Germination of yeast spores lacking mitochondrial deoxyribonucleic acid

Mutations in the Atp1p and Atp3p subunits of yeast ATP synthase differentially affect respiration and fermentation in Saccharomyces cerevisiae

ATP1-111, a suppressor of the slow-growth phenotype of yme1Delta lacking mitochondrial DNA is due to the substitution of phenylalanine for valine at position 111 of the alpha-subunit of mitochondrial ATP synthase (Atp1p in yeast). The suppressing activity of ATP1-111 requires intact beta (Atp2p) and gamma (Atp3p) subunits of mitochondrial ATP synthase, but not the stator stalk subunits b (Atp4p) and OSCP (Atp5p). ATP1-111 and other similarly suppressing mutations in ATP1 and ATP3 increase the growth rate of wild-type strains lacking mitochondrial DNA. These suppressing mutations decrease the growth rate of yeast containing an intact mitochondrial chromosome on media requiring oxidative phosphorylation, but not when grown on fermentable media. Measurement of chronological aging of yeast in culture reveals that ATP1 and ATP3 suppressor alleles in strains that contain mitochondrial DNA are longer lived than the isogenic wild-type strain. In contrast, the chronological life span of yeast cells lacking mitochondrial DNA and containing these mutations is shorter than that of the isogenic wild-type strain. Spore viability of strains bearing ATP1-111 is reduced compared to wild type, although ATP1-111 enhances the survival of spores that lacked mitochondrial DNA.

The heterotrimeric G-protein GanB(alpha)-SfaD(beta)-GpgA(gamma) is a carbon source sensor involved in early cAMP-dependent germination in Aspergillus nidulans

The role of heterotrimeric G-proteins in cAMP-dependent germination of conidia was investigated in the filamentous ascomycete Aspergillus nidulans. We demonstrate that the G alpha-subunit GanB mediates a rapid and transient activation of cAMP synthesis in response to glucose during the early period of germination. Moreover, deletion of individual G-protein subunits resulted in defective trehalose mobilization and altered germination kinetics, indicating that GanB(alpha)-SfaD(beta)-GpgA(gamma) constitutes a functional heterotrimer and controls cAMP/PKA signaling in response to glucose as well as conidial germination. Further genetic analyses suggest that GanB plays a primary role in cAMP/PKA signaling, whereas the SfaD-GpgA (G betagamma) heterodimer is crucial for proper activation of GanB signaling sensitized by glucose. In addition, the RGS protein RgsA is also involved in regulation of the cAMP/PKA pathway and germination via attenuation of GanB signaling. Genetic epistatic analyses led us to conclude that all controls exerted by GanB(alpha)-SfaD(beta)-GpgA(gamma) on conidial germination are mediated through the cAMP/PKA pathway. Furthermore, GanB may function in sensing various carbon sources and subsequent activation of downstream signaling for germination.

Involvement of actin and polarisome in morphological change during spore germination of Saccharomyces cerevisiae

We studied the morphological changes of Saccharomyces cerevisiae ascospores during germination. Initiation of germination is followed by polarization of actin patches, maintaining their localization to the site of cell surface growth. Loss of polarisome components, Spa2p, Pea2p, Bud6p or Bni1p, results in depolarization of actin patches. Green fluorescent protein-fused polarisome components exhibit the polarized localization, implying that polarisome is involved in the polarized outgrowth during germination. At the late stage of germination, we found that actin patches temporally depolarize before bud emergence. The observation that loss of Cla4p extends the polarized growth period suggests that Cla4p is involved in the actin-depolization step. Actin polarization in the initial stage is accelerated by overexpression of Ras2p, whereas hyperpolarization is continuously observed by overexpression of Rho1p. Thus, yeast spore germination is a morphological event that is regulated by a number of factors implicated in mitotic bud morphogenesis.

