EC:3.1.27.4 - FACTA Search

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Query: EC:3.1.27.4 (ribonuclease)
6,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hormones play a role in the regulation of gene expression by inducing changes in enzyme patterns in target cells mediated by the synthesis of specific RNA molecules. Erythropoiesis has been used as a system for studying the molecular mechanism of regulation of gene action by means of two hormones: erythropoietin and testosterone. Experiments designed to correlate the biochemical action of both hormones on rat marrow cells are herein reported. Both factors seems to act at different biochemical and citological levels. Erythropoietin triggers the erythropoietic process acting on the erythropoietin sensitive cells (ESC), in which the hormone induces the synthesis of a high molecular weight RNA, which is the precursor of a functional 9 S messenger RNA. Testosterone seems to act on polychromatophilic erythroblasts, in which the synthesis of ribosomal RNA or its precursor is stimulated. The steroid enhances the nuclear ribonuclease activity, which could represent a control mechanism for the processing (maturation) of high molecular weight RNAs. The incorporation of 3H-GTP and 3H-UTP into RNA by isolated rat bone marrow nuclei is stimulated by erythropoietin and testosterone. Using alpha-amanitine and different ionic strength conditions it was found that erythropoietin enhances preferentially RNA polymerase II activity while testosterone increases RNA polymerase I activity. It is postulated that erythropoietin and testosterone act synergically to create the biochemical machinery for hemoglobin synthesis, the macromolecule that characterizes the erythropoietic process.
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PMID:Hormonal control of gene expression: differential activation of rat bone marrow RNA polymerases by erythropoietin and testosterone. 9 87

Fidelity of preribosomal RNA transcription in vitro was studied after selective deproteinization of nucleoli using either sequential salt extraction or sodium deoxycholate treatment. Homochromatography fingerprinting and identification of marker oligonucleotides from a T1 ribonuclease digest of the transcripts were used to evaluate the RNA products. These studies indicated that: (1) nucleoli retained their endogenous RNA polymerase I activity and the specificity of transcription up to 0.6 M NaCl extraction; (2) exogenous RNA polymerase I transcribed nucleolar chromatin only after 1.0 M NaCl extraction and the transcription pattern, like that of totally deproteinized DNA, was completely random; (3) extraction of nucleoli with deoxycholate resulted in a DNP complex in which the endogenous RNA polymerase I transcribed pre-rRNA specifically; however, it also initiated random transcription, producing a "mixed" fingerprint pattern on the homochromatogram. The random transcription was selectively inhibited either by deoxycholate or rifampicin AF/013. These studies indicate that the selectivity of pre-rRNA transcription is due both to the endogenous RNA polymerase I molecules that were involved in transcription in vivo and are tightly bound to the template and to factors in intact nucleoli which prevent random transcription by the released RNA polymerase I molecules.
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PMID:Studies on the specificity of preribosomal RNA transcription in nucleoli after selective deproteinization. 11 95

The tRNATyr precursor molecule, synthesized from phi 80 psu3+ DNA (containing a single tRNA gene) by DNA-dependent RNA polymerase and q factor, was about 205 nucleotides long. The main product of its digestion with a ribonuclease tii preparation from Escherichia coli showed the same electrophoretic mobility as tRNAtyr precursor isolated in vivo and was found to be identical to it when analysed using fingerprint techniques. This intermediate precursor synthesized in vitro was converted further by processing with ribonuclease P into an RNA identical size to mature tRNATyr. It was concluded that the initiation of transcription of the tRNATyr gene in vitro occurs at the same site as that of transcription in vivo and a termination occurs at about 80 nucleotides beyond the CCA end of tRNATyr.
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PMID:Processing by ribonuclease II of the tRNATyr precursor of Escherichia coli synthesized in vitro. 32 7

When treated at pH less than 4.5, yeast nuclei or chromatin lose endogenous RNA synthetic activity. This activity is regained by addition of exogenous RNA polymerases. The specificity of transcription in this system by homologous RNA polymerases I and III has been investigated by gel electrophoresis, hybridization analysis, and RNase T1 mapping. Exogenous RNA polymerase I selectively transcribes rRNA genes. The transcription of these genes by polymerase I is 30- and 8-fold more selective than RNA polymerase III and Escherichia coli polymerase holoenzyme, respectively. Exogenous RNA polymerase III synthesized RNAs similar in size to authentic 5 S RNA, 4.5 S pre-tRNA, and 4 S tRNA. Eleven per cent of this RNA is 5 S RNA as determined by hybridization. Neither polymerase I nor E. coli polymerase synthesizes detectable quantities of RNA in this size range. AT1 ribonuclease digestion of 5 S RNA synthesized by exogenous RNA polymerase III acting on acid-treated chromatin gives a fragment pattern corresponding to that of 5 S RNA. Thus, RNA polymerase III transcribes the entire 5 S gene in this system.
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PMID:Specific gene transcription in yeast nuclei and chromatin by added homologous RNA polymerases I and II. 36 64

