Genes involved in meiosis and sporulation of a yeast

Summary 300 mutants blocked in meiosis or sporulation were isolated in Schizosaccharomyces pombe and grouped by complementation tests, linkage studies and cytological observation. In total, 5 genes pertaining to meiosis and 18 genes necessary for sporulation could be identified. In addition, a gene participating in dissolution of the separating walls during cell fusion was detected.     

Partial deprivation of GTP initiates meiosis and sporulation in Saccharomyces cerevisiae

Summary We have investigated the physiological conditions under which meiosis and the ensuing sporulation of Saccharomyces cerevisiae are initiated. Initiation of sporulation occurs in response to carbon, nitrogen, phosphorus, or sulfur deprivation, and also, when met auxotrophs are partially starved for methionine, but not after starvation of other amino acid auxotrophs. It also occurs after partial starvation of pur or gua auxotrophs for guanine but not after starvation of ura auxotrophs for uracil. Under all these sporulation conditions the concentrations of both guanine nucleotides (GTP) and S-adenosylmethionine (SAM) decrease whereas those of other nucleotides show no trend. We show that the decrease of guanine nucleotides is essential for the initiation of meiosis and sporulation: when a gua auxotroph, also lacking one of the two SAM synthetases, is starved for guanine but supplemented with 0.1 mM methionine, GTP decreases while SAM slightly increases and yet the cells sporulate.     

Protein Degradation, Meiosis and Sporulation in Proteinase-Deficient Mutants of SACCHAROMYCES CEREVISIAE

During the process of sporulation, a/α diploids degrade about 50% of their vegetative proteins. This degradation is not sporulation specific, for asporogenous diploids of a/a mating type degrade their vegetative proteins in a fashion similar to that of their a/α counterparts. Diploids lacking carboxypeptidase Y activity, prc1/prc1, show about 80% of wild-type levels of protein degradation, but are unimpaired in the production of normal asci. Diploids lacking proteinase B activity, prb1/prb1, show about 50% of wild-type levels of protein degradation. The effect on degradation of the proteinase B deficiency is epistatic to the degradation deficit attributable to the carboxypeptidase Y deficiency. The prb1 homozygotes undergo meiosis and produce spores, but the asci and, possibly, the spores are abnormal. Diploids homozygous for the pleiotropic pep4–3 mutation show only 30% of the wild-type levels of degradation when exposed to a sporulation regimen, and do not undergo meiosis or sporulation. Neither proteinase B nor carboxypeptidase Y is necessary for germination of spores.——Approximately half of the colonies arising from a/a or α/α diploids exposed to the sporulation regiment that express an initially heterozygous drug-resistance marker (can1) appear to arise from mating-type switches followed by meiosis and sporulation.     

Initiation of meiosis in cell cycle initiation mutants of Saccharomyces cerevisiae

Control of the initiation of meiosis in yeast was examined in diploids homozygous for one of four different temperature-sensitive mutations that affect “start” of the mitotic cell cycle. Two of the mutations, cdc28 and tra3, bring about deficiencies in the initiation of meiosis, while cdc25 and cdc35 do not prevent initiation of normal meiosis at both permissive and restrictive temperatures. Moreover, diploids homozygous for the latter two mutations are capable of initiating meiosis in rich growth media upon transfer to the high, non-permissive temperature. This unique feature contrasts with the behavior of other yeast strains which require a starvation sporulation medium for initiation of meiosis. It is suggested that the initiation of meiosis includes functions that are shared with “start” of the mitotic cell cycle, as well as functions related to the choice between the two processes. Meiosis in vegetative media at the restrictive temperature (in cdc25 or cdc35 homozygotes) may be important for the study of chemical and physiological phenomena resulting from the meiotic process and not from adaptation to the sporulation medium.     

