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Query: UNIPROT:P06889 (Mol)
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Transfer of F-like plasmids is regulated by the FinOP system, which controls the expression of traJ, a positive regulator of the transfer operon. F FinP is a 79 base antisense RNA, composed of two stem-loops, complementary to the 5' untranslated leader of traJ mRNA. Binding of FinP to the traJ leader sequesters the traJ ribosome binding site, preventing its translation and repressing plasmid transfer. The FinO protein binds stem-loop II of FinP and traJ mRNA and promotes duplex formation in vitro. FinO stabilizes FinP, increasing its effective concentration in vivo. To determine how FinO protects FinP from decay, the degradation of FinP was examined in a series of ribonuclease-deficient strains. Using Northern blot analysis, full-length FinP was found to be stabilized sevenfold in an RNase E-deficient strain. The major site of RNase E cleavage was mapped on synthetic FinP, to the single-stranded region between stem-loops I and II. A secondary site near the 5' end ( approximately 10 bases) was also observed. A GST-FinO fusion protein protected FinP from RNase E cleavage at both sites in vitro. Two duplexes between FinP and traJ mRNA were detected in an RNase III-deficient strain. The larger duplex resulted from extension of the FinP transcript at its 3' end, suggesting readthrough at the terminator that corresponds to FinP stem-loop II. A point mutant of finP (finP305; C30U) that is unable to repress traJ in the presence of FinO was also characterized. The pattern of RNase E digestion of finP305 RNA differed from FinP, and GST-FinO did not protect finP305 RNA from cleavage in vitro. The half-life of finP305 RNA decreased more than tenfold in vivo, such that the steady-state levels of finP305 RNA, in the presence of FinO, were insufficient to significantly reduce the level of traJ mRNA available for translation, allowing derepressed levels of transfer.
J Mol Biol 1999 Jan 29
PMID:Degradation of FinP antisense RNA from F-like plasmids: the RNA-binding protein, FinO, protects FinP from ribonuclease E. 991 89

Metabolic instability is a hallmark property of mRNAs in most if not all organisms and plays an essential role in facilitating rapid responses to regulatory cues. This article provides a critical examination of recent progress in the enzymology of mRNA decay in Escherichia coli, focusing on six major enzymes: RNase III, RNase E, polynucleotide phosphorylase, RNase II, poly(A) polymerase(s), and RNA helicase(s). The first major advance in our thinking about mechanisms of RNA decay has been catalyzed by the possibility that mRNA decay is orchestrated by a multicomponent mRNA-protein complex (the "degradosome"). The ramifications of this discovery are discussed and developed into mRNA decay models that integrate the properties of the ribonucleases and their associated proteins, the role of RNA structure in determining the susceptibility of an RNA to decay, and some of the known kinetic features of mRNA decay. These models propose that mRNA decay is a vectorial process initiated primarily at or near the 5' terminus of susceptible mRNAs and propagated by successive endonucleolytic cleavages catalyzed by RNase E in the degradosome. It seems likely that the degradosome can be tethered to its substrate, either physically or kinetically through a preference for monphosphorylated RNAs, accounting for the usual "all or none" nature of mRNA decay. A second recent advance in our thinking about mRNA decay is the rediscovery of polyadenylated mRNA in bacteria. Models are provided to account for the role of polyadenylation in facilitating the 3' exonucleolytic degradation of structured RNAs. Finally, we have reviewed the documented properties of several well-studied paradigms for mRNA decay in E. coli. We interpret the published data in light of our models and the properties of the degradosome. It seems likely that the study of mRNA decay is about to enter a phase in which research will focus on the structural basis for recognition of cleavage sites, on catalytic mechanisms, and on regulation of mRNA decay.
Prog Nucleic Acid Res Mol Biol 1999
PMID:Degradation of mRNA in Escherichia coli: an old problem with some new twists. 993 52

We have mapped transcription termination sites for RNA polymerase I in the yeast Saccharomyces cerevisiae. S1 nuclease mapping shows that the primary terminator is the Reb1p terminator located at +93 downstream of the 3' end of 25S rRNA. Reverse transcription coupled with quantitative PCR shows that approximately 90% of all transcripts terminate at this site. Transcripts which read through the +93 site quantitatively terminate at a fail-safe terminator located further downstream at +250. Inactivation of Rnt1p (an RNase III involved in processing the 3' end of 25S rRNA) greatly stabilizes transcripts extending to both sites and increases readthrough at the +93 site. In vivo assay of mutants of the Reb1p terminator shows that this site operates in vivo by the same mechanism as has previously been delineated through in vitro studies.
Mol Cell Biol 1999 Nov
PMID:Saccharomyces cerevisiae RNA polymerase I terminates transcription at the Reb1 terminator in vivo. 1052 25

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.
Mol Microbiol 1999 Dec
PMID:Analysis of the function of Escherichia coli poly(A) polymerase I in RNA metabolism. 1059 33

Yeast Rnt1 is a member of the double-stranded RNA (dsRNA)-specific RNase III family identified by conserved dsRNA binding (dsRBD) and nuclease domains. Comparative sequence analyses have revealed an additional N-terminal domain unique to the eukaryotic homologues of RNase III. The deletion of this domain from Rnt1 slowed growth and led to mild accumulation of unprocessed 25S pre-rRNA. In vitro, deletion of the N-terminal domain reduced the rate of RNA cleavage under physiological salt concentration. Size exclusion chromatography and cross-linking assays indicated that the N-terminal domain and the dsRBD self-interact to stabilize the Rnt1 homodimer. In addition, an interaction between the N-terminal domain and the dsRBD was identified by a two-hybrid assay. The results suggest that the eukaryotic N-terminal domain of Rnt1 ensures efficient dsRNA cleavage by mediating the assembly of optimum Rnt1-RNA ribonucleoprotein complex.
Mol Cell Biol 2000 Feb
PMID:The N-terminal domain that distinguishes yeast from bacterial RNase III contains a dimerization signal required for efficient double-stranded RNA cleavage. 1064 95