Analysis of the meiotic role of the mitochondrial ribosomal proteins Mrps17 and Mrpl37 in Saccharomyces cerevisiae

Sporulation in the yeast Saccharomyces cerevisiae is a complex and tightly regulated pathway that involves the induction of a large number of genes. We have identified MRPS17 in a cDNA library enriched for sporulation-specific genes. Homology searches show that the first one-third of Mrps17 has strong sequence similarity to bacterial S17 proteins, suggesting that Mrps17 is a potential mitochondrial ribosomal protein. This is further supported by the fact that mrps17Delta cells are respiratory-deficient and that a Mrps17-GFP fusion localizes to the mitochondria. We have confirmed by Northern blot analysis that both MRPS17 and MRPL37 are strongly induced during the middle stages of sporulation and that this induction is dependent on the presence of a middle sporulation element (MSE) in the promoters of these genes. Interestingly, we found that Mrps17 and Mrpl37, but not other mitochondrial ribosomal proteins, accumulate during the middle stages of sporulation. These results suggest that Mrps17 and Mrpl37 may have additional meiosis-specific roles.

Importance of mitochondrial dynamics during meiosis and sporulation

Opposing fission and fusion events maintain the yeast mitochondrial network. Six proteins regulate these membrane dynamics during mitotic growth-Dnm1p, Mdv1p, and Fis1p mediate fission; Fzo1p, Mgm1p, and Ugo1p mediate fusion. Previous studies established that mitochondria fragment and rejoin at distinct stages during meiosis and sporulation, suggesting that mitochondrial fission and fusion are required during this process. Here we report that strains defective for mitochondrial fission alone, or both fission and fusion, complete meiosis and sporulation. However, visualization of mitochondria in sporulating cultures reveals morphological defects associated with the loss of fusion and/or fission proteins. Specifically, mitochondria collapse to one side of the cell and fail to fragment during presporulation. In addition, mitochondria are not inherited equally by newly formed spores, and mitochondrial DNA nucleoid segregation defects give rise to spores lacking nucleoids. This nucleoid inheritance defect is correlated with an increase in petite spore colonies. Unexpectedly, mitochondria fragment in mature tetrads lacking fission proteins. The latter finding suggests either that novel fission machinery operates during sporulation or that mechanical forces generate the mitochondrial fragments observed in mature spores. These results provide evidence of fitness defects caused by fission mutations and reveal new phenotypes associated with fission and fusion mutations.

Yeast spore germination: a requirement for Ras protein activity during re-entry into the cell cycle

Saccharomyces cerevisiae spore germination is a process in which quiescent, non-dividing spores become competent for mitotic cell division. Using a novel assay for spore uncoating, we found that spore germination was a multi-step process whose nutritional requirements differed from those for mitotic division. Although both processes were controlled by nutrient availability, efficient spore germination occurred in conditions that did not support cell division. In addition, germination did not require many key regulators of cell cycle progression including the cyclin-dependent kinase, Cdc28p. However, two processes essential for cell growth, protein synthesis and signaling through the Ras protein pathway, were required for spore germination. Moreover, increasing Ras protein activity in spores resulted in an accelerated rate of germination and suggested that activation of the Ras pathway was rate-limiting for entry into the germination program. An early step in germination, commitment, was identified as the point at which spores became irreversibly destined to complete the uncoating process even if the original stimulus for germination was removed. Spore commitment to germination required protein synthesis and Ras protein activity; in contrast, post-commitment events did not require ongoing protein synthesis. Altogether, these data suggested a model for Ras function during transitions between periods of quiescence and cell cycle progression.

Germination of Saccharomyces cerevisiae ascospores without trehalose mobilization as revealed by in vivo 13C nuclear magnetic resonance spectroscopy

Saccharomyces cerevisiae ascospores germinate in the presence of acetate without any detectable trehalose degradation, as revealed by high-resolution nuclear magnetic resonance spectroscopy and by a standard colorimetric assay. The results presented here substantiate the hypothesis that in S. cerevisiae trehalose supplies energy during dormancy of the spores and not during the germination process.