The effects of fasting, and subsequent force-feeding of L-tryptophan on the activity of hepatic nuclear DNA-dependent RNA polymerases were studied in adult (5-6 weeks old), and old (5-6 months) male Wistar rats. Liver nuclei, nucleoli, and nucleoplasmic fraction were isolated from rats following a single tube-feeding of tryptophan or water, and were assayed in vitro for the activity of different RNA polymerases. Whereas in adult rats 24 h of fasting caused a significant reduction in the activity of RNA polymerase I and II, in old rats the activity of only polymerase II was decreased after 24 h of fasting. In fasted adult rats administration of tryptophan promptly restored the activities of both polymerases to the respective normal fed levels, while in old rats none of the polymerases were affected by tryptophan. In fasted adult rats the pattern of response for both forms of polymerases to a single tube-feeding of tryptophan, over a period of 5 h, was found to be biphasic. When ribonuclease activity of nuclei was suppressed by performing incubations at low temperatures (17-30 degrees C) the difference between the two groups for polymerase I was greatly reduced, and for polymerase II the difference was fully abolished. Pre-treatment of fasted adult rats with cycloheximide (1.5 mg/kg) was found to abolish the 30 min tryptophan-mediated stimulation of both polymerase I and II activities. In cycloheximide pretreated rats the activity of polymerase II, but not polymerase I returned to its original level 5 h after tryptophan force-feeding.
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PMID:Effects of fasting and tryptophan force-feeding on the activity of hepatic nuclear RNA polymerases in rats. 52 54

Nuclei of GH3 cells, isolated by detergent lysis, synthesized RNA for an extended period at 29 degrees C in the presence of rat liver ribonuclease inhibitor (RI). Extended RNA synthesis was dependent upon the presence of RI. Sucrose gradient sedimentation analysis of the cell-free reaction products showed that RNAs ranging from 4 S to greater than 28 S were synthesized. Further characterization of the RNA products was made by examining the sensitivity of synthesis to alpha-amanitin and actinomycin D as well as by oligo(dT)-cellulose binding properties. Evidence was obtained that RNA polymerases I, II, and III were functioning in isolated GH3 nuclei. Newly synthesized RNAs were found in both the nuclear pellet and postnuclear supernatant fractions. RNA polymerase I products remained associated with the nuclear pellet throughout a 60-min incubation period whereas RNAs synthesized by RNA polymerase III emerged rapidly into the supernatant fraction. RNA polymerase II products were distributed in both fractions and were found to contain poly(A). De novo poly(A) synthesis was demonstrated and found to be inhibited by cordvcepin triphosphate (3'-dATP). Supernatant RNAs synthesized by polymerase II contained a poly(A) segment of about 150 adenine residues; these transcripts sedimented heterogeneously with an apparent size distribution (under denaturing conditions) which was smaller than that of nuclear RNA polymerase II products and which resembled that of cellular mRNA. Qualitative differences in the nuclear and supernatant RNAs, the kinetics of appearance of the latter, and the differential effect of 3'-dATP on the extranuclear appearance of supernatant RNAs suggest that a process resembling nuclear-cytoplasmic RNA transport occurred in this cell-free nuclear system.
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PMID:Extended RNA synthesis in isolated nuclei from rat pituitary tumor cells. 98 56

We have described an in vitro system in which active su+III tRNATyr is synthesized from a phi80psu++III DNA template. Using this system, we have identified four essential components that are required for synthesis of tRNA. The first of these is DNA-dependent RNA polymerase. It has been shown that a crude preparation of DNA-dependent RNA polymerase synthesizes su++III tRNATyr precursor similar to that which has been isolated in vivo, and that this preparation is capable of supporting high levels of tRNA synthesis. With purified DNA-dependent RNA polymerase, the su++III tRNATyr precursor was not observed as a transcription product and tRNA synthesis was below detetable levels. On this basis, a second essential component for tRNA synthesis was identified. This fraction, designated Fraction V, in combination with purified RNA polymerase, catalyzes the synthesis of precursor tRNA. The third component is a ribonuclease (RNase P III), which specifically catalyzes the removal of the extra nucleotides present at the 3' terminus of the tRNA precursor. In the absence of this fraction, the in vitro synthesized su++III tRNATyr is slightly larger than 4 S and contains additional nucleotides beyond the normal --CCAOH 3 terminus of the mature tRNA. The fourth essential component required is a fraction containing RNase P, a previously identified endonuclease which specifically catalyzes the removal of the 5' extra nucleotides present on tRNA precursors.
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PMID:In vitro synthesis of transfer RNA. I. Purification of required components. 109 89

