UMLS:C0038187 - FACTA Search

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

In synchronous cultures of Bacillus subtilis 168/S grown on succinate as a sole carbon source (mean generation time 115 min), chromosome initiation occurs at the beginning of the cell cycle but the rate of membrane protein synthesis doubles in mid-cycle more or less coincident with nuclear segregation. In glucose-grown cultures, the doubling in rate of membrane protein synthesis occurs at about the same time as nuclear segregation and DNA initiation at the beginning of the cycle. Control of the rate of membrane synthesis by the chromosome has been demonstrated by inhibiting DNA synthesis using thymine starvation and showing that membrane protein synthesis continues at a constant rate, whereas the rate of cytoplasmic protein synthesis almost doubles. I suggest that the replication of a region at or close to the chromosome terminus is required to allow the doubling in rate of membrane synthesis.
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PMID:Control of membrane protein synthesis in Bacillus subtilis. 81 Jan 72

The response of non-differentiating bacteria to nutrient starvation is complex and includes the sequential synthesis of starvation-inducible proteins. Although starvation for different individual nutrients generally provokes unique and individual patterns of protein expression, some starvation stimulons share member proteins. Two-dimensional polyacrylamide gel electrophoresis revealed that the synthesis of a small (13.5 kDa) cytoplasmic protein in Escherichia coli was greatly increased during growth inhibition caused by the exhaustion of any of a variety of nutrients (carbon, nitrogen, phosphate, sulphate, required amino acid) or by the presence of a variety of toxic agents including heavy metals, oxidants, acids and antibiotics. To determine further the mode of regulation of the protein designated UspA (universal stress protein A) we cloned the gene encoding the protein by the technique of reverse genetics. We isolated the protein from a preparative two-dimensional polyacrylamide gel, determined its N-terminal amino acid sequence, and used this sequence to construct a degenerate oligonucleotide probe. Two phages of the Kohara library were found to contain the gene which then was subcloned from the DNA in the overlapping region of these two clones. The amino acid sequence, deduced from the nucleotide sequence of the uspA gene, shows no significant homology with any other known protein. The uspA gene maps at 77 min on the E. coli W3110 chromosome, and is transcribed in a clockwise direction. The increase in the level of UspA during growth arrest was found to be primarily a result of transcriptional activation of the corresponding gene. The induction was independent of the RelA/SpoT, RpoH, KatF, OmpR, AppY, Lrp, PhoB and H-NS proteins during stress conditions that are known to induce or activate these global regulators. The -10 and -35 regions upstream of the transcriptional start site of the uspA gene are characteristic of a sigma 70-dependent promoter.
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PMID:Cloning, mapping and nucleotide sequencing of a gene encoding a universal stress protein in Escherichia coli. 145 57

A mutant, PN6017, of the cellular slime mold Polysphondylium pallidum was selected by cell-surface labeling with a monoclonal antibody, mAb 293, and fluorescence-activated cell sorting. The antibody was directed against an L-fucose-containing epitope on glycoproteins, designated ep 293, and the mutant showed reduced and delayed expression of this epitope. PN6017 was distinguished from other mutants of this kind by extensive microcyst formation on agar plates under conditions where the wild type formed only sparse microcysts. In suspension cultures transformation of cells into microcysts was negligible in the wild type, and close to 100% in the mutant. Under these conditions microcyst formation in the mutant began at 5-7 h of starvation. At the same time expression of ep 293 and also of a developmentally regulated cytoplasmic protein, pallidin, became detectable. This coincidence in time suggests that microcyst formation in PN6017 is coupled to the same control mechanism as the two other developmentally regulated processes.
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PMID:A microcyst-overproducing mutant of Polysphondylium pallidum. 242 Apr 73

