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)

Genes of higher eucaryotic cells are considered to show only a limited response to nutritional stress. Here we show, however, that omission of a single essential amino acid from the medium caused a marked rise in the mRNA levels of c-myc, c-jun, junB and c-fos oncogenes and ornithine decarboxylase (ODC) in CHO cells. There was no general accumulation of mRNAs in amino acid-starved cells, since the gamma-actin, beta-tubulin, protein kinase C, RNA polymerase II, and glyceraldehyde-3-phosphate dehydrogenase mRNAs and the total poly(A)+ mRNA were not increased. The levels of c-myc, ODC, and c-jun mRNAs were elevated more by amino acid starvation than by inhibition of protein synthesis with cycloheximide, which is known to increase the levels of these mRNAs. Importantly, however, cycloheximide present during amino acid starvation reduced the rise in the levels of the mRNAs down to the level obtained with cycloheximide alone. This implies that protein synthesis is required for the accumulation of c-myc, ODC, and c-jun mRNAs in amino acid-deprived cells. The junB and c-fos mRNAs, instead, were increased to the same extent or less by amino acid starvation than by cycloheximide treatment. The accumulation of the c-myc mRNA in amino acid-starved cells was due to both stabilization of the mRNA and increase of its transcription. The rise in the c-jun mRNA level seemed to be caused merely by stabilization of the mRNA. Further, despite the inhibition of general protein synthesis, amino acid starvation led to an increase in the synthesis of c-myc polypeptide. The results suggest that mammalian cells have a specific mechanism for registering shortages of amino acids in order to make adjustments compatible with cellular growth.
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PMID:Deprivation of a single amino acid induces protein synthesis-dependent increases in c-jun, c-myc, and ornithine decarboxylase mRNAs in Chinese hamster ovary cells. 212 33

Transcription of the 26-kilobase (kb) dihydrofolate reductase (dhfr) gene in CHO cells is initiated at two sites: a major site (approximately 85% of the dhfr mRNA) at -63 relative to the translation start and a minor site (approximately 15%) at -107. Transcription also occurs from the opposite DNA strand in the dhfr 5' region, with a probable initiation site at approximately -195 relative to the dhfr translation start. A 4-kb polyadenylated RNA that is derived from the opposite-strand transcription increases threefold in abundance after serum starvation of CHO cells for 24 h. dhfr mRNA levels do not change during this time. The first dhfr exon lies within a 1-kb genomic region marked by exceptionally high G + C content and lack of DNA methylation. This region also includes a 214-base-pair (bp) exon for the opposite-strand transcript and five of the six DNase I-hypersensitive sites identified at the dhfr locus. Analysis of the DNA sequences of hamster, human (M. Chen, T. Shimada, A. D. Moulton, A. Cline, R. K. Humphries, J. Maizel, and A. W. Nienhuis, J. Biol. Chem. 259:3933-3943, 1984), and mouse (M. McGrogan, C. C. Simonsen, D. T. Smouse, P. J. Farnham, and R. T. Schimke, J. Biol. Chem. 260:2307-2314, 1985) dhfr genes reveals the presence of a 29-bp unit that is conserved 45 to 49 bp upstream of major and minor dhfr transcription start sites. This unit follows the consensus: GRGGCGGTGGCCTNNNNTGTCRCAARTRGGTR. The 5' part of the 29-bp unit contains a GC box that agrees with the GGGCGG consensus-binding site for the RNA polymerase II transcription factor Sp1 (D. Gidoni, W. A. Dynan, and R. Tjian, Nature (London) 312:409-413, 1984). Each of the three mammalian dhfr genes has several G-rich GC boxes proximal to the major dhfr transcription start site and several GC boxes of the opposite orientation (C rich) in a distal region about 500 bp upstream.
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PMID:Multiple transcription start sites, DNase I-hypersensitive sites, and an opposite-strand exon in the 5' region of the CHO dhfr gene. 302 46

