EC:3.1.27.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Replication of hepatitis delta virus (HDV) RNA occurs in the nuclei of infected cells. The replication is mediated by cellular factors containing an RNA polymerase II-like enzyme activity through a double rolling-circle mechanism and is regulated by delta antigens. In this study, UV cross-linking experiments were carried out to examine interactions between HDV RNA and proteins present in HeLa nuclear extract. Cellular proteins with molecular mass of 23 (p23), 36 (p36), 38 (p38), and 58 (p58) kDa bound to full-length HDV RNA of both genomic and antigenomic strands. Deletion analysis on the antigenomic strand mapped the interacting domain within a 79-nucleotide fragment but not at the ends of the rod-shaped viral RNA structure. The specificity of the RNA-protein interactions was demonstrated by competition experiments and the specific HDV RNA-binding proteins were purified through column chromatography. Electrophoresis mobility shift assay with the purified fractions demonstrated that the interaction between p36 and HDV RNA was relatively stable even in the presence of 0.5 M NaCl. Biochemical analysis including protein microsequencing identified the p36 as glyceraldehyde 3-phosphate dehydrogenase (GAPDH). RNase footprinting indicated that the UC-rich domain between nucleotides 379 and 414 of the HDV antigenomic RNA was involved in the GAPDH binding. Functional studies further demonstrated an enhancing effect of GAPDH on the ribozyme activity of HDV antigenomic RNA. In addition, in the presence of HDV RNA cellular GAPDH relocalized from the cytoplasm to the nucleus where HDV replication occurs. These results suggest that GAPDH is involved in the replication of HDV.
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PMID:Specific interaction between the hepatitis delta virus RNA and glyceraldehyde 3-phosphate dehydrogenase: an enhancement on ribozyme catalysis. 1081 69

Heterogeneous nuclear ribonucleoproteins (hnRNPs) A2 and B1 are abundant nuclear proteins that bind to nascent RNAs synthesized by RNA polymerase II. Previously we had found that the splicing isoforms hnRNP B0a/b, from which the ninth exon of the A2/B1 gene is excluded, are abundantly expressed in testis. We postulated that B0a/b are testis-specific isoforms, and investigated the expression of A2/B1 and B0a/b in rat tissues and in postnatal development of rat testes using RNase protection assay, immunoblotting, and immunohistochemistry. We found that hnRNP B0a/b mRNAs are expressed in several tissues but that the testis alone expresses B0a/b proteins. A sequential study using neonatal rat testes demonstrated that B0a/b mRNAs are produced after 17 days of age, but not translated until 4 weeks of age when round spermatids appear in addition to spermatogonia and spermatocytes. Immunohistochemically, hnRNP A2/B1 isoforms are expressed during spermatogenesis from spermatogonia through round spermatids, whereas the expression of A1 is restricted to spermatogonia. This expression pattern in the rat testis is maintained from birth through adulthood. These results suggest that the expression of the hnRNP A2/B1 gene is partly regulated by a testis-specific post-transcriptional mechanism, and that the products of the A2/B1 gene, especially hnRNP B0a/b, are involved in spermatogenesis.
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PMID:Testis- and developmental stage-specific expression of hnRNP A2/B1 splicing isoforms, B0a/b. 1097 4

The human ISG20/HEM45 gene was identified independently on the basis of its increased level of expression in response to either interferon or estrogen hormone. Notably, the encoded protein is homologous with members of the 3' to 5' exonuclease superfamily that includes RNases T and D, and the proofreading domain of Escherichia coli DNA polymerase I. We provide here direct biochemical evidence that Isg20 acts as a 3' to 5' exonuclease in vitro. This protein displays a pH optimum of approximately 7.0, prefers Mn2+ as a metal cofactor, and degrades RNA at a rate that is approximately 35-fold higher than its rate for single-stranded DNA. Along with RNase L, Isg20 is the second known RNase regulated by interferon. Previous data showed that Isg20 is located in promyelocytic leukemia (PML) nuclear bodies, known sites of hormone-dependent RNA polymerase II transcription and oncogenic DNA viral transcription and replication. The combined data suggest a potential role for Isg20 in degrading viral RNAs as part of the interferon-regulated antiviral response and/or cellular mRNAs as a regulatory component of interferon and estrogen signaling.
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PMID:The human interferon- and estrogen-regulated ISG20/HEM45 gene product degrades single-stranded RNA and DNA in vitro. 1140 64

