.     

Macromolecule Synthesis and Breakdown in Relation to Sporulation and Meiosis in Yeast

The time course of synthesis and breakdown of various macromolecules has been compared for sporulating (a/alpha) and nonsporulating (a/a and alpha/alpha) yeast cells transferred to potassium acetate sporulation medium. Both types of cells incorporate label into ribonucleic acid and protein. The gel electrophoresis patterns of proteins synthesized in sporulation medium are identical for sporulating and nonsporulating diploids; both are different from electropherograms of vegetative cells. Sporulating and nonsporulating strains differ with respect to deoxyribonucleic acid synthesis; no deoxyribonucleic acid is synthesized in the latter case, whereas the deoxyribonucleic acid complement is doubled in the former. Glycogen breakdown occurs only in sporulating strains. Breakdown of preexisting vegetative ribonucleic acid and protein molecules occurs much more extensively in sporulating than in nonsporulating cells. A timetable of these data is presented.     

Senescence in oat leaves: Changes in translatable mRNAs

Changes in translatable mRNA populations during the senescence of oat (Avena sativa L. cv. Victory) leaves were examined by analyzing the in vitro translation products of isolated RNA. Total RNA was isolated from oat leaves of 7-day-old seedlings, and also after these leaves were aged for different lengths of time under various conditions. Polypeptides from in vitro translations were separated by two-dimensional gel electrophoresis to estimate any changes in translatable mRNA populations associated with senescence. Corresponding leaf samples were monitored for loss of chlorophyll as a measure of the extent of senescence. The aging of excised leaves in the light for 4 days resulted in the disappearance or substantial quantitative decrease of a number of mRNA species, while only five new translatable mRNA species were produced. Three of these mRNAs were unique to aging of leaves under light. Two of these mRNA species were also produced during the early stages of senescence in attached leaves of seedlings grown under light. The translatable mRNA populations of leaves aged for 4 days either on intact seedlings or detached and kept in the light in the presence of kinetin were very similar. Aging of excised leaves in the dark on water for 24 h resulted in very extensive changes in translatable mRNA populations. Over thirty polypeptides disappeared or were substantially reduced in quantity, while about an equal number appeared de novo or were substantially increased in quantity. Aging of these leaves for an additional 24 or 48 h resulted in only a few additional changes in translatable mRNAs. The presence of kinetin during aging of excised leaves in the dark inhibited few of the numerous changes in mRNAs that occured during the first 24 h, but did inhibit most of the changes that occured after 48 or 72 h of aging in the dark. When leaves were first aged in the dark and then returned to light, most of the initial changes in translatable mRNAs expression were reversed. Such changes in mRNAs thus appear to be light-regulated and not necessarily associated with senescence.     

Transcriptional control of glucoamylase synthesis in vegetatively growing and sporulating Saccharomyces species.

Three unlinked, homologous genes, STA1, STA2, and STA3, encode the extracellular glycosylated glucoamylase isozymes I, II, and III, respectively, in Saccharomyces species. S. cerevisiae, which is sta0 (absence of functional STA genes in haploids), does carry a glucoamylase gene, delta sta, expressed only during sporulation (W. J. Colonna and P. T. Magee, J. Bacteriol. 134:844-853, 1978; I. Yamashita and S. Fukui, Mol. Cell. Biol. 5:3069-3073, 1985). In this study we examined some of the physiological and genetic factors that affect glucoamylase expression. It was found that STA2 strains grown in synthetic medium produce glucoamylase only in the presence of either Maltrin M365 (a mixture of maltooligosaccharides) or starch. Maximal levels of glucoamylase activity were found in cells grown in rich medium supplemented with glycerol plus ethanol, starch, or Maltrin. When various sugars served as carbon sources they all supported glucoamylase synthesis, although at reduced levels. In any given growth medium glucoamylase isozyme II synthesis was modulated by functionality of the mitochondria. Synthesis of glucoamylase is continuous throughout the growth phases, with maximal secretion taking place in the early stationary phase. In the various regimens, the differences in enzyme accumulation are accounted for by differences in the levels of glucoamylase mRNA. Both glucoamylase mRNA and enzyme activity were drastically and coordinately inhibited in MATa/MAT alpha diploids and by the presence of the regulatory gene STA10. Both effects were partially overcome when the STA2 gene was present on a multicopy plasmid. The STA2 mRNA and glucoamylase were coinduced in sporulating STA2/STA2 diploids. A smaller, coinduced RNA species was also detected by Northern blotting with a STA2 probe. The same mRNA species was detected in sporulating sta0 diploids and is likely to encode the sporulation-specific glucoamylase.     

