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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)

Rabbit globin mRNA species containing poly(A) segments of different lengths were prepared by partial phosphorolysis of mRNA with Escherichia coli polynucleotide phosphorylase. By varying the salt concentration and the time of incubation of the phosphorolysis mixture, as well as performing oligo(dT)-cellulose chromatography at 22 degrees C and at 4 degrees C, globin mRNA preparations containing poly(A) segments of approximately 122, 95, 68, 39, 32, 21, and 16 adenylate residues were obtained. It was found that the functional stability of the mRNA species containing 32 or more adenylate residues after injection into Xenopus laevis oocytes equaled that of the native globin mRNA. On the other hand, the functional stability of mRNA containing an average number of 21 adenylate residues was about 30% of the native mRNA, while that of mRNA containing 16 adenylate residues was as low as poly(A)-free globin MRNA.
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PMID:Globin mRNA species containing poly(A) segments of different lengths. Their functional stability in Xenopus oocytes. 77 10

Isoguanosine-5'-pyrosphosphate, in the presence of an oligonucleotide primer, was polymerized by Escherichia coli polynucleotide phosphorylase under conditions analogous to those required for polymerization of 5'-GMP. The resulting poly(isoguanylic acid), poly(isoG), was a multistranded helix with a stability considerably higher than that of poly(G), and fully resistant to various nucleolytic enzymes. The polymer exhibited a two-step temperature transition profile in moderately alkaline propylene glycol. Alkaline titration in aqueous medium, by ultraviolet and circular dichroism spectroscopy, showed two clearly defined transitions, the second of which was fully cooperative. The accompanying changes in sedimentation constants were consistent with a structure for poly(isoG) of a fourstranded helix, like neutral poly(G). In acid medium, spectral and potentiometric titrations demonstrated the existence of more than one transition in the pH range 6-12, with accompanying protonation of the isoguanosine residues. In neutral medium the polymer formed no complexes with other potentially complementary homopolymers. In acid medium, on the other hand, the protonated form of poly(isoG) did form a triple-stranded complex with poly(I), viz. 2poly(I) . poly(isoG)+. Possible structures are formulated for the neural and protonated forms of poly(isoG) which account for the two-step thermal transition in alkaline propylene glycol and on alkaline titration in aqueous medium. The nature of the protonated form, and its complex with poly(I) is also discussed.
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PMID:Preparation and properties of an analogue of poly(A) and poly(G): poly(isoguanylic acid). 77 26

The inhibitory properties of poly(A) on human spleen ribonuclease have been investigated. Hydrolytic activity has been shown to be strongly inhibited by poly(A) contained within RNAs isolated from a variety of natural sources. Furthermore, poly(A) segments of varying length have been covalently linked at the 3' terminus of Escherichia coli 5 S rRNA by polynucleotide phosphorylase in an attempt to construct an in vitro demonstration of the stabilization of RNA which contains poly(A). The extent to which these poly(A) tracts, varying from 4 to 132 nucleotides in length, could inhibit endonucleolytic attack on the 5 S rRNA to which they are linked was found to be dependent upon their length and upon small changes in spermidine concentration. The consequences of these findings are discussed in terms of a possible role for poly(A).
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PMID:Stabilization of an RNA molecule by 3'-terminal poly (A)-induced inhibition of RNase activity. 77 65

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

It is already known that modification of E. coli polynucleotide phosphorylase by endogenous proteolysis induces drastic changes in both phosphorolysis and polymerisation reactions. The structural parameters of the proteolysed polynucleotide phosphorylase are described. The phosphorolysis of polynucleotide, which is quite progressive for the native enzyme, is shown to be only partially progressive for the degraded enzyme, owing to the loss of polymer attachment sites.
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PMID:Study on the structure-function relationship of polynucleotide phosphorylase: model of a proteolytic degraded polynucleotide phosphorylase. 79 31

