Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.1 (chymotrypsin)
 10,938 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Chondrons have recently been extracted from adult articular cartilages and techniques developed to study their structure and composition in isolation. This study introduces methods to immobilize isolated canine chondrons in thin layers of agarose gel for immunohistochemistry and future in vitro studies. An antibody to Type VI collagen which stained the chondron in suspension was used to successfully validate the system and its feasibility for immunoelectron microscopy. Monoclonal and polyclonal antibodies to a variety of epitopes on the proteoglycan molecule were tested on fresh and fixed plugs cored from chondron-agarose gels. Plugs were immunolabeled with peroxidase-diaminobenzidine before or after digestion with testicular hyaluronidase or chondroitinase ABC. Trypsin/chymotrypsin were used to challenge epitopes of the core protein. The results indicate that epitopes to keratan sulfate, chondroitin sulfate, hyaluronate binding region, and core protein are localized in the chondron. Consistent staining was found in the tail and interconnecting segments between chondrons, whereas staining of the pericellular matrix and capsule adjacent to the chondrocyte varied according to the enzyme pre-treatment employed. We conclude that isolated chondrons are rich in proteoglycan monomer, which is particularly concentrated in the tail and interconnecting segments of the chondron where it could function to protect and stabilize the chondrocyte.
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PMID:Chondrons from articular cartilage. (IV). Immunolocalization of proteoglycan epitopes in isolated canine tibial chondrons. 171 45

Human promyelocytic cells (HL-60) were labeled with 35S-sulfate and either 3H-glucosamine or 3H-serine as precursors. Accumulation of 35S-labeled macromolecules was approximately linear for up to 96 h, with a mean cell:medium ratio of 5.5:1, although activity/10(5) viable cells reached a plateau level after 24 h. Virtually none of the cell-associated proteoglycan was removed by trypsinization, consistent with a predominantly intracellular localization. Proteoglycan heterogeneity was investigated by DEAE-Sephacel chromatography, isopyknic CsCl gradient centrifugation, and gel filtration chromatography. HL-60 cells appeared to synthesize a single proteoglycan species, Kav = 0.46 on Sepharose CL-4B and Kav = 0.32 on Sepharose CL-6B, recovered primarily from the high-density fractions of a dissociative CsCl gradient (rho greater than 1.40 g/l). Degradation products of lower charge density, lower buoyant density, and lower hydrodynamic size were also present, mainly in the cell pellets. The major proteoglycan was found to contain chondroitin sulfate chains of average Mr = 14.5 kD, yielding virtually 100% 4-sulfated disaccharides on digestion with chondroitinase ABC. The proteoglycan was resistant to trypsin, chymotrypsin, plasmin, and papain, and the core protein Mr was approximately 20 kD by molecular sieve chromatography. Induction of HL-60 cells with 0.15 dimethyl sulfoxide (DMSO) resulted in differentiation to a more mature granulocytic phenotype and was associated with a reduction in 35S-sulfate incorporation to 45% of control values or 32%, expressed as activity/10(5) cells. Proteoglycans synthesized by DMSO-treated cells were identical to those from untreated cells in terms of hydrodynamic size, glycosaminoglycan Mr, and sulfation.
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PMID:Biosynthesis of proteochondroitin sulfate by HL-60 human promyelocytic cells. 291 Oct 20

