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)

The in vitro metabolism of [14C]toluene by liver microsomes and liver slices from male Fischer F344 rats and human subjects has been compared. Rat liver microsomes produced only benzyl alcohol from toluene. Liver microsomes from human subjects metabolized toluene to benzyl alcohol, benzaldehyde, and benzoic acid. Liver microsomes from one human donor also produced p-cresol and o-cresol. The overall rate of toluene metabolism by human liver microsomes was 9-fold greater than by rat liver microsomes. Human liver microsomal metabolism of benzyl alcohol to benzaldehyde required NADPH and was inhibited by carbon monoxide and high pH (pH 10). but was not inhibited by ADP-ribose or sodium azide. These results suggest that cytochrome P-450, rather than alcohol dehydrogenase, was responsible for the metabolism of benzyl alcohol to benzaldehyde. Human and rat liver slices metabolized toluene to hippuric acid and benzoic acid. The overall rate of toluene metabolism by human liver slices was 1.3-fold greater than by rat liver slices. Cresols and cresol conjugates were not detected in human or rat liver slice incubations. Covalent binding of [14C]toluene to human liver microsomes and slices was 21-fold and 4-fold greater than to the comparable rat liver preparations. Covalent binding did not occur in the absence of NADPH, was significantly decreased by coincubation with cysteine, glutathione, or superoxide dismutase, and was unaffected by coincubation with lysine. Protease and ribonuclease digestion decreased the amount of toluene covalently bound to human liver microsomes by 78% and 27% respectively. Acid washing of human liver microsomes had no effect on covalent binding.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Metabolism and covalent binding of [14C]toluene by human and rat liver microsomal fractions and liver slices. 198 39

Seven cationic substances--human and egg-white lysozyme, RNase, protamine, histone, poly-L-lysine and poly-L-arginine; five cationic lysosomal fractions from human polymorphonuclears (PMNs); RNA; poly-L-glutamic acid; DNA; heparin; endotoxin; mastocytotropic agent compound 48/80; and cytochalasin B were tested for the influence on chemotaxis and random migration of human PMNs using under-agarose migration and Boyden chambers with two filters and [51Cr]PMNs. The above substances were either preincubated with PMNs, added to chemoattractants, or used instead of chemoattractants. In under-agarose migration method chemotaxis was inhibited by 11-35% when egg-white lysozyme, protamine, heparin, endotoxin, or compound 48/80 was added to the cells. High concentration of cytochalasin B inhibited chemotaxis by 73%. Cationic fractions I and V and low concentration of cytochalasin B enhanced chemotaxis by 11%, 41%, and 30%, respectively. When human and egg-white lysozyme, DNA, or cytochalasin B was added to the chemoattractants, motility of PMNs was inhibited. Cationic fractions II and V from human PMNs, when used as chemoattractants, enhanced cellular motility by 143-167%. Random migration was enhanced by heparin and inhibited by cytochalasin B and by cationic fractions from human PMNs. These findings suggest that various cationic and anionic substances and cationic fractions from human PMNs have heterogeneous influence on random migration and chemotactic activity of human PMN. Analysis relating chemotaxis to phagocytosis and to intracellular bactericidal activity (ICBA) has shown several patterns. Protamine, poly-L-lysine, poly-L-arginine, and agent compound 40/80 all inhibit chemotaxis and enhance phagocytosis and ICBA; cationic fractions II and V enhanced all three functions, whereas cytochalasin B suppressed phagocytosis and ICBA and had concentration-dependent modulatory influence on chemotaxis. It implies diverse mechanisms of action and possible impact on inflammatory reactions.
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PMID:Modulation of locomotor activity of polymorphonuclear cells by cationic substances and cationic lysosomal fractions from human neutrophils. 241 86