The release of lipoteichoic acid and mesosomal vesicles to the supernatant buffer during the formation of spherical, osmotically fragile bodies was studied using Streptococcus faecalis ATCC 9790. Autolytic N-acetylmuramidase action was permitted to take place in exponential-phase cells incubated in a buffer which provides an exceptional degree of osmotic stabilization. Both lipoteichoic acid and mesosomal vesicles were relatively rapidly released to the supernatant buffer. Most of the cellular content of lipoteichoic acid (and mesosomal vesicles) was found in the supernatant buffer at incubation times when the cells still retained over 75% of their cell wall. [14-C]- or [3-H]glycerol was used as a label for both cellular lipoteichoic acids and lipid-glycerol. Glycerol in lipoteichoic acid was quantitated after phenol-water and chloroform-methanol treatments and identified by products of acid hydrolysis and its ability to be precipitated by (i) antibodies specific for the polyglycerol-phosphate backbone, (ii) antibodies to the streptococcal group D antigen, and (iii) concanavalin A. Evidence was obtained that lipoteichoic acid was not associated with isolated mesosomal vesicles. Centrifugation of supernates at 200,000 X g sedimented membranous (mesosomal) vesicles and nearly all of the lipid-glycerol present, whereas essentially all of the lipoteichoic acid remained in the supernatant. The sedimented mesosomal vesicles differed from protoplast membrane in their higher lipid-phosphorus to protein ratio and in the absence of detectable levels of two enzymatic activities found in protoplast membranes, adenosine triphosphatase and polynucleotide phosphorylase. Both types of membranes were found to contain DD-carboxypeptidase and LD-transpeptidase activities at nearly the same specific activities. No evidence was obtained for the association of autolytic N-acetylmuramidase activity with either type of membrane preparation.
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PMID:Cellular localization of lipoteichoic acid in Streptococcus faecalis. 80 56

According to Cleland's theoretical predictions, inosine phosphorolysis catalyzed by chicken and pigeon's liver PNPase (Purine nucleoside:ortophosphate ribosyltransferase. E.C. 2.4.2.1.) appears to be a rapid equilibrium random bi-bi with "dead end" enzyme-phosphate-hypoxantine complex. This mechanism implies the existence of two essential active centers in the enzymatic molecule to which inosine and phosphate attach themselves independently. The observed lack of analogy in the PNPase mechanism of mechanism of different species seems to suggest the existence of structural differences between them.
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PMID:[Purine nucleoside phosphorylase. Catalytic reaction mechanism. II. Product-reaction-inhibition (author's transl)]. 81 90

An affinity analog with a 5-bromoacetamido uridine 5'-phosphate moiety bonded to the 3' end of A-U-G has been prepared with the aid of polynucleotide phosphorylase. This 3'-modified, chemically reactive A-U-G analog was used to probe the ribosomal codon binding site. The yield of the reaction depended strongly on the ribosomal source and was sensitive to salt-washing ribosomes. The major crosslinking product was identified to be protein S1. Since the reaction of this 3'-modified A-U-G programmed ribosomes for Met-tRNA-Met-M binding, it is concluded that protein S1 is located at or near the 3'-side of the ribosomal codon binding site.
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PMID:Location of protein S1 of Escherichia coli ribosomes at the 'A'-site of the codon binding site. Affinity labeling studies with a 3'-modified A-U-G analog. 82 27

Purified preparations of pigeon liver PNPase (E.C. 2.4.2.1) have been obtained by acid preparation of liver homogenates at pH = 5,followed by a fractionation with ammonium sulphate (25-50% saturation) and by a chromatographic adsorption on DEAE-cellulose. The preparation obtained shows a PNPase specific activity 325 times greater than that of the original homogenates. Kinetic studies carried out with homogenates and purified preparations of pigeon liver PNPase seem to suggest that inosine and deoxynosine react on the same catalytic site of the enzyme molecule.
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PMID:[Purification of purine nucleoside phosphorylase activity on deoxyinosine (author's transl)]. 82 97

In the phosphorolytic degradation catalyzed by chicken liver PNPase (E.C. 2.4.2.1) inosine appears to behave as a better substrate than xanthosine. Hypoxanthine, xanthine, guanine and purine (1 X 10(-1)M) appear to be inhibitors of the pigeon liver PNPase, whereas allopurinol, ATP, ITP, CTP and UTP (1. X 10(-3) M) do not inhibit the enzyme. Both PNPase activities exhibit the same optimum temperature (37-40 degrees C). Chicken liver PNPase optimum pH is in the range 6.5-7, whereas that of pigeon liver is in the range 7-7.5. Lineweaver-Burk plots for the inosine phosphorolysis catalyzed by chicken liver PNPase yielded straight lines if substrate concentrations were lower than 1 X 10(-4) M but concave downward curves at higher concentrations. This activation increases when the homogenates are stored at 4 degrees C and pH = 7 during 24 h or more; pigeon liver PNPase does not show this activation phenomenon.
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PMID:[Purine metabolites in the activity of purine nucleoside phosphorylase (author's transl)]. 82 98

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