Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.25.1 (proteasome)
28,817 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

(1) RNase Ms was inactivated by iodoacetate. The inactivation was most rapid at pH 6.0, and was inhibited in the presence of a denaturant such as 8 m urea or 6 m guanidine-HCL. (2) Competitive inhibitors protected RNase Ms from inactivation by iodoacetate; the effect was in the order 2',(3')-GTP greater than 2',(3')-AMP, 2',(3')-UMP greater than or equal to 2',(3')-CMP. The order is not consistent with that of the binding constants of the 4 nucleotides towards RNase Ms (A is greater than C greater than G greater than U). (3) RNase Ms was inactivated with the concomitant incorporation of one molar equivalent of carboxymethly group. The following evidence indicated that the carboxymethyl group was incorporated into the carboxyl group of an aspartic acid or glutamic acid residue. (i) The carboxymethyl group incorporated into RNase Ms was liberated by treatment with 0.1 n NaOH or 1 m hydroxylamine. (ii) The amino acid composition of carboxymethylated RNase Ms (CM RNase Ms) after acid hydrolysis is similar to that of RNase Ms. (4) 14C-Labeled CM RNase Ms was digested successively with alkaline protease and amino-peptidase M. The radioactive amino acid released was eluted just before aspartate on an amino acid analyzer. After hydrolysis with 6 n HCL, glutamic acid was produced exclusively from the radioactive amino acid. The specific radioactivity of this amino acid calculated from the radioactivity and glutamic acid formed was practctically the same as that of CM RNase Ms. Thus, it was concluded that a carboxymethyl group was incorporated at the carboxyl group of a glutamic acid residue of RNnase Ms. (5) CM RNase Ms bound with 2'-AMP to the same extent as native RNase Ms, but bound to a lesser extent with 2',(3')-GMP. (6) Although the conformation of CM RNase Ms as judged from the CD spectrum was practically the same as that of native RNase Ms, the reactivity of CM RNase Ms towards dinitrofluorobenzene was different from that of native RNase Ms, indicating some difference in the conformation. (7) These results indicate that one glutamic acid residue is involved in the active of RNase Ms.
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PMID:Carboxymethylation of a minor ribonuclease from Aspergillus saitoi. 47 29

The proteasome (the multicatalytic endoproteinase complex) in mammalian tissues hydrolyzes proteins and several types of peptides. When this structure was isolated rapidly from rabbit skeletal muscle in the presence of glycerol, its various peptidase and protease activities showed a large reversible activation by physiological concentrations of ATP (Ka = 0.3-0.5 mM). Hydrolysis of succinyl-Leu-Leu-Val-Tyr-(4-methylcoumaryl-7-amide) was stimulated up to 12-fold by ATP, whereas degradation of casein and bovine serum albumin increased 4- to 7-fold. Neither ADP nor AMP had any effect. CTP, GTP, UTP, and the nonhydrolyzable analogs adenosine 5'-[beta,gamma-imino]triphosphate (AMPP[NH]P) and adenosine 5'-[alpha,beta-methylene]triphosphate (AMP[CH2]PP) increased peptide hydrolysis as well as ATP did. However, only ATP stimulated casein breakdown and only in the presence of Mg2+. Thus, nucleotide binding allows activation of the peptidase functions, but ATP hydrolysis seems necessary for enhanced degradation of proteins. The ATP effect on proteolysis was reversible and did not require ubiquitin. Sensitivity to ATP was labile, and with storage at 4 degrees C the enzyme became fully active in the absence of ATP or Mg2+. The ATP-activated form closely resembles the proteasome complex described previously, which did not show ATP dependence: both have molecular masses of 650 kDa, contain the same 8-10 subunits, and are precipitated by the same antibodies. A similar ATP-activated form was found in rabbit liver but not in rabbit reticulocytes. The proteasome seems to represent a ubiquitin-independent, ATP-stimulated proteolytic activity within nucleated mammalian cells.
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PMID:Skeletal muscle proteasome can degrade proteins in an ATP-dependent process that does not require ubiquitin. 253 33

