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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)

Alteration of the subcellular distribution of Mod5p-I, a tRNA modification enzyme, member of the sorting isozyme family, affects tRNA-mediated nonsense suppression. Altered suppression efficiency was used to identify MDP genes, which, when mutant, change the mitochondrial/cytosolic distribution of Mod5p-I,KR6. MDP2 is the previously identified VRP1, which encodes verprolin, required for proper organization of the actin cytoskeleton. MDP3 is identical to PAN1, which encodes a protein involved in initiation of translation and actin cytoskeleton organization. We report here the cloning and characterization of wild-type and mutant MDP1 alleles and the isolation and characterization of a multicopy suppressor of mdp1 mutations. MDP1 is identical to RSP5, which encodes ubiquitin-protein ligase, and mdp1 mutations are suppressed by high copy expression of ubiquitin. All four characterized mdp1 mutations cause missense changes located in the hect domain of Rsp5p that is highly conserved among ubiquitin-protein ligases. In addition to its well-known function in protein turnover, ubiquitination has been proposed to play roles in subcellular sorting of proteins via endocytosis and in delivery of proteins to peroxisomes, the endoplasmic reticulum and mitochondria. mdp1, as well as mdp2/vrp1 and mdp3/pan1 mutations, affect endocytosis. Further, mdp1 mutations show synthetic interactions with mdp2/vrp1 and mdp3/pan1. Identification of MDP1 as RSP5, along with our previous identification of MDP2/VRP1 and MDP3/PAN1, implicate interactions of the ubiquitin system, the actin cytoskeleton and protein synthesis in the subcellular distribution of proteins.
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PMID:MDP1, a Saccharomyces cerevisiae gene involved in mitochondrial/cytoplasmic protein distribution, is identical to the ubiquitin-protein ligase gene RSP5. 905 70

The Nedd4 gene was initially identified by a subtraction cloning approach as a highly expressed transcript in the mouse embryonic brain. Cloning of the Nedd4 cDNA indicated that it can encode a protein of approximately 103 kDa, consisting of a Ca2+ and phospholipid binding domain, three putative protein-protein interaction domains (the WW domains), and a carboxyl-terminus region similar to the ubiquitin-protein ligase domain (hect domain). In mouse embryos, the expression of Nedd4 in the central nervous system is highest during neurogenesis and decreases as development progresses. In addition to the central nervous system, the expression of Nedd4 is detected in various embryonic tissues and persists in most adult tissues. Using an antibody raised against a fusion protein, we show that Nedd4 protein is localized to the cellular cytoplasm. We have mapped the mouse Nedd4 gene to chromosome 9 using an interspecific backcross panel. Nedd4 maps to a previously defined homologous region between human and mouse chromosomes and thus provides additional information regarding interspecies comparative mapping.
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PMID:cDNA cloning, expression analysis, and mapping of the mouse Nedd4 gene. 907 11

Conjugation of multiple ubiquitins serves as a committed step in the degradation of a variety of intracellular eukaryotic proteins by the 26S proteasome. Conjugates are formed via a three-enzyme cascade; the initial step requires ubiquitin-activating enzyme (E1), which couples ubiquitin activation to ATP hydrolysis. Previously, we showed that many higher plants contain multiple E1 proteins and described several E1 genes from wheat. To facilitate understanding of the roles of the different plant E1s, we characterized the E1 gene and protein family from Arabidopsis thaliana. Arabidopsis E1s are encoded by two genes (AtUBA1 and AtUBA2) that synthesize approximately 123-kDa proteins with 81% amino acid sequence identity to each other and 44-75% sequence identity with confirmed E1s from other organisms. Like other E1 proteins, AtUBA1 and 2 contain a cysteine residue in the putative active site for forming the ubiquitin thiol-ester intermediate. Enzymatic analysis of the corresponding proteins expressed in Escherichia coli demonstrated that both proteins activate ubiquitin in an ATP-dependent reaction and transfer the activated ubiquitin to a variety of Arabidopsis E2s with near equal specificity. Expression studies by quantitative RT-PCR and histochemistry with transgenic plants containing AtUBA promoter-beta-glucuronidase-coding region fusions showed that the AtUBA1 and 2 genes are co-expressed in most, if not all, Arabidopsis tissues and cells. Collectively, the data indicate that E1 proteins, and presumably the rest of the ubiquitin pathway, are present throughout Arabidopsis. They also show that the AtUBA1 and 2 genes are not differentially expressed nor do they encode E1s with dramatically distinct enzymatic properties.
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PMID:The ubiquitin-activating enzyme (E1) gene family in Arabidopsis thaliana. 907 89

