Gene/Protein
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Enzyme
Compound
Pivot Concepts:
Gene/Protein
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Target Concepts:
Gene/Protein
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Query: EC:3.1.27.5 (
RNase
)
17,967
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A variety of 5'-3H-methyl-labeled, oxidized viral mRNAs were used as probes for detecting in wheat germ initiation complexes proteins that interact with, and can be cross-linked to, the 5'-cap structure. A limited and reproducible set of specific proteins was obtained with the different mRNAs. The binding of these proteins to the 5'-end of mRNA apparently results in protection against nucleotide pyrophosphatase digestion of the cap even in initiation complexes in which the 5'-end is susceptible to
pancreatic RNase
digestion. Cross-linked proteins from mammalian initiation complexes comigrated with several of the subunits of similarly treated eIF-3. A model for
cap binding protein
interaction with mRNA cap during initiation of translation is suggested.
...
PMID:Interaction of a limited set of proteins with different mRNAs and protection of 5'-caps against pyrophosphatase digestion in initiation complexes. 49 38
Influenza virus polymerase uses capped RNA primers for transcription initiation in infected cells. This unique mechanism involves the specific binding of the polymerase to capped mRNA precursors in the nucleus of infected cells. These host RNAs are then cleaved by a polymerase associated endonuclease at a position 10-15 nucleotides downstream of the cap structure. The resulting capped RNA oligonucleotides function as primers for transcription initiation. The viral cap binding site has previously been mapped to the PB2 subunit of the trimeric influenza polymerase complex. We have established a quantitative assay system for the analysis of cap interaction with PB2 as part of the native, viral ribonucleoprotein complex (RNP) using a specific UV cross-linking approach. Cap binding was not affected by the
RNase
pretreatment of the capped RNA substrate and cap binding was not inhibited by excess uncapped RNA, indicating that under the assay conditions, the majority of the binding energy was contributed by the interaction with the cap structure. Binding to 7-methyl-GTP was found to involve synergistic interaction with 7-methyl guanosine and triphosphate binding subsites. A similar mode of interaction with 7-methyl-GTP was found for human
cap binding protein
eIF4E. However, the potency of 7-methyl-GTP for cap binding inhibition was 200-fold stronger with eIF4E and had a higher contribution from the triphosphate moiety as compared to influenza RNP. Due to this difference in cap subsite interaction, it was possible to identify novel cap analogues, which selectively interact with influenza virus, but not human
cap binding protein
.
...
PMID:Quantitative analysis of influenza virus RNP interaction with RNA cap structures and comparison to human cap binding protein eIF4E. 1275 27
Poly(A)-specific
ribonuclease
(PARN) is a cap-interacting and poly(A)-specific 3'-exoribonuclease. Here we have investigated how the cap binding complex (CBC) affects human PARN activity. We showed that CBC, via its 80-kDa subunit (
CBP80
), inhibited PARN, suggesting that CBC can regulate mRNA deadenylation. The CBC-mediated inhibition of PARN was cap-independent, and in keeping with this, the
CBP80
subunit alone inhibited PARN. Our data suggested a new function for CBC, identified CBC as a potential regulator of PARN, and emphasized the importance of communication between the two extreme ends of the mRNA as a key strategy to regulate mRNA degradation. Based on our data, we have proposed a model for CBC-mediated regulation of PARN, which relies on an interaction between
CBP80
and PARN. Association of CBC with PARN might have importance in the regulated recruitment of PARN to the nonsense-mediated decay pathway during the pioneer round of translation.
...
