EC:3.1.26.9 - FACTA Search

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Query: EC:3.1.26.9 (ribonuclease)
6,589 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have isolated a unique genomic fragment encoding human ribonuclease 4 (RNase 4) of the mammalian ribonuclease gene family, whose members include pancreatic ribonuclease, eosinophil-derived neurotoxin, eosinophil cationic protein and angiogenin. We have determined that the coding sequence of RNase 4 resides on a single exon found on human chromosome 14. The mRNA encoding RNase 4 was detected by Northern analysis in a number of human somatic tissues, including pancreas, lung, skeletal muscle, heart, kidney and placenta, but not brain; liver represents the most abundant source. Interestingly, the mRNA encoding RNase 4 is approximately 2 kb in length, which is approximately twice as large as the mRNAs encoding other members of this gene family. A larger (approximately 2.4 kb), second transcript was detected in hepatic, pancreatic and renal tissues. The approximately 2 kb RNase 4 mRNA was detected in cells of the human promyelocytic leukemia line, HL-60, that had been treated with dibutyryl-cAMP to promote neutrophilic differentiation. In contrast, no mRNA encoding RNase 4 could be detected in cells treated with phorbol myristic acid (PMA), an agent promoting differentiation toward monocyte/macrophages, suggesting the existence of elements regulating tissue specific expression of this gene.
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PMID:Human ribonuclease 4 (RNase 4): coding sequence, chromosomal localization and identification of two distinct transcripts in human somatic tissues. 750 48

A ribonuclease (RNase) that cleaves specifically on the 3' side of uridine [Shapiro, R., Fett, J. W., Strydom, D. J. & Vallee, B. L. (1986a) Biochemistry 25, 7255-7264] was purified from human plasma and its amino acid sequence was determined. This protein is a 119-residue single-chain polypeptide cross-linked by four disulfide bonds and has an amino-terminal pyroglutaminyl residue. No post-translational modifications were observed during extensive sequence studies on peptide fragments, except for the amino-terminal pyroglutamic acid and a possible deamidation of Asn66. The protein is homologous to the pancreatic ribonucleases and angiogenin, but differs substantially from both of these proteins; the protein sequence has 43% identity with human pancreatic ribonuclease and 39% identity with human angiogenin, as compared to 35% identity between human angiogenin and pancreatic ribonuclease. It is referred to as RNase 4, based on the nomenclature currently used for the genes of pancreatic RNase (RNase 1) and the eosinophil-derived RNases (RNase 2 and RNase 3). Virtually all of the RNase active-site components, including the catalytic residues His12, His119 and Lys41, are preserved. However, some invariant residues of RNase 1 are replaced, e.g. Lys7 by arginine, Asp14 by histidine, and Pro42 by arginine. RNase 4 contains a unique two-residue deletion at the position corresponding to amino acids 77 and 78 of pancreatic RNase, and its carboxyterminal sequence is truncated at position 122. The deletion in angiogenin at position 21 is also found in RNase 4. RNase 4 is very similar to two RNases isolated from bovine and porcine liver, and together they form a new family in the RNase superfamily. The degree of inter-species similarity (90%) is much greater than within the pancreatic RNase and angiogenin families, which suggests that this ribonuclease could possess a physiologically important function other than general RNA catabolism.
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PMID:The amino acid sequence of human ribonuclease 4, a highly conserved ribonuclease that cleaves specifically on the 3' side of uridine. 822 79

Ribonucleases with antitumor activity are mainly found in the oocytes and embryos of frogs, but the role of these ribonucleases in frog development is not clear. Moreover, most frog ribonuclease genes have not been cloned and characterized. In the present study, a group of ribonucleases were isolated from Rana catesbeiana (bullfrog). These ribonucleases in mature oocytes, namely RC-RNase, RC-RNase 2, RC-RNase 3, RC-RNase 4, RC-RNase 5 and RC-RNase 6, as well as liver-specific ribonuclease RC-RNase L1, were purified by column chromatographs and detected by zymogram assay and western blotting. Characterization of these purified ribonucleases revealed that they were highly conserved in amino acid sequence and had a pyroglutamate residue at their N-termini, but possessed different specific activities, base specificities and optimal pH values for their activities. These ribonucleases were cytotoxic to cervical carcinoma HeLa cells, but their cytotoxicities were not closely correlated to their enzymatic specific activities. Some other amino acid residues in addition to their catalytic residues were implicated to be involved in the cytotoxicity of the frog ribonucleases to tumor cells. Because the coding regions lack introns, the ribonuclease genes were cloned by PCR using genomic DNA as template. Their DNA sequences and amino acid sequences are homologous to those of mammalian ribonuclease superfamily, approximately 50 and approximately 25%, respectively.
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PMID:Purification and cloning of cytotoxic ribonucleases from Rana catesbeiana (bullfrog). 1105 5

