Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0038187 (starvation)
24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The synthesis of the arginine pathway carbamoylphosphate synthase (CPSase A) of Saccharomyces cerevisiae is subject to two control mechanisms. One mechanism is specific for CPSase A and is exerted by arginine; it probably involves a repressor-operator type of interaction. This "specific" mechanism regulates the expression of gene cpaI coding for the small "glutaminase" subunit of CPSase A but has little influence on the production of the large subunit of the enzyme, a product of gene cpaII. This large component, which alone has no biological significance, accumulates freely under conditions of arginine repression. The second mechanism is general: it controls enzyme synthesis in a number of amino acid biosynthetic pathways in addition to the arginine sequence. Two types of evidence that this "general" mechanism participates in the control of CPSase A synthesis are presented: (1) Derepression upon starvation for any amino acid of which the synthesis is subject to this general control; and (2) repression during growth in amino acid-rich medium. In contrast to the specific mechanism, the "general" mechanism regulates the expression of both the cpaI and cpaII genes.
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PMID:Dual regulation of the synthesis of the arginine pathway carbamoylphosphate synthase of Saccharomyces cerevisiae by specific and general controls of amino acid biosynthesis. 22 37

Chicken kidney contains two arginases with different sedimentation coefficients and substrate specificity. The ligher of these arginases, which hydrolyses only L-arginine, has been purified about 3000-fold. Like the "ureotelic" arginase, developed in chicken liver after starvation, it displays many of the properties of the arginase of the "ureotelic" species. This seems to exclude the possibility that ureotelism and uricotelism are characterized by a specific type of arginases. Both liver and kidney arginases are located in the mitochondrial matrix. The rate of hydrolysis of arginine thus not only depends on the arginase activity but also on the rate of transport of arginine into the matrix. This last process therefore is of regulatory significance.
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PMID:Molecular charcteristics of chicken kidney arginase. 23 78

Hypergastrinemia and hyperglucagonemia follow portacaval shunt (PCS) or cirrhosis in man and experimental animals. The cause is unknown although portal diversion and hepatic dysfunction are suggested. In these studies transhepatic techniques were used to define the hepatic handling of basal and arginine-stimulated gastrin and glucagon levels in sham-operated and portacaval-shunted pigs and in a group of pair-fed sham-operated pigs. After PCS, basal gastrin levels were lower than those in sham-operated animals but were also lower in the pair-fed group, suggesting that the change resulted from partial starvation. Arginine-stimulation caused a rise in hepatic venous levels in PCS and in pair-fed pigs and in portal venous levels in sham-operated pigs. These data also suggested a response to diminished intake in PCS pigs. There was an immediate transitory rise in portal immunoreactive glucagon (Unger 30K) after PCS and a subsequent rise from the 4th postoperative day in all circulations. Arginine stimulation caused in sham-operated and PCS pigs a biphasic rise in the portal circulation and a later rise in the arterial circulation in PCS pigs. These data suggest that the effect of PCS upon gastrin levels is associated with the impaired appetite while the effect upon glucagon is the result of diversion past the liver.
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PMID:Transhepatic hormone levels in the portacaval shunted pig--the effects of arginine upon gastrin and glucagon release. 29 Feb 69

The rate of synthesis of ribosomal proteins relative to that of total protein was measured at various times during recovery from arginine starvation in isogenic re+ and rel- strains of Escherichia coli K 12. Total ribosomal proteins are preferentially synthesized early during recovery. Higher rates of synthesis are obtained in the rel+ strain than in the rel- strain. Differential rates of synthesis of individual ribosomal proteins are observed at the various times studied. The rate of synthesis of individual proteins increases with time up to maximum values then the rates come down to values similar to those found in exponentially growing cells. The time of restart of synthesis of each protein has been estimated (1) by the time at which the maximum value is reached, and (2) by measuring the rate of synthesis at early time (3 min). Most ribosomal proteins behave similarlly in rel- and rel+ strains. Proteins have been listed from highly labelled (early proteins) to poorly labelled (late proteins). The significance of the order of restart is considered.
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PMID:On the control of ribosomal protein biosynthesis in Escherichia coli. II. Studies during recovery from amino acid starvation. 32 Oct 27

Previously, we reported that starvation of Rel Escherichia coli for methionine, but not leucine or histidine, results in chromatographically unique species of aspartyl-specific transfer ribonucleic acid (tRNAAsp) lacking the modified nucleoside Q. The present studies demonstrate that methionine starvation of Rel+ E. coli yields a qualitatively similar, but less pronounced, effect. Furthermore, during recovery from methionine starvation in Rel E. coli, the chromatographic elution pattern of tRNAAsp shifts towards that observed for unstarved cells after 1 h of recovery, and the shift appears complete after 2 h of recovery. This shift is inhibited by rifampin. Incorporation of [2-14C]methionine or [methyl-3H]methionine into growing cells of E. coli does not result in labeling of nucleoside Q. We interpret these findings to indicate that methionine has an indirect role in Q formation and that Q-deficient tRNA can be modified slowly to contain Q but that transcription is required. The chromatographic elution patterns of tRNAAsp from Rel E. coli starved for arginine, lysine, or glutamic acid indicate that these amino acids are not the source of the three- or five-carbon sequences in the modified portion of Q.
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PMID:Role of methionine in the synthesis of nucleoside Q in Escherichia coli transfer ribonucleic acid. 33 22