Previously, we isolated an ATP-dependent proteolytic pathway in muscle, liver, and reticulocytes that requires ubiquitin and the enzymes which conjugate ubiquitin to proteins. We report here that skeletal muscle contains another soluble alkaline energy-dependent (but ubiquitin-independent) proteolytic activity. The cleavage of non-ubiquitinated protein substrates by the partially purified protease requires ATP hydrolysis since ATP in the absence of Mg2+, nonhydrolyzable ATP analogs, and pyrophosphate all fail to stimulate proteolysis. Proteolytic activity is also stimulated by UTP, CTP, and GTP, although not as effectively as by ATP (Km(ATP) = 0.027 mM). The enzyme is inactivated by the serine protease inhibitors diisopropyl fluorophosphate and 3,4-dichloroisocoumarin, but not by specific inhibitors of aspartic, thiol, or metalloproteases. It is maximally active at pH 8 and has a molecular weight of approximately 600,000. This new activity differs from the 720-kDa multicatalytic proteinase, but resembles the soluble ATP-dependent proteolytic system that we previously isolated from murine erythroleukemia cells.
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PMID:A novel ATP-requiring protease from skeletal muscle that hydrolyzes non-ubiquitinated proteins. 255 95

Targeting of different cellular proteins for conjugation and subsequent degradation via the ubiquitin pathway involves diverse recognition signals and distinct enzymatic factors. A few proteins are recognized via their N-terminal amino acid residue and conjugated by a ubiquitin-protein ligase that recognizes this residue. Most substrates, including the N alpha-acetylated proteins that constitute the vast majority of cellular proteins, are targeted by different signals and are recognized by yet unknown ligases. We have previously shown that degradation of N-terminally blocked proteins requires a specific factor, designated FH, and that the factor acts along with the 26S protease complex to degrade ubiquitin-conjugated proteins. Here, we demonstrate that FH is the protein synthesis elongation factor EF-1 alpha. (a) Partial sequence analysis reveals 100% identity to EF-1 alpha. (b) Like EF-1 alpha, FH binds to immobilized GTP (or GDP) and can be purified in one step using the corresponding nucleotide for elution. (c) Guanine nucleotides that bind to EF-1 alpha protect the ubiquitin system-related activity of FH from heat inactivation, and nucleotides that do not bind do not exert this effect. (d) EF-Tu, the homologous bacterial elongation factor, can substitute for FH/EF-1 alpha in the proteolytic system. This last finding is of particular interest since the ubiquitin system has not been identified in prokaryotes. The activities of both EF-1 alpha and EF-Tu are strongly and specifically inhibited by ubiquitin-aldehyde, a specific inhibitor of ubiquitin isopeptidases. It appears, therefore, that EF-1 alpha may be involved in releasing ubiquitin from multiubiquitin chains, thus rendering the conjugates susceptible to the action of the 26S protease complex.
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PMID:Protein synthesis elongation factor EF-1 alpha is essential for ubiquitin-dependent degradation of certain N alpha-acetylated proteins and may be substituted for by the bacterial elongation factor EF-Tu. 805 36

Sequences of four new heat-shock (HS) genes of Escherichia coli organized into two operons were determined. The operon at 83 min specifies two proteins of 15.8 kDa (HslT) and 16.1 kDa (HslS), which are identical to IbpA and IbpB, respectively. Expression of mRNA from a sigma 32-dependent promoter of the hslTS/ibpAB operon is stimulated 30-75-fold upon temperature upshift. The transcription start point (tsp) is located at a G, 96 bp upstream from the AUG start codon of hslT/ibpA. The deduced amino acid sequences of HslT/IbpA and HslS/IbpB are 48% identical to each other and were found to be remotely related to the chloroplast low-molecular-weight HS protein, which is highly conserved among plants. The second hs operon is much less actively stimulated by temperature upshift, although it has a hs promoter that perfectly matches the consensus of promoters recognized by sigma 32. Located at 88.9 min, the hslVU operon specifies proteins of 19.1 kDa (HslV) and 49.6 kDa (HslU). Multiple tsp were found in this operon. HslV is remotely related to the eukaryotic proteasome proteins, and HslU is very similar to a Pasteurella haemolytica protein of unknown function. Both HslU and the P. haemolytica protein share a ATP/GTP-binding motif near their N-termini. The two operons described here are transcribed counterclockwise on the standard genetic map.
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PMID:Sequence analysis of four new heat-shock genes constituting the hslTS/ibpAB and hslVU operons in Escherichia coli. 824 18