The growth of MCF-7 cells was arrested by 24 h of isoleucine deprivation. Following replenishment of the medium, the incorporation of uridine and thymidine into trichloroacetic acid-precipitable material began to increase slowly and gradually rose to the level of cycling cells. The addition of 5 X 10(-9) M estradiol to growth-arrested cells dramatically shortened the time of onset of macromolecular synthesis and increased the overall amount of precursor incorporation 2- to 4-fold over the level obtained by arrested control cells. The increase in uridine incorporation preceded the increase in thymidine incorporation by 6 h. Inhibition of protein synthesis with cycloheximide blocked the recovery of macromolecular synthesis in both control and estrogen-treated cells. Actinomycin D was ineffective in blocking the estrogen-stimulated recovery of macromolecular synthesis at concentrations known to inhibit pre-rRNA synthesis (10(-8) M). At higher concentrations, uridine and thymidine incorporation were inhibited in a dose-dependent manner. Inhibition of RNA polymerase II activity with alpha-amanitin similarly blocked both the recovery of the cells from isoleucine starvation and the potentiation of this by estradiol. Dihydrofolate reductase and thymidine kinase activities are both stimulated by estradiol in MCF-7 cells. In cycling cells, estrogen stimulates a 2-fold increase in their messenger RNAs (mRNAs) within 24 h. The level of dihydrofolate reductase mRNA is unaffected by isoleucine starvation, and estrogen caused no change in dihydrofolate reductase mRNA levels over a 24-h period following reversal of growth arrest. Similar results were observed for the 600-nucleotide pS2 mRNA that has been identified as an estrogen-induced RNA in MCF-7 cells. In contrast, thymidine kinase mRNA was found to be increased by estrogen at 24 h, but not at 12 h, following reversal of growth arrest. This increase correlates with increases in thymidine, but not uridine incorporation. These data indicate that the estrogen-stimulated increase in thymidine incorporation following release from growth arrest is dependent on new RNA synthesis. However, the hormone did not increase the levels of three estrogen-regulated mRNAs coordinately with the increases observed in uridine incorporation.
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PMID:Relationship between the expression of estrogen-regulated genes and estrogen-stimulated proliferation of MCF-7 mammary tumor cells. 398 99

The effect of sucrose feeding on endogenous intestinal RNA polymerase activities and on chromatin structure was studied in rats. Adult rats were given a 70% sucrose solution for 15 hours following a 48-hour starvation period. Comparison was made with rats starved for 63 hours and with ad libitum nourished animals. Chromatin-bound RNA polymerase I activity was significantly reduced by starvation. Sucrose feeding provoked a significant rise in the activity, but the level found in the nourished rats was not reached. The free poly[d(A-T)]-dependent RNA polymerase I activity of the sucrose-fed rats exceeded that of the starved and the nourished animals. Chromatin-bound RNA polymerase II activity was enhanced most markedly by sucrose feeding. The balance between the chromatin-bound and free enzymes was shifted towards the chromatin-bound state when compared to the starved and nourished rats. Starvation caused a reduction in the size of oligonucleosomes but sucrose feeding restored almost entirely the original pattern obtained in the nourished animals. These results reflect modifications in the structure of chromatin after sucrose feeding. The present report demonstrates that the adaptive processes triggered in the intestine by dietary sucrose are associated with changes in gene expression.
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PMID:Modulation of RNA polymerase activities in the intestine of adult rats by dietary sucrose. 661 82

