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:3.4.24.27 (thermolysin)
1,894 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have studied the fragmentation by pepsin in 1 M-acetic acid of the erythrocyte anion-transport protein in erythrocyte membranes. The location of the fragments obtained was determined by radioiodinating the protein with the use of lactoperoxidase, and identifying the labelled peptides obtained in peptide "maps" of thermolysin digests of the fragments. Three of the fragments were found to be related overlapping products, and shared a common C-terminus. The major site of pepsin cleavage leading to the C-termini of these fragments was shown to be close to the major site of extracellular cleavage of the protein by proteinases active at a neutral pH. Another two fragments were isolated and shown to be derived from the C-terminal portion of the protein. No well-defined large radioactive fragments of the protein were solubilized from the membrane by pepsin in 1 M-acetic acid, the bulk of the radioactivity attributable to the anion transport protein being recovered in very small fragments that could not be resolved by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Our results suggest that the polypeptide chain of the anion-transport protein emerges at the extracellular face of the membrane 8000-13000 daltons on the N-terminal side of the major site of extracellular cleavage of the protein by proteinases that are active at a neutral pH.
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PMID:The anion-transport protein of the human erythrocyte membrane. Studies on fragments produced by pepsin digestion. 39 52

Proteolysis of reconstituted membranes with papain and thermolysin reveals the existence of two rhodopsin populations: one susceptible to proteolysis and the other protected. The susceptible population corresponds to rhodopsin molecules with the same orientation as rhodopsin in the native membrane, while the protected population corresponds to "inverted" rhodopsin molecules only found in reconstituted membranes. Using an iodination enhancement probe, we demonstrate that lactoperoxidase catalyzes iodination of rhodopsin exclusively on the external surface of these sealed reconstituted vesicles. Furthermore, we find that both rhodopsin populations in reconstituted membranes (normal and inverted) are readily iodinated by lactoperoxidase, providing definitive evidence that the rhodopsin polypeptide spans the membrane thickness. Additional conclusions from these experiments are discussed in terms of a model for the folding of the rhodopsin polypeptide in the membrane.
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PMID:Organization of rhodopsin in photoreceptor membranes. 2. Transmembrane organization of bovine rhodopsin: evidence from proteolysis and lactoperoxidase-catalyzed iodination of native and reconstituted membranes. 71 47

The structure of the major human erythrocyte membrane protein (protein E) was investigated by studying the products of proteolysis of the native protein in the membrane. The distribution and location of the tyrosine residues labelled by radioiodination by lactoperoxidase was determined. Proteolysis of the extracellular region of the protein by thermolysin released four tyrosine-containing peptides, all of which were also found to remain in the major fragment that is retained in the membrane. The presence of these duplicated sites in the extracellular region of the protein was confirmed by limited trypsin digestion of the intracellular region of the protein. Two groups of fragments were obtained. Both groups contained a set of the extracellular labelled sites, but they differed in containing distinct groups of intracellular sites, showing that the two sets of extracellular sites are linked by an intracellular region of the protein. The polypeptide chain thus traverses the membrane twice. An S-shaped model which is consistent with these data is proposed.
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PMID:The major human erythrocyte membrane protein. Evidence for an S-shaped structure which traverses the membrane twice and contains a duplicated set of sites. 116 51

The proteolytic cleavage of Chlamydia trachomatis LGV-434 surface proteins and resultant effects on infectivity and association with cultured human epithelial (HeLa) cells have been examined. Of several proteases examined, trypsin, chymotrypsin, and thermolysin extensively cleaved the chlamydial major outer membrane protein (MOMP). Two proteases, trypsin and thermolysin, cleaved the MOMP to the extent that monomeric MOMP was not detectable by immunoblotting with monospecific polyclonal antibodies. In the case of thermolysin, not even antigenic fragments were detected. Surprisingly, infectivity toward HeLa cells was not diminished. In addition, the association of intrinsically 14C-radiolabeled elementary bodies (EBs) with HeLa cells or their dissociation by proteinase K was not measurably affected by prior trypsinization of the EBs. Trypsinization of lactoperoxidase surface-iodinated elementary bodies demonstrated that most of the 125I-labeled surface proteins were cleaved. In all cases, however, a number of proteolytic cleavage fragments remained associated with the EB surface after surface proteolysis. When trypsinized EBs were electrophoresed under nonreducing conditions and immunoblotted with either polyclonal or type-specific monoclonal MOMP antibodies, MOMP was found in a large oligomeric form that failed to enter the polyacrylamide stacking gel. Additionally, trypsinized viable EBs bound radioiodinated type-specific MOMP monoclonal antibody as efficiently as did the control nontrypsinized organisms. Taken together, the findings indicate that although the MOMP is highly susceptible to surface proteolysis, the supramolecular structure of the protein on the EB surface is apparently maintained by disulfide interactions. Thus, if surface-exposed chlamydial proteins are involved in the initial interaction of chlamydiae with eucaryotic cells, the functional domains of these proteins which mediate this interaction must be resistant to proteolysis and remain associated with the EB surface.
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PMID:Effect of proteolytic cleavage of surface-exposed proteins on infectivity of Chlamydia trachomatis. 258 Jul 94