Synthesis of beta-glucanases during sporulation in Saccharomyces cerevisiae: formation of a new, sporulation-specific 1,3-beta-glucanase.

A biphasic synthesis of 1,3-beta-glucanase occurred when cells of Saccharomyces cerevisiae AP-1 (a/alpha) were incubated in sporulation medium. The capacity to degrade laminarin increased very slowly during the first 7 h but at a much faster rate thereafter. Changes occurring during the first period were not sporulation specific since the moderate increase in activity against laminarin was insensitive to glutamine and hydroxyurea and also took place in the nonsporulating strain S. cerevisiae AP-1 (alpha/alpha). However, the changes taking place after 7 h must be included in the group of sporulation-specific events since they were inhibited by glucose, glutamine, and hydroxyurea and did not occur in the nonsporulating diploid. Consequently, only when the cells had been incubated for at least 7 h in sporulation medium did full induction of activity against laminarin take place upon shift to a medium which favored vegetative growth. Changes in the relative proportions of the vegetative glucanases, namely, endo- and exo-1,3-beta-glucanase, and the formation of a new sporulation-specific 1,3-beta-glucanase account for the observed events and are the consequence of the expression of the sporulation program.     

Bisexual Mating Behavior in a Diploid of SACCHAROMYCES CEREVISIAE: Evidence for Genetically Controlled Non-Random Chromosome Loss during Vegetative Growth

A diploid strain of Saccharomyces cerevisiae has been isolated which exhabits bisexual mating behavior. The strain mates with either a or alpha strains with a relative mating efficiency of 1 to 2%. The efficiency of mating is correlated with the frequency with which subclones of this strain revert to a single mating type. Crosses of the bisexual diploid with a/a or alpha/alpha diploids yield bisexual segregants with a frequency of approximately 3%. Analysis of the segregation of the mating type alleles and other markers on chromosome III indicates that the primary event which leads to the bisexual phenotype is the loss of one homolog of chromosome III during vegetative growth to produce a monosomic (2n-1) diploid. Evidence is presented that the loss of chromosome III and possibly of other chromosomes during vegetative growth is affected by a recessive nuclear gene-her (hermaphrodite)-which is not closely linked to the mating type locus.     

Developmental changes in messenger RNAs and protein synthesis in Dictyostelium discoideum

The pattern of proteins synthesized at different stages of differentiation of the slime mold Dictyostelium discoideum was studied by two-dimensional polyacrylamide gel electrophoresis. Of the approximately 400 proteins detected during growth and/or development, synthesis of most continued throughout differentiation. Approximately 100 proteins show changes in their relative rates of synthesis. During the transition from growth to interphase, the major change observed is reduction in the relative rate of synthesis of about 8 proteins. Few further changes are noticeable until the stage of late cell aggregation, when production of about 40 new proteins begins and synthesis of about 10 is reduced considerably. Thereafter, there are few changes in the pattern of protein synthesis. Major changes in the relative rates of synthesis of a number of proteins are found during culmination, but few culmination-specific proteins are observed. In an attempt to understand the molecular basis for these changes, mRNA was isolated from different stages of differentiation and translated in an improved wheat germ cell-free system; the products were resolved on two-dimensional gels. The ratio of total translatable mRNA to total cellular RNA is constant throughout growth and differentiation. Messenger RNAs for many, but not all, developmentally regulated proteins can be identified by translation in cell-free systems. Actin is the major protein synthesized by vegetative cells and by early differentiating cells. The threefold increase in the relative rate of synthesis of actin during the first 2 hr of differentiation and the decrease which occurs thereafter can be accounted for by parallel changes in the amount of translatable actin mRNA. Most of the changes in the pattern of protein synthesis which occur during the late aggregation and culmination stages can also be accounted for by parallel increases or decreases in the amounts of translatable mRNAs encoding these proteins. It is concluded that mRNAs do not appear in a translatable form before synthesis of the homologous protein begins, and that regulation of protein synthesis during development is primarily at the levels of production or destruction of mRNA.     