The 20 S proteasome is a multicatalytic protease that has been implicated in several processes including ATP/ubiquitin-dependent proteolysis. However, the ATP requirement(s) related to proteasome function is undefined. We demonstrate that a protein kinase activity copurifies through multiple steps utilized to isolate latent 20 S proteasomes from human erythrocytes. The kinase phosphorylates serine residues within a single 30-kDa proteasome subunit. The activity is not sensitive to cyclic AMP or protein kinase inhibitor, indicating that it is not a cyclic AMP-dependent kinase. It is sensitive to nanomolar levels of heparin and is able to utilize both ATP and GTP as phosphodonors, similar to casein kinase II activity. Moreover, a polyclonal antibody specific for casein kinase II recognizes the alpha' subunit of casein kinase II in the 20 S preparation and specifically immunoprecipitates the proteasome-phosphorylating activity. These characteristics suggest that the proteasome kinase is similar or identical to casein kinase II. It is suggested that phosphorylation of the 30-kDa proteasome subunit by casein kinase II may be involved in regulating the activity and/or assembly of proteasome complexes.
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PMID:Copurification of casein kinase II with 20 S proteasomes and phosphorylation of a 30-kDa proteasome subunit. 834 24

In corroboration of the hypothesized regulation of phototransduction proteins by the ubiquitin-dependent pathway, we identified free ubiquitin (8 kDa) and ubiquitin-protein conjugates (50 to >200 kDa; pI 5.3-6.8 by two-dimensional electrophoresis) in bovine rod outer segments (ROS). A 38-kDa ubiquitinylated protein and transducin (Gt) were eluted together from light-adapted ROS membranes with GTP. When ROS were dark-adapted, this 38-kDa ubiquitinylated species and Gt were readily solubilized in buffer lacking GTP. These data are consistent with ubiquitinylation of Gt and corroborate previous cell-free experiments identifying Gt as a substrate for ubiquitin-dependent proteolysis (Obin, M. S., Nowell, T., and Taylor, A. (1994) Biochem. Biophys. Res. Commun. 200, 1169-1176). Evidence for ubiquitinylation of rhodopsin (36 kDa), the (photo)receptor coupled to Gt, included (i) the presence in ROS membranes "stripped" of peripheral membrane proteins of numerous ubiquitin-protein conjugates, including two whose masses (44 and 50 kDa) are consistent with mono- and diubiquitinylated rhodopsin; (ii) catalysis by permeabilized ROS of 125I-labeled ubiquitin-protein conjugates whose masses (42, 50, and 58 kDa) suggest a "ladder" of mono-, di-, and triubiquitinylated rhodopsin; (iii) parallel mobility shifts on SDS-polyacrylamide gels of rhodopsin and these 125I-labeled ubiquitin-protein conjugates; and (iv) generation of enhanced levels of 125I-labeled ubiquitin-protein conjugates when stripped, detergent-solubilized ROS membranes (95% rhodopsin) were incubated with reticulocyte lysate. A functional ubiquitin-dependent pathway in ROS is demonstrated by the presence of (i) the ubiquitin-activating enzyme (E1); (ii) four ubiquitin carrier proteins (E214K, E220K, E225K, and E235K) and pronounced activity of E214K, an enzyme required for "N-end rule" proteolysis; (iii) ATP-dependent 26 S proteasome activity that rapidly degrades high mass 125I-labeled ubiquitin-ROS protein conjugates; and (iv) distinct ubiquitin C-terminal isopeptidase/hydrolase activities, including potent ubiquitin-aldehyde-insensitive activity directed at high mass ubiquitinylated moieties. Considered together, the data support a novel role for the ubiquitin-dependent pathway in the regulation of mammalian phototransduction protein levels and/or activities and provide the first identification of a non-calpain proteolytic system in photoreceptors.
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PMID:Ubiquitinylation and ubiquitin-dependent proteolysis in vertebrate photoreceptors (rod outer segments). Evidence for ubiquitinylation of Gt and rhodopsin. 866 97

The ocular lens consists of a single layer of epithelial cells on its anterior surface and underlying fiber cells, which are derived from the epithelial cells by differentiation and make up the bulk of the lens. Because lens cells are segregated by age and stage of differentiation, we are using this tissue to study the role of the proteasome in differentiation. The purpose of this study is to corroborate the ATPase function of chick subunit 4 (cS4) and assess the levels of the mRNA in the differentiating lens relative to other tissues. We have generated a computer model of the tertiary structure of the ATPase domain of the cS4 of the ATPase complex that regulates the 20S proteasome. The predicted polypeptide from the cloned cDNA of cS4 (440 residues) had a calculated molecular mass of 49,182 and is 98 and 73% identical to human and yeast S4 protein sequences, respectively. A computer search for comparison with known proteins in GenBank showed that the cS4 protein sequence has a conserved region of about 200 amino acid residues including an ATP/GTP binding site and a mitochondrial energy transfer proteins signature sequence. Based on secondary structure, the computer-generated model of the ATPase domain is comparable to that of RecA, with a root mean square deviation of 0.851 from the RecA triad. mRNA in the 14-day-old chick embryo lens is derived primarily (90%) from differentiating cells. The level of cS4 mRNA determined by quantitative RT/PCR in this differentiating tissue was comparable to the cS4 mRNA levels in chick liver, heart, and brain.
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PMID:cDNA cloning of a chick homologue of human ATPase complex subunit 4, quantitative tissue distribution and tertiary structure comparison of the ATPase domain to RecA. 880 79

