A new method for assaying ubiquitin C-terminal hydrolases was developed using a 125I-labeled ubiquitin-αNH-MHISPPEPESEEEEEHYC as substrate. Since the peptide portion was almost exclusively radiolabeled, the enzymes could be assayed directly by simple measurement of the radioactivity released into acid-soluble products. Using this assay protocol, we identified at least 10 ubiquitin C-terminal hydrolase activities from the extract of chick skeletal muscle, which were tentatively named UCHs 1 through 10. Of these, UCH-6 was purified to apparent homogeneity. Purified UCH-6 behaved as a dimer of 27-kDa subunits. The apparent molecular masses of the other partially purified UCHs ranged from 35 to 810 kDa as determined under a nondenaturing condition. Muscle UCHs, except UCH-1, were activated dramatically by poly-L-Lys but with an unknown mechanism. All of the UCHs were sensitive to inhibition by sulfhydryl-blocking agents such as iodoacetamide. In addition, all of the UCHs were capable of releasing free ubiquitin from a ubiquitin-αNH-carboxyl extension protein of 80 amino acids and from ubiquitin-αNH-dihydrofolate reductase. Five of the enzymes, UCHs 1 through 5, were also capable of generating free ubiquitin from poly-His-tagged diubiquitin. In addition, UCH-1 and UCH-7 could remove ubiquitin that had been ligated covalently by an isopeptide linkage to a ubiquitin(RGA)-αNH-peptide, the peptide portion of which consists of the 20 amino acids of the calmodulin binding domain of myosin light chain kinase. These results suggest that the 10 UCH activities isolated from chick skeletal muscle appear to be distinct from each other at least in their chromatographic behavior, size, and substrate specificity. A new method for assaying ubiquitin C-terminal hydrolases was developed using a 125I-labeled ubiquitin-αNH-MHISPPEPESEEEEEHYC as substrate. Since the peptide portion was almost exclusively radiolabeled, the enzymes could be assayed directly by simple measurement of the radioactivity released into acid-soluble products. Using this assay protocol, we identified at least 10 ubiquitin C-terminal hydrolase activities from the extract of chick skeletal muscle, which were tentatively named UCHs 1 through 10. Of these, UCH-6 was purified to apparent homogeneity. Purified UCH-6 behaved as a dimer of 27-kDa subunits. The apparent molecular masses of the other partially purified UCHs ranged from 35 to 810 kDa as determined under a nondenaturing condition. Muscle UCHs, except UCH-1, were activated dramatically by poly-L-Lys but with an unknown mechanism. All of the UCHs were sensitive to inhibition by sulfhydryl-blocking agents such as iodoacetamide. In addition, all of the UCHs were capable of releasing free ubiquitin from a ubiquitin-αNH-carboxyl extension protein of 80 amino acids and from ubiquitin-αNH-dihydrofolate reductase. Five of the enzymes, UCHs 1 through 5, were also capable of generating free ubiquitin from poly-His-tagged diubiquitin. In addition, UCH-1 and UCH-7 could remove ubiquitin that had been ligated covalently by an isopeptide linkage to a ubiquitin(RGA)-αNH-peptide, the peptide portion of which consists of the 20 amino acids of the calmodulin binding domain of myosin light chain kinase. These results suggest that the 10 UCH activities isolated from chick skeletal muscle appear to be distinct from each other at least in their chromatographic behavior, size, and substrate specificity.
A new cytoplasmic endoprotease, named protease So, was purified to homogeneity from Escherichia coli by conventional procedures with casein as the substrate. Its molecular weight was 140,000 when determined by gel filtration on Sephadex G-200 and 77,000 when estimated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Thus, it appears to be composed of two identical subunits. Protease So had an isoelectric point of 6.4 and a K m of 1.4 μM for casein. In addition to casein, it hydrolyzed globin, glucagon, and denatured bovine serum albumin to acid-soluble peptides but did not degrade insulin, native bovine serum albumin, or the “auto α” fragment of β-galactosidase. A variety of commonly used peptide substrates for endoproteases were not hydrolyzed by protease So. It had a broad pH optimum of 6.5 to 8.0. This enzyme is a serine protease, since it was inhibited by diisopropyl fluorophosphate and phenylmethylsulfonyl fluoride. Although it was not inhibited by chelating agents, divalent cations (e.g., Mg 2+ ) stabilized its activity. Protease So was sensitive to inhibition by N -tosyl- l -phenylalanine chloromethyl ketone but not by N -tosyl- l -lysine chloromethyl ketone. Neither ATP nor 5′-diphosphate-guanosine-3′-diphosphate affected the rate of casein hydrolysis. Protease So was distinct from the other soluble endoproteases in E. coli (including proteases Do, Re, Mi, Fa, La, Ci, and Pi) in its physical and chemical properties and also differed from the membrane-associated proteases, protease IV and V, and from two amino acid esterases, originally named protease I and II. The physiological function of protease So is presently unknown.
HslVU in E. coli is a new type of ATP‐dependent protease consisting of two heat shock proteins: the HslU ATPase and the HslV peptidase that has two repeated Thr residues at its N terminus, like certain β‐type subunit of the 20S proteasomes. To gain an insight into the catalytic mechanism of HslV, site‐directed mutagenesis was performed to replace each of the Thr residues with Ser or Val and to delete the first or both Thr. Also each of the five internal Ser residues in HslV were replaced with Ala. The results obtained by the mutational analysis revealed that the N‐terminal Thr acts as the active site nucleophile and that certain Ser residues, particularly Ser 124 and Ser 172 , also contribute to the peptide hydrolysis by the HslVU protease. The mutational studies also revealed that both Thr, Ser 103 , and Ser 172 , but not Ser 124 , are involved in the interaction of HslV with HslU and hence in the activation of HslU ATPase as well as in the HslVU complex formation.
