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Query: EC:3.4.21.4 (trypsin)
 42,187 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The light-dependent transhydrogenase system of Rhodopseudomonas spheroides which consists of a peripheral protein factor and a membrane-bound component contains essential sulfhydryl groups that are sensitive to p-hydroxymercuribenzoic acid (PMB). There are two types of sulfhydryl groups required for light-dependent (LD) transhydrogenation. One type is associated with the membrane-bound component and participates in or influences the binding of one of the substrates, NADH. A second type is associated with the peripheral protein factor and is not involved with the binding of the substrates. These sulfhydryl groups are masked or buried in the protein and are only exposed upon treatment of the peripheral protein factor with urea or trypsin. The peripheral protein factor may be an integral part of the transhydrogenase complex or may be required for the energization process. This factor appears to play an important role in the activation and control of LD-transhydrogenation.
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PMID:Essential sulfhydryl groups and the light-dependent transhydrogenase system of Rhodopseudomonas spheroides: localization of substrate binding sites and evidence for masked or buried sulfhydryl groups in the peripheral protein factor. 698 81

Methyl sterol oxidase of microsomal synthesis of cholesterol from lanosterol is a mixed-function oxidase that is dependent upon reduced pyridine nucleotide. The methyl sterol oxidase, as well as NADH-cytochrome c reductase, in intact rat liver microsomes are inhibited by anti-cytochrome b5 immunoglobulin, but NADPH-cytochrome c reductase is not affected. There is a decreased time lag prior to onset of reoxidation of steady state levels of reduced cytochrome b5 when 4-methyl sterol oxidase substrates are present. Trypsin treatment of microsomes destroys cytochrome b5 with loss of methyl sterol oxidase activity. Activity is restored by addition of purified cytochrome b5 to trypsin-treated microsomes. Initial attempts to solubilize and purify 4-methyl sterol oxidase have been only partially successful due to the extreme lability of the oxidase. However, DEAE-cellulose column chromatography of a detergent extract of microsomes yields a fraction that contains the oxidase, lipids, and NADH-cytochrome b5 reductase but is free of cytochrome b5. Oxidation of 4 alpha [30-3H] methyl-5 alpha-cholest-7-en-3 beta-ol by methyl sterol oxidase in this isolated fraction can be fully restored by the addition of purified liver microsomal cytochrome b5. These results strongly support the suggestion that membrane-bound cytochrome b5 of rat liver microsomes is an obligatory electron carrier from NADH to 4-methyl sterol oxidase.
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PMID:Total enzymic synthesis of cholesterol from lanosterol. Cytochrome b5-dependence of 4-methyl sterol oxidase. 722 57

A method for biomembrane reconstitution from microsomal proteins and lipids solubilized by sodium cholate consisting in a removal of the detergent by its dialysis followed by treatment with 10% albumin has been developed. A comparison of the original and reconstituted membranes showed that the phospholipid, protein and enzymatic composition of the latter is similar or only slightly different from that of the original ghosts. The reconstituted membranes contained 1.5 times more cytochrome b5 and an equal amount of cytochrome P-450. No more than 20% of cytochrome P-450 was represented by the inactive form. The inactivation rate of the reduced hemoprotein in the reconstituted membranes was lower than in the ghosts. Both in the reconstituted and original membranes the similarity of solubilization patterns of microsomal electron carries upon trypsin treatment was indicative of identical topography of these proteins. The most effective was the reconstitution of NADH and cumole hydroperoxide-dependent N-demethylase, whereas the p-hydroxylase and O-dealkylase activities of the reactivated P-450 were not retained. Hence, no complete reconstitution of the properties of the microsomal membrane and its redox chain was observed in spite of the effective removal of the detergent, similar localization of microsomal electron carriers in the reconstituted membranes and ghosts and the reconversion of cytochrome P-420 into cytochrome P-450.
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PMID:[Comparative study of original and reconstituted by self-assembly endoplasmic reticulum membranes]. 729 23

Activity of NADH-, succinate- and cytochrome c oxidase systems of respiratory chain from rat liver mitochondrial membranes was studied in animals with various type of liver impairment under conditions of chronic allergic ulcerous colitis. Activity of the polyenzymatic systems did not exhibit marked differences as compared with the controls in fatty and chronic dystrophy but the activity was considerably increased if chronic dystrophy progressed and hepatitis developed. In chronic allergic ulcerous colitis resistance of the polyenzymatic oxidase systems to heat treatment was decreased in liver mitochondrial membranes. Under conditions of the pathology proteins and phospholipids from mitochondrial membranes were especially sensitive to the effect of trypsin and phospholipase; the rate of reactions correlated well with the severity of the liver impairment. Development of latent impairments in liver mitochondrial membranes was shown to depend on the severity of the pathological process.
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PMID:[Activity and stability of liver mitochondrial membrane polyenzyme systems in chronic allergic ulcerative colitis]. 731 85