Dermatan sulfate proteoglycans (DS-PGs) isolated from bovine articular cartilage have been examined for their effects on the adhesive responses of BALB/c 3T3 cells and bovine dermal fibroblasts on plasma fibronectin (pFN) and/or type I collagen matrices, and compared to the effects of the chondroitin sulfate/keratan sulfate proteoglycan monomers (CS/KS-PGs) from cartilage. DS-PGs inhibited the attachment and spreading of 3T3 cells on pFN-coated tissue culture substrata much more effectively than the cartilage CS/KS-PGs reported previously; in contrast, dermal fibroblasts were much less sensitive to either proteoglycan class unless they were pretreated with cycloheximide. Both cell types failed to adhere to substrata coated only with the proteoglycans; binding of the proteoglycans to various substrata has also been quantitated. While a strong inhibitory effect was obtained with the native intact DS-PGs, little inhibitory effect was obtained with isolated DS chains (liberated by alkaline-borohydride cleavage) or with core protein preparations (liberated by chondroitinase ABC digestion). In marked contrast, DS-PGs did not inhibit attachment or spreading responses of either 3T3 or dermal fibroblasts on type I collagen-coated substrata when the collagen was absorbed with pFN alone, DS-PGs alone, or the two in combination. These results support evidence for (a) collagen-dependent, fibronectin-independent mechanisms of adhesion of fibroblasts, and (b) different sites on the collagen fibrils where DS-PGs bind and where cell surface "receptors" for collagen bind. Experiments were developed to determine the mechanism(s) of inhibition. All evidence indicated that the mechanism using the intact pFN molecule involved the binding of the DS-PGs to the glycosaminoglycan (GAG)-binding sites of substratum-bound pFN, thereby inhibiting the interaction of the fibronectin with receptors on the cell surface. This was supported by affinity chromatography studies demonstrating that DS-PGs bind completely and effectively to pFN-Sepharose columns whereas only a subset of the cartilage CS/KS-PG binds weakly to these columns. In contrast, when a 120-kD chymotrypsin-generated cell-binding fragment of pFN (CBF which has no detectable GAG-binding activity as a soluble ligand) was tested in adhesion assays, DS-PGs inhibited 3T3 adherence on CBF more effectively than on intact pFN. A variety of experiments indicated that the mechanism of this inhibition also involved the binding of DS-PGs to only substratum-bound CBF due to the presence of a cryptic GAG-binding domain not observed in the soluble CBF.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Fibronectin-mediated adhesion of fibroblasts: inhibition by dermatan sulfate proteoglycan and evidence for a cryptic glycosaminoglycan-binding domain. 295 85

Heparan sulfate-rich proteoglycan is present on the surface of NMuMG mouse mammary epithelial cells. All of this cell surface fraction is lipophilic, assessed by intercalation into lipid vesicles, and requires proteolytic cleavage to be released from the cell surface. No proteoglycan is competitively displaced by heparin. The cell surface lipophilic proteoglycan constitutes 52-55% of the total cellular proteoglycan while the remaining proteoglycan is apparently intracellular, comprising a nonlipophilic fraction (35%) and a small (10-13%) lipophilic fraction. Trypsin or chymotrypsin cleaves a labile site between the region of the cell surface proteoglycan bearing the glycosaminoglycan chains and the cell-associated portion of the core protein, producing a proteoglycan that is nonlipophilic, has an increased bouyant density, and is smaller than the parent molecule. We refer to this proteoglycan as the ectodomain of the cell surface proteoglycan. The correlation between its cell surface location and lipophilic properties suggests that a hydrophobic domain of its core protein may anchor this proteoglycan in the plasma membrane. In vivo, the proteoglycan may be cleaved from this putative anchor, generating nonlipophilic proteoglycan present as a matrix component, or it may remain a membrane component, anchoring the cell directly to the extracellular matrix.
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PMID:Cell surface proteoglycan of mammary epithelial cells. Protease releases a heparan sulfate-rich ectodomain from a putative membrane-anchored domain. 315 52

Physicochemical and chemical properties of small proteoglycans containing galactosaminoglycan chains from cultured human skin fibroblasts and human smooth-muscle cells were compared to determine the extent of structural similarity. The proteoglycan secreted by smooth-muscle cells was of larger molecular size and of higher buoyant density, due to longer glycosaminoglycan chains, than the secretion product of skin fibroblasts. Additionally, both proteoglycans differed in the ratio of iduronic acid and glucuronic acid residues. On the other hand, degradation of secreted [3H]leucine-labelled proteoglycans with chondroitin ABC lyase followed by SDS/polyacrylamide-gel electrophoresis resulted in the appearance of core protein bands of identical size (Mr 48,000 and 45,000, depending on the number of asparagine-bound oligosaccharides). An Mr value of 40,000 was determined for the core protein of cells pretreated with tunicamycin. An antibody against the core protein from fibroblast secretions was cross-reactive with the core protein from smooth-muscle cells. Core protein accumulating intracellularly after treatment with carbonyl cyanide m-chlorophenylhydrazone exhibited, on reduction and alkylation, an isoelectric point of 7.8 in both cell types. Limited proteolysis by staphylococcal V8 serine proteinase or endoproteinase Lys-C led in both instances to the formation of peptides of identical size. Peptides bearing asparagine-bound oligosaccharides were free of glycosaminoglycan chains. Similar peptide patterns were obtained when 125I-labelled core proteins were digested with either trypsin or chymotrypsin. Thus small proteoglycans from fibroblasts and smooth-muscle cells can be differentiated by their glycosaminoglycan moieties but not by the nature of their core proteins.
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PMID:Comparison of small proteoglycans from skin fibroblasts and vascular smooth-muscle cells. 380 Sep 48