The occasional cleavage of the Pseudomonas cytochrome-c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) molecule into two well-defined fragments during the preparation of the enzyme is shown to be identical to that caused by elastase isolated from the culture solution of Pseudomonas aeruginosa. A cyanogen bromide fragmentation of proteolytically cleaved and of intact enzyme shows the cleaved peptide bond to be situated in cyanogen bromide fragment II. The amino-acid sequence of this fragment was established by sequencing peptides obtained with trypsin, thermolysin, chymotrypsin and o-iodosobenzoate. It is concluded from the sequence homology that the polypeptide chain of Pseudomonas peroxidase is wrapped around the high-potential heme in a similar manner as in high-potential cytochromes c in general. The specific proteolytic cleavage occurs at a Ser-Val (Leu-Pro) region which is assumed to be the site of attachment between enzyme and membrane. The cleavage of the Ser-Val bond renders the peroxidase molecule enzymatically inactive by impeding the conformational changes essential for the function of the native enzyme.
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PMID:Specific cleavage of Pseudomonas cytochrome-c peroxidase by elastase from Pseudomonas aeruginosa. 282 23

An active form of phosphorylase phosphatase of Mr = 33,000, referred to as the catalytic subunit for over a decade, was purified to near-homogeneity from rabbit skeletal muscle. Repeated immunization of a sheep produced immunoglobulins that blocked the activity of the phosphatase. These immunoglobulins were affinity-purified on columns of immobilized phosphorylase phosphatase and used as macromolecular probes in a "Western" immunoblotting procedure with peroxidase-conjugated rabbit anti-sheep immunoglobulins. Only one protein, of Mr = 33,000, was stained in samples of the immunogen, attesting to the specificity of the probes. However, the Mr = 33,000 phosphatase protein was not detected in muscle extracts or in partially purified preparations. Instead, a single protein of Mr = 70,000 was detected. Limited proteolysis, in particular by Staphylococcus aureus V8 protease and thermolysin, converted the immunoreactive protein from Mr = 70,000 to Mr = 33,000. Coagulation of the phosphatase preparation with 80% ethanol at room temperature rendered the Mr = 70,000 protein insoluble, but allowed extraction of the Mr = 33,000 protein from the precipitate. Thus, we conclude that the immunoreactive protein of Mr = 70,000 is the "catalytic subunit" of phosphorylase phosphatase with a catalytic domain of Mr = 33,000. Previous purification schemes have yielded only the fragment of Mr = 33,000 due to its relative resistance to proteolysis and coagulation. Gel filtration chromatography of the "native" form of phosphorylase phosphatase showed Mr approximately 230,000. Both the Mr = 70,000 catalytic subunit and a Mr = 60,000 protein related to inhibitor-2 were detected by immunoblotting in the same fractions that exhibited activity after treatment with Co2+ and trypsin. Only the Mr = 60,000 protein was degraded during this activation process. We propose that the native phosphorylase phosphatase is an elongated structure with two-fold symmetry, containing one catalytic subunit of Mr = 70,000 and one regulatory subunit of Mr = 60,000.
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PMID:Phosphorylase phosphatase catalytic subunit. Evidence that the Mr = 33,000 enzyme fragment is derived from a native protein of Mr = 70,000. 298

F (fusion) and HANA (hemagglutinin and neuraminidase) glycoproteins of HVJ (Sendai virus) were purified and characterized. The NH2-terminal hydrophobic region of the F1 (larger) subunit of F (fusion)-glycoprotein seems to be required for the hemolytic and cell fusion-inducing activity of the virus for the following reasons. (1) Selective splitting off of a 2,500-3,500 dalton segment from the NH2-terminal region of F1 by chymotrypsin or thermolysin resulted in inactivation of the biological activities of HVJ. (2) At least a part of this region may be exposed to the surrounding medium, since it is preferentially iodinated and is easily split by aminopeptidase M, chymotrypsin, and thermolysin. Tryptic digestion, which does not remove the NH2-terminal region but produce nicking of F1 subunit to subfragments F1a (larger one) and F1b (smaller one), resulted in substantial structural changes evidenced by circular dichroism measurement and iodination by lactoperoxidase method. Trypsin-digested F seems to have the NH2-terminal hydrophobic region buried within hydrophobic interior of the protein (or in the lipid bilayers). Based on these and other results, we propose a hypothesis featuring direct interaction of the hydrophbic region with the lipid bilayers of the target-cell membrane as an important step in fusion reactions between the viral envelope and cell membranes.
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PMID:Viral proteins in cell fusion. 631 Aug 22