Targeting of different cellular proteins for conjugation and subsequent degradation via the ubiquitin pathway involves diverse recognition signals and distinct enzymatic factors. A few proteins are recognized via their N-terminal amino acid residue and conjugated by a ubiquitin-protein ligase that recognizes this residue. However, most substrates, including N-alpha-acetylated proteins that constitute the vast majority of cellular proteins, are targeted by different signals and are recognized by yet unknown ligases. In addition to the ligases, other factors may also be specific for the recognition of this subset of proteins. We have previously shown that degradation of N-terminally blocked proteins require a specific factor, designated FH, and that the factor acts along with the 26S protease complex to degrade ubiquitin-conjugated proteins (Gonen et al., 1991). Further studies have shown that FH is identical to the protein synthesis elongation factor EF-1 alpha, and that it can be substituted by the bacterial elongation factor EF-Tu (Gonen et al., 1994). This, rather surprising, finding raises two important and interesting problems. The first involves the mechanism of action of the factor and the second the possibility that protein synthesis and degradation may be regulated by a commonly shared factor. Here, we demonstrate that EF-1 alpha is a ubiquitin C-terminal hydrolase (isopeptidase) that is probably involved in trimming the conjugates to lower molecular weight forms recognized by the 26S proteasome complex. Additional findings demonstrate that its activity is inhibited specifically by tRNA. This finding raises the possibility that under anabolic conditions, when the factor is associated with AA.tRNA and GTP, it is active in protein synthesis but inactive in proteolysis. Under catabolic conditions, when the factor is predominantly found in its apo form, it is active in proteolysis.
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PMID:Protein synthesis elongation factor EF-1 alpha is an isopeptidase essential for ubiquitin-dependent degradation of certain proteolytic substrates. 886 Oct 13

The 26 S proteasome can be assembled from the multicatalytic protease (or 20 S proteasome) and a large multisubunit regulatory complex in an ATP-dependent reaction. The 26 S proteasome and its regulatory complex were purified from rabbit reticulocytes for characterization of their nucleotidase properties. Both particles hydrolyze ATP, CTP, GTP, and UTP to the corresponding nucleoside diphosphate and inorganic phosphate. The Km values for hydrolysis of specific nucleotides by the 26 S proteasome are 15 microM for ATP and CTP, 50 microM for GTP, and 100 microM for UTP; Km values for nucleotide hydrolysis by the regulatory complex are 2-4-fold higher for each nucleotide. Several ATPase inhibitors (erythro-9-[3-(2-hydroxynonyl)]adenine, oligomycin, ouabain, and thapsigargin) had no effect on ATP hydrolysis by either complex whereas known inhibitors of proteolysis by the 26 S enzyme (hemin, N-ethylmaleimide (NEM), and vanadate) significantly reduced ATP hydrolysis by both particles. Hydrolysis of all nucleotides was inhibited by 5 mM NEM but only GTP and UTP hydrolysis was significantly reduced at 50 microM NEM. The 15 microM Km for ATP hydrolysis by the 26 S proteasome is virtually identical to the observed Km of 12 microM ATP for Ub-conjugate degradation. Although nucleotide hydrolysis is required for protein degradation by the 26 S proteasome, nucleotide hydrolysis and peptide bond cleavage are not strictly coupled. Substrate specificity constants (kcat/Km) are similar for hydrolysis of each nucleotide, yet GTP and UTP barely supported Ub-conjugate degradation. Further evidence that nucleotide hydrolysis is not coupled to peptide bond cleavage was obtained using N-acetyl-leucyl-leucyl-norleucinal (LLnL). This compound inhibited peptide hydrolysis by the multicatalytic protease and Ub-conjugate degradation by the 26 S proteasome, but it had little effect on ATP or UTP hydrolysis by the 26 S enzyme.
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PMID:Nucleotidase activities of the 26 S proteasome and its regulatory complex. 895 78


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