Cartilage proteoglycan monomers associate with hyaluronic acid to form proteoglycan aggregates. Link protein, interacting with both hyaluronic acid and proteoglycan, serves to stabilize the aggregate structure. In the course of determining the primary structure of link protein, two peptides produced by digestion of rat chondrosarcoma link protein with trypsin or chymotrypsin have been selectively purified by immunoaffinity chromatography on a column of monoclonal anti-link protein antibody (8A4) immobilized to Sepharose 4B. These peptides have been sequenced using the double-coupling dimethylaminoazobenzene isothiocyanate/phenyl isothiocyanate procedure. A consensus sequence, Cys-X-Ala-Gly-Trp-Leu-X-Asp-Gly-Ser-Val-X-Tyr-Pro-Ile-X-X-Pro, obtained by comparing the affinity-isolated tryptic peptide with the affinity-isolated chymotryptic peptide and an overlapping tryptic peptide, shows homology with a sequence obtained from the NH2-terminal of a CNBr peptide from proteo glycan core protein of bovine nasal cartilage: Ser-Ser-Ala-Gly-Trp-Leu-Ala-Asp-Arg-Ser-Val-Arg-Tyr-Pro-Ile-Ser-. We suggest that the common sequence is structurally important to the function of these proteins and may be involved in the binding of both link protein and proteoglycan to hyaluronic acid.
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PMID:An amino acid sequence common to both cartilage proteoglycan and link protein. 390 75

Isolates of tick-borne encephalitis (TBE) virus from Finland, Germany, Czechoslovakia, Switzerland and Austria were compared with strains of the Far Eastern subtype isolated in Russia as well as Louping ill virus and other flaviviruses belonging to a different serocomplex: West Nile, Murray Valley encephalitis and Rocio viruses. Analysis of the structural polypeptides by SDS--polyacrylamide gel electrophoresis (SDS--PAGE) revealed identical mol. wt. of the glycoprotein E (mol. wt. 55 000) and the core protein C (mol. wt. 15 000) for all the TBE virus strains analysed. However, the small envelope protein M from viruses isolated in Germany, Switzerland and Austria migrated slightly slower (apparent mol. wt. 7500) compared to M from viruses isolated in Finland, Czechoslovakia or the Far Eastern subtype strains (apparent mol. wt. 6500 to 7000). The structural glycoproteins were isolated from purified [35S]methionine-labeled virions and subjected to peptide mapping by limited proteolysis with alpha-chymotrypsin or V8 protease followed by SDS--PAGE of the resulting cleavage products. With both proteases a remarkably homogeneous pattern was obtained for all the European isolates with only very minor deviations from a common pattern in single cases. Similar but distinguishable patterns were obtained for the Far Eastern subtype strains and also Louping ill virus, which, in addition, differed in the mol. wt. of its core protein C (mol. wt. 16 000) and the small membrane protein M (mol. wt. 9000). These almost identical peptide maps observed with the TBE virus strains were in sharp contrast to the unrelated patterns obtained with the glycoproteins from West Nile, Murray Valley encephalitis and Rocio viruses. Although these viruses are serologically closely related and members of the same serocomplex of flaviviruses their glycoprotein peptide maps were completely different from one another. In a competitive radioimmunoassay all European TBE virus isolates showed identical immunological reactivity which further points to the great stability of this type of virus.
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PMID:Homogeneity of the structural glycoprotein from European isolates of tick-borne encephalitis virus: comparison with other flaviviruses. 617 53

