EC:3.1.27.1 - FACTA Search

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Query: EC:3.1.27.1 (RNase)
16,360 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cold shock response of Escherichia coli is elicited by downshift of temperature from 37 degrees C to 15 degrees C and is characterized by induction of several cold shock proteins, including CsdA, during the acclimation phase. CsdA, a DEAD-box protein, has been proposed to participate in a variety of processes, such as ribosome biogenesis, mRNA decay, translation initiation, and gene regulation. It is not clear which of the functions of CsdA play a role in its essential cold shock function or whether all do, and so far no protein has been shown to complement its function in vivo. Our screening of an E. coli genomic library for an in vivo counterpart of CsdA that can compensate for its absence at low temperature revealed only one protein, RhlE, another DEAD-box RNA helicase. We also observed that although not detected in our genetic screening, two cold shock-inducible proteins, namely, CspA, an RNA chaperone, and RNase R, an exonuclease, can also complement the cold shock function of CsdA. Interestingly, the absence of CsdA and RNase R leads to increased sensitivity of the cells to even moderate temperature downshifts. The correlation between the helicase activity of CsdA and the stability of mRNAs of cold-inducible genes was shown using cspA mRNA, which was significantly stabilized in the DeltacsdA cells, an effect counteracted by overexpression of wild-type CsdA or RNase R but not by that of the helicase-deficient mutant of CsdA. These results suggest that the primary role of CsdA in cold acclimation of cells is in mRNA decay and that its helicase activity is pivotal for promoting degradation of mRNAs stabilized at low temperature.
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PMID:Complementation analysis of the cold-sensitive phenotype of the Escherichia coli csdA deletion strain. 1755 20

The fission yeast centromeric repeats are transcribed and ultimately processed into small interfering RNAs (siRNAs) that are required for heterochromatin formation. siRNA generation requires dsRNA synthesis by the RNA-directed RNA polymerase complex (RDRC) and processing by the Dicer ribonuclease. Here we show that Dcr1, the fission yeast Dicer, is physically associated with RDRC. Dcr1 generates siRNAs in an ATP-dependent manner that requires its conserved N-terminal helicase domain. Furthermore, C-terminal truncations of Dcr1 that abolish its interaction with RDRC, but can generate siRNA in vitro, abolish siRNA generation and heterochromatic gene silencing in vivo. Finally, reconstitution experiments show that the association of Dcr1 with RDRC strongly stimulates the dsRNA synthesis activity of RDRC. Our results suggest that heterochromatic dsRNA synthesis and siRNA generation are physically coupled processes. This coupling has implications for cis-restriction of siRNA-mediated heterochromatin assembly and for mechanisms that give rise to siRNA strand polarity.
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PMID:Coupling of double-stranded RNA synthesis and siRNA generation in fission yeast RNAi. 1770 23

The mitochondrial degradosome (mtEXO), the main RNA-degrading complex of yeast mitochondria, is composed of two subunits: an exoribonuclease encoded by the DSS1 gene and an RNA helicase encoded by the SUV3 gene. We expressed both subunits of the yeast mitochondrial degradosome in Escherichia coli, reconstituted the complex in vitro and analyzed the RNase, ATPase and helicase activities of the two subunits separately and in complex. The results reveal a very strong functional interdependence. For every enzymatic activity, we observed significant changes when the relevant protein was present in the complex, compared to the activity measured for the protein alone. The ATPase activity of Suv3p is stimulated by RNA and its background activity in the absence of RNA is reduced greatly when the protein is in the complex with Dss1p. The Suv3 protein alone does not display RNA-unwinding activity and the 3' to 5' directional helicase activity requiring a free 3' single-stranded substrate becomes apparent only when Suv3p is in complex with Dss1p. The Dss1 protein alone does have some basal exoribonuclease activity, which is not ATP-dependent, but in the presence of Suv3p the activity of the entire complex is enhanced greatly and is entirely ATP-dependent, with no residual activity observed in the absence of ATP. Such absolute ATP-dependence is unique among known exoribonuclease complexes. On the basis of these results, we propose a model in which the Suv3p RNA helicase acts as a molecular motor feeding the substrate to the catalytic centre of the RNase subunit.
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PMID:In vitro reconstitution and characterization of the yeast mitochondrial degradosome complex unravels tight functional interdependence. 1765 49