Evidence for the presence of a Cdc2-like protein in Physarum polycephalum has been obtained using a peptide antibody directed against a highly conserved amino acid sequence near the N-terminal end of Cdc2, Cdc28 and Cdc2HS. The antibody detected a 34 kDa cytoplasmic protein, similar in apparent size to Cdc2 in yeast and Cdc2Hs in HeLa cells. A 60 kDa nuclear band was also detected in Physarum but not in yeast or HeLa. Evidence is presented that this is not related to the 34 kDa protein nor is it found in HeLa nuclei or yeast cells. The Cdc2-like protein level did not fluctuate over more than 10 h of the naturally synchronous cell cycle of Physarum. Several heat-shock experiments using regimens that either: delayed mitosis and S-phase; prevented mitosis or uncoupled S-phase from mitosis were performed. None had any effect on the level of the Cdc2-like protein. The induction of spherulation by starvation was shown to have no effect on the levels of the 34 kDa Cdc2 analog. The invariant level of the 34 kDa protein during the cell cycle and starvation is consistent with previous results obtained with yeast. Three heat-shock regimens which either delay mitosis, eliminate S-phase or uncouple mitosis from S-phase in Physarum also had no effect on the level of the 34 kDa protein. This result emphasizes the stable nature of this protein.
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PMID:Evidence for a homolog of the yeast cell cycle regulatory gene product of cdc2+ in Physarum polycephalum. 266

The bulk of cellular protein in hepatocytes is sequestered and degraded by two classes of autophagy, (a) an overt or macro form, and (b) microautophagy. Macroautophagy is rapidly induced by amino acid deprivation and the administration of glucagon and suppressed by amino acids and insulin. Amino acids appear to be its primary regulator since liver perfusion studies have shown that it can be inhibited almost completely and proteolysis decreased from maximal (4.5% hr) to basal rates (1.7%/hr) by 4 times normal plasma amino acid concentrations. The resulting alterations in the aggregate volume of autophagic vacuoles are associated with proportional changes in the amount of cytoplasmic protein sequestered and in rates of protein degradation. Since the apparent turnover of autophagic vacuoles is 0.087 min-1, the pools of sequestered protein at all levels of macroautophagic stimulation are sufficient to account fully for the observed rates of accelerated rate of proteolysis. Microautophagy differs from the former in that the cytoplasmic 'bite' is smaller and it is not subject to acute physiological regulation. It is, however, dramatically decreased to near zero during refeeding after prior starvation. These and other findings indicate that it is adaptively regulated, possibly as a consequence of alterations in the amount of smooth endoplasmic reticulum. The amino acid control of accelerated protein degradation appears to involve direct inhibition by a small group of amino acids (Leu, Tyr/Phe, Gln, Pro, Met, Trp, and His) and the permissive action of alanine. Of unusual interest is the fact that, whereas the inhibitory amino acid group evokes responses identical to a complete amino acid mixture at 0.5x and 4x normal amino acid concentrations, it loses its effectiveness at normal levels; similar responses have been shown for leucine alone. The loss of effectiveness at normal concentrations is abolished by the addition of 0.5 mM alanine which by itself is not directly inhibitory. No other amino acid can replace alanine. These findings suggest a novel role for alanine that could be of importance in linking energy demands to proteolysis. A hypothetical model for proteolytic regulation by leucine and the other inhibitory amino acids is presented.
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PMID:The lysosomal pathway of intracellular proteolysis in liver: regulation by amino acids. 349 68

Cytoplasmic protein in hepatocytes is sequestered and degraded by two general classes of lysosomes, overt autophagic vacuoles (macroautophagy) and dense bodies (microautophagy). Volumes of the apparent space in each class that contain the internalized protein, together with estimates of cytoplasmic protein concentration, were used as a basis for predicting rates of protein degradation by the lysosomal system in livers of fed, 48-hr starved, and starved-refed mice. Assuming that the turnover of all sequestered protein is equal to that previously determined in overt autophagic vacuoles (0.087 min-1), we obtained close agreement between predicted and observed rates in the three conditions studied. The two autophagic components, though, exhibited different patterns of regulation. Microautophagy followed a downward course through starvation and into refeeding, a trend that explained fully the fall in absolute rates of protein degradation during starvation. By contrast, macroautophagy remained constant throughout starvation but was virtually abolished with refeeding. Whereas regulation of the latter can be explained largely by immediate responses to the supply of amino acids, present evidence together with results of others indicate that microsequestration could be linked to functional and quantitative alterations in the smooth endoplasmic reticulum. Both types of regulation contributed equally to the marked suppression of proteolysis during cytoplasmic regrowth.
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PMID:Quantitative correlation between proteolysis and macro- and microautophagy in mouse hepatocytes during starvation and refeeding. 634 Jan 16