We have shown that the synthesis of active su+III tRNATyr from a phi80psu+III DNA template requires the action of four distinct enzymatic activities. The first of these, DNA-dependent RNA polymerase, catalyzes the formation of a large molecular weight transcript, initiating synthesis at a specific site 41 nucleotides proximal to the 5' end of the su+III tRNATyr structural gene and continuing at least 100 nucleotides beyond the 3' terminus of the su+III tRNATyr sequence. The second required component, designated Fraction V, allows purified DNA-DEPENDENT RNA polymerase to function in tRNA synthesis. We have shown that this fraction contains an endonuclease that together with DNA-dependent RNA polymerase is responsible for the synthesis of su+III tRNATyr "precursor". Thus, su+III tRNATyr precursor is not itself the primary transcription product of the su+III tRNATyr gene, but rather, it arises as a result of post-transcriptional cleavage of a much larger transcript by the action of the nuclease present in Fraction V. The third enzymatic activity required for synthesis of active su+III tRNATyr is a ribonuclease (RNase P III) that specifically catalyzes the removal of the 3' extra nucleotides from the su+III tRNATyr precursor. The fourth activity required for synthesis of tRNA is a previously identified endonuclease, RNase P, that specifically catalyzes the removal of the 5' extra nucleotides from tRNA precursors. The properties of RNase P purified according to the procedure developed in this laboratory have been compared with those of the enzyme purified from ribosomes according to the procedure described by Robertson et al. (Robertson, H.D., Altman, S., and Smith, F.D. (1972) J.Biol. Chem. 247, 5243-5251.).
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PMID:In vitro synthesis of transfer RNA. II. Identification of required enzymatic activities. 109 90

A single ip injection of triiodothyronine (T3; 30 mug/100 g BW) to thyroidectomized rats markedly stimulates RNA synthesis in isolated liver nuclei. The increased level of RNA synthesized in vitro by isolated nuclei does not depend on a reduced degradation of the nascent RNA molecules, since ribonuclease activities are not affected by the administration of T3. In addition, our results have confirmed previous findings of Tata et al. that the increase in nucleolar alpha-amanitin-resistant RNA polymerase I activity at low ionic strength always preceded the rise of the nucleoplasmic alpha-amanitin-sensitive RNA polymerase II activity at high ionic strength. Moreover, it has been found that a significant increase in an alpha-amanitin-resistant activity at high ionic strength occurs as early as 10 h after hormone injection. This enzyme, which forms RNA with a U to G ratio significantly higher than that of RNA synthesized by the nucleolar alpha-amanitin-resistant enzyme, is probably nucleoplasmic RNA polymerase III which is though to synthesize 5S and transfer RNAs. The possible role and the mechanism(s) of the early and concomitant increase in nucleolar and nucleoplasmic alpha-aminitin-resistant activities, and of the subsequent rise of RNA polymerase II activity following T3 administration are discussed.
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PMID:Sequential stimulation of nuclear RNA polymerase activities in livers from thyroidectomized rats treated with triiodothyronine. 119 15

It has been reported (Iborra et al. (1979) J. Biol. Chem. 254, 10920-10924) that the third and the fifth largest subunit of yeast RNA polymerase I exhibit ribonuclease H activity. The authors suggested that the third largest subunit is identical with the chromatin-associated ribonuclease H49, the putative yeast equivalent of bovine ribonuclease H IIb. Although the third largest subunit of calf thymus RNA polymerase I and ribonuclease H IIb display nearly identical molecular masses under denaturing conditions, serological analysis reveals that, in contrast to their counterparts in yeast, these mammalian proteins are distinct entities. Interestingly, sera from some patients with mixed connective tissue disease which contain antibodies directed against RNA polymerase I, also react with ribonuclease H IIb epitopes. This observation suggests that a protein displaying ribonuclease H IIb antigenicity could be associated with RNA polymerase I. Additional indications supporting this conclusion are discussed.
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PMID:Class II ribonuclease H comigrates with, but is distinct from, the third largest subunit of calf thymus RNA polymerase I. 169 96

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