Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.6.1.25 (triphosphatase)
 1,529 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The reovirus M1, L1, and L2 genes encode proteins found at each vertex of the viral core and are likely to form a structural unit involved in RNA synthesis. Genetic analyses have implicated the M1 gene in viral RNA synthesis and core nucleoside triphosphatase activity, but there have been no direct biochemical studies of mu2 function. Here, we expressed mu2 in vitro and assessed its RNA-binding activity. The expressed mu2 binds both poly(I-C)- and poly(U)-Sepharose, and binding activity is greater in Mn2+ than in Mg2+. Heterologous RNA competes for mu2 binding to reovirus RNA transcripts as effectively as homologous reovirus RNA does, providing no evidence for sequence-specific RNA binding by mu2. Protein mu2 is now the sixth reovirus protein demonstrated to have RNA-binding activity.
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PMID:The reovirus protein mu2, encoded by the M1 gene, is an RNA-binding protein. 973 83

The mammalian Orthoreovirus (mORV) core particle is an icosahedral multienzyme complex for viral mRNA synthesis and provides a delimited system for mechanistic studies of that process. Previous genetic results have identified the mORV mu2 protein as a determinant of viral strain differences in the transcriptase and nucleoside triphosphatase activities of cores. New results in this report provided biochemical and genetic evidence that purified mu2 is itself a divalent cation-dependent nucleoside triphosphatase that can remove the 5' gamma-phosphate from RNA as well. Alanine substitutions in a putative nucleotide binding region of mu2 abrogated both functions but did not affect the purification profile of the protein or its known associations with microtubules and mORV microNS protein in vivo. In vitro microtubule binding by purified mu2 was also demonstrated and not affected by the mutations. Purified mu2 was further demonstrated to interact in vitro with the mORV RNA-dependent RNA polymerase, lambda3, and the presence of lambda3 mildly stimulated the triphosphatase activities of mu2. These findings confirm that mu2 is an enzymatic component of the mORV core and may contribute several possible functions to viral mRNA synthesis.
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PMID:Nucleoside and RNA triphosphatase activities of orthoreovirus transcriptase cofactor mu2. 1461 38

A low-copy component of mammalian reovirus particles is mu2, an 83-kDa protein encoded by the M1 viral genome segment and packaged within the viral core. Previous studies have identified mu2 as a nucleoside triphosphate phosphohydrolase (NTPase) as well as an RNA 5'-triphosphate phosphohydrolase (RTPase), putatively involved in reovirus RNA synthesis and/or 5'-capping. Other studies have identified mu2 as a microtubule-binding protein, which also associates with the viral factory matrix protein muNS and thereby anchors the factories to cellular microtubules during infections by most reovirus strains. To extend studies of mu2 functions during infection, we tested a small interfering RNA (siRNA) directed against the M1 plus-strand RNAs of reovirus strains Type 1 Lang (T1L) and Type 3 Dearing (T3D). The siRNA strongly suppressed mu2 expression by either strain and reduced infectious yields in a strain-dependent manner. This first strain difference was genetically mapped to the M1 genome segment and tentatively assigned to a single mu2 sequence polymorphism, Pro/Ser208, which also determines a T1L-T3D strain difference in microtubule association. The siRNA-based defect in mu2 expression was rescued by plasmids, containing silent mutations in the siRNA-targeted sequence, which encoded either T1L or T3D mu2, but the growth defect was rescued only by T1L mu2. This second strain difference was also mapped to Pro/Ser208, in that swapping this one residue between T1L and T3D mu2 reversed the rescue phenotypes. Thus, the T1L-T3D strain difference in mu2-microtubule association was correlated not only with the extent of reduction in infectious yields by the siRNA but also with the extent of rescue by plasmid-derived mu2. In addition, the rescue capacity of T1L mu2 was abrogated by nocodazole treatment, providing independent evidence for the importance of mu2-microtubule association in plasmid-based rescue. In two separate cases, the results revealed functional differences between virus- and plasmid-derived mu2. Ala substitutions within the NTP-binding motif of T1L mu2 also abrogated its rescue capacity, suggesting that the NTPase or RTPase activity of mu2 is additionally required for effective viral growth.
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PMID:Silencing and complementation of reovirus core protein mu2: functional correlations with mu2-microtubule association and differences between virus- and plasmid-derived mu2. 1745 69