The ribonuclease A (RNase A) superfamily has been the subject of extensive studies in the areas of protein evolution, structure and biochemistry and are exciting molecules in that they appear to be responding to unique selection pressures, generating proteins capable of multiple and diverse activities. The RNase 4 and RNase 5/ang 1 shared locus breaks a pattern that is otherwise canonical among the members of the RNase A gene superfamily. Conserved among humans, mice and rats, the locus includes two non-coding exons followed by two distinct exons encoding RNase 4 and RNase 5/ang 1. Transcription from this locus is controlled by differential splicing and tissue-specific expression from promoters located 5' to each of the non-coding exons. Promoter 1, 5' to exon I, is universally active, while Promoter 2, 5' to exon II, is active only in hepatic cells in promoter assays in vitro. Transcription from Promoter 2 is dependent on an intact HNF-1 consensus binding site which binds the transcription factor HNF-1alpha. In summary, RNase 4 and RNase 5/ang 1 are unique among the RNase A ribonuclease genes in that they maintain a complex gene locus that is conserved across species with transcription initiated from tissue-specific dual promoters followed by differential exon splicing.
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PMID:The mouse RNase 4 and RNase 5/ang 1 locus utilizes dual promoters for tissue-specific expression. 1572 82

The antimicrobial defense of the skin is partially mediated by RNase 7, an abundant ribonuclease of the stratum corneum (SC). Here, we investigated the expression and regulation of members of the RNase A family and of the endogenous RNase inhibitor (RI) protein in epidermal keratinocytes (KCs). Reverse transcription-PCR screening revealed that KCs expressed not only RNase 7 but also RNase 5, which was shown earlier to kill the yeast Candida albicans, as well as RNase 1, RNase 4, and RI. The mRNA and protein levels of RNase 5, RNase 7, and RI increased during KC differentiation. When RNase 5 and RNase 7 were incubated with RI in vitro, not only their ribonucleolytic activities but also their antimicrobial activities were strongly suppressed. Immunochemical analyses revealed that SC contains RNase 5, whereas RI was not detectable. Unlike recombinant RNase 5, recombinant RI was degraded when exposed to SC extract. The addition of aprotinin prevented the degradation of RI, indicating that serine proteases of the SC cleave RI. Taken together, this study adds RNase 5 to the list of antimicrobial factors present in the SC and suggests that proteases contribute indirectly to the defense function of the SC by releasing the RI-mediated inhibition of RNase 5 and RNase 7.
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PMID:Degradation by stratum corneum proteases prevents endogenous RNase inhibitor from blocking antimicrobial activities of RNase 5 and RNase 7. 1980 22

Stress-induced phosphorylation of eIF2alpha inhibits global protein synthesis to conserve energy for repair of stress-induced damage. Stress-induced translational arrest is observed in cells expressing a nonphosphorylatable eIF2alpha mutant (S51A), which indicates the existence of an alternative pathway of translational control. In this paper, we show that arsenite, heat shock, or ultraviolet irradiation promotes transfer RNA (tRNA) cleavage and accumulation of tRNA-derived, stress-induced small RNAs (tiRNAs). We show that angiogenin, a secreted ribonuclease, is required for stress-induced production of tiRNAs. Knockdown of angiogenin, but not related ribonucleases, inhibits arsenite-induced tiRNA production and translational arrest. In contrast, knockdown of the angiogenin inhibitor RNH1 enhances tiRNA production and promotes arsenite-induced translational arrest. Moreover, recombinant angiogenin, but not RNase 4 or RNase A, induces tiRNA production and inhibits protein synthesis in the absence of exogenous stress. Finally, transfection of angiogenin-induced tiRNAs promotes phospho-eIF2alpha-independent translational arrest. Our results introduce angiogenin and tiRNAs as components of a phospho-eIF2alpha-independent stress response program.
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PMID:Angiogenin cleaves tRNA and promotes stress-induced translational repression. 1933 86