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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)
The interaction of pyridoxal, pyridoxal-5'-mono-, di- and triphosphate with certain enzymes of polynucleotide synthesis (DNA-dependent RNA polymerase, DNA-dependent DNA polymerase I and
polynucleotide phosphorylase
from Escherichia coli and terminal deoxyribonucleotide transferase from calf thymus) was studied. All compounds tested was found to be reversible and competitive inhibitors of these enzymes. The reduction of the enzyme-inhibitor complex with NaBH4 gives rise to the complete irreversible inhibition of the enzymes under study. The comparison of the inhibition constants for pyridoxal and its phosphorylated derivatives with those for mono-, di- and triphosphates of nucleosides was carried out for the enzymes. The results obtained suggest that the modified epsilon-amino-group of lysine residue should be localized at the catalytic site in the vicinity of the pyrophosphate binding area of an enzyme.
Mol
Biol (Mosk)
PMID:[Interaction of oligophosphates of pyridoxal with certain enzymes of polynucleotide synthesis]. 38 98
Escherichia coli was depleted of active ribosomes by a thermal shock at 47 degrees C which quantitatively destroyed the 30S ribosomal subunits. During recovery, RNA is synthesized while protein synthesis resumes only after about 90 minutes. It is shown that lac mRNA is synthesized in the complete absence of ribosomal activity and hence RNA synthesis is not coupled to protein synthesis. Transcription time and average transcript length were slightly less than in untreated cells. lac mRNA was degraded much more slowly in bacteria depleted of ribosomes. In E. coli W both functional half life (T 1/2 = 28 min vs. 2.25 in untreated cells) and chemical stability. The analysis of rna and pnp mutants showed that
polynucleotide phosphorylase
is involved in lac mRNA degradation in heat treated cells but that RNase I is not. The functional T 1/2 was increased in pnp mutants and was 95 min during the recovery period. The rate of chemical decay is so slow that the half-life cannot be accurately determined.
Mol
Gen Genet 1979 Jun 07
PMID:Synthesis and degradation of lac mRNA in E. coli depleted of 30S ribosomal subunits. 38 32
In a mutant strain defective in
polynucleotide phosphorylase
, under conditions where the enzyme becomes limiting, it is possible to demonstrate that chemical as well as functional half lives of mRNA become longer if the strain is also missing ribonuclease II. These results allow to unify in a simple model a variety of observations about turnover of RNA in a variety of bacteria.
Mol
Gen Genet 1975 Sep 08
PMID:Polynucleotide phosphorylase can participate in decay of mRNA in Escherichia coli in the absence of ribonuclease II. 110 47
The Escherichia coli glyA structural gene is followed by two REP sequences and a rho-independent transcription terminator. These sequences are essential for maintaining glyA mRNA stability and gene expression by blocking the 3' to 5' exonucleolytic activities of
polynucleotide phosphorylase
and ribonuclease II. The results support the model of cooperative endonucleolytic and 3' to 5' exonucleolytic activities in mRNA decay.
Mol
Gen Genet 1990 Jan
PMID:Escherichia coli glyA mRNA decay: the role of 3' secondary structure and the effects of the pnp and rnb mutations. 169 34
The transcripts of the rpsO-pnp operon of Escherichia coli, coding for ribosomal protein S15 and
polynucleotide phosphorylase
, are processed at four sites in the 249 nucleotides of the intercistronic region. The initial processing step in the decay of the pnp mRNA is made by RNase III, which cuts at two sites upstream from the pnp gene. The other two cleavages are dependent on the wild-type allele of the rne gene, which encodes the endonucleolytic enzyme RNase E. The cuts are made 37 nucleotides apart at the base of the stem-loop structure of the rho-independent attenuator located downstream from rpsO. The cleavage downstream from the attenuator generates an rpsO mRNA.nearly identical with the monocistronic attenuated transcript, while the cleavage upstream from the transcription attenuator gives rise to an rpsO mesage lacking the terminal 3' hairpin structure. The rapid degradation of the processed mRNA in an rne+ strain, compared to the slow degradation of the transcript that accumulates in an rne- strain, suggests that RNase E initiates the decay of the rpsO message by removing the stabilizing stem-loop at the 3' end of the RNA.
J
Mol
Biol 1991 Jan 20
PMID:Decay of mRNA encoding ribosomal protein S15 of Escherichia coli is initiated by an RNase E-dependent endonucleolytic cleavage that removes the 3' stabilizing stem and loop structure. 170 67
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.
...
PMID:Enzymatic basis for hydrolytic versus phosphorolytic mRNA degradation in Escherichia coli and Bacillus subtilis. 170 36
Two 3'-5' exoribonucleases,
polynucleotide phosphorylase
and ribonuclease II play a central role in the degradation of bacterial mRNA to ribonucleotides. Sequences with the potential to form stem-loop structures can stabilize upstream mRNA against 3'-5' exoribonucleolytic attack in vivo by blocking the processive activities of these enzymes. For many mRNA species stem-loop structures appear to provide a very efficient block to decay from the 3' end, such that the rate-determining step for mRNA decay occurs elsewhere in the transcript. We have examined the stalling of 3'-5' exoribonucleases at stem-loop structures in vitro. Although stem-loop structures alone can impede the progress of both enzymes, the duration of stalling at these structures in vitro is insufficient to account for the increased half-lives that they confer on mRNA in vivo. These data suggest that an additional factor, such as a stem-loop binding protein, is required for stabilization of mRNA by stem-loop structures in vivo. The implications for the regulation of mRNA stability are discussed.