Treatment of intact pigeon erythrocytes with trypsin or alpha-chymotrypsin does not alter the isoproterenol-dependent adenylate cyclase activity in plasma membranes prepared after proteolysis. However, both proteases affect adenylate cyclase activity when isolated membranes are digested. Thus, the proteases probably act at the cytoplasmic side of the membranes. This conclusion is supported by the finding that proteases are able to inhibit NADH cytochrome c oxidoreductase, an enzyme located on the inner face of the plasma membrane. In isolated membranes, trypsin inhibits adenylate cyclase. Chymotrypsin (2.5 microgram/ml, 10 min, 37 degrees C) activates adenylate cyclase about 3-fold when the enzyme activity is measured with NaF, guanosine 5'-(beta, gamma-imino)-triphosphate, or guanosine 5'-(beta, gamma-imino)-triphosphate and isoproterenol. Chymotrypsin also activates adenylate cyclase in membranes pretreated with cholera toxin. Activation by chymotrypsin is not expressed when adenylate cyclase is assayed with 5 mM Mn2+ without guanine nucleotides or fluoride. However, the chymotryptic activation is expressed when guanosine 5'-(beta, gamma-imino)-triphosphate is present together with Mn2+. We conclude that interaction of the guanine nucleotide regulatory subunit with the catalytic subunit of adenylate cyclase is required for expression of chymotryptic activation.
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PMID:The site of alpha-chymotryptic activation of pigeon erythrocyte adenylate cyclase. 737 11

The presence of cytochromes b5, P-450 and P-420 and activities of NADH- and NADPH-cytochrome c redutases were determined in plasma membranes isolated from microvilli of the chick and rat intestinal epithelium and erythrocyte membranes from chick, rat and man. The results are compared with the amounts of these components found in microsomal fractions from intestinal epithelium and in nuclear membranes from chick erythrocytes. Plasma membranes from intestinal microvilli and from erythrocytes contained significant amounts of NADH-cytochrome c reductase activity and of a pigment spectrophotometrically indistinguishable from rat liver microsomal cytochrome b5. In addition, cytochrome b5 fragments were prepared from the membranes by limited trypsin digestion and consisted of two to four components with Mr values in the range 10 000-13 500. In low-temperature difference spectra, the presence of a second cytochrome was noted which was similar to cytochrome P-420. Cytochrome P-450 and NADPH-cytochrome c reductase activities were not detected in plasma membrane fractions in significant concentrations but were present in the corresponding endomembrane fractions. These findings in highly purified, well defined plasma membrane fractions, in which contamination by endomembranes is minimal, strengthen the evidence for the existence of cytochrome-containing redox systems in plasma membranes of various cells and suggest that such redox components are general components of the cell surface. Possible functions and origins of these redox components in plasma membranes are discussed.
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PMID:Plasma membranes from intestinal microvilli and erythrocytes contain cytochromes b5 and P-420. 740 43

Submitochondrial particles catalyze transhydrogenation from NADPH to [14C]NADP. This transhydrogenation is energy-linked, since its rate increases several-fold when the system is energized by succinate oxidation in the presence of rotenone (inhibitable by antimycin A or uncouplers), or by ATP hydrolysis (inhibitable by rutamycin or uncouplers). As in the case of transhydrogenation reactions from NAD(P)H to 3-ace-tylpyridine adenine dinucleotide phosphate and to thionicotinamide adenine dinucleotide phosphate, transhydrogenation from NADPH to [14C]NADP is also sensitive to treatment of the particles with trypsin or the arginyl residue modifier, butanedione. However, unlike the former reactions, transhydrogenation from NADPH to [14C]NADP cannot accumulate energy in the concentrations of the products, because, except for radioactivity, the nature and concentrations of the reactants and products remain unchanged throughout the course of the reaction. Therefore, the unrecoverable energy utilization by this region could be ascribed to an entropic component of the process, very likely an enzyme conformation change necessary for facilitation of hydride ion transfer from NADPH to [14C]NADP. This interpretation is in agreement with our previous kinetic evidence for enzyme conformation change associated with energy-linked transhydrogenation from NADH to 3-acetylpyridine adenine dinucleotide phosphate and thionicotinamide adenine dinucleotide phosphate, and with our conclusions regarding the mechanism of action of the transhydrogenase enzyme (Galante, Y.M., Lee, Y., and Hatefi, Y. (1980) J. Biol. Chem. 255, 9641-9646).
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PMID:Energy-linked transhydrogenation from NADPH to [14C]NADP. 743 83

