EC:2.7.7.8 - FACTA Search

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Query: EC:2.7.7.8 (polynucleotide phosphorylase)
723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Polyriboadenylate polymerase was isolated from Escherichia coli PR7 (RNase I-, pnp) in good yield and high purity. The enzyme catalyzes the polymerization of ATP and ADP. These polymerizations show an initial lag which can be removed by the addition of poly(A). However, poly(A) does not function as a primer. UDP and CDP can also serve as substrates but with decreased efficiency. The polymerization of CDP is enhanced by the presence of an oligonucleotide which again does not function as a primer. Polymerization of [gamma-32P]ATP or [beta-32P]ADP result in products with no radioactivity. The product formed from [alpha-32P]ATP on hydrolysis with alkali yields labeled pAp and 2',3'-AMP; thus the enzyme synthesizes poly(A) chains de novo. During the polymerization of ATP, no burst of free ADP can be detected and the time course of phosphate release from ATP ro ADP follows very closely the kinetics of polymerization. dATP and dADP are effective inhibitors of poly(A) synthesis from either ATP or ADP. Sulfhydryl reagents inhibit only the polymerization of ATP and the inhibition is fully reversed by dithiothreitol. However, the enzyme can be protected from sulfhydryl reagents by preincubation with either ATP or ADP in the absence of Mg2+ which is required for polymerization. Studies using acrylamide gel electrophoresis indicate that the polymerization activity with either ATP or nucleoside diphosphates resides in the same protein. The enzyme catalyzes the following exchanges: 32Pi into ADP, 32Pi into ATP, and [14C] ADP into ATP in the presence of phosphate. While the enzyme catalyzes the phosphorolysis of its own product, (pAp-(Ap)nA), it fails to cleave the dephosphorylated product, (Ap(Ap)nA), or ribosomal RNA or tRNA in the presence of inorganic phosphate. The differences and similarities between poly(A) polymerase and polynucleotide phosphorylase are discussed. Based on the 32P exchange studies and other properties of poly(A) polymerase, a plausible mechanism for its action is proposed.
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PMID:Further studies on the isolation and properties of polyriboadenylate polymerase from Escherichia coli PR7 (RNase I-, pnp). 78 66

The kinetics of 3H-uridine incorporation into measles-infected Vero cells demonstrated that maximum virus-specific RNA synthesis occurred between 16 and 20 h after infection. Sedimentation analysis on sucrose gradients revealed the presence of four species of RNA having sedimentation coefficients 4S, 12 to 26S, 28 to 36S and 50S. Annealing studies showed that RNA sedimenting in the 12 to 36S regions was 100% complementary in base sequence to nucleocapsid 50S RNA, and at least 96% of the 50S genomic RNA was transcribed during virus replication. Polynucleotide binding experiments ane ribonuclease treatment indicated that poly(A) sequences were associated with the intracellular 12 to 26S, 28 to 36S and 50S RNAs. Denaturation of intracellular 50S RNA followed by sucrose gadient centrifugation demonstrated that this was a mixture of genomic 50S and heterogeneous RNAs which sedimented at 4 to 40S. The genomic RNA did not contain poly(A) sequences, and these are presumably associated with the heterogeneously sedimenting RNAs. The size of poly(A) sequences present on the 12 to 36S RNAs was estimated to be in the range of 70 to 140 nucleotides. Treatment of the 12 to 36S RNAs and their poly(A) sequences with polynucleotide phosphorylase indicated that the poly(A) was located on the 3' end of the RNAs, but that under the experimental conditions used this was protected by the secondary structure of the molecules.
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PMID:Rolyadenylic acid [poly(A)] sequences associated with measles virus intracellular ribonucleic acid (RNA) species. 88 16