Proteinase activities of Saccharomyces cerevisiae during sporulation.

Sporulation in Saccharomyces cerevisiae occurs in the absence of a exogenous nitrogen source. Thus, the internal amino acid pool and the supply of nitrogen compounds from protein and nucleic acid turnover must be sufficient for new protein synthesis. Since sporulation involves an increased rate of protein turnover, an investigation was conducted of the changes in the specific activity of various proteinases. A minimum of 30% of the vegetative proteins was turned over during the course of sporulation. There was a 10- to 25-fold increase in specific activity of various proteinases, with a maximum activity around 20 h after transfer into the sporulation medium. The increase in activities was due to de novo synthesis since inhibition of protein synthesis by cycloheximide blocks both an increase in proteinase activities and sporulation. There was no increase observed in proteinase activities of nonsporogenic cultures (a and alpha/alpha strains) inoculated into the sporulation medium, suggesting that the increase in proteinase activities is "sporulation specific" and not a consequence of step-down conditions. The elution patterns through diethylaminoethyl-Sephadex chromatography of various proteinases extracted from T0 and T18 cells were similar, and no new species was observed.     

Switching in levels of translatable mRNAs for enolase isozymes during development of chicken skeletal muscle

Developmental changes in the levels of translatable mRNAs for alpha and beta enolase subunits in chicken muscle were determined using the rabbit reticulocyte cell-free translation system. The level of translatable alpha mRNA was decreased gradually during the development of the muscle. On the contrary, the levels of translatable beta mRNA was not detected at early embryonic stage, but increased dramatically after hatching. These changes were closely correlated with those of the corresponding enzyme activities. The results suggest that the developmental changes in the activities of alpha alpha and beta beta enolases in chicken muscle arise as the result of changes in the amount of corresponding mRNAs.     

GAS2 and GAS4, a pair of developmentally regulated genes required for spore wall assembly in Saccharomyces cerevisiae

The GAS multigene family of Saccharomyces cerevisiae is composed of five paralogs (GAS1 to GAS5). GAS1 is the only one of these genes that has been characterized to date. It encodes a glycosylphosphatidylinositol-anchored protein functioning as a beta(1,3)-glucan elongase and required for proper cell wall assembly during vegetative growth. In this study, we characterize the roles of the GAS2 and GAS4 genes. These genes are expressed exclusively during sporulation. Their mRNA levels showed a peak at 7 h from induction of sporulation and then decreased. Gas2 and Gas4 proteins were detected and reached maximum levels between 8 and 10 h from induction of sporulation, a time roughly coincident with spore wall assembly. The double null gas2 gas4 diploid mutant showed a severe reduction in the efficiency of sporulation, an increased permeability of the spores to exogenous substances, and production of inviable spores, whereas the single gas2 and gas4 null diploids were similar to the parental strain. An analysis of spore ultrastructure indicated that the loss of Gas2 and Gas4 proteins affected the proper attachment of the glucan to the chitosan layer, probably as a consequence of the lack of coherence of the glucan layer. The ectopic expression of GAS2 and GAS4 genes in a gas1 null mutant revealed that these proteins are redundant versions of Gas1p specialized to function in a compartment at a pH value close to neutral.     