Sensitivity of meiotic yeast cells to ultraviolet light

Sporulating cells of Saccharomyces cerevisiae show an increasing sensitivity to ultraviolet irradiation. Maximum sensitivity is reached at a time comparable to meiotic prophase. Sensitivity is expressed as reduced sporulation after the irradiation. The uv effect can be efficiently reversed by photoreactivating light. Viability is also more severely affected during premeiotic DNA synthesis and during meiosis than in earlier stages in sporulation. Cells left in sporulation medium after the irradiation show a reduced viability compared with the cells plated immediately after the irradiation. Non-sporulating diploids do not acquire sensitivity when exposed to sporulation medium, hence the sensitivity is related to the sporulation process. That meiosis itself is affected, rather than spore formation alone, is evident from experiments in which the uv irradiation interferes with the uncovering of a recessive marker and with commitment to meiosis. It is proposed that during meiotic prophase, the DNA repair system is different from that found in vegetative cells.     

Conversion of Mitotic to Meiotic Cells in Saccharomyces cerevisiae II. Relation between Premeiotic DNA Replication and Revertibility to Mitosis

Meiotic differentiation was investigated using a synchronousmeiotic system of the yeast, Saccharomyces cerevisiae, withrespect to revertibility to mitotic division. When cells weretransferred from a sporulation (SPM) to a growth (YHA) medium,reversion to mitosis took place at all stages up to and includingthe post synthetic phase of DNA. Continuous treatment with 4mM hydroxyurea (HU) during sporulation resulted in the extensionof the the premeiotic S phase. Revertibility to mitosis alsowas extended after the lengthened S phase. Pulse treatment with50 min HU for 2 h during the premeiotic S phase caused a 2-hdelay in the revertibility to mitosis. Similar results wereobtained by treatment with elevated temperatures. The resultsdemonstrate an irreversible commitment of cells to meiosis afterthe completion of premeiotic DNA replication. When cells were transferred from SPM to poor nutrient media,the timing of their reversion to mitosis varied. If transferredto glucose-based media, cells in the premeiotic S phase underwentmitosis; whereas, if transferred to acetate-based media, theycontinued meiotic development. Thus, conversion to meiosis dependson the nutritional environment to which cells are transferred,which implies that a sequence of intracellular change duringpremeiosis leads to meiotic differentiation. (Received February 10, 1983; Accepted June 1, 1983)     

The Schizosaccharomyces pombe cdt2(+) gene,a target of G1-S phase-specific transcription factor complex DSC1, is required for mitotic and premeiotic DNA replication

We have defined five sev genes by genetic analysis of Schizosaccharomyces pombe mutants, which are defective in both proliferation and sporulation. sev1(+)/cdt2(+) was transcribed during the G1-S phase of the mitotic cell cycle, as well as during the premeiotic S phase. The mitotic expression of cdt2(+) was regulated by the MCB-DSC1 system. A mutant of a component of DSC1 affected cdt2(+) expression in vivo, and a cdt2(+) promoter fragment containing MCB motifs bound DSC1 in vitro. Cdt2 protein also accumulated in S phase and localized to the nucleus. cdt2 null mutants grew slowly at 30 degrees and were unable to grow at 19 degrees. These cdt2 mutants were also medially sensitive to hydroxyurea, camptothecin, and 4-nitroquinoline-1-oxide and were synthetically lethal in combination with DNA replication checkpoint mutations. Flow cytometry analysis and pulsed-field gel electrophoresis revealed that S-phase progression was severely retarded in cdt2 mutants, especially at low temperatures. Under sporulation conditions, premeiotic DNA replication was impaired with meiosis I blocked. Furthermore, overexpression of suc22(+), a ribonucleotide reductase gene, fully complemented the sporulation defect of cdt2 mutants and alleviated their growth defect at 19 degrees. These observations suggest that cdt2(+) plays an important role in DNA replication in both the mitotic and the meiotic life cycles of fission yeast.     