Citrate transport in Lactococcus lactis biovar diacetylactis (L. diacetylactis) is catalyzed by citrate permease P (CitP), which is encoded by the plasmidic citP gene. Two partial overlapping open reading frames citQ and citR are located upstream of citP. These two genes, together with citP, constitute the citQRPoperon. In this report it was shown that in L. diacetylactis and Escherichia coli, cit mRNA is subject to the same specific cleavages at a complex secondary structure which includes the central region of citQ and the 5'-end of citR. The role of ribonucleases in the fate of the cit mRNA processing was investigated in E. coli RNase mutant strains. The results obtained indicate that both endoribonucleases RNase E and RNase III are involved in the generation of mRNA processed species. RNase E is responsible for the major cleavages detected within citQ and upstream of citR, whereas RNase III cleaves citR within its ribosomal binding site. Preliminary results indicate the existence of a RNaselll-like enzyme in L. diacetylactis. Based on these results, a model for the role of cit mRNA processing in the expression of citP is presented.
J Mol Microbiol Biotechnol 1999 Nov
PMID:The role of Escherichia coli RNase E and RNase III in the processing of the citQRP operon mRNA from Lactococcus lactis biovar diacetylactis. 1094 65

When a gene encoding the Schizosaccharomyces pombe dsRNA-specific RNase III, pac1, was expressed in transgenic tobacco plants, six out of thirteen transformed plants gave progeny among which were individuals displaying a distinctive chlorotic phenotype. These chlorotic plants strongly resemble those transformed with a 35S-Nii (nitrite reductase) transgene, in which both Nii host genes and the 35S-Nii transgene are silenced by co-suppression. RNA blots showed that the host Nii genes were silenced in chlorotic 35S-pac1 plants but not in individuals with a normal green phenotype. Neither the transcript levels of the other cellular genes tested nor the transcription of Nii genes was significantly affected by the expression of pac1. This is the first observation of post-transcriptional silencing of host genes by a transgene with no apparent sequence similarity to the target gene.
Plant Mol Biol 2000 Sep
PMID:Expression of a yeast RNase III gene in transgenic tobacco silences host nitrite reductase genes. 1109 79

The rncS gene of Bacillus subtilis encodes Bs-RNase III, a narrow-specificity endoribonuclease. Previous attempts to disrupt rncS were unsuccessful. Here, a strain was constructed in which Bs-RNase III expression was dependent upon transcription of rncS from a temperature-sensitive plasmid. Growth of this strain at the non-permissive temperature resulted in 90-95% cell death, and virtually all the cells that survived retained the rncS-expressing plasmid. Thus, we conclude that rncS is essential in B. subtilis. The rncS conditional strain also revealed that Bs-RNase III participates in the processing of ribosomal RNA, in addition to processing small cytoplasmic RNA, a member of the signal recognition particle RNA family. Most significantly, a rare rncS null strain was isolated that will aid further study of the critical role Bs-RNase III plays in B. subtilis.
Mol Microbiol 2000 Dec
PMID:Endoribonuclease RNase III is essential in Bacillus subtilis. 1112 76

When Escherichia coli cells are shifted to low temperatures (e.g. 15 degrees C), growth halts while the 'cold shock response' (CSR) genes are induced, after which growth resumes. One CSR gene, pnp, encodes polynucleotide phosphorylase (PNPase), a 3'-exoribonuclease and component of the RNA degradosome. At 37 degrees C, ribonuclease III (RNase III, encoded by rnc) cleaves the pnp untranslated leader, whereupon PNPase represses its own translation by an unknown mechanism. Here, we show that PNPase cold-temperature induction involves several post-transcriptional events, all of which require the intact pnp mRNA leader. The bulk of induction results from reversal of autoregulation at a step subsequent to RNase III cleavage of the pnp leader. We also found that pnp translation occurs throughout cold-temperature adaptation, whereas lacZ(+) translation was delayed. This difference is striking, as both mRNAs are greatly stabilized upon the shift to 15 degrees C. However, unlike the lacZ(+) mRNA, which remains stable during adaptation, pnp mRNA decay accelerates. Together with other evidence, these results suggest that mRNA is generally stabilized upon a shift to cold temperatures, but that a CSR mRNA-specific decay process is initiated during adaptation.
Mol Microbiol 2001 Jan
PMID:Cold-temperature induction of Escherichia coli polynucleotide phosphorylase occurs by reversal of its autoregulation. 1112 93

The last few years have witnessed the appreciation of dsRNA as a regulator of gene expression, a potential antiviral agent, and a tumor suppressor. However, in spite of these clear effects on the cell function, the mechanism that controls dsRNA maturation and stability remains unknown. Recently, the discovery of eukaryotic orthologues of the bacterial dsRNA specific ribonuclease III (RNase III) suggested a central role for these enzymes in the regulation of dsRNA and eukaryotic RNA metabolism in general. This article reviews the structure-function features of the eukaryotic RNase III family and their roles in dsRNA metabolism with an emphasis on the yeast RNase III. Yeast RNase III is involved in the maturation of the majority of snRNAs, snoRNAs, and rRNA. In addition, perturbation of the expression level of yeast RNase III alters meiosis and causes sterility. These basic functions of the yeast RNase III appear to be widely conserved which makes it a good model to understand the importance of eukaryotic dsRNA metabolism.
Curr Issues Mol Biol 2001 Oct
PMID:The RNase III family: a conserved structure and expanding functions in eukaryotic dsRNA metabolism. 1171 70


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