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Query: UMLS:C0038187 (
starvation
)
24,951
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Alkalization of the medium is associated with and required for the cellular development to meiosis and sporulation in the yeast Saccharomyces cerevisiae. To elucidate the molecular mechanisms for the significance of external alkalization, we isolated mutants defective in division arrest at G1 phase under an alkaline condition. The mutants obtained had recessive alleles of SRB10 encoding the cyclin (SRB11)-dependent protein kinase that phosphorylates the CTD domain of the largest subunit of RNA polymerase II and negatively regulates the transcriptional initiation of certain genes. A delta srb11 deletion mutant showed the same cell cycle defect. When shifted to alkali, wild-type cells decreased transcript levels of G1-cyclin genes (CLN1 to CLN3) and KIN28-CCL1 (encoding another
CTD kinase
-cyclin pair which, in contrast, stimulates the promoter clearance and transcriptional elongation in most genes), resulting in the accumulation of G1 cells and the hypophosphorylated form of RNA polymerase II and in an increase in cell size. However, under the same conditions, a delta srb10 mutant was defective in these events, except the downregulation of CLN1 and CLN2. The delta srb10 mutation also influenced on the transcript levels of meiosis-inducing genes called IME1 and IME2: the mutation elevated the transcript level of IME1 but reduced that of IME2, resulting in partial defects in premeiotic DNA synthesis and meiosis. Overexpression of KIN28 and CCL1 in wild-type cells impaired the alkali-induced G1 arrest and the rate of meiosis and elevated the transcript levels of SRB11 and IME1. These results indicate that a transcriptional autoregulatory loop for KIN28-CCL1 and SRB10-SRB11 is important for G1 arrest and meiosis. We also found that environmental conditions for meiosis finely regulate the transcript levels of KIN28 and CCL1, such that nitrogen
starvation
first elevates them but subsequent alkalization of medium decreases them.
...
PMID:A transcriptional autoregulatory loop for KIN28-CCL1 and SRB10-SRB11, each encoding RNA polymerase II CTD kinase-cyclin pair, stimulates the meiotic development of S. cerevisiae. 1086 6
Phosphorylation of the tandem YSPTSPS repeats of the RNA polymerase II CTD inscribes an informational code that orchestrates eukaryal mRNA synthesis. Here we interrogate the role of the CTD in phosphate homeostasis in fission yeast. Expression of Pho1 acid phosphatase, which is repressed during growth in phosphate-rich medium and induced by phosphate
starvation
, is governed strongly by CTD phosphorylation status, but not by CTD repeat length. Inability to place a Ser7-PO4 mark (as in S7A) results in constitutive derepression of Pho1 expression in phosphate-replete medium. In contrast, indelible installation of a Ser7-PO4 mimetic (as in S7E) hyper-represses Pho1 in phosphate-replete cells and inhibits Pho1 induction during
starvation
. Pho1 phosphatase is derepressed by ablation of the CTD Ser5-PO4 mark, achieved either by mutating Ser5 in all consensus heptads to alanine, or replacing all Pro6 residues with alanine. We find that Ser5 status is a tunable determinant of Pho1 regulation, i.e., serial decrements in the number of consensus Ser5 heptads from seven to two elicits a progressive increase in Pho1 expression in phosphate-replete medium. Pho1 is also derepressed by hypomorphic mutations of the
CTD kinase
Cdk9. Inactivation of the CTD phosphatase Ssu72 attenuates Pho1 induction in wild-type cells and blocks Pho1 derepression in S7A cells. These experiments implicate Ser5, Pro6, and Ser7 as component letters of a CTD coding "word" that transduces a repressive transcriptional signal via serine phosphorylation.
...
PMID:RNA polymerase II CTD phospho-sites Ser5 and Ser7 govern phosphate homeostasis in fission yeast. 2626 92