The effects of culture media, solid substrates, and relative humidity on growth, sporulation and conidial discharge of Valdensinia heterodoxa

Valdensinia heterodoxa (Sclerotiniacae) is a potential fungal bioherbicide for control of salal (Gaultheria shallon). The effect of culture media, substrates and relative humidity (RH) on growth, sporulation and conidial discharge of V. heterodoxa was determined for two isolates PFC2761 and PFC3027 in vitro. Culture media significantly affected the growth, sporulation, and conidial discharge of V. heterodoxa. Of eight agar media used, colony radial growth was optimal on salal oatmeal agar and salal potato dextrose agar for isolates PFC2761 and PFC3027, respectively; whereas sporulation was at an optimum on salal oatmeal agar for both isolates. Of the eight liquid media tested, mycelial production was highest on wheat bran–salal–potato dextrose broth. Growth on solid substrates greatly stimulated sporulation and conidial discharge of V. heterodoxa. Of the 12 solid substrates used, the greatest numbers of discharged conidia were observed from wheat bran and wheat bran–salal within 14 d of sporulation. Sporulation on solid substrates continued for 42 d. RH significantly affected the sporulation and conidial discharge for both isolates across all solid substrates tested. No conidia were produced or discharged below 93 % RH on wheat bran–salal and millet. With an increase of the RH from 93 to 97 %, sporulation and the number of discharged conidia increased significantly for both isolates on wheat bran–salal, but not on millet.     

Isolation and characterization of recessive sporeless mutants in the basidiomycete Coprinus cinereus

Summary Twenty-four sporeless mutants were isolated from an Amut Bmut strain (mutant in the incompatibility factors) of the basidiomycete Coprinus cinereus. All the sporeless mutations were recessive to the wild type. These mutants and a previously isolated recessive sporeless strain, N2-7 (Kanda and Ishikawa 1986) were crossed with a wildtype strain. An F1 random spore analysis indicated that sporulation deficiencies in these mutants were caused by single nuclear gene mutations. These mutations were all complementary to each other, thus twenty-five sporulation genes were identified. Five of them were linked to the A incompatibility factor. Cytological observations classified these mutants into the following four types according to the stage of the blockage: (1) meiosis stopped at meta-anaphase I; (2) meiosis was completed, but further basidial development did not occur; (3) basidial development stopped at the sterigma stage; (4) basidial development stopped at the prespore stage.     

Temperature sensitivity of flocculation induction,conjugation and sporulation in fission yeast

Homothallic cultures of Schizosaccharomyces pombe, anaerobically grown to stationary phase in broth at 32°C, were induced by aeration to flocculate. Flocculation was followed by copulation, conjugation, zygote formation, meiosis and sporulation. Cultures grown to stationary phase at 32°C and then aerated at 37°C did not sporulate. Grown to stationary phase at 37°C, cultures were not immediately inducible when aerated at 32°C. To identify which events in the developmental sequence were thermosensitive, we grew and induced cultures at 32°C and then shifted them at various times to 37°C. We observed the following events to be thermosensitive: development of respiratory sufficiency, readiness (inducibility of a culture within 1 h), flocculation induction, copulation, conjugation and early sporulation (including meiosis). Respiration, flocculation and spore maturation were thermoresistant. Conjugation-induced lysis and post-developmental deflocculation were enhanced at 37°C.NRCC no. 17775     

Meiotic effects of DNA-defective cell division cycle mutations of Saccharomyces cerevisiae