The disappearance of ribosomes in Escherichia coli cells starved for a carbon source was studied. We used a series of mutants, some of them lacking in ribonuclease I(RNase I, EC 2.7.7.17), and other containing various combinations of modified polynucleotide phosphorylase (PNPase, EC 2.7.7.8) and modified ribonuclease II (RNase II, EC 3.1.4.1). RNA was prepared from the starved mutant cells and separated on polyacrylamide gels. The results obtained indicate that 23 S RNA degradation is similar in all strains that lack RNase I, and is slightly increased in the strain that contains this enzyme. The extent of 16 S RNA degradation is identical in all strains tested. RNA species in the size of 4 S and smaller accumulate in mutants containing modified forms of PNPase and RNase II. The appearance of an RNA species 10% smaller than 16 S RNA (d16 S RNA) was observed in all strains that contain unmodified RNase II. Analysis of ribosomes and polysomes and their RNA content indicated that polysomes are converted to monosomes and these, in turn, to ribosomal subunits. No RNA degradation products were found in polysomes, 70 S, OR 50 C particle; 30 S subunits contained 16 S RNA as well as the d16 S RNA species. Subunits are degraded to a similar extent in all strains lacking RNase I, and at a slightly faster rate in the strain that contains RNase I. The RNA to protein ratio in subunits prepared from starved cells is similar to that of unstarved cultures. Very little degradation of ribosomal proteins occurs in these mutants during carbon starvation. The proteins released from degraded ribosomes are found in the fast sedimenting (20,000 times g) pellet. Cell viability studies indicated a direct correlation between the capacity of the mutants to recovery from starvation and their capacity to degrade RNA. Thus a biological necessity for degradation of ribosomes during starvation is implied. Based on these data we propose that the endonucleolytic degradation of ribosomal RNA is the primary event in starvation degradation. It takes place in ribosomal subunits, which fall apart after the endonucleoltic attack. The RNA pieces produced by this cleavage are degraded to nucleotide by RNase II and PNPase. The ribosomal proteins attach to the cell membrane.
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PMID:The fate of ribosomes in Escherichia coli cells starved for a carbon source. 108 66

Decay of pre-existing ribonucleic acid was studied in Escherichia coli cells subjected to high temperature or to starvation for nitrogen, phosphate, amino acids, or a carbon source. In these studies a series of mutants affected in ribonucleic I(RNase I, EC 3.1.4.22) polynucleotide phosphorylase (EC 2.7.7.8) or ribonuclease II (RNase II, EC 3.1.4.23) were used. Degradation of total RNA and the disappearance of 23 S and 16 S rRNA were followed. The results obtained indicated that, by and large, decay of 23 S and 16 S RNA parallels that of total RNA. Decay of RNA depended on the nuclease content of the cells as well as on the treatment of applied. It was most pronounced during carbon starvation and least in cells deprived of phosphate ions. It was most effective in strains containing all three nucleases and least in the strain defective in all three. The exonucleases polynucleotide phosphorylase and RNase II did not seem to affect the extent of 23 S and 16 S RNA disappearance. Strains with modified exonucleases did accumulate low molecular weight RNA species during treatments which induced considerable degradation of 23 S and 16 S RNA. Based on the above date and previous observations, we suggest that during various starvations a similar mechanism is operative. The 23 S and 16 S RNAs are degraded endonucleolytically, and this is the rate-limiting step during starvation. The exonucleases polynucleotide phosphorylase and RNase II seem to participate primarily in the decay of the low molecular weight RNA species formed by the endonuclease(s), not as yet identified.
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PMID:Decay of ribosomal ribonucleic acid in Escherichia coli cells starved for various nutrients. 109 48

Escherichia coli cells, made permeable to ribonucleoside-5'-diphosphates by treatment with toluene, efficiently promote the synthesis of homo- and heteropolynucleotides. This synthesis is catalyzed by polynucleotide phosphorylase because, among other things, it is inhibited by orthophosphate, and E. coli Q13, a mutant having a Mn-2+-dependent polynucleotide phosphorylase, promotes polynucleotide synthesis in the presence of Mn-2+ but not of Mg-2+. Cells of E. coli B and E. coli MRE 600 (A Mutant lacking ribonuclease I) are about equally active in promoting poly(A, U, G, C) synthesis. Sucrose density gradient and agarose gel electrophoretic analysis of the product show that it is polydisperse with sedimentation coefficients ranging between 4 S and 27 S. The synthesized polynucleotides can be translated by the toluene-treated cells.
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PMID:Synthesis of heteropolyribonucleotides by toluene-treated Escherichia coli cells. 109 65

RNase PH is a Pi-dependent exoribonuclease that can act at the 3' terminus of tRNA precursors in vitro. To obtain information about the function of this enzyme in vivo, the Escherichia coli rph gene encoding RNase PH was interrupted with either a kanamycin resistance or a chloramphenicol resistance cassette and transferred to the chromosome of a variety of RNase-resistant strains. Inactivation of the chromosomal copy of rph eliminated RNase PH activity from extracts and also slowed the growth of many of the strains, particularly ones that already were deficient in RNase T or polynucleotide phosphorylase. Introduction of the rph mutation into a strain already lacking RNases I, II, D, BN, and T resulted in inviability. The rph mutation also had dramatic effects on tRNA metabolism. Using an in vivo suppressor assay we found that elimination of RNase PH greatly decreased the level of su3+ activity in cells deficient in certain of the other RNases. Moreover, in an in vitro tRNA processing system the defect caused by elimination of RNase PH was shown to be the accumulation of a precursor that contained 4-6 additional 3' nucleotides following the -CCA sequence. These data indicate that RNase PH can be an essential enzyme for the processing of tRNA precursors.
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PMID:RNase PH is essential for tRNA processing and viability in RNase-deficient Escherichia coli cells. 164 89

