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Query: EC:6.3.2.19 (ubiquitin-protein ligase)
 799 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A previously studied species of ubiquitin-protein ligase contains specific sites for the binding of basic (Type I) and bulky hydrophobic (Type II) NH2-terminal amino acid residues of protein substrates. We now describe another enzyme that ligates ubiquitin specifically to proteins that have NH2-terminal residues other than the above two categories (Type III substrates). The new species of ligase, that we call E3 beta, is separable from the formerly described ligase (termed E3 alpha) by affinity chromatography on protein substrate columns. E3 beta was partially purified from extracts of rabbit reticulocytes and was shown to be required for the breakdown of Type III proteins. Apart from its different substrate specificity, it resembles E3 alpha in some physical properties, in a requirement for ubiquitin carrier protein (E2) for conjugate formation, and in its action to ligate multiple ubiquitin units to the substrate protein. The denatured derivative of bovine pancreatic ribonuclease is a specific substrate for E3 alpha, while that of ribonuclease S-protein is a good substrate for E3 beta. Since S-protein is formed by the removal from ribonuclease of NH2-terminal S-peptide, it is suggested that E3 beta interacts with an NH2-terminal determinant exposed in ribonuclease S-protein.
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PMID:A ubiquitin-protein ligase specific for type III protein substrates. 232 89

A free NH2-terminal group has been previously shown to be an obligatory signal for recognition and subsequent degradation of proteins in a partially fractionated and reconstituted ubiquitin proteolytic system. Naturally occurring proteins with acetylated NH2-termini--most cellular proteins fall in this category--were not degraded by this system. Other studies have suggested that the identity of the NH2-terminal residue is important in determining the metabolic stability of a protein in vivo (N-end rule). Whole reticulocyte lysate and antibodies directed against the ubiquitin-activating enzyme (E1) have now been used to show that such acetylated proteins are degraded in a ubiquitin-dependent mode. Although fractionation of lysate does not affect its proteolytic activity toward substrates with free NH2-termini, it completely abolishes the activity toward the blocked substrates, indicating that an important component of the system was either removed or inactivated during fractionation. An NH2-terminal "unblocking" activity that removes the blocking group, thus exposing a free NH2-terminus for recognition according to the N-end rule, does not seem to participate in this pathway. Incubation of whole lysate with labeled histone H2A results in the formation of multiple ubiquitin conjugates. In contrast, the fractionated system is devoid of any significant conjugating activity. These results suggest that a novel conjugating enzyme (possibly a ubiquitin-protein ligase) may be responsible for the degradation of these acetylated proteins by recognizing structural features of the substrate that are downstream and distinct from the NH2-terminal residue.
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PMID:Degradation of proteins with acetylated amino termini by the ubiquitin system. 254 30