The meiotic effects of several cell division cycle (cdc) mutations of Saccharomyces cerevisiae have been investigated by electron microscopy and by genetic and biochemical methods. Diploid strains homozygous for cdc mutations known to confer defects on vegetative DNA synthesis were subjected to restrictive conditions during meiosis. Electron microscopy revealed that all four mutants were conditionally arrested in meiosis after duplication of the spindle pole bodies but before spindle formation for the first meiotic division. None of these mutants became committed to recombination or contained synaptonemal complex at the meiotic arrest. — The mutants differed in their ability to undergo premeiotic DNA synthesis under restrictive conditions. Both cdc8 and cdc21, which are defective in the propagation of vegetative DNA synthesis, also failed to undergo premeiotic DNA synthesis. The arrest of these mutants at the stage before meiosis I spindle formation could be attributed to the failure of DNA synthesis because inhibition of synthesis by hydroxyurea also caused arrest at this stage. — Premeiotic DNA synthesis occurred before the arrest of cdc7, which is defective in the initiation of vegetative DNA synthesis, and of cdc2, which synthesizes vegetative DNA but does so defectively. The meiotic arrest of cdc7 homozygotes was partially reversible. Even if further semiconservative DNA replication was inhibited by the addition of hydroxyurea, released cells rapidly underwent commitment to recombination and formation of synaptonemal complexes. The cdc7 homozygote is therefore reversibly arrested in meiosis after DNA replication, whereas vegetative cultures have previously been shown to be defective only in the initiation of DNA synthesis.     

DNA polymerases, deoxyribonucleases, and recombination during meiosis in Saccharomyces cerevisiae.

We utilized strains of Saccharomyces cerevisiae that exhibit high efficiency of synchrony of meiosis to examine several aspects of meiosis including sporulation, recombination, DNA synthesis, DNA polymerase I and II, and Mg2+-dependent alkaline DNases. The kinetics of commitment to intragenic recombination and sporulation are similar. The synthesis of DNA, as measured directly with diphenylamine, appears to precede the commitment to recombination. Both DNA polymerase I and II activities and total DNA-synthesizing activity in crude extracts increase two- to threefold before the beginning of meiotic DNA synthesis. Increases of 10- to 20-fold over mitotic levels are found for Mg2+-dependent alkaline DNase activity in crude extracts before and during the commitment to meiotic intragenic recombination. Of particular interest is the comparable increase in a nuclease under the control of the RAD52 gene; this enzyme has been identified by the use of antibody raised against a similar enzyme from Neurospora crassa. Since the RAD52 gene is essential for meiotic recombination, the nuclease is implicated in the high levels of recombination observed during meiosis. The effects observed in this report are meiosis specific since they are not observed in an alpha alpha strain.     

BIOCHEMICAL CHANGES IN YEAST DURING SPORULATION. I. FATE OF NUCLEIC ACIDS AND RELATED COMPOUNDS

Changes in nuclear figures and in activities of nucleic acid and protein syntheses were observed mainly on Saccharomyces cerevisiae G2-2 during sporogenesis. Patterns of DNA synthesis and of meiosis show that the sporogenic process in yeast was divided into an induction phase (I-phase), a DNA-synthesizing phase (S-phase) and a maturation phase (M-phase). Meiotic figures appeared most frequently at the end of the S-phase at approximately 12 hr in sporulation culture. In M-phase visible spores formed. The amount of protein increased in the initial 7 hr culture of 1-phase, then decreased in the S- and M-phases. But in sporulation culture of the asporogenic diploid strain 3c × a, protein did not decrease. RNA increased within 3 hr of the I-phase then stopped increasing. DNA synthesis occurred critically during S-phase, i.e. between 7 and 12 hr. and was somewhat resumed during the later part of M-phase. Oligodeoxyri-bonucleotide content decreased in the I- and M-phases and increased temporarily. Deoxyribosides decreased linearly during the sporogenic processes. Based on these results and results of experiments estimating the incorporation of ¹⁴C-uracil into nucleic acid and ¹⁴C-amino acid mixture into protein fractions, the roles of nucleic acid synthesis activities in meiosis and in sporulation are discussed.     