Germination conditions that require mitochondrial function in Saccharomyces cerevisiae: utilization of acetate and galactose

Ascospores of Saccharomyces cerevisiae inherited at least one functioning mitochondrion as shown by their ability to germinate on nonfermentable carbon sources. After transfer to germination medium, the optical density of the culture at 600 nm decreased (phase-dark), reaching a minimum within 60 min in the presence of glucose and within 180 min after transfer to acetate medium; thereafter, the optical density increased. Budding cells first appeared 90 min after transfer to glucose and 150 min after transfer to acetate. Augmentation of respiratory components, respiratory activity, and macromolecular synthesis (except for DNA synthesis) started at about the same time on glucose and on acetate, although the highest values for all these processes were reached in the presence of glucose. Mitochondrial inhibitors which affected germination on acetate did not arrest germination on glucose. However, mitochondrial activity was required for germination on galactose in a strain carrying the mutated allele imp1 of the nucleomitochondrion-connecting gene IMP1.

Temperature-sensitive lethal mutations on yeast chromosome I appear to define only a small number of genes

A method was developed for isolating large numbers of mutations on chromosome I of the yeast Saccharomyces cerevisiae. A strain monosomic for chromosome I (i.e., haploid for chromosome I and diploid for all other chromosomes) was mutagenized with either ethyl methanesulfonate or N-methyl-N'-nitro-N-nitrosoguanidine and screened for temperature-sensitive (Ts-) mutants capable of growth on rich, glucose-containing medium at 25 degrees but not at 37 degrees. Recessive mutations induced on chromosome I are expressed whereas those on the diploid chromosomes are usually not expressed because of the presence of wild-type alleles on the homologous chromosomes. Dominant ts mutations on all chromosomes should also be expressed, but these appeared rarely.--Of the 41 ts mutations analyzed, 32 mapped on chromosome I. These 32 mutations fell into only three complementation groups, which proved to be the previously described genes CDC15, CDC24 and PYK1 (or CDC19). We recovered 16 or 17 independent mutations in CDC15, 12 independent mutations in CDC24 and three independent mutations in PYK1. A fourth gene on chromosome I, MAK16, is known to be capable of giving rise to a ts-lethal allele, but we recovered no mutations in this gene. The remaining nine mutations isolated using the monosomic strain appeared not to map on chromosome I and were apparently expressed in the original mutants because they had become homozygous or hemizygous by mitotic recombination or chromosome loss.--The available information about the size of chromosome I suggests that it should contain approximately 60-100 genes. However, our isolation in the monosomic strain of multiple, independent alleles of just three genes suggests that only a small proportion of the genes on chromosome I is easily mutable to give a Ts--lethal phenotype.--During these studies, we located CDC24 on chromosome I and determined that it is centromere distal to PYK1 on the left arm of the chromosome.

Stimulation of yeast ascospore germination and outgrowth by S-adenosylmethionine

The supplementation of S-adenosylmethionine (SAM) to germination medium stimulated the accumulation of [14C]uracil from the medium into germinating cells, as well as its incorporation into ribonucleic acid during germination and outgrowth of ascospores of Saccharomyces cerevisiae. In addition to uracil, the accumulation of leucine, cytosine, serine, and methionine was also stimulated by the extracellular addition of this sulfonium compound. The SAM-stimulatory effect was dose dependent; half-maximal stimulation was observed at about 50 muM. The effect exerted by SAM supplementation appeared to be specific for SAM and for germination and outgrowth. In the absence of SAM biosynthesis (in the presence of cycloleucine), spores were inhibited in their ability to accumulate label, whereas the supplementation of SAM completely reversed the cycloleucine-induced inhibition of accumulation. In addition to accumulation and incorporation, the kinetics of bud formation during outgrowth were also stimulated by exogenous SAM. The stimulation of budding by SAM was amplified in an ethionine-resistant strain. These observations suggest that SAM may be essential for the initiation of cell division during the breaking of spore dormancy.