In the multienzyme ubiquitin-dependent proteolytic pathway, conjugation of ubiquitin to target proteins serves as a signal for protein degradation. Rabbit reticulocytes possess a family of proteins, known as E2's, that form labile ubiquitin adducts by undergoing transthiolation with the ubiquitin thiol ester form of ubiquitin activating enzyme (E1). Only one E2 appears to function in ubiquitin-dependent protein degradation. The others have been postulated to function in regulatory ubiquitin conjugation. We have purified and characterized a previously undescribed E2 from rabbit reticulocytes. E2(230K) is an apparent monomer with a molecular mass of 230 kDa. The enzyme forms a labile ubiquitin adduct in the presence of E1, ubiquitin, and MgATP and catalyzes conjugation of ubiquitin to protein substrates. Exogenous protein substrates included yeast cytochrome c(Km = 125 mu M; kcat approximately 0.37 min-1) and histone H3 (Km less than 1.3 mu M; kcat approximately 0.18 min-1) as well as lysozyme, alpha-lactalbumin, and alpha-casein. E2(230K) did not efficiently reconstitute Ub-dependent degradation of substrates that it conjugated, either in the absence or in the presence of the ubiquitin-protein ligase that is involved in degradation. E2(230K) may thus be an enzyme that functions in regulatory Ub conjugation. Relative to other E2's, which are very iodoacetamide sensitive, E2(230K) was more slowly inactivated by iodoacetamide (k(obs) = 0.037 min-1 at 1.5 mM iodoacetamide; pH 7.0, 37 degrees C). E2(230K) was also unique among E2's in being subject to inactivation by inorganic arsenite (k(i)max = 0.12 min-1; K(0.5) = 3.3 mM; pH 7.0, 37 degrees C). Arsenite is considered to be a reagent specific for vicinal sulfhydryl sites in proteins, and inhibition is usually rapidly reversed upon addition of competitive dithiol compounds. Inactivation of E2(230K) by arsenite was not reversed within 10 min after addition of dithiothreitol at a concentration that blocked inactivation if it was premixed with arsenite; inactivation is therefore irreversible or very slowly reversible. We postulate that a conformation change of E2(230K) may be rate-limiting for interaction of enzyme thiol groups with arsenite.
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PMID:A novel, arsenite-sensitive E2 of the ubiquitin pathway: purification and properties. 255 69

The RAD6 gene from the yeast Saccharomyces cerevisiae encodes a ubiquitin carrier protein (E2) required for a variety of cellular processes including DNA repair, induced mutagenesis, and sporulation. Here we identify an E2 from a higher plant, wheat, that is similar to RAD6 with respect to both structure and in vitro substrate specificity. The protein was purified from wheat germ by a combination of ubiquitin covalent affinity chromatography and anion-exchange HPLC and has an apparent molecular mass of 23 kDa [referred to as E2(23 kDa)]. E2(23 kDa) was capable of binding ubiquitin by means of a thiol ester linkage in an ATP-dependent and ubiquitin-activating enzyme-dependent reaction. In the presence of a variety of target proteins, E2(23 kDa), like the RAD6 gene product, formed covalent ubiquitin-protein conjugates in vitro only with histones in a ubiquitin protein ligase-independent reaction. E2(23 kDa) recognized both core and linker histones with an apparent order of preference of H2A greater than or equal to H1 greater than H2B greater than H3 greater than H4. This E2 protein was approximately 17-fold more effective at conjugating ubiquitin to histones than three other purified wheat germ E2 proteins tested. Mouse anti-E2(23 kDa) antibodies were used to isolate E2(23 kDa) DNA sequences from a wheat cDNA expression library. Antibody-positive clones were confirmed by amino acid identity of the sequence deduced from the cDNA to the peptide sequence of an E2(23 kDa) tryptic fragment. Protein expressed in Escherichia coli by the E2(23 kDa) cDNA was capable of both thiol ester adduct formation and conjugation of ubiquitin to histones. Analysis of the E2(23 kDa) cDNA shows that it encodes a protein with considerable amino acid sequence similarity to the yeast RAD6 gene product. Similarities exist at the amino terminus, the region surrounding the putative ubiquitin binding site, and at the carboxyl terminus, which is unusually acidic. Based on both the structural and enzymatic similarities to the RAD6 gene product, E2(23 kDa) may represent the first DNA repair enzyme identified in higher plants.
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PMID:A ubiquitin carrier protein from wheat germ is structurally and functionally similar to the yeast DNA repair enzyme encoded by RAD6. 255 33