The rapid synthesis and breakdown of mRNA in prokaryotes can impose a significant energy drain on these cells. Previous in vivo studies [Duffy, J. J., Chaney, S. G. & Boyer, P. D. (1972) J. Mol. Biol. 64, 565-579; Chaney, S. G. & Boyer, P. D. (1972) J. Mol. Biol. 64, 581-591] indicated that while RNA turnover in Escherichia coli was hydrolytic, it was nonhydrolytic in Bacillus subtilis. Here we provide an explanation for these observations based on enzymatic analysis of extracts of these two organisms. RNA degradation to the mononucleotide level in E. coli extracts is due solely to two active ribonucleases, RNase II and polynucleotide phosphorylase, which act hydrolytically and phosphorolytically, respectively. RNase II activity represents close to 90% of the total activity of the extract, as expected for predominantly hydrolytic degradation in this organism. In contrast, RNase II is absent from B. subtilis extracts, and the primary mode of RNA degradation is phosphorolytic, employing the Bacillus equivalent of polynucleotide phosphorylase and releases nucleoside diphosphates as products. A low level of a Mn2(+)-stimulated, hydrolytic ribonuclease is also detectable in B. subtilis extracts. Overall, E. coli and B. subtilis extracts differ by about 20- to 100-fold, depending on the substrate, in their relative use of hydrolytic and phosphorolytic routes of RNA degradation. The relation of the mode of mRNA degradation to the environment of the cell is discussed.
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PMID:Enzymatic basis for hydrolytic versus phosphorolytic mRNA degradation in Escherichia coli and Bacillus subtilis. 170 36

Final trimming of the 3' terminus of tRNA precursors in Escherichia coli is thought to proceed by an exonucleolytic mechanism. However, mutant strains lacking as many as four exoribonucleases known to act on tRNA still grow normally and process tRNA normally. Extracts from such a multiple-RNase-deficient strain accurately mature tRNA precursors exonucleolytically in vitro in a reaction that requires inorganic phosphate. Here we show that this reaction is not due to polynucleotide phosphorylase (PNPase) but, rather, that it is mediated by a phosphate-requiring exonuclease that we have named RNase PH. Purified PNPase is incapable of completely processing tRNA precursors, and extracts from a PNPase- strain retain full activity for phosphorolytic processing. Although both PNPase and RNase PH act in a phosphorolytic manner, they differ substantially in size and substrate specificity. RNase PH has a molecular mass of 45-50 kDa and favors tRNA precursors as substrates. The possible physiological role of RNase PH and the advantages of phosphorolytic processing are discussed.
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PMID:RNase PH: an Escherichia coli phosphate-dependent nuclease distinct from polynucleotide phosphorylase. 245 97

RNase A4 is a new RNase activity found as a contaminant in commercial polynucleotide phosphorylase. This enzyme has the ability of hydrolyzing the phosphodiester bond between pyrimidine-A in both loop and paired regions of RNA.
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PMID:A novel RNA digesting activity from commercial polynucleotide phosphorylase. 388 Dec 76

A number of "surface" enzymes of Escherichia coli (i.e., among those selectively released by osmotic shock) all displayed higher specific activities in extracts of minicells than in extracts of typical rod forms; these enzymes included alkaline phosphatase, cyclic phosphodiesterase, acid hexose monophosphatase, 5'-nucleotidase, and ribonuclease I. In addition, alkaline phosphatase, cyclic phosphodiesterase, and acid hexose monophosphatase were cytochemically localized to regions of minicell periplasm that resembled reactive polar enlargements of the periplasm in rod forms. In contrast, a number of "internal" cytoplasmic enzymes (inorganic pyrophosphatase, beta-galactosidase, glutamine synthetase, polynucleotide phosphorylase, and ribonuclease II) showed elevated or similar specific activities in extracts of rod forms versus extracts of minicells. A specific heat-labile inhibitor for 5'-nucleotidase, known to occur in the cytoplasm, also showed no enrichment in minicells. These findings indicate that the "surface" enzymes are segregated in vivo into the terminal minicell buds, possibly because these enzymes are concentrated in the polar enlargements of the periplasm in typical rod forms.
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PMID:Biochemical and cytochemical evidence for the polar concentration of periplasmic enzymes in a "minicell" strain of Escherichia coli. 431 25

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