Analysis of the amino acid sequence of core protein muA of avian reovirus has indicated that it may share similar functions to protein mu2 of mammalian reovirus. Since mu2 displayed both nucleotide triphosphatase (NTPase) and RNA triphosphatase (RTPase) activities, the purified recombinant muA ( muA) was designed and used to test these activities. muA was thus expressed in bacteria with a 4.5 kDa fusion peptide and six His tags at its N terminus. Results indicated that muA possessed NTPase activity that enabled the protein to hydrolyse the beta-gamma phosphoanhydride bond of all four NTPs, since NDPs were the only radiolabelled products observed. The substrate preference was ATP>CTP>GTP>UTP, based on the estimated k(cat) values. Alanine substitutions for lysines 408 and 412 (K408A/K412A) in a putative nucleotide-binding site of muA abolished NTPase activity, further suggesting that NTPase activity is attributable to protein muA. The activity of muA is dependent on the divalent cations Mg(2+) or Mn(2+), but not Ca(2+) or Zn(2+). Optimal NTPase activity of muA was achieved between pH 5.5 and 6.0. In addition, muA enzymic activity increased with temperature up to 40 degrees C and was almost totally inhibited at temperatures higher than 55 degrees C. Tests of phosphate release from RNA substrates with muA or K408A/K412A muA indicated that muA, but not K408A/K412A muA, displayed RTPase activity. The results suggested that both NTPase and RTPase activities of muA might be carried out at the same active site, and that protein muA could play important roles during viral RNA synthesis.
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PMID:Avian reovirus core protein muA expressed in Escherichia coli possesses both NTPase and RTPase activities. 1748 41

Mammalian reoviruses are nonenveloped particles containing a genome of 10 double-stranded RNA (dsRNA) gene segments. Reovirus replication occurs within viral inclusions, which are specialized nonmembranous cytoplasmic organelles formed by viral nonstructural and structural proteins. Although these structures serve as sites for several major events in the reovirus life cycle, including dsRNA synthesis, gene segment assortment, and genome encapsidation, biochemical mechanisms of virion morphogenesis within inclusions have not been elucidated because much remains unknown about inclusion anatomy and functional organization. To better understand how inclusions support viral replication, we have used RNA interference (RNAi) and reverse genetics to define functional domains in two inclusion-associated proteins, muNS and mu2, which are interacting partners essential for inclusion development and viral replication. Removal of muNS N-terminal sequences required for association with mu2 or another muNS-binding protein, sigmaNS, prevented the capacity of muNS to support viral replication without affecting inclusion formation, indicating that muNS-mu2 and muNS-sigmaNS interactions are necessary for inclusion function but not establishment. In contrast, introduction of changes into the muNS C-terminal region, including sequences that form a putative oligomerization domain, precluded inclusion formation as well as viral replication. Mutational analysis of mu2 revealed a critical dependence of viral replication on an intact nucleotide/RNA triphosphatase domain and an N-terminal cluster of basic amino acid residues conforming to a nuclear localization motif. Another domain in mu2 governs the capacity of viral inclusions to affiliate with microtubules and thereby modulates inclusion morphology, either globular or filamentous. However, viral variants altered in inclusion morphology displayed equivalent replication efficiency. These studies reveal a modular functional organization of inclusion proteins muNS and mu2, define the importance of specific amino acid sequences and motifs in these proteins for viral replication, and demonstrate the utility of complementary RNAi-based and reverse genetic approaches for studies of reovirus replication proteins.
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PMID:Identification of functional domains in reovirus replication proteins muNS and mu2. 1917 25