Poxviruses are large enveloped viruses that replicate in the cytoplasm of vertebrate or invertebrate cells. At least six virus-encoded proteins are required for synthesis and processing of the double-stranded DNA genome of vaccinia virus, the prototype member of the family. One of these proteins, D5, is an NTPase that contains an N-terminal archaeoeukaryotic primase domain and a C-terminal superfamily III helicase domain. Here we report that individual conserved aspartic acid residues in the predicted primase active site were required for in vivo complementation of infectious virus formation as well as genome and plasmid replication. Furthermore, purified recombinant D5 protein synthesized oligoribonucleotides in vitro. Incorporation of label from [alpha-(32)P]CTP or [alpha-(32)P]UTP into a RNase-sensitive and DNase-resistant product was demonstrated by using single-stranded circular bacteriophage DNA templates and depended on ATP or GTP and a divalent cation. Mutagenesis studies showed that the primase and NTPase activities of the recombinant D5 protein could be independently inactivated. Highly conserved orthologs of D5 are present in all poxviruses that have been sequenced, and more diverged orthologs are found in members of all other families of nucleocytoplasmic large DNA viruses. These viral primases may have roles in initiation of DNA replication or lagging-strand synthesis and represent potential therapeutic targets.
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PMID:Poxvirus DNA primase. 1800 36

In this article, we report on the genetic analysis of the Schizosaccharomyces pombe open reading frames SPCC1322.01 and SPAC637.11, respectively, which encode proteins that are similar to the exoribonuclease Dss1p and the RNA helicase Suv3p, respectively, forming the mitochondrial degradosome of Saccharomyces cerevisiae. While the helicase Suv3p is exchangeable between S. cerevisiae and S. pombe, the functions of Dss1p and the putative fission yeast RNase protein are specific for each species. Unlike S. cerevisiae mutants lacking a functional degradosome, the major defect of fission yeast knock-out strains is their inability to perform downstream processing of transcripts. In addition, the lack of pah1 results in instability of mitochondrial RNA ends. Overexpression of par1 and pah1 has no significant effect on the steady-state levels of mitochondrial RNAs. The Pet127p-stimulated RNA degradation activity is independent of Par1p/Pah1p in fission yeast mitochondria. The results presented herein indicate that both fission yeast proteins play only a minor role (if at all) in mitochondrial RNA degradation. We assume that the RNA-degrading function was taken over by other enzymes in fission yeast mitochondria, while the former degradosome proteins were recruited to new cellular pathways, for example, RNA processing in fission yeast (as discussed in this article) or mitochondrial DNA replication, apoptosis, or chromatin maintenance in eukaryotes, during evolution.
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PMID:The 3' ends of mature transcripts are generated by a processosome complex in fission yeast mitochondria. 1830 78

Ribonucleoprotein complexes (RNP) remodeling by DEAD-box proteins is required at all stages of cellular RNA metabolism. These proteins are composed of a core helicase domain lacking sequence specificity; flanking protein sequences or accessory proteins target and affect the core's activity. Here we examined the interaction of eukaryotic initiation factor 4AI (eIF4AI), the founding member of the DEAD-box family, with two accessory factors, eIF4B and eIF4H. We find that eIF4AI forms a stable complex with RNA in the presence of AMPPNP and that eIF4B or eIF4H can add to this complex, also dependent on AMPPNP. For both accessory factors, the minimal stable complex with eIF4AI appears to have 1:1 protein stoichiometry. However, because eIF4B and eIF4H share a common binding site on eIF4AI, their interactions are mutually exclusive. The eIF4AI:eIF4B and eIF4AI:eIF4H complexes have the same RNase resistant footprint as does eIF4AI alone (9-10 nucleotides [nt]). In contrast, in a selective RNA binding experiment, eIF4AI in complex with either eIF4B or eIF4H preferentially bound RNAs much longer than those bound by eIF4AI alone (30-33 versus 17 nt, respectively). The differences between the RNase resistant footprints and the preferred RNA binding site sizes are discussed, and a model is proposed in which eIF4B and eIF4H contribute to RNA affinity of the complex through weak interactions not detectable in structural assays. Our findings mirror and expand on recent biochemical and structural data regarding the interaction of eIF4AI's close relative eIF4AIII with its accessory protein MLN51.
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PMID:Interactions between eIF4AI and its accessory factors eIF4B and eIF4H. 1871 48

