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: UNIPROT:P15088 (mast cell)
14,925 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The covalent structure of the rat liver 60 S ribosomal subunit protein L37 was determined. Twenty-four tryptic peptides were purified and the sequence of each was established; they accounted for all 111 residues of L37. The sequence of the first 30 residues of L37, obtained previously by automated Edman degradation of the intact protein, provided the alignment of the first 9 tryptic peptides. Three peptides (CN1, CN2, and CN3) were produced by cleavage of protein L37 with cyanogen bromide. The sequence of CN1 (65 residues) was established from the sequence of secondary peptides resulting from cleavage with trypsin and chymotrypsin. The sequence of CN1 in turn served to order tryptic peptides 1 through 14. The sequence of CN2 (15 residues) was determined entirely by a micromanual procedure and allowed the alignment of tryptic peptides 14 through 18. The sequence of the NH2-terminal 28 amino acids of CN3 (31 residues) was determined; in addition the complete sequences of the secondary tryptic and chymotryptic peptides were done. The sequence of CN3 provided the order of tryptic peptides 18 through 24. Thus the sequence of the three cyanogen bromide peptides also accounted for the 111 residues of protein L37. The carboxyl-terminal amino acids were identified after carboxypeptidase A treatment. There is a disulfide bridge between half-cystinyl residues at positions 40 and 69. Rat liver ribosomal protein L37 is homologous with yeast YP55 and with Escherichia coli L34. Moreover, there is a segment of 17 residues in rat L37 that occurs, albeit with modifications, in yeast YP55 and in E. coli S4, L20, and L34.
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PMID:The primary structure of rat liver ribosomal protein L37. Homology with yeast and bacterial ribosomal proteins. 635 Feb 92

Two different isoenzymes of fructose-P2 aldolase can be resolved by chromatography of crude spinach leaf extracts on DEAE-cellulose columns. The acidic isoenzyme comprises about 85% of the total leaf aldolase activity. The two forms differ in primary structure as judged by their distinctive amino acid compositions, tryptic peptide patterns, and immunological properties. Only the acidic isoenzyme was detected in extracts of isolated chloroplasts, suggesting that this molecule represents the chloroplast form of spinach leaf aldolase while the basic isoenzyme is of cytosolic origin. The cytosolic (basic) isoenzyme and chicken aldolase A4 are similar in the following respects. 1) They have similar specific catalytic activity (10-15 units/mg); 2) they are both highly sensitive to inactivation by very limited digestion with bovine pancreatic carboxypeptidase A; 3) they both have subunit molecular weights of 40,000; 4) they both have derivatized (blocked) NH2-terminal structures; 5) they are both resistant to thermal denaturation at 50 degrees C; and 6) they both regain catalytic activity following reversible denaturation at pH 2.3 or in 5.8 M urea. Also, the cytosolic aldolase cross-reacted immunologically with the single aldolases present in spinach seeds and in wheat germ. Further, this isoenzyme readily "hybridized" with chicken aldolase A4 in vitro. These observations demonstrate the close homology between the cytosolic aldolases derived from plant and animal origins. The chloroplast aldolase had a specific catalytic activity of about 8 units/mg and, like its cytosolic counterpart, was severely inactivated by limited digestion with carboxypeptidase A. However, this isoenzyme was distinct from the cytosolic aldolase in the following characteristics: 1) its "small" subunit size (Mr congruent to 38,000); 2) its underivatized NH2-terminal structure; 3) its high sensitivity to thermal denaturation at 50 degrees C; and 4) its inability to refold into an enzymatically active conformation following denaturation at pH 2.3 or in 5.8 M urea. The distinctive properties of the chloroplast aldolase may be expected for an enzyme which is synthesized as a higher molecular weight precursor on cytosolic polysomes and is then proteolytically processed to the "mature" form during its migration into the chloroplast organelle.
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PMID:Isolation and characterization of the cytosolic and chloroplast forms of spinach leaf fructose diphosphate aldolase. 642 Mar 97