The ubiquitin-activating enzyme exists as two isoforms: E1a, localized predominantly in the nucleus, and E1b, localized in the cytoplasm. Previously we generated hemagglutinin (HA) epitope-tagged cDNA constructs, HA1-E1 (epitope tag placed after the first methionine) and HA2-E1 (epitope tag placed after the second methionine) (Handley-Gearhart, P. M., Stephen, A. G., Trausch-Azar, J. S., Ciechanover, A., and Schwartz, A. L. (1994) J. Biol. Chem. 269, 33171-33178), which represent the native isoforms. HA1-E1 is exclusively nuclear, whereas HA2-E1 is found predominantly in the cytoplasm. Using high resolution isoelectric focusing and SDS-polyacrylamide gel electrophoresis, we confirm that these epitope-tagged constructs HA1-E1 and HA2-E1 represent the two isoforms E1a and E1b. HA1-E1/E1a exists as one non-phosphorylated and four phosphorylated forms, and HA2-E1/E1b exists as one predominant non-phosphorylated form and two minor phosphorylated forms. We demonstrate that the first 11 amino acids are essential for phosphorylation and exclusive nuclear localization of HA1-E1. Within this region are four serine residues and a putative nuclear localization sequence (NLS; 5PLSKKRR). Removal of these four serine residues reduced phosphorylation levels by 60% but had no effect on nuclear localization of HA1-E1. Each serine residue was independently mutated to an alanine and analyzed by two-dimensional electrophoresis; only serine 4 was phosphorylated. Disruption of the basic amino acids within the NLS resulted in loss of exclusive nuclear localization and a 90-95% decrease in the phosphorylation of HA1-E1. This putative NLS was able to confer nuclear import on a non-nuclear protein in digitonin-permeabilized cells in a temperature- and ATP-dependent manner. Thus the predominant requirement for efficient phosphorylation of HA1-E1/E1a is a functional NLS, suggesting that E1a may be phosphorylated within the nucleus.
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PMID:Identification of a region within the ubiquitin-activating enzyme required for nuclear targeting and phosphorylation. 909 46

The maltose transporter in Saccharomyces cerevisiae is degraded in the vacuole after internalization by endocytosis when protein synthesis is impaired and a fermentable substrate is present. The possible implication of the ubiquitin pathway in this inactivation, known as catabolite inactivation, has been investigated. Using mutants deficient in npi1/rsp5 ubiquitin-protein ligase and npi2/doa4 ubiquitin-protein hydrolase, we have shown that these two enzymes are required for normal endocytosis and degradation of the transporter. These facts indicate that the ubiquitin pathway is involved in catabolite inactivation of the maltose transporter. The results also revealed that both enzymes act in the internalization step of endocytosis.
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PMID:Catabolite inactivation of the yeast maltose transporter requires ubiquitin-ligase npi1/rsp5 and ubiquitin-hydrolase npi2/doa4. 911 4

The E6-AP gene (UBE3A) encodes an E3 ubiquitin-protein ligase that binds the human papillomavirus E6 oncoprotein and catalyzes the ubiquitination of p53. Recent studies have also established that mutations in E6-AP are the genetic basis of the Angelman syndrome in humans. In this study we present the genomic structure of the coding region of E6-AP and an analysis of a set of five E6-AP mRNAs with the potential to encode three protein isoforms of the E6-AP protein (isoforms I, II, and III) that differ at their extreme amino-termini. These transcripts were expressed in a variety of different cell lines examined.
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PMID:The human E6-AP gene (UBE3A) encodes three potential protein isoforms generated by differential splicing. 914 3

A recently described protein module consisting of 35-40 semiconserved residues, termed the WW domain, has been identified in a number of diverse proteins including dystrophin and Yes-associated protein (YAP). Two putative ligands of YAP, termed WBP-1 and WBP-2, have been found previously to contain several short peptide regions consisting of PPPPY residues (PY motif) that mediate binding to the WW domain of YAP. Although the function(s) of the WW domain remain to be elucidated, these observations strongly support a role for the WW domain in protein-protein interactions. Here we report the isolation of three novel human cDNAs encoding a total of nine WW domains, using a newly developed approach termed COLT (cloning of ligand targets), in which the rapid cloning of modular protein domains is accomplished by screening cDNA expression libraries with specific peptide ligands. Two of the new genes identified appear to be members of a family of proteins, including Rsp5 and Nedd-4, which have ubiquitin-protein ligase activity. In addition, we demonstrate that peptides corresponding to PY and PY-like motifs present in several known signaling or regulatory proteins, including RasGAP, AP-2, p53BP-2 (p53-binding protein-2), interleukin-6 receptor-alpha, chloride channel CLCN5, and epithelial sodium channel ENaC, can selectively bind to certain of these novel WW domains.
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PMID:Identification of novel human WW domain-containing proteins by cloning of ligand targets. 916 21