Unambiguous TATA boxes have not been identified in upstream sequences of Tetrahymena thermophila genes analyzed to date. To begin a characterization of the promoter requirements for RNA polymerase II, the gene encoding TATA-binding protein (TBP) was cloned from this species. The derived amino acid sequence for the conserved C-terminal domain of Tetrahymena TBP is one of the most divergent described and includes a unique 20-amino-acid C-terminal extension. Polyclonal antibodies generated against a fragment of Tetrahymena TBP recognize a 36-kDa protein in macronuclear preparations and also cross-react with yeast and human TBPs. Immunocytochemistry was used to examine the nuclear localization of TBP during growth, starvation, and conjugation (the sexual phase of the life cycle). The transcriptionally active macronuclei stained at all stages of the life cycle. The transcriptionally inert micronuclei did not stain during growth or starvation but surprisingly stained with anti-TBP throughout early stages of conjugation. Anti-TBP staining disappeared from developing micronuclei late in conjugation, corresponding to the onset of transcription in developing macronuclei. Since micronuclei do not enlarge or divide at this time, loss of TBP appears to be an active process. Thus, the transcriptional differences between macro- and micronuclei that arise during conjugation are associated with the loss of a major component of the basal transcription apparatus from developing micronuclei rather than its appearance in developing macronuclei.
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PMID:TATA-binding protein and nuclear differentiation in Tetrahymena thermophila. 826 41

In hypotrichous ciliates such as Euplotes crassus genes in the transcriptionally active macronucleus are present on individual minichromosomes which occur in gene-specific copy numbers. This different degree of gene amplification can be understood as a means to preset the expression potential of the respective genetic information. In addition, the actual steady state transcript amounts are governed by the transcription rates and transcript stabilities. To establish the relative effects of these three parameters the copy numbers of genes transcribed by the three different polymerases were determined. The transcript levels of growing or starving vegetative cells were then determined, and nuclear run-on assays were performed to determine the transcription rates of the genes in the different nutritional states. A weak correlation between the gene copy numbers and transcription rates was found. The transcripts of genes synthesized by RNA polymerase II exhibited different stabilities upon starvation of the cells, compared to the supposedly stable ribosomal 5S and 26S RNA. Refeeding of the cells after starvation also resulted in a differential response with respect to the accumulation of the transcripts of different genes transcribed by RNA polymerase II, which can be interpreted in the context of the gene functions.
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PMID:Transcription rates and transcript stabilities of macronuclear genes in vegetative Euplotes crassus cells. 852 May 83

The rates of transcription of several protein coding genes during Acanthamoeba differentiation have been examined by nuclear run-on and RNase protection assays. During early encystment, transcription by RNA polymerase II increases approximately 4-fold, whereas transcription by RNA polymerases I and III is decreased, as previously described. The rates of transcription from a wide variety of individual genes are only slightly affected during the first 16 h of encystment, although profilin gene expression is markedly increased. The levels of mRNAs encoding TPBF, TATA binding protein, cyclin-dependent kinase, protein disulfide isomerase, profilin, myosin II heavy chain, ubiquitin and extendin are stable during mature cyst formation, whereas mRNAs encoding actin, S-adenosyl methionine synthase and tubulin are substantially decreased in abundance within 16 h of starvation-induced encystment. We conclude that in contrast to the negative regulation of large rRNA and 5S rRNA synthesis during differentiation, the RNA polymerase II transcription apparatus is not negatively regulated. Control of Acanthamoeba differentiation is likely to be mediated by positive regulation of genes necessary for cyst maturation.
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PMID:Transcription by RNA polymerase II during Acanthamoeba differentiation. 987 98