Nuclear DNA helicase II (NDH II), also designated RNA helicase A, is a multifunctional protein involved in transcription, RNA processing, and transport. Here we report that NDH II binds to F-actin. NDH II was partially purified from HeLa nuclear extracts by ion-exchange chromatography on Bio-Rex 70 and DEAE-Sepharose. Upon gel-filtration chromatography on Sepharose 4B, partially purified NDH II resolved into two distinct peaks. The first NDH II peak, corresponding to the void volume of Sepharose 4B, displayed coelution with an abundant 42-kDa protein that was subsequently identified as actin. Several nuclear proteins such as RNA polymerase II, the U5 small nuclear ribonucleoprotein (RNP)-associated WD40 protein, and heterogeneous nuclear RNPs (hnRNPs) copurified with NDH II. However, only hnRNPs A1 and C were found together with NDH II and actin polymers during gel filtration. NDH II and hnRNP C from the HeLa nuclear extract coeluted with F-actin on Sepharose 4B in an RNase-resistant manner, whereas hnRNP A1 was nearly completely removed from F-actin-associated hnRNP complexes following RNA digestion. The association of NDH II and hnRNP C with F-actin was abolished by gelsolin, an F-actin-depolymerizing protein that fragments actin polymers into oligomers or monomers. Furthermore, NDH II co-immunoprecipitated with F-actin and hnRNP C, respectively. In vitro translated NDH II coeluted with F-actin on Sepharose 4B, whereas no coelution with F-actin was observed for in vitro translated hnRNP A1 or C1. Binding to F-actin requires an intact C terminus of NDH II and most likely a native protein conformation. Electron microscopy indicated a close spatial proximity among NDH II, hnRNP C, and F-actin within the HeLa nucleus. These results suggest an important function of NDH II in mediating the attachment of hnRNP-mRPP RNP complexes to the actin nucleoskeleton for RNA processing, transport, or other actin-related processes.
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PMID:Nuclear DNA helicase II/RNA helicase A binds to filamentous actin. 1168 88

We have analyzed the response of a number of human cell lines to treatment with antisense oligodeoxynucleotides (ODNs) directed against RNA polymerase II, replication protein A, and Ha-ras. ODN-delivery to the cells was liposome-mediated or via electroporation, which resulted in different intracellular locations of the ODNs. The ODN-mediated target mRNA reduction varied considerably between the cell lines. In view of the essential role of RNase H activity in this response, RNase H was analyzed. The mRNA levels of RNase H1 and RNase H2 varied considerably in the cell lines examined in this study. The intracellular localization of the enzymes, assayed by green-fluorescent protein fusions, showed that RNase H1 was present throughout the whole cell for all cell types analyzed, whereas RNase H2 was restricted to the nucleus in all cells except the prostate cancer line 15PC3 that expressed the protein throughout the cell. Whole cell extracts of the cell lines yielded similar RNase H cleavage activity in an in vitro liquid assay, in contrast to the efficacy of the ODNs in vivo. Overexpression of RNase H2 did not affect the response to ODNs in vivo. Our data imply that in vivo RNase H activity is not only due to the activity assayed in vitro, but also to an intrinsic property of the cells. RNase H1 is not likely to be a major player in the antisense ODN-mediated degradation of target mRNAs. RNase H2 is involved in the activity assayed in vitro. The presence of cell-type specific factors affecting the activity and localization of RNase H2 is strongly suggested.
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PMID:The involvement of human ribonucleases H1 and H2 in the variation of response of cells to antisense phosphorothioate oligonucleotides. 1185 17