The general amino acid permease, Gap1, of Saccharomyces cerevisiae is very active in cells grown on proline as the sole nitrogen source. Adding NH4+ to the medium triggers inactivation and degradation of the permease via a regulatory process involving Npi1p/Rsp5p, a ubiquitin-protein ligase. In this study, we describe several mutations affecting the C-terminal region of Gap1p that render the permease resistant to NH4(+)-induced inactivation. An in vivo isolated mutation (gap1pgr) causes a single Glu-->Lys substitution in an amino acid context similar to the DXKSS sequence involved in ubiquitination and endocytosis of the yeast alpha-factor receptor, Ste2p. Another replacement, substitution of two alanines for a di-leucine motif, likewise protects the Gap1 permease against NH4(+)-induced inactivation. In mammalian cells, such a motif is involved in the internalization of several cell-surface proteins. These data provide the first indication that a di-leucine motif influences the function of a plasma membrane protein in yeast. Mutagenesis of a putative phosphorylation site upstream from the di-leucine motif altered neither the activity nor the regulation of the permease. In contrast, deletion of the last eleven amino acids of Gap1p, a region conserved in other amino acid permeases, conferred resistance to NH4+ inactivation. Although the C-terminal region of Gap1p plays an important role in nitrogen control of activity, it was not sufficient to confer this regulation to two NH4(+)-insensitive permeases, namely the arginine (Can1p) and uracil (Fur4p) permeases.
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PMID:A C-terminal di-leucine motif and nearby sequences are required for NH4(+)-induced inactivation and degradation of the general amino acid permease, Gap1p, of Saccharomyces cerevisiae. 917 53

The epithelial Na+ channel (ENaC) was previously shown to be expressed in several Na(+)- and fluid-absorbing epithelia, particularly those of the kidney, colon, and lung. We have recently identified the ubiquitin-protein ligase Nedd4 as an interacting protein with ENaC and demonstrated that Nedd4 binds by its WW domains to the proline-rich PY motifs of ENaC. These PY motifs were recently shown to be deleted/mutated in patients afflicted with Liddle's syndrome, a hereditary form of systemic renal hypertension. Such mutations cause elevated channel activity by an increase in channel number/stability at the plasma membrane and by increased channel opening. We then proposed that Nedd4, by regulating channel stability/ degradation, may be a suppressor of ENaC. To test whether Nedd4 is localized to those tissues/regions that express ENaC, we performed immunocytochemical analysis of rat Nedd4 (rNedd4) distribution in rat kidney, colon, and lung tissues. Our results show that, in the kidney, rNedd4 is primarily localized to the cortical collecting tubules and outer and inner medullary collecting ducts. These tubular segments were previously shown to express ENaC. The epithelium lining medullary calyxes was also intensely stained, and microvillar borders of proximal convoluted tubules expressed variable amounts of rNedd4. In the lung, rNedd4 was mainly expressed in the epithelia lining the airways, in the submucosal glands and ducts, and in the distal respiratory epithelium. These sites resemble the pattern of ENaC expression. In contrast, in the distal colon, rNedd4 was strongly expressed in the epithelia lining the crypts but not in the ENaC-expressing surface epithelium. Low-salt diet (to elevate serum aldosterone levels) had no effect on rNedd4 distribution in the kidney or colon. Thus Nedd4 is coexpressed and likely colocalizes with ENaC in specific regions within the kidney and lung but not in the colon. We speculate this difference in colocalization may reflect differences in the regulation of channel stability in those tissues.
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PMID:Immunolocalization of the ubiquitin-protein ligase Nedd4 in tissues expressing the epithelial Na+ channel (ENaC). 922 16

Glucose triggers transcriptional and post-transcriptional mechanisms that increase the level and activity of Saccharomyces cerevisiae plasma membrane H+-ATPase. We have studied the post-transcriptional activation of the enzyme by glucose and have found that Rsp5, a ubiquitin-protein ligase enzyme, Ubc4, a ubiquitin-conjugating enzyme, and the 26S proteasome complex are implicated in this activation. These results suggest that ATPase activation by glucose requires the ubiquitin-proteasome proteolytic pathway. This is supported by the fact that over-expression of the ubiquitin-specific protease Ubp2, which cleaves ubiquitin from its branched conjugates, inhibits this activation. We propose that glucose triggers degradation of an inhibitory protein resulting in enzyme activation.
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PMID:Glucose activation of the yeast plasma membrane H+-ATPase requires the ubiquitin-proteasome proteolytic pathway. 927 Dec 26


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