Ubiquitin is encoded as a variable, spacerless repeat of the gene terminating with an additional amino acid or as a gene coding for a single ubiquitin with a carboxyl-terminal extension of 52 to 80 amino acids. We report the identification and partial purification of enzymes that specifically hydrolyze the peptide bond between ubiquitin-ubiquitin conjugate (Ub-Ubase) or ubiquitin fusion proteins (Ub-Xase). The Ub-Ubase was separated from the Ub-Xase by dye-ligand-Sepharose chromatography. The Ub-Xase was purified further by affinity chromatography on ubiquitin-Sepharose. The fidelity of the endoprotease reaction was assessed by measuring the ability of the released ubiquitin to be activated by ubiquitin-activating enzyme (E1) which requires intact ubiquitin and by sequence analysis of the released carboxyl extension protein with 52 amino acids after endoproteolysis of human ubiquitin with 52-amino acid carboxyl extension. The failure of both Ub-Ubase and Ub-Xase to cleave a mutant ubiquitin-Gly-76----Ala-metallothionein showed that the endoproteases distinguish Gly-X from an Ala-X peptide bonds.
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PMID:Multiple (alpha-NH-ubiquitin)protein endoproteases in cells. 265 91

It was found previously that the enzyme ubiquitin-protein ligase (E3) contains specific protein substrate binding sites that are responsible for the selection of proteins for degradation by the ubiquitin system. In the present study, we have tried to gain more insight into the mode of action of E3 by the characterization of other binding sites of this enzyme. Following the ligation of ubiquitin to 125I-lysozyme, the conjugates produced are very tightly bound to E3, as indicated by size analysis on glycerol density gradient centrifugation. The strong binding of ubiquitin-protein conjugates to the enzyme may account for the apparently processive addition of multiple molecules of ubiquitin to the protein substrate. Both the protein substrate moiety and the ubiquitin moiety participate in the interaction of ubiquitin-protein conjugates with E3, as indicated by competition with specific agents and by the comparison of the binding of ubiquitin-conjugated protein to that of free protein. In addition to the binding of its substrates and products, E3 also appears to interact with some of the enzymes with which it acts in concert. When E3 is incubated with the ubiquitin-carrier protein E2, a complex is formed between the two enzymes as analyzed on glycerol gradients. The formation of an E2.E3 complex may facilitate the transfer of activated ubiquitin from E2 to the protein substrate bound to the ligase.
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PMID:Binding sites of ubiquitin-protein ligase. Binding of ubiquitin-protein conjugates and of ubiquitin-carrier protein. 273 27

Caffeine has been reported to induce premature chromosome condensation (PCC) in S-phase cells in the presence of an inhibitor of DNA synthesis. We found that when S-phase cells are treated with caffeine and hydroxyurea after X irradiation, substantially more potentially lethal damage (PLD) is expressed, but the addition of cycloheximide, which inhibits PCC induction in S-phase cells, in the presence of caffeine and hydroxyurea reduces the expression of PLD to the same level as seen with caffeine alone. This can be interpreted to mean that the expression of PLD seen with caffeine in the absence of an inhibitor of DNA synthesis is not associated with chromosome condensation. Evidence that PCC induction in S-phase cells and the influence of caffeine on PLD expression were suppressed by incubation at 40 degrees C of tsBN75 cells with a ts defect in ubiquitin-activating enzyme indicates the involvement of ubiquitin in these two processes. These observations as well as previous findings on ubiquitin suggest to us that caffeine induces changes in DNA-chromatin conformation, which are caused by induction of PCC or ubiquitination of chromosomal protein. Such changes occurring postirradiation would favor expression of PLD.
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PMID:X-ray-related potentially lethal damage expressed by chromosome condensation and the influence of caffeine. 279 83

We investigated the effect of heat shock on the development of thermotolerance using mouse FM3A cells and the temperature-sensitive mutant ts85. The shift-up incubation of FM3A from 33 to 39.5 degrees induced thermotolerance to subsequent heating at 44 degrees. In contrast, the similar treatment of ts85 at the nonpermissive temperature of 39.5 degrees could not induce thermotolerance. Furthermore, when ts85 cells were treated at 33 degrees after being heated at 44 degrees, they developed a reduced level of thermotolerance as compared with that developed in FM3A cells. Since ts85 cells are defective in ubiquitin-activating enzyme, these results suggest a role of the ubiquitin-protein conjugation system in the development of thermotolerance.
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PMID:Defect in the development of thermotolerance in the mouse temperature-sensitive mutant ts85 lacking ubiquitin-activating enzyme. 283 80