Polyamine biosynthesis during germination of yeast ascospores

The role of the diamine putrescine during germination and outgrowth of ascospores of Saccharomyces cerevisiae was examined. Ornithine decarboxylase activity increased and declined rapidly during germination and outgrowth; peak activity was attained after the cells had proceeded through the G1 interval of the cell cycle, whereas minimal activity was present at the completion of the first cell division. alpha-Methylornithine inhibited both ornithine decarboxylase activity and the in vivo accumulation of putrescine. In the presence of alpha-methylornithireak dormancy and proceed through one cell division. Subsequent cellular growth, however, was retarded but not completely inhibited. The supplementation of Methylglyoxal bis(guanylhydrazone) to sporulation medium greatly inhibited this sexual process. These data suggest that the synthesis of putrescine is not required for the breaking of spore dormancy, but that polyamine biosynthesis may be essential for meiosis and sporulation.

Relationship between polyamines and macromolecules in germinating yeast ascospores

The accumulation of spermidine and/or spermine was not necessary for normal macromolecule biosynthesis or germination and outgrowth of Saccharomyces cerevisiae spores.

Respiratory competence of Dictyostelium discoideum spores

Analysis of the respiratory chain of spores of Dictyostelium discoideum, which lack a cyanide-sensitive respiration, indicated that cytochromes a-a3, b, and c-c1 are present at levels identical to those found in the vegetative amoebae. The specific activities of enzymes of both the respiratory chain and the citric acid cycle in the 600 x g supernatant fraction of sonically treated spores were at least as high as in similar preparations of amoebae. The activities of glutamic dehydrogenase and oligomycin-sensitive adenosine triphosphatase were reduced in the spores 30 and 56%, respectively. Intact spores appeared to lack a cyanide-sensitive respiration as a result of inadequate quantities of respiratory substrate and, more importantly, as a result of a lack of the cofactor nicotinamide adenine dinucleotide. The emergence phase of spore germination was sensitive to the antibiotic chloramphenicol, which is a specific inhibitor of mitochondrial protein synthesis. It is concluded that germination requires the early synthesis of oxidized nicotinamide adenine dinucleotide and generation of respiratory substrates and one or more mitochondrially synthesized proteins.

Function of S-adenosylmethionine in germinating yeast ascospores

Germination and outgrowth of ascospores of Saccharomyces cerevisiae 4579 require both methionine and adenine, whereas leucine is only required for outgrowth. The methionine requirement may be satisfied by S-adenosylmethionine, but this sulfonium compound will not substitute for adenine. Between 30 and 70 min of protein synthesis is initially required for the completion of germination in strain 4579. The inhibition of S-adenosylmethionine synthetase by trifluoromethionine prevents both germination and protein synthesis. During the initial stages of germination, the S-adenosylmethionine synthetase, S-adenosylmethionine decarboxylase, and transfer ribonucleic acid methyltransferases increased significantly, indicating that polyamines and/or the methylation of transfer ribonucleic acid are required for the initiation of germination.

Control of enzyme synthesis and stability during sporulation in Saccharomyces cerevisiae

Studies were undertaken to understand the control of synthesis, stability and modification of UDP galactose epimerase and DNA-dependent RNA polymerase during sporulation of Saccharomyces cerevisiae. When a pre-induced culture of an inducible strain (wild type) is transferred to sporulation medium, the epimerase is inactivated to an undetectable level within 16 hours. Surprisingly, the addition of cycloheximide, a protein synthesis inhibitor, during sporulation stabilizes the epimerase activity. However, in a constitutive strain, the epimerase continues to be synthesized de novo during sporulation. Since the enzyme is synthesized during both vegatative growth and sporulation constitutively, the controls for synthesis of epimerase must be similar under these physiologically different conditions. After chromatography on DEAE Sephadex, there is no change observed in the elution patterns of RNA polymerase forms extracted from acetate growth vegetative cells, sporulating cells or from mature asci ; in all cases RNA polymerase consists of three forms, Ib, II and III. However, single spore suspension obtained from asci by treatment with zymolase contains a new form with chromatographic properties similar to those of form Ia. Our data suggests that form Ia may be a modification product of from Ib.