The preparation of a pure, monoiodinated derivative of mast cell-degranulating peptide (MCD peptide), the mast cell-degranulating peptide from bee venom, has enabled us to identify binding sites in rat brain membranes that have a high affinity and specificity for this peptide. These binding sites are evenly distributed throughout the brain and copurify with synaptic membranes. Saturation-binding curves, determined by rapid centrifugation or filtration assays, indicate a single population of sites with a concentration of 200 fmol/mg membrane protein in partially fractionated, lysed brain membranes. Dissociation constants of 150 and 140 pM were calculated for the iodinated and native peptides, respectively. These binding sites are probably associated with the neurotoxic action of MCD peptide in the central nervous system. No similar binding sites have been identified in peripheral tissue preparations, and other polycationic mast cell-degranulating agents including compound 48/80 show no such specificity. Specific modification of the primary amines, arginine residues, or disulfide bridges of MCD peptide results in a complete loss of binding activity. Other components of bee venom show specificity for the MCD peptide-binding site, suggesting that a class of neurotoxins in bee venom (possibly including secapin and tertiapin, but not apamin) share the specific action of MCD peptide on the central nervous system.
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PMID:The characterization of high-affinity binding sites in rat brain for the mast cell-degranulating peptide from bee venom using the purified monoiodinated peptide. 650 Dec 83

A highly unusual endothelial cell collagen (Sage, H., Pritzl, P., and Bornstein, P., (1980) Biochemistry 19, 5747-5755) has been characterized in greater detail. Pulse-chase experiments with bovine aortic endothelial cells revealed two nondisulfide-bonded collagens, of apparent chain Mr = 177,000 and 125,000, with an estimated synthesis and secretion time of 75 min. Stepwise, quantitative processing to stable lower molecular weight forms as described for type I procollagen was not observed. Endothelial collagen was secreted over a temperature range of 24-37 degrees C and, prior to heat denaturation, did not display affinity for a gelatin-binding fragment of fibronectin coupled to Sepharose. The presence of a pepsin-resistant domain (Mr = 50,000) in both the soluble and cell layer-associated forms of this protein was shown by ion exchange chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Endothelial collagen was cleaved by vertebrate collagenase into several discrete fragments that differed in molecular weight from the characteristic alpha A and alpha B fragments generated from the interstitial collagens. Nontriple helical domains corresponding to the NH2- and COOH-terminal propeptides of other procollagen types were not found after incubation of endothelial collagen with bacterial collagenase. Additional evidence for the lack of extended noncollagenous sequences was provided by studies with mast cell proteases, which convert native procollagen to collagen but are unreactive toward native interstitial collagens. Endothelial collagen was not cleaved by these enzymes at 37 degrees C, but, as observed for interstitial collagen alpha chains, required prior heating at elevated temperatures for cleavage to occur. In view of this unique set of structural characteristics, and a distribution that is not restricted to the endothelium, we have designated this protein as type VIII collagen.
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PMID:Biosynthetic and structural properties of endothelial cell type VIII collagen. 663 Feb 35

The covalent structure of the rat liver 60 S ribosomal subunit protein L39 was determined. Fourteen tryptic peptides were purified, and the sequence of each was established by a micromanual procedure; they accounted for all 50 residues of L39. The sequence of the NH2-terminal 32 residues of L39, obtained by automated Edman degradation of the intact protein, provided the alignment of the first seven tryptic peptides. Two peptides, CNI (28 residues) and CNII (22 residues), were produced by cleavage of protein L39 with cyanogen bromide and the sequence of CNII was determined by automated Edman degradation. This sequence established the order of tryptic peptides T8 through T14. The carboxyl-terminal amino acids were identified after carboxypeptidase A treatment. Protein L39 contains 50 amino acids and has a molecular weight of 7308. There are indications that a portion of rat L39 is related to a fragment of Escherichia coli ribosomal protein S1.
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PMID:The primary structure of rat liver ribosomal protein L39. 670 49