Conjugation of ubiquitin to certain proteins can trigger their degradation. A major question concerns the structural features of a protein which make it susceptible to ubiquitin ligation. Recent studies have shown that the selection of proteins for degradation occurs most probably on a binding site of the ubiquitin-protein ligase (E3). It was shown that a free alpha-NH2 group is one important feature of the protein structure recognized by the ubiquitin-ligating enzyme. Proteins with basic or bulky hydrophobic residues in the NH2-terminal position are recognized by the ligase, marked by ubiquitin, and degraded. This is not true, however, for proteins with an acidic residue in this position. We have previously shown that a tRNA-dependent post-translational conjugation of arginine to acidic NH2 termini of proteins is essential for their degradation via the ubiquitin pathway, and we speculated that this modification is required for their recognition by the ligase. In the present study we have partially purified from rabbit reticulocytes the modifying enzyme, arginyl-tRNA-protein transferase, and characterized it. We have separated the enzyme from other known components of the ubiquitin system and shown that it is specifically required for degradation of proteins with either an aspartate or glutamate residue in their NH2-terminal position. We have shown that the action of the transferase is required for conjugation of ubiquitin to the substrate and most probably for its recognition by the ligase. The enzyme in its native form has a molecular mass of about 360 kDa. It appears to be a complex between several molecules of arginyl-tRNA synthetase and arginyl-tRNA-protein transferase.
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PMID:Purification and characterization of arginyl-tRNA-protein transferase from rabbit reticulocytes. Its involvement in post-translational modification and degradation of acidic NH2 termini substrates of the ubiquitin pathway. 284 21

The covalent ligation of the 8.6-kDa protein ubiquitin to histones within transcriptionally poised regions is believed to participate in the localized regulation of chromatin structure. This unique post-translational modification is thought to be distinct from similar cytosolic reactions in requiring ubiquitin-activating enzyme (E1) and one or more putative ubiquitin carrier proteins (E2) but not isopeptide ligase (E3). Apparently homogeneous preparations of the E2 isozymes were tested for their ability to catalyze the E3-independent conjugation of ubiquitin to linker histone H1 and core histones H2A, H2B, H3, and H4 in the presence of catalytic amounts of E1. Significant rates of nonprocessive core histone monoubiquitination were catalyzed by the E2(14kDa), E2(20kDa), and E2(32kDa) isozymes but not by either E2(17kDa) or E2(24kDa). The former three E2 isozymes also supported slow rates of direct multiple ubiquitination to secondary ligation sites on the histones. Rate studies for the monoubiquitination of H2A and H2B revealed that: 1) E2(14kDa) catalyzed a second order reaction with respect to histone concentration; 2) E2(32kDa)-mediated ligation proceeded by hyperbolic kinetics, yielding Km values of 2.8 and 12 microM for H2A and H2B, respectively; and 3) E2(20kDa) exhibited complex kinetics composed of both second order and hyperbolic pathways, the latter having Km values of 0.83 and 1.5 microM for H2A and H2B, respectively. Pulse-chase kinetics suggested that both ubiquitin thiol esters formed to E2(20kDa) were catalytically competent in H2A ligation. The active E2 isozymes also catalyzed the processive multiple ubiquitination of calf thymus H1. Other rate studies determined that Kd values for binding of the active E2 species to E1 ternary complex were 0.1 nM for E2(14kDa), 0.4 nM for E2(32kDa), and 3.6 nM for E2(20kDa). The data indicate that E2(20kDa) and E2(32kDa) are specific but mechanistically distinct ligation enzymes responsible for the conjugation of ubiquitin to nucleosomal proteins.
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PMID:Functional diversity among putative E2 isozymes in the mechanism of ubiquitin-histone ligation. 284 16


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