Stimulation of later functions of the yeast meiotic protein kinase Ime2p by the IDS2 gene product.

Ime2p is a protein kinase that is expressed only during meiosis in Saccharomyces cerevisiae. Ime2p stimulates early, middle, and late meiotic gene expression and down-regulates expression of IME1, which specifies an activator of early meiotic genes that acts independently of Ime2p. We have identified a new gene, IDS2 (for IME2-dependent signaling), which has a functional relationship to Ime2p. An ids2 null mutation delays down-regulation of IME1 and expression of middle and late meiotic genes. In an ime1 null mutant that express IME2 from the GAL1 promoter (ime1 delta PGAL1-IME2 mutant), early meiotic gene expression depends only upon Ime2p. In such strains, Ids2p is dispensable for expression of the early genes HOP1 and SPO13 but is essential for expression of the middle and late genes SPS1, SPS2, and SPS100. Ids2p is also essential for the autoregulatory pathway through which Ime2p activates its own expression via the IME2 upstream activation sequences (UAS). An PGAL1-IME2 derivative that produces a truncated Ime2p (lacking its C-terminal 174 residues) permits IME2 UAS activation in the absence of Ids2p. This observation suggests that Ids2p acts upstream of Ime2p or that Ids2p and Ime2p act in independent, convergent pathways to stimulate IME2 UAS activity. Accumulation of epitope-tagged Ids2p derivatives is greatest in growing cells and declines during meiosis. We propose that Ids2p acts indirectly to modify Ime2p activity, thus permitting Ime2p to carry out later meiotic functions.     

Stimulation of yeast meiotic gene expression by the glucose-repressible protein kinase Rim15p.

The Saccharomyces cerevisiae RIM15 gene was identified previously through a mutation that caused reduced ability to undergo meiosis. We report here an analysis of the cloned RIM15 gene, which specifies a 1,770-residue polypeptide with homology to serine/threonine protein kinases. Rim15p is most closely related to Schizosaccharomyces pombe cek1+. Analysis of epitope-tagged derivatives indicates that Rim15p has autophosphorylation activity. Deletion of RIM15 causes reduced expression of several early meiotic genes (IME2, SPO13, and HOP1) and of IME1, which specifies an activator of early meiotic genes. However, overexpression of IME1 does not permit full expression of early meiotic genes in a rim15delta mutant. Ime1p activates early meiotic genes through its interaction with Ume6p, and analysis of Rim15p-dependent regulatory sites at the IME2 promoter indicates that activation through Ume6p is defective. Two-hybrid interaction assays suggest that Ime1p-Ume6p interaction is diminished in a rim15 mutant. Glucose inhibits Ime1p-Ume6p interaction, and we find that Rim15p accumulation is repressed in glucose-grown cells. Thus, glucose repression of Rim15p may be responsible for glucose inhibition of Ime1p-Ume6p interaction.     

RSC Nucleosome-remodeling complex plays prominent roles in transcriptional regulation throughout budding yeast gametogenesis

RSC is a nucleosome-remodeling complex of Saccharomyces cerevisiae essential for growth that can alter histone-DNA interaction by using the energy of ATP hydrolysis. Nps1p/Sth1p is an ATPase subunit of RSC. A mutation in the conserved ATPase domain of Nps1p causes a sporulation defect with decreased expression of early meiotic genes, especially IME2. This defect is partially suppressed by the overexpression of either IME1 or IME2. A homozygous diploid of a novel temperature-sensitive nps1 mutation, nps1-13, harboring amino acid substitutions within the bromodomain, was unable to sporulate. Overexpression of IME, IME2, or both of these genes allowed the completion of meiosis I and meiosis II in nps1-13 but not the formation of mature asci. In nps1-13 carrying YEpIME1, the expression of a group of sporulation-specific genes, which express at the middle stages of sporulation and are required for spore-wall formation, notably diminished, and several late sporulation genes expressed at the early stages of sporulation. These results suggest that Nps1p/RSC plays important roles during the spore development process by controlling gene expression for initiating both meiosis and spore morphogenesis, and ensures proper expression timing of late meiotic genes.