Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.1.26.3 (RNase III)
 1,015 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To help understand the role of polyadenylation in Escherichia coli RNA metabolism, we constructed an IPTG-inducible pcnB [poly(A) polymerase I, PAP I] containing plasmid that permitted us to vary poly(A) levels without affecting cell growth or viability. Increased polyadenylation led to a decrease in the half-life of total pulse-labelled RNA along with decreased half-lives of the rpsO, trxA, lpp and ompA transcripts. In contrast, the transcripts for rne (RNase E) and pnp (polynucleotide phosphorylase, PNPase), enzymes involved in mRNA decay, were stabilized. rnb (RNase II) and rnc (RNase III) transcript levels were unaffected in the presence of increased polyadenylation. Long-term overproduction of PAP I led to slower growth and irreversible cell death. Differential display analysis showed that new RNA species were being polyadenylated after PAP I induction, including the mature 3'-terminus of 23S rRNA, a site that was not tailed in wild-type cells. Quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) demonstrated an almost 20-fold variation in the level of polyadenylation among three different transcripts and that PAP I accounted for between 94% and 98.6% of their poly(A) tails. Cloning and sequencing of cDNAs derived from lpp, 23S and 16S rRNA revealed that, during exponential growth, C and U residues were polymerized into poly(A) tails in a transcript-dependent manner.
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PMID:Analysis of the function of Escherichia coli poly(A) polymerase I in RNA metabolism. 1059 33

The transient existence of small RNAs free of binding to the RNA chaperone Hfq is part of the normal dynamic lifecycle of a sRNA. Small RNAs are extremely labile when not associated with Hfq, but the mechanism by which Hfq stabilizes sRNAs has been elusive. In this work we have found that polynucleotide phosphorylase (PNPase) is the major factor involved in the rapid degradation of small RNAs, especially those that are free of binding to Hfq. The levels of MicA, GlmY, RyhB, and SgrS RNAs are drastically increased upon PNPase inactivation in Hfq(-) cells. In the absence of Hfq, all sRNAs are slightly shorter than their full-length species as result of 3'-end trimming. We show that the turnover of Hfq-free small RNAs is growth-phase regulated, and that PNPase activity is particularly important in stationary phase. Indeed, PNPase makes a greater contribution than RNase E, which is commonly believed to be the main enzyme in the decay of small RNAs. Lack of poly(A) polymerase I (PAP I) is also found to affect the rapid degradation of Hfq-free small RNAs, although to a lesser extent. Our data also suggest that when the sRNA is not associated with Hfq, the degradation occurs mainly in a target-independent pathway in which RNase III has a reduced impact. This work demonstrated that small RNAs free of Hfq binding are preferably degraded by PNPase. Overall, our data highlight the impact of 3'-exonucleolytic RNA decay pathways and re-evaluates the degradation mechanisms of Hfq-free small RNAs.
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PMID:The crucial role of PNPase in the degradation of small RNAs that are not associated with Hfq. 2235 64

Bacterial RNA processing and degradation involves the co-ordinated action of a large number of RNases, RNA helicases and other proteins. It is not known how this functional network is organized within the cell nor how it is co-ordinated or regulated. In the present study, we show that multiple components of the RNA degradation and processing network of Escherichia coli are localized within extended cellular structures that appear to coil around the periphery of the cell. These include Orn, Hfq, PAP I, RNase III, RppH, RraA and RraB in addition to the previously reported proteins RNase II and RNaseE. Double-label localization studies of several of the proteins showed co-localization of the proteins within the observed structures. Assembly of the proteins into the structures was independent of the MreBCD or MinCDE cytoskeletal systems, RNA synthesis, or nucleoid positioning within the cell. Our results indicate that the components of the RNA processing and degradation network are compartmentalized within the cell rather than diffusely distributed in the cytoplasm. This sequestration provides the cell with a possible mechanism to control access to RNA substrates and to functionally co-ordinate the multiple players of the RNA processing and degradation pathways.
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PMID:The Escherichia coli RNA processing and degradation machinery is compartmentalized within an organized cellular network. 2443 30