PMID:Inhibition of mRNA deadenylation by the nuclear cap binding complex (CBC). 1631 9
Mutations in EBS1 were identified in Saccharomyces cerevisiae that cosuppress missense, frameshift, and nonsense mutations. Evidence from studies of loss of function and overexpression of EBS1 suggests that Ebs1p affects gene expression by inhibiting translation and that a loss of EBS1 function causes suppression by increasing the rate of translation. Changes in EBS1 expression levels alter the expression of wild-type genes, but, in general, no changes in mRNA abundance were associated with a loss of function or overexpression of EBS1. Translation of a lacZ reporter was increased in strains carrying an ebs1-Delta mutant gene, whereas translation was decreased when EBS1 was overexpressed. The
cap binding protein
eIF-4E copurifies with Ebs1p in the absence of RNA, suggesting that the two proteins interact in vivo. Although physical and genetic interactions were detected between Ebs1p and Dcp1p, copurification was
RNase
sensitive, and changes in the expression of Ebs1p had little to no effect on decapping of the MFA2 transcript. The combined results suggest that Ebs1p inhibits translation, most likely through effects on eIF-4E rather than on decapping. Finally, EBS1 transcript levels are under the control of nonsense-mediated mRNA decay (NMD), providing the first example of an NMD-sensitive transcript whose protein product influences a step in gene expression required for NMD.
...
PMID:Ebs1p, a negative regulator of gene expression controlled by the Upf proteins in the yeast Saccharomyces cerevisiae. 1646 71
We previously reported that the HCV (hepatitis C virus) protein NS5A up-regulated mRNA cap binding eIF4F (eukaryotic initiation factor 4F) complex assembly through mTOR (mechanistic target of rapamycin)-4EBP1 (eIF4E-binding protein 1) pathway and that NS5A (non-structural protein 5A) physically interacted with translation apparatus. In the present study, we demonstrate that NS5A co-ordinates a unique assembly of the
cap binding protein
eIF4E and 40S ribosome to form a complex that we call ENR (eIF4E-NS5A-ribosome). Recruitment of NS5A and eIF4E to 40S ribosome was confirmed by polysome fractionation, subcellular fractionation and high-salt-wash immunoprecipitation. These observations were also confirmed in HCV-infected cells, validating its biological significance. eIF4E phosphorylation was critical for ENR assembly. 80S ribosome dissociation and
RNase
integrity assays revealed that, once associated, the ENR complex is stable and RNA interaction is dispensable. Both the N- and C-terminal regions of NS5A domain 1 were indispensable for this assembly and for the NS5A-induced HCV IRES (internal ribosome entry site) activation. The present study demonstrates that NS5A initially associates with phosphorylated eIF4E of eIF4F complex and subsequently recruits it to 40S ribosomes. This is the first time the interaction of viral protein with both eIF4E and ribosomes has been reported. We propose that this assembly would determine the outcome of HCV infection and pathogenesis through regulation of viral and host translation.
...
PMID:A unique phosphorylation-dependent eIF4E assembly on 40S ribosomes co-ordinated by hepatitis C virus protein NS5A that activates internal ribosome entry site translation. 2489 74
Poly(A)-specific
ribonuclease
(PARN), a multifunctional multi-domain deadenylase, is crucial to the regulation of mRNA turnover and the maturation of various non-coding RNAs. Despite extensive studies of the well-folding domains responsible for PARN catalysis, the structure and function of the C-terminal domain (CTD) remains elusive. PARN is a cytoplasm-nucleus shuttle protein with concentrated nucleolar distribution. Here, we identify the nuclear and nucleolar localization signals in the CTD of PARN. Spectroscopic studies indicated that PARN-CTD is intrinsically disordered with loosely packed local structures/tertiary structure. Phosphorylation-mimic mutation S557D disrupted the local structure and facilitated the binding of the CTD with the well-folded domains, with no impact on PARN deadenylase activity. Under normal conditions, the nucleolus-residing PARN recruited
CBP80
into the nucleoli to repress its deadenylase activity, while DNA damage-induced phosphorylation of PARN-S557 expelled
CBP80
from the nucleoli to discharge activity inhibition and attracted nucleoplasm-located CstF-50 into the nucleoli to activate deadenylation. The structure switch-induced function switch of PARN reshaped the profile of small nuclear non-coding RNAs to respond to DNA damage. Our findings highlight that the structure switch of the CTD induced by posttranslational modifications redefines the subset of binding partners, and thereby the RNA targets in the nucleoli.
...
PMID:The Intrinsically Disordered C-Terminal Domain Triggers Nucleolar Localization and Function Switch of PARN in Response to DNA Damage. 3138