Uninduced cultures of Saccharomyces cerevisiae exhibit high basal levels of allantoinase, allantoicase, and ureidoglycolate hydrolase, the enzymes responsible for degrading allantoin to urea. As a result, these activities increase only 4- to 8-fold upon induction, whereas the urea-degrading enzymes, urea carboxylase and allophanate hydrolase, have very low basal levels and routinely increase 30-fold on induction. Differences in the inducibility of these five enzymes were somewhat surprising because they are all part of the same pathway and have the same inducer, allophanate. Our current studies reconcile these observations. S. cerevisiae normally contained up to 1 mM allantoin sequestered in a cellular organelle, most likely the vacuole. Separation of the large amounts of allantoin and the enzymes that degrade it provide the cell with an efficient nitrogen reserve. On starvation, sequestered allantoin likely becomes accessible to these degradative enzymes. Because they are already present at high levels, the fact that their inducer is considerably removed from the input allantoin is of little consequence. This suggests that at times metabolite compartmentation may play an equal role with enzyme induction in the regulation of allantoin metabolism. Metabolism of arginine, another sequestered metabolite, must be controlled both by induction of arginase and compartmentation because arginine serves both as a reserve nitrogen source and a precursor of protein synthesis. The latter function precludes the existence of high basal levels of arginase.
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PMID:Metabolite compartmentation in Saccharomyces cerevisiae. 35 30

Saccharomyces cerevisiae responds to deperivation of nutrients by arresting cell division at the unbudded G1 stage. Cells situated outside of G1 at the time of deperivation complete the cell cycle before arresting. This prompted an investigation of the source of nutrients used by these cells to complete division and the mechanisms controlling their availability. We found a close correlation between accumulation of unbudded cells and loss of previously formed allophanate hydrolase activity after nutrient starvation. These losses were not specific to the allantoin, system since they have been observed for a number of other enzymes and also when cellular protein levels were monitored with [3H]leucine. Loss of hydrolase activity was also observed when protein synthesis was inhibited either by addition of inhibitors or loss of the prtl gene product. We found that onset of nutrient starvation brought about release of large quantities of arginine and allantoin normally sequestered in the cell vacuole. Treatment of a cells with alpha-factor resulted in both the release of allantoin and arginine from the cell vacuole and the onset of intracellular protein degradation. These effects were not observed when either alpha cells or a/alpha diploid strains were treated with alpha-factor. These data suggest that release of vacuolar constitutents and protein turnover may be regulated by the G1 arrest signal.
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PMID:Control of vacuole permeability and protein degradation by the cell cycle arrest signal in Saccharomyces cerevisiae. 36 91

We have isolated two regulatory mutants altered in the leader region of the Escherichia coli tryptophan (trp) operon. In one mutant, trpL29, the AUG translation start codon for the trip leader peptide is replaced by AUA. The other mutant, trpL75, has a G leads to A change at residue 75, immediately after the UGA translation stop codon for the trp leader peptide. In vivo, trpL29 and trpL75 increase the efficiency of transcription termination at the trp attenuator 3- to 5-fold. trpL29 and trpL75 also fail to respond fully to tryptophan starvation and other conditions that normally relieve transcription termination at the trp attenuator. The trpL29 mutation, which presumably reduces synthesis of the trp leader peptide, is cis dominant. The effect of starvation for a number of the amino acids in the trp leader peptide was determined. Only starvation for tryptophan and arginine, amino acids that occur at residues 10, 11, and 12 of the 14-residue trp leader peptide, elicits relief of transcription termination. Our findings suggest that translation of trp leader RNA is involved in regulation of transcription termination at the attenuator. A model is discussed in which the location of the ribosome synthesizing the leader peptide is communicated to the RNA polymerase transcribing the leader region.
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PMID:Translational control of transcription termination at the attenuator of the Escherichia coli tryptophan operon. 36 6

Arginase-minus mutants of Saccharomyces cerevisiae were arrested in growth and accumulated at the unbudded G-1 stage of the cell cycle when starved for nitrogen. If, however, arginine was added to the culture medium at the time of starvation, growth ceased but the cells did not collect at the unbudded G-1 stage. We suggest that arginine addition prevented the cells from collecting at the G-1 stage by starving them for histidine and lysine, thereby inhibiting synthesis of proteins needed to complete the cell cycle.
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PMID:Addition of basic amino acids prevents G-1 arrest of nitrogen-starved cultures of Saccharomyces cerevisiae. 37 55

It has been shown that in bacteria, besides specific regulatory mechanisms, the synthesis of aminoacid biosynthetic enzymes is also controlled by the endogenous aminoacid pool. The latter regulates the intracellular level of ppGpp, a positive effector of RNA messenger transcription. A similar regulatory control exists in yeast but does not appear to involve the same general effector. This was established by the observation that derepression of the enzymes belonging to several aminoacid biosynthetic pathways follows aminoacid starvation or tRNA discharging. We now report the repression of the arginine pathway by the total aminoacid pool. New mutations affecting the repressibility of the arginine enzymes as well as enzymes belonging to other aminoacid biosyntheses, when cells are grown in the presence of an excess of aminoacids, were identified.
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PMID:Concerted repression of the synthesis of the arginine biosynthetic enzymes by aminoacids: a comparison between the regulatory mechanisms controlling aminoacid biosyntheses in bacteria and in yeast. 37 2


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