Regulated expression of the prolactin gene in rat pituitary tumor cells

Prolactin (PRL) gene expression in three strains of GH cells (rat pituitary tumor cells) has been quantitated by measurement of: (a) intracellular and extracellular PRL, (b) cytoplasmic translatable PRL-specific mRNA (mRNAPRL), and (c) molecular hybridization of cytoplasmic poly(A) RNA to cDNAPRL (DNA complementary to mRNAPRL). Three GH cell lines utilized in this investigation were a PRL-producing (PRL+) strain, GH4C1, a PRL nonproducing 5-bromo-deoxyuridine resistnat (PRL- BrdUrdr) strain, F1BGH12C1, and a new strain, 928-9b, derived by fusion of PRL+ cells with a nuclear monolayer of the PRL-, BrdUrdr GH cell strain. PRL production is a characteristic of 928-9b cells, but the level of PRL production (2-4 micrograms/mg protein/24 h) is much lower than that of the PRL+ strain, GH4C1 (15-25 micrograms/mg protein/24 h). Levels of cytoplasmic translatable mRNAPRL and cytoplasmic PRL-RNA sequences quantitated with a cDNAPRL probe were also much lower in 928-9b as compared to the PRL+ parent. PRL-RNA sequences could not be detected in the PRL- strain. Thyrotopin-releasing hormone (TRH) stimulates PRL synthesis about threefold and inhibit a growth hormone (GH) synthesis 72% in the PRL+ strain. TRH has no effect on the synthesis of either PRL or GH in the 928-9b strain, although TRH receptors could be detected in these cells. Stimulation of PRL synthesis in the PRL+ strain by TRH could be correlated with increases in levels of cytoplasmic translatable mRNAPRL and increases in cytoplasmic PRL-RNA sequences. These results demonstrate that the graded expression of the PRL gene at the basal level, and in response to TRH, is caused by the regulated production of specific mRNA, i.e., mRNAPRL in these three GH cell strains.     

The genetic control of cell growth and development in yeast Saccharomyces cerevisiae. Disturbed sporulation in diploids with decreased activity of the Ras/cAMP signal transduction pathway

Seven haploid strains (four with the MAT alpha mating type and three with the MATa mating type) were selected from the Peterhof genetic collection of yeast. Previous phenotypic analysis assigned six of these strains to a physiological group of strains with a lower activity of the Ras/cAMP signal transduction pathway. The haploids were crossed, and the resulting 12 diploids showed higher glycogen accumulation, tolerance to heat shock and nitrogen starvation, and sporulation in complete media. Ten of the diploids expressed the hypersporulation phenotype (higher sporulation efficiency). The phenotypic characters of these ten diploids suggested a reduced activity of the Ras/cAMP pathway. All 12 diploids were tested for sporulation and production of two groups of asci (those with one or two spores and those with three or four spores) as dependent on culture conditions (21, 30, or 34 degrees C; standard sporulation medium or a complete medium containing potassium acetate or glycerol in place of glucose). Sporulation proved to depend on temperature and medium composition. The results are collated with the data on yeast phenotypes associated with a lower activity of the Ras/cAMP signal transduction pathway.     

Clostridium perfringens type A: in vitro system for sporulation and enterotoxin synthesis.

Polysomes were isolated from an enterotoxigenic strain of Clostridium perfringens during vegetative growth and at 1-h intervals after transfer into Duncan-Strong sporulation medium. During vegetative growth, about 67% of the ribosomes were in polysomal complexes. This proportion decreased to about 20% during the first 2 h in sporulation medium and then gradually increased to a maximum of 45% at 6 h. Ribosomes isolated from cells in vegetative or in sporulation phase could equally translate vegetative, sporulation, and natural viral R17 messenger ribonucleic acid with either vegetative or sporulation initiation factors. When polysomes were allowed to complete their nascent chains with labeled amino acids in vitro, most of the polypeptides synthesized by the vegetative phase and by the sporulation phase polysomes appeared to be identical. There were, however, notable differences upon further investigation. Specifically, when antiserum against the enterotoxin was reacted with the completed polypeptides, no counts were precipitated from the vegetative products. On the other hand, up to 12% of the total labeled protein was precipitated from the products obtained with the sporulation phase polysomes. Upon electrophoresis on sodium dodecyl sulfate, the putative enterotoxin synthesized in vitro ran as a major band with a molecular weight of 35,000, and as two minor bands with molecular weights of 17,000 and 52,000, respectively.