Eukaryotic RNA polymerase II and Escherichia coli RNA polymerase possess an intrinsic ribonuclease activity that is stimulated by the polymerase-binding proteins SII and GreB, respectively. This factor-activated hydrolysis of nascent RNA has been postulated to be involved in transcription elongation as well as removal of incorrect bases misincorporated into RNA. Little is known about the frequency of misincorporation by RNA polymerases in vivo or about the mechanisms involved in improving RNA polymerase accuracy. Here we have developed a luciferase reporter system in an effort to assay for base misincorporation in living Saccharomyces cerevisiae. The assay employs a luciferase open reading frame that contains a premature stop codon. The inactive truncated enzyme would become active if misincorporation by RNA polymerase II took place at the stop triplet. Yeast lacking SII did not display a significant change in reporter activity when compared with wild-type cells. We estimate that under our assay conditions, mRNAs with a misincorporation at the test site could not exceed 1 transcript per 500 cells. The reporter assay was very effective in detecting the previously described process of nonsense suppression (translational read-through) by ribosomes, making it difficult to determine an absolute level of basal (SII-independent) misincorporation by RNA polymerase II. Although these data cannot exclude the possibility that SII is involved in proofreading, they make it unlikely that such a contribution is physiologically significant, especially relative to the high frequency of translational errors.
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PMID:Use of an in vivo reporter assay to test for transcriptional and translational fidelity in yeast. 1200 89

Elongin A is a transcription elongation factor that increases the overall rate of mRNA chain elongation by RNA polymerase II. To investigate the function of Elongin A in vivo, the two alleles of the Elongin A gene have been disrupted by homologous recombination in murine embryonic stem (ES) cells. The Elongin A-deficient ES cells are viable, but show a slow growth phenotype because they undergo a delayed mitosis. The cDNA microarray and RNase protection assay using the wild-type and Elongin A-deficient ES cells indicate that the expression of only a small subset of genes is affected in the mutant cells. Taken together, our results suggest that Elongin A regulates transcription of a subset but not all of genes and reveal a linkage between Elongin A function and cell cycle progression.
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PMID:Mammalian elongin A is not essential for cell viability but is required for proper cell cycle progression with limited alteration of gene expression. 1260 9

In adenovirus type 5-infected cells, RNA polymerase III transcription of a gene superimposed on the 5' end of the E2E RNA polymerase II transcription unit produces two small (<100-nucleotide) RNAs that accumulate to low steady-state concentrations (W. Huang, R. Pruzan, and S. J. Flint, Proc. Natl. Acad. Sci. USA 91:1265-1269, 1984). To gain a better understanding of the function of this RNA polymerase III transcription, we have examined the properties of the small E2E RNAs and E2E RNA polymerase III transcription in more detail. The accumulation of cytoplasmic E2E RNAs and the rates of E2E transcription by the two RNA polymerases during the infectious cycle were analyzed by using RNase T(1) protection and run-on transcription assays, respectively. Although the RNA polymerase III transcripts were present at significantly lower concentrations than E2E mRNA throughout the period examined, E2E transcription by RNA polymerase III was found to be at least as efficient as that by RNA polymerase II. The short half-lifes of the small E2E RNAs estimated by using the actinomycin D chase method appear to account for their limited accumulation. The transcription of E2E sequences by RNA polymerase II and III in cells infected by recombinant adenoviruses carrying ectopic E2E-CAT (chloramphenicol transferase) reporter genes with mutations in E2E promoter sequences was also examined. The results of these experiments indicate that recognition of the E2E promoter by the RNA polymerase II transcriptional machinery in infected cells limits transcription by RNA polymerase III, and vice versa. Such transcriptional competition and the properties of E2E RNAs made by RNA polymerase III suggest that the function of this viral RNA polymerase III transcription unit is unusual.
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PMID:Unusual properties of adenovirus E2E transcription by RNA polymerase III. 1263 61

TATA-binding protein (TBP)-related factor 2 (TRF2) is one of four closely related RNA polymerase II transcription factors. We compared the intracellular localizations of TBP and TRF2 during the cell cycle and mitosis in HeLa cells. We show that during interphase, endogenous or exogenously expressed TRF2 is located almost exclusively in the nucleolus in HeLa or Cos cells. TRF2 localization is not affected by stress or mitotic stimuli, but TRF2 is rapidly released from the nucleolus upon inhibition of pol I transcription or treatment by RNase. These results suggest that localization of HeLa TRF2 requires a nucleolar-associated RNA species. In contrast, in 3T3 fibroblast cells, exogenously expressed TRF2 localizes to the nucleoplasm. Constitutive expression of ectopic TRF2 in 3T3 cells leads to a prolonged S phase of the cell cycle and reduced proliferation. Together with previous data, our results highlight the cell-specific localization and functions of TRF2. Furthermore, we show that during cell division, HeLa TRF2 and TBP are localized in the mitotic cytoplasm and TRF2 relocalizes into the nascent nucleoli immediately after mitosis, whereas TBP reassociates with the chromatin. Although partially contradictory results have been reported, our data are consistent with a model where only small proportion of the cellular TBP remains associated with specific promoter loci during mitosis.
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PMID:Cell-specific nucleolar localization of TBP-related factor 2. 1526 81