Meiosis in protists. Some structural and physiological aspects of meiosis in algae, fungi, and protozoa

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Induction of petite mutations during germination and outgrowth of Saccharomyces cerevisiae ascospores

The germination and outgrowth of Saccharomyces cerevisiae ascospores were studied by determining the sensitivity of the ascospores to the action of chemical mutagens. Survival of the ascospores after N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) treatment was low during the first 2 h of germination and then increased and remained constant. Survival of the ascospores after 2-methoxy-6-chloro-9-(3-[ethyl-2-chloroethyl]aminopropylamino)acridine-2HC1 (ICR-170) treatment was constant from 0 to 5 h, but as the ascospores completed outgrowth at 6 h they became more sensitive to killing by ICR-170. Survival of the ascospores remained high during treatment with 2-methoxy-6-chloro-9-(3-[ethyl-2-hydroxyethyl]aminopropylamino)acridine-2HC1 (ICR-170-OH) or 2,7-diamino-10-ethyl-9-phenyl-phenanthridinium bromide. The main classes of mutations screened for were petites and auxotrophs. The induction of petites and auxotrophs by MNNG was independent of the stage of germination and outgrowth treated. Petite induction by ICR-170 was dependent upon the stage of germination and outgrowth treated. The early hours of germination (0 to 3 h) were not sensitive to petite induction. However, there was maximal petite induction at 5 h into germination and outgrowth, followed by a decline. During this same time period, ICR-170 induced less than 1% auxotrophic colonies. This finding is very unusual because ICR-170 induced 15% auxotrophic colonies in starved log-phase cultures of S. cerevisiae. The acridine ICR-170-OH induced no mutations during germination and outgrowth of the ascospores. Ethidium bromide induced petites, and the petite frequency became maximal at 5 h of germination and outgrowth, a result similar to that obtained with ICR-170.

Characteristics of developing mitochondrial genetic and respiratory functions in germinating fungal spores

Spores of the fungus Botryodiplodia theobromae began a cyanide-sensitive oxygen consumption immediately upon exposure to a liquid medium, and spore germination and respiration were not affected by ethidium bromide, D-threochloramphenicol, and acriflavin until later during germ tube emergence. These inhibitors of the mitochondrial genetic system all inhibited total cell protein synthesis to the same intermediate degree from the outset of incubation. When spores were incubated in water under non-germinating conditions, protein synthesis and oxygen uptake proceeded at initial rates almost identical to those seen in spores germinating in the presence of the three mitochondrial system inhibitors. Although the spores respired at rapid rates from the onset of incubation, no cytochrome absorption peaks could be observed in mitochondrial fractions prepared from ungerminated spores; they were readily observed in germinated spores, however. When the spores were germinated in the presence of inhibitors of the mitochondrial system, an excess of cytochrome c was observed in the near absence of cytochromes a and b. The results indicate that the ungerminated spores of this organism contain a preserved, potentially functional aerobic respiratory system which requires cycloheximide-sensitive ribosome activity to become functional when the spores are inoculated into a liquid medium.

Sporulation of Saccharomyces cerevisiae in the absence of a functional mitochondrial genome

The role of the mitochondrial system during sporulation of Saccharomyces cerevisiae was studied. Addition of ethidium bromide (EthBr) to cells growing in acetate medium resulted in the quantitative (>98%) conversion of the culture to the petite genotype in one generation. The cells were respiratory active (derepressed) but contained no mitochondrial deoxyribonucleic acid (mtDNA) as demonstrated by analytical ultracentrifugation in CsCl. When transferred to acetate sporulation medium, the culture sporulated. Ascus production was only slightly below that of the control culture. Synthesis of mtDNA occurred during sporulation in the control but not in the EthBr-treated culture. Mitochondrial protein synthesis was virtually eliminated in the EthBr-treated culture. Therefore, completely derepressed cells can sporulate without a functional mitochondrial genetic system. When partially repressed cells were treated with EthBr, no ascus formation was observed after transfer to sporulation medium. Control cultures underwent respiratory adaptation in sporulation medium and then sporulated. Extensive derepression of the respiratory system is thus required for sporulation, and this adaptation is dependent on a functional mitochondrial system. Our results suggest that once the cells are fully derepressed no mitochondrial genetic information has to be expressed during meiosis and ascus formation.