We have isolated a 725-bp full-length cDNA clone for the human eosinophil cationic protein (ECP). ECP is a small, basic protein found in the matrix of the eosinophil's large specific granule that has cytotoxic, helminthotoxic, and ribonuclease activity, and is a member of the ribonuclease multigene family. The cDNA sequence shows 89% sequence identity with that reported for the related granule protein, eosinophil-derived neurotoxin (EDN). The open reading frame encodes a previously unidentified 27-amino acid leader sequence preceding a 133-residue mature ECP polypeptide with a molecular mass of 15.6 kD. The encoded amino acid sequence of ECP shows 66% identity to that of EDN and 31% identity to that of human pancreatic ribonuclease, including conservation of the essential structural cysteine and cataytic lysine and histidine residues. mRNA for ECP was detected in eosinophil-enriched peripheral granulocytes and in a subclone of the promyelocytic leukemia line, HL-60, induced toward eosinophilic differentiation with IL-5. No ECP mRNA was detected in uninduced HL-60 cells, or in HL-60 cells induced toward monocytic differentiation with vitamin D3 or toward neutrophilic differentiation with DMSO. In contrast, mRNA for EDN was detected in uninduced HL-60 cells and was upregulated in HL-60 cells induced with DMSO. Despite similarities in sequence and cellular localization, these results suggest that ECP and EDN are subject to different regulatory mechanisms.
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PMID:Human eosinophil cationic protein. Molecular cloning of a cytotoxin and helminthotoxin with ribonuclease activity. 247 57

Two different hybrid genes were constructed which fuse the Bacillus amyloliquefaciens alkaline protease gene (apr[BamP]) promoter and signal peptide coding region to a synthetic bpr gene coding for the mature bovine pancreatic RNase A. The first gene fusion (apr-bpr1) contained the apr[BamP] signal peptide coding region fused to mature bpr through a linker coded 3-amino acid region and retained the signal processing site ala-ala of the alkaline protease. The second fusion (apr-bpr2) joined the end of the apr[BamP] signal peptide coding sequence to the mature bpr resulting in a hybrid signal processing site ala-lys. B. subtilis strains harboring these gene fusions secreted bovine pancreatic RNase A into the growth medium. Cleavage at the hybrid signal processing site ala-lys resulted in the secretion of bovine pancreatic RNase A from B. subtilis which had an N-terminal amino acid sequence that was identical to the native RNase A. Bovine pancreatic RNase A contains four disulfide bonds and the proper formation of these bonds is required for activity. RNase activity could be detected in the culture supernatants of strains carrying the apr-bpr gene fusions, which suggests that the proper disulfide bonds have formed spontaneously.
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PMID:Expression of bovine pancreatic ribonuclease A coded by a synthetic gene in Bacillus subtilis. 250 Nov 58

The nucleotide sequences of 1288 bp of plasmid ColE5-099, 1609 bp of ColE6-CT14 and 2099 bp of ColE9-J were determined. These sequences encompass the structural genes for the C-terminal receptor-binding and nuclease domains of colicins E5, E6 and E9, their cis- or trans-acting immunity proteins and four lysis proteins including an atypical one of non-lipoprotein nature (Lys) present in the ColE9-J plasmid. The ColE6 gene organisation, in the order col-imm-E8imm-lys, is identical to that found in the previously described double-immunity gene system of ColE3-CA38 (an RNase producer). The corresponding genes in the two plasmids are 87%-94% homologous. In ColE9-J, the genes are organised as col-imm-lys-E5imm-lys. The E9 col-imm gene pair is homologous to the colicin E2-P9 type (a DNase producer). Downstream from E9imm is an E5imm (designated E5imm[E9]) which is trans-acting. Neither the predicted structures of E5Imm[E9] nor the cis-acting Imm resident in the ColE5-099 plasmid which differs by a single amino acid shows any resemblance to other immunity structures which have been sequenced. Furthermore, the E5col sequences differ from those predicted previously for other colicins except for the conserved btuB-specified receptor-binding domain. A novel 205 nucleotide long insertion sequence is found in the ColE9-J plasmid. This insertion sequence, which we named ISE9, has features reminiscent of the degenerate transposon IS101 previously found in plasmid pSC101. One effect of ISE9 is the presence of the atypical lysis gene, lys.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Nucleotide sequences from the colicin E5, E6 and E9 operons: presence of a degenerate transposon-like structure in the ColE9-J plasmid. 254 75