J
Mol
Biol 1991 Sep 05
PMID:mRNA degradation by processive 3'-5' exoribonucleases in vitro and the implications for prokaryotic mRNA decay in vivo. 192 Apr 21
Filaments formed by the polymerization of RecA protein along DNA in the presence of Mg2+ and adenosine 5'-0-(3-thiotriphosphate) (ATP gamma S) are seen by electron microscopy to have a 10 nm diameter with a 9 nm helical repeat. When certain preparations of apparently pure RecA protein are incubated with Mg2+ and ATP gamma S in the absence of nucleic acid for extended times, very long filaments with the same 10 nm diameter and 9 nm axial repeat are seen. We show here that these long 10 nm filaments can contain RNA which is present as a contaminant of the RecA protein and poly(A) which is synthesized during the incubations by an activity that is apparently
polynucleotide phosphorylase
. RecA protein purified by a procedure developed in this laboratory did not contain RNA and did not form these very long 10 nm filaments. However, when exogenous RNA was added to this protein, 10 nm filament formation was observed.
Mol
Gen Genet 1985
PMID:10 nm RecA protein filaments formed in the presence of Mg2+ and ATP gamma S may contain RNA. 241 90
In this paper we examine the binding of Escherichia coli transcription termination factor rho to single-stranded RNA. Random polyribonucleotide copolymers containing low ratios of the fluorescent base 1,N6-ethenoadenosine have been synthesized using
polynucleotide phosphorylase
. Binding of rho to these polynucleotides elicits a significant increase in fluorescence, thus allowing either the direct monitoring of the titration of these polynucleotides with rho or measurement of the competitive displacement of the protein from these probes with other nucleic acids, even in the presence of biologically significant concentrations of ATP. By these techniques, it is shown that the binding site size (n) of rho protein to polynucleotides is 13(+/- 1) nucleotide residues per rho monomer (or 78(+/- 6) nucleotide residues per rho hexamer). Binding constants (K) and co-operativity parameters (omega) for the binding of rho to these polynucleotides have been measured as a function of nucleotide composition and of salt concentration. The results show that the affinity of rho for cytosine residues is quite strong and salt concentration independent, whilst binding to uridine residues is somewhat weaker and very salt concentration dependent. Poly(rC) and poly(dC) bind to rho competitively and with equal affinity and site size, although poly(rC) is the strongest cofactor for activating rho-dependent ATPase and poly(dC) has no ATPase cofactor activity at all. It is also shown that ATP (or ADP or ATP-gamma-S) binding does not change the binding site size of rho on RNA nor decrease its affinity for RNA binding. Circular dichroism measurements of rho binding to phage R17 RNA suggest that the affinity (K omega) of rho for RNA may be increased by ATP. The possible significance of these results for models of rho-dependent transcription termination is discussed in the companion paper.
J
Mol
Biol 1988 Feb 20
PMID:Interactions of Escherichia coli transcription termination factor rho with RNA. I. Binding stoichiometries and free energies. 245 Oct 28
We have characterized a chloroplast processing activity that catalyzes the conversion of the plastid cytochrome b6/f subunit IV (pet D) mRNA 3' end precursor to the mature RNA possessing a 3' inverted repeat (IR). In a chloroplast soluble protein extract, the activity requires Mg2+ or Mn2+, but not K+. In the absence of Mg2+, the pet D 3' IR-RNA product does not accumulate, and UV-cross-linking indicates that the 3' IR-RNA precursor binds several new proteins in addition to those previously characterized as part of the 3' IR-RNA: protein complex in vitro. In contrast, high concentrations of Zn2+ or Cu2+ suppress protein binding and inhibit the processing reaction. The purified exoribonuclease
polynucleotide phosphorylase
(E.C.2.7.7.8) is not efficient in processing the pet D 3' IR-RNA precursor, whereas Escherichia coli ribonuclease II rapidly processes the pet D IR-RNA precursor to a product of a size similar to that of the mature 3' IR-RNA, but also rapidly degrades the mature RNA in the absence of chloroplast extract. We therefore conclude that the maturation of the pet D mRNA in vitro requires specific chloroplast enzymes which process the mRNA 3' end precursor in the absence of efficient transcription termination. The chloroplast enzyme activities are biochemically distinct from their bacterial counterparts. We also note that specific chloroplast components may be required to stabilize the mature pet D mRNA 3' end against further exonucleolytic degradation.
Plant
Mol
Biol 1989 Dec
PMID:Chloroplast mRNA 3' end maturation is biochemically distinct from prokaryotic mRNA processing. 248 89
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