Porcine alveolar macrophages (AM), as we reported in 1981, inactivate slow-reacting substance of anaphylaxis (SRS-A) in a time- and cell-number-dependent fashion. In the present study, metabolism of synthetic leukotriene D4 (LTD4) to leukotriene E4 (LTE4) by AM was demonstrated (mean conversion, 216 pmoles LTD/10(7) AM/60 min). The metabolism was inhibited by cooling or by removal of calcium ions plus addition of EDTA but not by dinitrophenol or puromycin, lipoxygenase inhibitors, the peroxidase inhibitor aminotriazole, or the hydroxyl ion scavenger benzoic acid. Similarly, although the addition of catalase plus superoxide dismutase significantly augmented (169 +/- 25% control) SRS release from dispersed porcine lung cells, the presence of these enzymes did not prevent LTD4 metabolism by AM. Inhibitors of gamma-glutamyl transpeptidase were also without effect but the dipeptidase inhibitors L-cysteine and dithiothreitol significantly reduced the conversion, as did pretreatment of AM with thermolysin (100 micrograms/ml). These data indicate that an AM dipeptidase, which may at least partly be located on the cell surface, converts LTD4 to the less bioactive LTE4.
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PMID:Metabolism of leukotriene D4 by porcine alveolar macrophages. 632 Jun 96

Incubation of purified prostaglandin endoperoxide synthetase from sheep vesicular glands with aspirin results in a covalent binding of the acetyl group of acetylsalicylic acid to the protein. During this acetylation, the cyclooxygenase activity is lost, but not the peroxidase activity. The reaction is completed when almost one acetyl group is bound per polypeptide chain (Mr = 68 000). After proteolysis of [3H]acetyl-protein with pronase, radioactive N-acetylserine was obtained. Originally, however, the hydroxyl group of an internal serine residue in the chain is acetylated. The formation of N-acetylserine can be explained by a rapid O leads to N acetyl shift as soon as the NH2 group of serine is liberated. A radioactive dipeptide was isolated from a thermolysin digest of the [3H]acetyl-enzyme containing phenylalanine and serine, phenylalanine being its N-terminal amino acid. Automatic Edman degradation of native and acetylated enzyme showed that only one polypeptide sequence was present: Ala-Asp-Pro-Gly-Ala-Pro-Ala-Pro-Val-Asn-Pro-X-X-Tyr-. The N-terminal sequence has an apolar character.
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PMID:Acetylation of prostaglandin endoperoxide synthetase with acetylsalicylic acid. 677 69

The unfolding and refolding rates of the heme-and Ca2+ -containing Coprinus cinereus peroxidase (CIP) have been measured at pH 12.1, in 4 M urea, and at 61.2 degrees C. The change in peroxidase activity paralleled the change in the Soret band absorbance of the heme group. The unfolding rate constant (ku), was determined independently in thermolysin digestion and EDTA experiments at 59.4 degrees C. Both gave ku values of 1.5 ms-1, and also showed that the presence of 4 mM EDTA made CIP unfolding practically irreversible. Unfolding and refolding rates could therefore be determined under identical conditions of denaturation having either EDTA or Ca2+ in excess. The refolding rates at high pH and in 4 M urea were measured by adding Ca2+ to the unfolded CIP, whereas refolding at 61.2 degrees C was evaluated by comparing the unfolding carried out under reversible (excess of Ca2+) and irreversible conditions (excess EDTA). The activation energies for the unfolding at 61.2 degrees C are approximately delta G++(u) 100, T delta S++(u) 200, and delta H++(u) 300 kJ/mol. Five different additives, glycerol, EtOH, Na2SO4, guanidinium chloride (GdmCl), and NaCl, all at 100 mM, were used as probes to evaluate the mechanism of base, urea, and heat on unfolding and refolding. Salts destabilized CIP at high pH, primarily by enhancing the unfolding rate but also by decreasing the refolding rate. Glycerol had the reverse effects and thus stabilized CIP at high pH. The unfolding rate in urea was only slightly affected by the additives, with the exception of GdmCl which enhanced the unfolding rate. The refolding rate was decreased in urea by EtOH and GdmCl, in contrast to glycerol and Na2SO4 which increased the refolding rate. At high temperature the unfolding was affected only slightly by the additives, except for GdmCl, and to a lesser extent NaCl, which enhanced the unfolding rate. The refolding rates were greatly decreased by Na2SO4, EtOH, and GdmCl, whereas glycerol and Nacl enhanced the process. It appears that 100 mM NaCl functions as a catalyst for the temperature-induced process, enhancing both the unfolding and refolding rates. The results indicate that the mechanisms of CIP unfolding and refolding are similar in urea and at high temperature but different at high pH.
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PMID:Unfolding and refolding of Coprinus cinereus peroxidase at high pH, in urea, and at high temperature. Effect of organic and ionic additives on these processes. 865 38


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