Human angiogenin is a blood vessel inducing protein whose primary structure displays 33% identity to that of bovine pancreatic ribonuclease A (RNase A). Angiogenin catalyzes limited cleavage of 18S and 28S ribosomal RNA and is several orders of magnitude less potent than RNase A toward conventional substrates. A striking structural difference between angiogenin and RNase is the virtual absence of sequence similarity within the region of RNase that contains the Cys-65--Cys-72 disulfide bond. Indeed, angiogenin lacks this disulfide linkage. The present report describes the use of regional mutagenesis to generate a covalent angiogenin/RNase hybrid protein, ARH-I, where residues 58-70 of angiogenin have been replaced by the corresponding segment of RNase A (residues 59-73). The protein expressed in Escherichia coli readily folds at pH 8.5 to form the four expected disulfide bonds. The in vivo angiogenic potency of ARH-I is markedly diminished compared with that of angiogenin when examined using the chick chorioallantoic membrane assay. In contrast, its enzymatic activity is dramatically increased. With high molecular weight wheat germ RNA and tRNA, ARH-I is 660- and 300-fold more active than angiogenin, respectively, while with poly(uridylic acid), poly(cytidylic acid), cytidylyl(3'----5')adenosine (CpA), and uridylyl(3'----5')adenosine (UpA) activity is enhanced by about 200-fold. In addition, the specificity of ARH-I toward dinucleoside 3',5'-phosphates is qualitatively similar to RNase A; while angiogenin prefers cytidylyl(3'----5')guanosine (CpG) to UpA, both RNase and the hybrid prefer UpA to CpG. ARH-I also displays greater than 10-fold enhanced activity toward rRNA in intact ribosomes, while abolishing the capacity of the ribosome to support cell-free protein synthesis. The enhanced enzymatic properties of ARH-I parallel a 2-fold increase in chemical reactivity of active-site lysine and histidine residues based on rates of chemical modification. The data indicate that introduction of a region of RNase A containing the Cys-65--Cys-72 disulfide bond into angiogenin dramatically increases RNase-like enzymatic activity while reducing its angiogenicity.
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PMID:A covalent angiogenin/ribonuclease hybrid with a fourth disulfide bond generated by regional mutagenesis. 271 39

Extensive 15N-NMR investigations of active-site amino acids were made possible by the solid-phase synthesis of the N-terminal pentadecapeptide of RNase A with selectively 15N-enriched amino acids. On complexation with S-protein a fully active RNase S' complex was obtained. The 15N resonances of the side chains of lysine-7 (N epsilon), glutamine-11 (N gamma), and histidine-12 (N pi, tau) were studied in the free synthetic peptide, in the RNase S' complex and in the nucleotide complexes RNase S' with 2'CMP, 3'CMP, and 5'AMP. The analysis of the 15N-1H couplings, the 15N line broadenings due to proton exchange, and the chemical shift values showed that, while the imidazole ring is directly involved in the peptide-protein interaction, the side chains of Lys-7 and Gln-11 do not contribute to this interaction. In the nucleotide complexes the resonances of His-12 and Gln-11 are shifted downfield. In the 2'CMP complex a doublet for the N tau signal of His-12 indicates a stable H bond between this nitrogen and the phosphate group of nucleotide. The other nucleotide influence the resonances of the imidazole group much less, possibly due to a slightly different orientation of the phosphate group. The downfield shift of the Gln-11 resonance indicates an interaction between the carbonyl oxygen of the amide group and the phosphate moiety of the nucleotide. The only observable effect of nucleotide complexation on the Lys-7 signal is line broadening due to reduced proton exchange. For comparison with the 15N-NMR titration curves of His-12 in RNase S' the 1H-NMR titration curves of RNase A were also recorded. Both shape and pK values were very similar for the 15N and the 1H titration curves. An extensive analysis of the protonation equilibria with several fitting models showed that a mutual interaction of the imidazole groups of the active-site histidines results in flat titration curves. The Hill plots of all resonances of the imidazole rings, including the 15N resonances, show a small inflection in the pH range 5.8-6.4. Since the existence of a diimidazole system is most likely in this pH range, the inflection could be interpreted as a disturbance of the mutual electrostatic interaction of the active-site histidines by a partial H-bond formation between the imidazole groups.
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PMID:15N- and 1H-NMR investigations of the active-site amino acids in semisynthetic RNase S' and RNase A. 283 66