The mitochondrial energy-linked transhydrogenase enzyme catalyzes hydride ion transfer between NAD and HADP, of which the reaction NADH leads to NADP is slow in the absence of energy and is accelerated 10-fold or more when the mitochondrial membrane is energized by ATP hydrolysis or respiration. The enzyme is a proton pump and effects proton translocation coupled to hydride ion transfer from NADPH to NAD (Earle, S.R., and Fisher, R.R. (1980) J. Biol Chem. 255, 827-830). The present studies have shown that submitochondrial particles also catalyze transhydrogenation from NADPH to two NADP analogs, namely 3-acetylpyridine adenine dinucleotide phosphate (AcPyADP) and thionicotinamide adenine dinucleotide phosphate (thioNADP). Both reaction rates are greatly accelerated when the system is energized by ATP hydrolysis (inhibitable by uncouplers or rutamycin) or succinate oxidation (inhibitable by uncouplers or antimycin A). As in the case of NAD(H) in equilibrium with NADP(H) reactions, the transhydrogenations from NADPH to AcPyADP and thioNADP are inhibited by treatment of submitochondrial particles with trypsin or the arginyl residue modifier, butanedione. The Km values of the above substrates and the Vmax values under energy-linked conditions have been determined. The finding that the mitochondrial energy-linked transhydrogenase enzyme catalyzes transhydrogenation from NADPH to NADP analogs has revealed features regarding substrate site specificities and the effect of substrates on the directionality of proton translocation by the enzyme.
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PMID:Energy-linked mitochondrial transhydrogenation from NADPH to NADP analogs. 743 92

Transhydrogenase catalyses the reversible transfer of reducing equivalents between NAD(H) and NADP(H) to the translocation of protons across a membrane. Uniquely in Rhodospirillum rubrum, the NAD(H)-binding subunit (called Ths) exists as a separate subunit which can be reversibly dissociated from the membrane-located subunits. We have expressed the gene for R. rubrum Ths in Escherichia coli to yield large quantities of protein. Low concentrations of either trypsin or endoproteinase Lys-C lead to cleavage of purified Ths specifically at Lys227-Thr228 and Lys237-Glu238. Observations on the one-dimensional 1H-NMR spectra of Ths before and after proteolysis indicate that the segment which straddles the cleavage sites forms a mobile loop protruding from the surface of the protein. Alanine dehydrogenase, which is very similar in sequence to the NAD(H)-binding subunit of transhydrogenase, lacks this segment. Limited proteolytic cleavage has little effect on some of the structural characteristics of Ths (its dimeric nature, its ability to bind to the membrane-located subunits of transhydrogenase, and the short-wavelength fluorescence emission of a unique Trp residue) but does decrease the NADH-binding affinity, and does lower the catalytic activity of the reconstituted complex. The presence of NADH protects against trypsin or Lys-C cleavage, and leads to broadening, and in some cases, shifting, of NMR spectral signals associated with amino acid residues in the surface loop. This indicates that the loop becomes less mobile after nucleotide binding. Observation by NMR during a titration of Ths with NAD+ provides evidence of a two-step nucleotide binding reaction. By introducing an appropriate stop codon into the gene coding for the polypeptide of E. coli transhydrogenase cloned into an expression vector, we have prepared the NAD(H)-binding domain equivalent to Ths. The E. coli protein is sensitive to proteolysis by either trypsin or Lys-C in the mobile loop. Judging by the effect of NADH on its NMR spectrum and on the fluorescence of its Trp residues, the protein is capable of binding the nucleotide though it is unable to dock with the membrane-located subunits of transhydrogenase from R. rubrum.
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PMID:Conformational dynamics of a mobile loop in the NAD(H)-binding subunit of proton-translocating transhydrogenases from Rhodospirillum rubrum and Escherichia coli. 755 67

The pyridine nucleotide transhydrogenase of Escherichia coli catalyzes the reversible transfer of hydride ion equivalents between NAD+ and NADP+ coupled to translocation of protons across the cytoplasmic membrane. Recently, transhydrogenation of 3-acetylpyridine adenine dinucleotide (AcPyAD+), an analog of NAD+, by NADH has been described using a solubilized preparation of E. coli transhydrogenase [Hutton, M., Day, J.M., Bizouarn, T., and Jackson, J.B. (1994) Eur. J. Biochem. 219, 1041-1051]. This reaction depended on the presence of NADP(H). We show that (a) this reaction did not require NADP(H) at pH 6 in contrast to pH 8; (b) the reaction occurred at pH 8 in the absence of NADP(H) in the mutant beta H91K and in a mutant in which six amino acids of the carboxy-terminus of the alpha subunit had been deleted; (c) the mutant transhydrogenases contained bound NADP+ and were in a conformation in which the beta subunit was digestible by trypsin; (d) the conformation of the beta subunit of the wild-type enzyme was made susceptible to trypsin digestion by NADP(H) or by placing the enzyme at pH 6 in the absence of NADP(H). It is concluded that reduction of AcPyAD+ by NADH does not involve NADPH as an intermediate and that the role of NADP(H) in this reaction at pH 8 is to cause the transhydrogenase to adopt a conformation favouring transhydrogenation between NADH and AcPyAD+.
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PMID:The mechanism of hydride transfer between NADH and 3-acetylpyridine adenine dinucleotide by the pyridine nucleotide transhydrogenase of Escherichia coli. 757 17


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