RNase R and RNase II are the two representatives from the RNR family of processive, 3' to 5' exoribonucleases in Escherichia coli. Although RNase II is specific for single-stranded RNA, RNase R readily degrades through structured RNA. Furthermore, RNase R appears to be the only known 3' to 5' exoribonuclease that is able to degrade through double-stranded RNA without the aid of a helicase activity. Consequently, its functional domains and mechanism of action are of great interest. Using a series of truncated RNase R proteins we show that the cold-shock and S1 domains contribute to substrate binding. The cold-shock domains appear to play a role in substrate recruitment, whereas the S1 domain is most likely required to position substrates for efficient catalysis. Most importantly, the nuclease domain alone, devoid of the cold-shock and S1 domains, is sufficient for RNase R to bind and degrade structured RNAs. Moreover, this is a unique property of the nuclease domain of RNase R because this domain in RNase II stalls as it approaches a duplex. We also show that the nuclease domain of RNase R binds RNA more tightly than the nuclease domain of RNase II. This tighter binding may help to explain the difference in catalytic properties between RNase R and RNase II.
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PMID:The roles of individual domains of RNase R in substrate binding and exoribonuclease activity. The nuclease domain is sufficient for digestion of structured RNA. 1900 32

The mitochondrial degradosome (mtEXO) of S. cerevisiae is the main exoribonuclease of yeast mitochondria. It is involved in many pathways of mitochondrial RNA metabolism, including RNA degradation, surveillance, and processing, and its activity is essential for mitochondrial gene function. The mitochondrial degradosome is a very simple example of a 3' to 5'-exoribonucleolytic complex. It is composed of only two subunits: Dss1p, which is an RNR (RNase II-like) family exoribonuclease, and Suv3p, which is a DExH/D-box RNA helicase. The two subunits form a tight complex and their activities are highly interdependent, with the RNase activity greatly enhanced in the presence of the helicase subunit, and the helicase activity entirely dependent on the presence of the ribonuclease subunit. In this chapter, we present methods for studying the function of the yeast mitochondrial degradosome in vivo, through the analysis of degradosome-deficient mutant yeast strains, and in vitro, through heterologous expression in E. coli and purification of the degradosome subunits and reconstitution of a functional complex. We provide the protocols for studying ribonuclease, ATPase, and helicase activities and for measuring the RNA binding capacity of the complex and its subunits.
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PMID:In vivo and in vitro approaches for studying the yeast mitochondrial RNA degradosome complex. 1916 56

In Escherichia coli, the cold shock response occurs when there is a temperature downshift from 37 degrees C to 15 degrees C, and this response is characterized by induction of several cold shock proteins, including the DEAD-box helicase CsdA, during the acclimation phase. CsdA is involved in a variety of cellular processes. Our previous studies showed that the helicase activity of CsdA is critical for its function in cold shock acclimation of cells and that the only proteins that were able to complement its function were another helicase, RhlE, an RNA chaperone, CspA, and a cold-inducible exoribonuclease, RNase R. Interestingly, other major 3'-to-5' processing exoribonucleases of E. coli, such as polynucleotide phosphorylase and RNase II, cannot complement the cold shock function of CsdA. Here we carried out a domain analysis of RNase R and showed that this protein has two distinct activities, RNase and helicase, which are independent of each other and are due to different domains. Mutant RNase R proteins that lack the RNase activity but exhibit the helicase activity were able to complement the cold shock function of CsdA, suggesting that only the helicase activity of RNase R is essential for complementation of the cold shock function of CsdA. We also observed that in vivo deletion of the two cold shock domains resulted in a loss of the ability of RNase R to complement the cold shock function of CsdA. We further demonstrated that RNase R exhibits helicase activity in vitro independent of its RNase activity. Our results shed light on the unique properties of RNase R and how it is distinct from other exoribonucleases in E. coli.
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PMID:Escherichia coli RNase R has dual activities, helicase and RNase. 2002 28

The Escherichia coli endoribonuclease RNase E is an essential enzyme having key roles in mRNA turnover and the processing of several structured RNA precursors, and it provides the scaffold to assemble the multienzyme RNA degradosome. The activity of RNase E is inhibited by the protein RraA, which can interact with the ribonuclease's degradosome-scaffolding domain. Here, we report that RraA can bind to the RNA helicase component of the degradosome (RhlB) and the two RNA-binding sites in the degradosome-scaffolding domain of RNase E. In the presence of ATP, the helicase can facilitate the exchange of RraA for RNA stably bound to the degradosome. Our data suggest that RraA can affect multiple components of the RNA degradosome in a dynamic, energy-dependent equilibrium. The multidentate interactions of RraA impede the RNA-binding and ribonuclease activities of the degradosome and may result in complex modulation and rerouting of degradosome activity.
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PMID:The regulatory protein RraA modulates RNA-binding and helicase activities of the E. coli RNA degradosome. 2010 55

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