Affinity labelling with radioactive, periodate-oxidized tRNA has been used to investigate the structures of tRNA-binding sites in Escherichia coli aminoacyl-tRNA synthetases. Labelled peptides were isolated by means of a combination of techniques involving chymotryptic digestion of the enzyme, gel filtration, ribonuclease digestion of tRNA, chromatography on a TSK 2000 column and reversed-phase chromatography. An isocratic phenylthiohydantoin identification system has been interfaced to a sequencer, allowing the characterization of modified lysine residues by means of both chromatographic retention and liquid scintillation counting.
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PMID:Analytical strategy for determination of active site sequences in aminoacyl-tRNA synthetases. 283 97

Hepatic ethanol metabolism generates the reactive intermediate, acetaldehyde, which binds to proteins. The binding of acetaldehyde to purified enzymes was determined in order to ascertain whether such binding altered their catalytic functions. [14C]Acetaldehyde was incubated with alcohol dehydrogenase, glucose-6-phosphate dehydrogenase, lactate dehydrogenase and RNase A, each at 37 degrees C (pH 7.4). In some reactions, sodium cyanoborohydride was included for stabilization of Schiff bases, formed as a result of the reaction between acetaldehyde and the amino groups of the enzymes. Portions of each reaction mixture were removed for determination of stable and total (stable plus borohydride-reducible) adducts. Alcohol dehydrogenase and lactate dehydrogenase were not inhibited by adduct formation. Glucose-6-phosphate dehydrogenase and RNase, the activities of which depend on a lysine residue at their catalytic sites, were inhibited in a dose- and time-dependent manner. The degree of inhibition directly correlated with total adduct formation. Phosphate, known to inhibit binding to the active site lysine of RNase, prevented the inhibition of catalytic activity caused by adduct formation. These findings indicate that the binding of acetaldehyde to lysine at the catalytic site can inhibit enzyme activity.
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PMID:Covalent binding of acetaldehyde selectively inhibits the catalytic activity of lysine-dependent enzymes. 293 8

13C NMR spectroscopy has been used to characterize Amadori (ketoamine) adducts formed by reaction of [2-13C]glucose with free amino groups of protein. The spectra of glycated proteins were acquired in phosphate buffer at pH 7.4 and were interpreted by reference to the spectra of model compounds, N alpha-formyl-N epsilon-fructose-lysine and glycated poly-L-lysine (GlcPLL). The anomeric carbon region of the spectrum (approximately 90-105 ppm) of glycated cytochrome c was superimposable on that of N alpha-formyl-N epsilon-fructose-lysine, and contained three peaks characteristic of the alpha- and beta-furanose and beta-pyranose anomers of Amadori adducts to peripheral lysine residues on protein (pK alpha approximately 10.5). The spectrum of GlcPLL yielded six anomeric carbon resonances; the second set of three was displaced about 2 ppm to lower shielding of the first and was assigned to the Amadori adduct at the alpha-amino terminus (pK alpha approximately 7.5). The spectrum of glycated RNase was similar to that of GlcPLL, but contained a third set of three signals attributable to modification of active site lysine 41 (pK alpha approximately 8.8). The assignments for RNase were confirmed by analysis of spectra taken at pH 4 and under denaturing conditions. The spectrum of glycated hemoglobin was comparable to that of GlcPLL, and distinct resonances could be assigned to Amadori adducts at amino-terminal valine and intrachain N epsilon-lysine residues. Chemical analyses were performed to measure the relative extent of alpha- and epsilon-amino group modification in the glycated macromolecules, and the results were compared with estimates based on integration of the NMR spectra.
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PMID:Characterization of glycated proteins by 13C NMR spectroscopy. Identification of specific sites of protein modification by glucose. 298 92


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