Chinese hamster ovary (CHO) cells were subjected to severe amino acid starvation for histidine, leucine, methionine, asparagine, tyrosine, glutamine, valine, and lysine, using amino acid analogs or mutations in specific aminoacyl-tRNA synthetases. At protein synthetic rates of less than 5%, in all cases, the newly synthesized proteins were found on two-dimensional electrophoretic gels to consist of a few intensely labeled spots, with the exception of lysine. This pattern could also be produced by strong inhibition of cytoplasmic protein synthesis with cycloheximide, and was abolished by preincubation with the mitochondrial protein synthesis inhibitor chloramphenicol. It appears therefore that the spots represent mitochondrial protein synthesis and that animal cells must have separate aminoacyl-tRNA synthetases for mitochondrial tRNAs corresponding to all these amino acids except, possibly, for lysine.
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PMID:Selective synthesis of mitochondrial proteins by Chinese hamster ovary cells severely starved for various amino acids. 671 12

The suppression of proteolysis that normally accompanies cytoplasmic growth was investigated in livers of mice that had lost approximately 40% of their protein content during 48 h of starvation. The deficit was fully restored after 24 h of refeeding, and the net regain was linear between 12 and 24 h. Rates of protein breakdown were determined from (a) differences between synthesis and the net change in total liver protein, and (b) rates of valine release during 15-min in situ perfusions in the presence of cycloheximide. With appropriate correction for the turnover of a short lived pool, both procedures gave the same results; rates at 12 and 24 h of refeeding were decreased 90% over values in fed controls, an effect which accounted for 93% of protein regrowth. Measurements of degradable, intralysosomal protein revealed that sequestration of cytoplasmic protein by lysosomes was correspondingly decreased. Because the ratio of intracellular proteolysis to internalized protein was the same during refeeding as in earlier experiments where autophagy was the dominant process, the uptake of cytoplasmic proteins by lysosomes appears to be an obligatory step in proteolysis at all levels of regulation. The 20-fold range in rates of degradation exhibited by the mouse hepatocyte thus provides this cell with an unusual capability for regulating its protein content against relatively small changes in protein synthesis.
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PMID:Suppression of cytoplasmic protein uptake by lysosomes as the mechanism of protein regain in livers of starved-refed mice. 710 81

The specificity action of cycloheximide was tested using a cycloheximide resistant mutant of Physarum polycephalum. This resistance has previously been shown to reside with the ribosomes, making cytoplasmic protein synthesis refractile to the action of the drug. We show here that cycloheximide in the mutant strain causes specific alterations in metabolism without influencing the growth rate. These are: 1. lowered specific activity of glutamate dehydrogenase during starvation, 2. alteration of the molecular weight of glutamate dehydrogenase, 3. inhibition of uptake of amino acids from the medium into the internal pools. Possible explanations for these effects of cycloheximide outside of protein synthesis per se are considered. We conclude that cycloheximide may not be considered a specific inhibitor of protein synthesis, and that a causal relationship between protein synthesis and any biological process cannot be claimed unless such specificity is demonstrated in each case, preferably by use of mutants.
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PMID:Muliple sites of action of cycloheximide in addition to inhibition of protein synthesis in Physarum polycephalum. 743 63

The synthesis of the small, cytoplasmic protein UspA universal stress protein A) of Escherichia coli is induced as soon as the cell growth rate falls below the maximal growth rate supported by the medium, regardless of the condition inhibiting growth. The increase in UspA synthesis appears to be the result of induction of the monocistronic uspA gene. Induction of this gene during a heat-shock treatment is demonstrated to be the result of transcriptional activation of a sigma 70-dependent promoter which has previously been shown to be activated also during carbon starvation-induced growth arrest. Mutant cells lacking UspA grow at rates indistinguishable from the isogenic parent at different temperatures and in the presence of different growth inhibitors but are impaired in their ability to survive prolonged periods of complete growth inhibition caused by a variety of diverse stresses, including CdCl2, H2O2, DNP, CCCP exposure, and osmotic shock. Moreover, the uspA mutation results in an increased sensitivity of cells to carbon-source starvation (i.e. glucose, glycerol or succinate depletion). Also, the mutation causes a marked alteration in the timing of starvation protein expression but protein expression during steady-state growth appears to be normal. The results presented have prompted us to postulate that UspA may have a general protective function related to the growth arrest state.
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PMID:Expression and role of the universal stress protein, UspA, of Escherichia coli during growth arrest. 815 77

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