A novel role of Dma1 in regulating forespore membrane assembly and sporulation in fission yeast

In fission yeast Schizosaccharomyces pombe, a diploid mother cell differentiates into an ascus containing four haploid ascospores following meiotic nuclear divisions, through a process called sporulation. Several meiosis-specific proteins of fission yeast have been identified to play essential roles in meiotic progression and sporulation. We report here an unexpected function of mitotic spindle checkpoint protein Dma1 in proper spore formation. Consistent with its function in sporulation, expression of dma1(+) is up-regulated during meiosis I and II. We showed that Dma1 localizes to the SPB during meiosis and the maintenance of this localization at meiosis II depends on septation initiation network (SIN) scaffold proteins Sid4 and Cdc11. Cells lacking Dma1 display defects associated with sporulation but not nuclear division, leading frequently to formation of asci with fewer spores. Our genetic analyses support the notion that Dma1 functions in parallel with the meiosis-specific Sid2-related protein kinase Slk1/Mug27 and the SIN signaling during sporulation, possibly through regulating proper forespore membrane assembly. Our studies therefore revealed a novel function of Dma1 in regulating sporulation in fission yeast.     

Developmental regulation of a sporulation-specific enzyme activity in Saccharomyces cerevisiae.

An alpha-glucosidase activity (SAG) occurs in a/alpha Saccharomyces cerevisiae cells beginning at about 8 to 10 h after the initiation of sporulation. This enzyme is responsible for the rapid degradation of intracellular glycogen which follows the completion of meiosis in these cells. SAG differs from similar activities present in vegetative cells and appears to be a sporulation-specific enzyme. Cells arrested at various stages in sporulation (DNA replication, recombination, meiosis I, and meiosis II) were examined for SAG activity; the results show that SAG appearance depends on DNA synthesis and some recombination events but not on the meiotic divisions.     

Genetic control of fungal differentiation: The three sporulation pathways of Neurospora crassa

Sporulation in the mold Neurospora crussa can proceed along three very different pathways, leading to the production of three types of spores. Two asexual sporulation pathways that lead to the formation of macroconidia and microconidia involve budding from hyphae by two different mechanisms. A much more complex sexual reproductive pathway involves the formation of a fruiting body called a perithecium, in which meiosis takes place and ascospores are formed in sac-like cells called asci. Numerous mutations exist that affect these developmental pathways, and genes have been isolated that are expressed preferentially during sporulation. The Neurospora sporulation pathways offer a simple system with which to study mechanisms and regulation of development that are usually obscured by complex cell-cell interactions involved in animal and plant development.     

组蛋白H3K4甲基转移酶复合物亚基Ash2参与裂殖酵母产孢

在氮源缺乏及信息素存在的条件下,裂殖酵母(Schizosaccharomyces pombe)进行减数分裂并完成产孢。在此过程中,信息素介导的MAPK(Mitogen-activated protein kinases)信号通路调控减数分裂相关基因的表达。Spk1是MAPK通路的核心成员,通过蛋白磷酸化的方式激活转录因子Ste11,从而激活mei2⁺、mam2⁺和map3⁺等减数分裂相关基因的表达。尽管组蛋白H3K4甲基化参与基因转录激活、染色质重塑等诸多生物学过程,但其在裂殖酵母产孢过程中的作用并不清楚。文章通过序列比对,发现裂殖酵母Ash2作为H3K4甲基转移酶复合物COMPASS的亚基具有两个保守的结构域,定位于细胞核内参与H3K4的甲基化修饰。ash2⁺的缺失引起裂殖酵母在氮源缺乏时产孢过程的延迟及产孢率下降。ChIP、定量PCR分析结果显示,ash2⁺的缺失降低了spk1⁺编码区H3K4的二甲基化水平,造成spk1⁺mRNA水平的明显下调。在ash2Δ细胞中,虽然ste11⁺的转录水平没有变化,但Ste11的靶基因mei2⁺、mam2⁺和map3⁺的转录水平明显下降。在裂殖酵母中,组蛋白H3K4甲基转移酶复合物COMPASS的亚基Ash2通过调控二甲基化水平修饰从而调节MAPK信号通路,参与裂殖酵母的有性生殖,为建立表观遗传修饰与减数分裂之间的联系提供了新的线索。