The presence of phospholipids as a component of chromatin is now well documented and many enzymes such as sphingomyelinase, sphingomyelin-synthase, reverse sphingomyelin-synthase and phosphatidylcholine-dependent phospholipase C have been described and characterised. Other lipids were demonstrated inside the nucleus especially plasmalogens and cholesterol. The chromatin phospholipids, comprising 10% of that present in the nucleus, show a different metabolism with respect to those present in either microsomes or in nuclear membranes; they increase also during the DNA duplication as shown during both liver regeneration and cell maturation. They appear localised near newly synthesized RNA in decondensed chromatin. Digestion of chromatin with RNase, but not with DNase, causes a loss of phospholipids. The composition of the chromatin phospholipid fraction shows an enrichment in sphingomyelin and phosphatidylserine. In this review the behaviour of single lipids in relation to cell proliferation, cell differentiation and apoptosis is described. Sphingomyelin, the lipid most represented in chromatin with respect to microsomes and nuclear membranes, is localised near to newly synthesized RNA, its presence appearing to protect RNA from RNase digestion. This effect is reversed by sphingomyelinase which digests sphingomyelin and, as a consequence, RNA may be hydrolysed. The amount of sphingomyelin is restored by sphingomyelin-synthase. Sphingomyelin increases during the differentiation process and apoptosis. An increase of sphingomyelinase with consequent decrease in sphingomyelin is observed at the beginning of S-phase of the cell cycle. A possible role in stabilising the DNA double helix is indicated. Phosphatidylserine behaves similarly during differentiation and appears to stimulate both RNA and DNA polymerases. Phosphatidylcholine is implicated in cell proliferation through the activation of intranuclear phosphatidylcholine-dependent phospholipase C and diacylglycerol production. The increase in diacylglycerol stimulates phosphatidylcholine synthesis through the major pathway from cytidyltriphosphate. An inhibition of phosphatidylcholine synthesis is responsible for the initiation of apoptosis. The presence of reverse sphingomyelin-synthase favours the formation of phosphatidylcholine, the donor of phosphorylcholine, from sphingomyelin. Little information has been reported for phospatidylethanolamine, but phosphtidylinositol appears to influence cell differentiation and proliferation. This last effect is due to the action of two enzymes: PI-PLCss1 having a role in the onset of DNA synthesis and PC-PLCgamma1 acting in G2 transit. Phosphoinositides also may have an important role: in membrane-stripped nuclei isolated from mitogen stimulated cells a decrease in PIP and PIP2 followed by an increase in diacylglycerol and a translocation of protein kinase C inside the nucleus is observed. On the other hand, overexpression of the enzyme inositol polysphosphate-1-phosphatase reduced DNA synthesis by 50%. Nevertheless, an enhanced rate of phosphorylation has been demonstrated in cells induced to differentiate. These molecules probably favour RNA transcription, counteracting the inhibition of H1 on RNA polymerase II. Plasmalogens were demonstrated in the nucleus and their increase favours the increased activity of phosphatidylcholine-dependent phospholipase C when DNA synthesis starts. Moreover, two forms of cholesterol has been described in chromatin: one, a less soluble sphingomyelin-linked form and a free fraction. Cholesterol increases during liver regeneration, first as a linked fraction and then, when DNA synthesis starts, as a free fraction. The changes of these components have been summarised in relation to cell function in order to give an overview of their possible roles in the different phases of cell duplication and their influence on cell differentiation and during apoptosis. Finally, the relevance of these molecules as intranuclear signals is discussed and future directions are indicated in clarifying pathological process such as tumour cell transformation and the possibility in finding new therapeutic tools.
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PMID:The role of intranuclear lipids. 1551 99

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