Gene/Protein
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Gene/Protein
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Target Concepts:
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Query: EC:2.7.7.6 (
RNA polymerase
)
34,946
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A thermosensitive conditional yeast mutant (ts-187) which suppresses protein synthesis at the nonpermissive temperature (36 degrees C) also suppresses RNA synthesis. The effect of temperature on the mutant is similar to the addition of cycloheximide--it inhibits the incorporation of labeled precursors into RNA in both whole cells and isolated nuclei. The effect of temperature is selective for the RNA polymerases bound to the nuclear template but not for the total RNA polymerases. Thus, the specific activities and total amounts of
RNA polymerase
species extracted and assayed with exogenous DNA template are similar in the ts-187 cultured at 23 degrees C and at 36 degrees C. On the contrary, the nuclear polymerases, i.e., RNA synthesis in isolated nuclei, are dramatically inhibited in cells cultured at 36 degrees C. When amino acid starved ts-187 cells are transferred to 36 degrees C, release from the inhibtion of RNA synthesis is observed. As with the addition of cycloheximide, this relaxation is observed in cells but not in isolated nuclei. The parental strain, A364A, which responds by stimulating instead of inhibiting protein synthesis when the temperature is increased to 36 degrees C, also exhibits an inhibition in the incorporation of labeled precursor into RNA as well as reducing RNA synthesis in isolated nuclei. However, these are transitory inhibitions and afterward there is reinitiation of both processes. Reinitiation of RNA synthesis in isolated nuclei is similar to the relaxed phenomenon and it is called "nuclear relaxation". This relaxation can only be obtained if protein synthesis is not inhibited; however, cellular relaxation occurs in the absence of protein synthesis. The repression of the nuclear
RNA polymerase
activities which starvation and inhibition of protein synthesis produce appears to be due to a restriction in the nuclear DNA template. This notion is supported by the fact that a net diminution of these nuclear enzyme activities is observed in spheroplasts cultured under starving conditions. Studies of the four main ribonucleotide pools indicate that stringency and inhibition of protein synthesis (ts-187 cultured at 36 degrees C) produce an increase in UTP and CTP pools. This is consistent with the concept that stringency and inhibition of protein synthesis affect the rate of utilization rather than the synthesis of these ribonucleotide residues. In the A364A and ts-187 yeast strains, the conversion of uracil but not of uridine into the UTP and CTP is inhibited when there is inhibition of the nuclear RNA polymerases. This indicates that the
uracil phosphoribosyltransferase
but not the uridine-cytidine kinase is allosterically inhibited by UTP and CTP in yeast. The feedback inhibition in the metabolic pathway of the base explains why relaxation cannot be detected when uracil instead of uridine is used as the labeled RNA precursor.
...
PMID:Control of ribonucleic acid synthesis in eukaryotes. 2. The effect of protein synthesis on the activities of nuclear and total DNA-dependent RNA polymerase in yeast. 77 13
Transcriptional attenuation of the pyrimidine biosynthetic (pyr) operon from Bacillus subtilis was reconstituted with an in vitro system that consisted of pyr DNA templates, B. subtilis
RNA polymerase
, four ribonucleoside triphosphates, and the purified B. subtilis PyrR regulatory protein. The templates used each specified one of the three known attenuation regions of the pyr operon. Runoff (read-though) and terminated transcripts of the predicted lengths were the only major products synthesized. Transcription of the template that specifies the 5' leader attenuation region of the operon was examined in detail. Termination of transcription at the attenuator was strongly promoted by the combination of PyrR plus UMP. The concentration of UMP required for half-maximal effect was 2.5 microM. UTP also promoted termination in the presence of PyrR, but concentrations 10-fold higher than UMP were required; UDP was only effective at 100 times the concentration of UMP. Other pyrimidine and purine metabolites tested did not affect termination. PRPP, which like UMP is a substrate for the
uracil phosphoribosyltransferase
activity of PyrR, antagonized UMP-dependent transcriptional termination, but uracil did not. Transcriptional attenuation by PyrR plus UMP was also demonstrated in vitro with templates from the other two pyr attenuation regions. The results strongly support the model for transcriptional regulation of the B. subtilis pyr operon previously proposed by R. J. Turner, Y. Lu, and R. L. Switzer (J. Bacteriol. 176:3708-3722, 1994).
...
PMID:Transcriptional attenuation of the Bacillus subtilis pyr operon by the PyrR regulatory protein and uridine nucleotides in vitro. 895 3