Rpb4 and Rpb7 are two yeast RNA polymerase II (Pol II) subunits whose mechanistic roles have recently started to be deciphered. Although previous data suggest that Rpb7 can stably interact with Pol II only as a heterodimer with Rpb4, RPB7 is essential for viability, whereas RPB4 is essential only during some stress conditions. To resolve this discrepancy and to gain a better understanding of the mode of action of Rpb4, we took advantage of the inability of cells lacking RPB4 (rpb4Delta, containing Pol IIDelta4) to grow above 30 degrees C and screened for genes whose overexpression could suppress this defect. We thus discovered that overexpression of RPB7 could suppress the inability of rpb4Delta cells to grow at 34 degrees C (a relatively mild temperature stress) but not at higher temperatures. Overexpression of RPB7 could also partially suppress the cold sensitivity of rpb4Delta strains and fully suppress their inability to survive a long starvation period (stationary phase). Notably, however, overexpression of RPB4 could not override the requirement for RPB7. Consistent with the growth phenotype, overexpression of RPB7 could suppress the transcriptional defect characteristic of rpb4Delta cells during the mild, but not during a more severe, heat shock. We also demonstrated, through two reciprocal coimmunoprecipitation experiments, a stable interaction of the overproduced Rpb7 with Pol IIDelta4. Nevertheless, fewer Rpb7 molecules interacted with Pol IIDelta4 than with wild-type Pol II. Thus, a major role of Rpb4 is to augment the interaction of Rpb7 with Pol II. We suggest that Pol IIDelta4 contains a small amount of Rpb7 that is sufficient to support transcription only under nonstress conditions. When RPB7 is overexpressed, more Rpb7 assembles with Pol IIDelta4, enough to permit appropriate transcription also under some stress conditions.
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PMID:Rpb7 can interact with RNA polymerase II and support transcription during some stresses independently of Rpb4. 1008 33

The effects of distamycin A on Acanthamoeba transcription, growth and differentiation were determined. Distamycin A inhibits transcription both in vitro and in vivo and can displace from DNA the transcription activator TATA binding protein promoter binding factor (TPBF). Inhibition in vivo is surprisingly selective for large rRNA precursors, 5S rRNA, profilin, S-adenosylmethionine synthetase, and extendin. Transcription from the TATA binding protein (TBP), TPBF, protein disulfide isomerase, tubulin and RNA polymerase II large subunit genes is only slightly inhibited. Moreover the rate of 5S rRNA transcription eventually recovers and exceeds that of untreated cells, while profilin transcription remains inhibited. Distamycin A inhibition is accompanied by a complex pattern of alterations to steady state levels of mRNAs. Actin, profilin and S-adenosylmethionine synthetase mRNAs are degraded, whereas mRNA encoding TBP is increased slightly in abundance. Transcription inhibition is accompanied by cessation of growth and severe morphological changes to Acanthamoeba, which are consistent with loss of production of mRNA encoding cytoskeletal proteins. Distamycin A also prevents starvation-induced differentiation of Acanthamoeba, in part due to complete prevention of cellulose production and cell wall formation.
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PMID:Distamycin A selectively inhibits Acanthamoeba RNA synthesis and differentiation. 1052 2

Shifting rats to a protein-free, carbohydrate-rich diet, although not starvation, resulted in the appearance of mRNA for, and activity of, 3-phosphoglycerate dehydrogenase (3-PGDH) in liver as well as in a marked decrease in plasma cystine concentration. Refeeding with protein caused a 50% decrease in the mRNA in 8 h and its complete disappearance within 24 h, followed by a slower disappearance of the enzymic activity. Intraperitoneal administration of cysteine or methionine to protein-starved rats decreased the mRNA by 50-60% after 8 h. However, the repeated administration of cysteine failed to cause the complete disappearance of this mRNA in 24 h. In hepatocytes in primary culture, cysteine plus methionine and glucagon had, independently, an approx. 4-fold inhibitory effect on the abundance of the 3-PGDH mRNA and caused its almost complete disappearance when tested together. Insulin had an approx. 2-fold stimulatory effect, which was antagonized by cysteine plus methionine but was still apparent in the presence of glucagon. Nuclear run-on experiments and analysis of the stability of the mRNA with 5,6-dichlorobenzimidazole riboside, an inhibitor of RNA polymerase II, suggested that the effect of cysteine plus methionine was due to destabilization of the mRNA, whereas the effect of glucagon was exerted on transcription. Cysteine, but not methionine, inhibited the accumulation of 3-PGDH mRNA in FTO2B hepatoma cells. In conclusion, the dietary control of the expression of the 3-PGDH gene in liver seems to involve the negative effects of cysteine and glucagon and the positive effect of insulin.
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PMID:Role of cysteine in the dietary control of the expression of 3-phosphoglycerate dehydrogenase in rat liver. 1054 28

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