Ecotin, a homodimeric protein composed of 142-residue subunits, is a novel protease inhibitor present in the periplasm of Escherichia coli. It shows a broad inhibitory specificity towards a group of serine proteases and binds two molecules of protease to form a tetrameric complex in a distinct chelation mechanism. The ecotin-chymotrypsin complex has been crystallized in the triclinic space group P1 with unit-cell parameters a = 57.29, b = 57.39, c = 79.75 A, alpha = 91.49, beta = 88.63 and gamma = 112.45 degrees. The asymmetric unit contains the whole tetrameric complex, consisting of two molecules of chymotrypsin bound to the ecotin dimer, with a corresponding crystal volume per protein mass (VM) of 2.58 A3 Da-1 and a solvent fraction of 48.9%. The crystals diffract beyond 2.0 A with Cu Kalpha X-rays and are very stable in the X-ray beam. Native X-ray data have been collected from a crystal to approximately 2.0 A Bragg spacing.
The primary structures of two proteins that comprise PA28, an activator of the 20S proteasome, have been determined by cDNA cloning and sequencing. These protein subunits, termed PA28α and PA28β, are about 50% identical to one another and are highly conserved between rat and human. PA28α and PA28β are homologous to a previously described protein, Ki antigen, whose function is unknown. PA28α, but neither PA28β nor Ki antigen, contains a ‘KEKE motif’, which has been postulated to promote the binding of proteins having this structural feature. PA28α and PA28β were coordinately regulated by γ‐interferon, which greatly induced mRNA levels of both proteins in cultured cells. The mRNA level of the Ki antigen also increased in response to γ‐interferon treatment, but the magnitude of the increase was less than that for the PA28s, and the effect was transient. These results demonstrate the existence of a new protein family, at least two of whose members are involved in proteasome activation. They also provide the basis for future structure/function studies of PA28 subunits and the determination of their relative physiological roles in the regulation of proteasome activity.
Induction of protease La was found to increase to higher extent in E. coli that had been treated with canavanine for longer period. However, hydrolysis of canavanine-containing proteins occurred rapidly but at nearly an identical rate regardless of the period of canavanine-treatment. Exposure of E. coli to heat also raised the level of protease La but showed little effect on overall rate of proteolysis. These results suggest that induction of protease La under stress occurs as a part of heat shock response but not necessarily for elimination of denatured or abnormal proteins.
The heat shock protein ClpB in Escherichia coli is a protein-activated ATPase and consists of two proteins with sizes of 93 and 79 kDa. By polymerase chain reaction-aided site-directed mutagenesis, both the proteins have been shown to be encoded by the same reading frame of the clpB gene, the 93-kDa protein (ClpB93) from the 5'-end AUG translational initiation site and the 79-kDa protein (ClpB79) from the 149th codon (an internal GUG start site). Both the purified ClpB93 and ClpB79 proteins behave as tetrameric complexes with a very similar size of about 350 kDa upon gel filtration on a Superose-6 column. Both appear to be exclusively localized to the cytosol of E. coli. Both show inherent ATPase activities and have an identical Km of 1.1 mM for ATP. The ATPase activity of ClpB93 is as markedly stimulated by proteins, including casein and insulin, as that of wild-type ClpB, but the same proteins show little or no effect on ClpB79. Because ClpB79 lacks the 148 N-terminal sequence of ClpB93 but retains the two consensus sequences for adenine nucleotide binding, the N-terminal portion appears to contain a site(s) or domain(s) responsible for protein binding. Furthermore, ClpB79 is capable of inhibiting the casein-activated ATPase activity of ClpB93 in a dose-dependent manner but without any effect on its inherent ATPase activity. In addition, ClpB93 mixed with differing amounts of ClpB79 behave as tetrameric molecules, although its protein-activated ATPase activity is gradually reduced. These results suggest that tetramer formation between ClpB93 and ClpB79 may be responsible for the inhibition of the activity.
We have previously shown that chick muscle extracts contained at least 10 different ubiquitin C-terminal hydrolases (UCHs). Here we report the purification and characterization of one of the UCHs, called UCH-8, with 125I-labelled ubiquitin-α-NH-MHISPPEPESEEEEEHYC as a substrate. The purified UCH-8 behaved as a 240 kDa protein on a Superdex-200 column under non-denaturing conditions but as a 130 kDa polypeptide on analysis by PAGE under denaturing conditions, suggesting that the enzyme consists of two identical subunits. Thus this enzyme seems to be distinct in its dimeric nature from other purified UCHs that consist of a single polypeptide, except that UCH-6 is also a homodimer of 27 kDa subunits. UCH-8 was maximally active between pH 7.5 and 8, but showed little or no activity below pH 7 and above pH 9. Like other UCHs it was sensitive to inhibition by thiol-blocking agents such as N-ethylmaleimide, and by ubiquitin aldehyde. The purified UCH-8 hydrolysed not only ubiquitin-α-NH-protein extensions, including ubiquitin-α-NH-carboxy extension protein of 80 amino acid residues and ubiquitin-α-NH-dihydrofolate reductase, but also branched poly-ubiquitin that are ligated to proteins through ϵ-NH-isopeptide bonds. However, it showed little or no activity against poly-His-tagged di-ubiquitin, suggesting that UCH-8 is not involved in the generation of free ubiquitin from the linear poly-ubiquitin precursors. These results suggest that UCH-8 might have an important role in the production of free ubiquitin and ribosomal proteins from their conjugates as well as in the recycling of ubiquitin molecules after the degradation of poly-ubiquitinated protein conjugates by the 26 S proteasome.
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