G-actin bound to deoxyribonuclease I (DNase I) is resistant to digestion by trypsin and chymotrypsin. In the absence of DNase I, G-actin is cleaved by these proteases to yield a 33 500 molecular weight core protein which is not degraded further. The major sites of proteolytic action in the amino acid sequence of actin have been identified as being adjacent to residues arginine-62 and lysine-68 for trypsin and leucine-57 for chymotrypsin. These residues are rendered inaccessible to proteases in the buffer by complex formation with DNase I. Digestion of G-actin with pronase from Streptomyces griseus yields fragmentation patterns that are similar to those observed with trypsin and chymotrypsin. This is likely to be because the specificities of the major constituents of pronase resemble those of trypsin and chymotrypsin. Again, complex formation with DNase I protects the otherwise vulnerable bonds in actin against proteolysis. Incubation with subtilisin Carlsberg leads to complete digestion of G-actin. No subtilisin-resistant core protein accumulates during the incubation. Protection of G-actin when complexed to DNase I is less than complete in this case but still is significant. This is interpreted in terms of the broad specificity of subtilisin and the observed fragmentation pattern of free G-actin when treated with subtilisin.
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PMID:Protection of actin against proteolysis by complex formation with deoxyribonuclease I. 626 44

The topology of beef heart Complex III has been studied by tryptic and chymotryptic digestion of isolated Complex III, Mg2+-ATP submitochondrial particles, and mitoplasts. Degradation products were detected by the immunoreplication technique using specific antibodies against core protein 1 (50 K) and core protein 2 (47 K). It can be shown that both peptides are digested from the matrix side of the inner membrane. However, no evidence was found that these peptides were digested by trypsin or chymotrypsin from the cytoplasmic side. It is concluded that the beef heart core proteins are membrane-bound peptides containing tryptic and chymotryptic digestion sites only on the matrix surface of the inner membrane. The data also suggest that beef heart core protein 2 contains multiple domains which are inserted into the membrane from the matrix surface. Proteolytic treatment of submitochondrial particles under conditions which digested at least 50% of the core proteins from the matrix surface did not, however, influence NADH oxidation rates or the respiratory control ratios.
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PMID:Studies on beef heart ubiquinol-cytochrome c reductase. Topological studies on the core proteins using proteolytic digestion and immunoreplication. 630 20

The orientation of the different subunits of complex III in the yeast inner mitochondrial membrane has been investigated by several different approaches. Immunoinhibition studies of cytochrome c reductase activity in intact mitoplasts and submitochondrial particles using IgG obtained from specific antisera against complex III, the iron-sulfur protein, core protein I, and core protein II suggested a transmembranous orientation of the complex with the antigenic sites of the iron-sulfur protein exposed on the cytoplasmic surface of the membrane. A lack of immunoinhibition was observed with the IgG against either core protein suggesting that these proteins may not be involved in catalysis. Digestion of mitoplasts with chymotrypsin indicated that the protein mass of cytochromes b and c1 protrudes from the cytoplasmic surface of the membrane; however, the hemes of cytochrome b appear to be buried within the membrane while the heme of cytochrome c1 is partially exposed on the chymotrypsin-sensitive portion of the polypeptide. By contrast, the iron-sulfur protein does not protrude from the membrane as it is completely resistant to chymotrypsin digestion. Labeling with the hydrophilic membrane-impermeant probe diazobenzenesulfonate suggests that core protein II is exposed on both sides of the membrane but protrudes into the matrix; while core protein I is within the membrane. Immunoprecipitation studies of sodium dodecyl sulfate and Triton X-100-solubilized mitochondria with subunit-specific antisera suggest that cytochromes b and c1 and core protein I are tightly associated in complex III. By contrast, the iron-sulfur protein and core protein II are loosely associated with the other subunits of the complex such that they are dissociated by low concentrations of detergent.
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PMID:Topographical orientation of complex III in the yeast mitochondrial membrane. 631 51


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