The preparation of N alpha 1 N epsilon 29-bis-methylsulphonylethyloxycarbonyl-des-alanineB30-B-chain-disulphide-O gamma 13 O gamma 21-dimethyl ester is described. Starting with the di-S-sulphonate-B-chain it was prepared by i) removal of the C-terminal amino acid by digestion with carboxypeptidase A, ii) reduction and oxidation to form the cyclic disulphide, iii) esterification of the three carboxyl groups (alpha COOH = LysB29, gamma COOH - GluB13 and GluB21) followed by selective tryptic hydrolysis of the alpha-carboxyl ester, and iv) the protection of both amino groups (alpha NH2 = PheB1, epsilon NH2 = LysB29). This B-chain derivative was activated selectively at the C-terminal carboxyl group by formation of a mixed anhydride, and condensed with the dipeptide Thr-Arg. All protecting groups were removed by treatment with alkali. The human-B-chain C-terminal elongated with Arg was obtained in a yield of 30% based on the protected des-AlaB30-B-chain derivative.
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PMID:Preparation of partially protected des-alanineB30-insulin-B-chain-disulphide and its use in semisynthesis. 675 63

Extremities, peptide maps and phosphorylatable site localization of human erythrocyte L' and liver L pyruvate kinases (EC 2.7.1.40) were investigated. L' and L subunits seemed to have similar, blocked NH2 termini and differ in their sensitivity to carboxypeptidase A, that is to say in their C-terminal ends. After digestion by Staphylococcus aureus V8 protease, the phosphorylated sites of both L' and L subunits were located on those peptides which were different in L' and L, that is to say on the C-terminal sides. A mild proteolytic attack of the native tetrameric enzymes by trypsin partially degraded the phosphorylatable peptides without removing the phosphoserine residue; in the same conditions, chymotrypsin split off this phosphorylated residue and subtilisin totally degraded the phosphorylated peptides. From these results it appears, therefore, that age-dependent proteolytic degradation of L' subunits in old red cells involves the C-terminal side of the molecules, ultimately resulting in cleavage of the phosphorylated site. Since erythrocyte L' and liver L subunits are encoded by different species of messenger RNAs, our results indicate, in addition, that these messenger RNA species should differ by their 3' coding sequences.
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PMID:Molecular organization of human L' and L pyruvate kinases. 675 52

D-Alanine carboxypeptidase is a penicillin-sensitive intrinsic membrane enzyme which is composed of a hydrophilic NH2-terminal catalytic domain (Mr congruent to 45,000 to 47,000) and a COOH-terminal membranous segment (approximately 20 to 30 amino acids in length) (Waxman, D. J., and Strominger, J. L. (1979) J. Biol. Chem. 254, 4863-4875; Waxman, D. J., and Strominger, J. L. (1981) J. Biol. Chem. 256, 2059-2066). The primary structures of the COOH-terminal 30 amino acids of two D-alanine carboxypeptidase purified from bacterial membranes were determined (residues numbered from the COOH terminus): Bacillus stearothermophilus: (formula see text) Water-soluble fragments of the B. stearothermophilus D-alanine carboxypeptidase were shown to be formed by cleavage after Phe27 or after Leu25 as indicated by carboxypeptidase A and B analysis and by the release of the four COOH-terminal chymotryptic peptides (Val26-Leu25, Ser24-Phe16, Val15-Trp12, and Thr11-Leu1) upon formation of water-soluble chymotrypsin D-alanine carboxypeptidase. This indicates that the membranous fragment is largely contained within the COOH-terminal 24 residues. Thus, this bacterial membrane protein probably does not contain the significant cytoplasmic domain characteristic of transmembrane proteins such as glycophorin. The absence of an uninterrupted stretch of 20 to 25 uncharged residues suggests that the membrane anchoring of D-alanine carboxypeptidase may differ from that of simple transmembrane proteins. Possible structures for the membranous segment of D-alanine carboxypeptidase are discussed.
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PMID:Primary structure of the COOH-terminal membranous segment of a penicillin-sensitive enzyme purified from two Bacilli. 678 May 59

An unusual type of posttranslational modification has been observed in a rat brain in vitro system. It consists in leucine addition to a preformed protein in such a way that the added leucine is not located at either the NH2 or the COOH terminus of the acceptor protein. The incorporation reaction requires ATP, ATP-generating components and tRNA. It is inhibited by aurintricarboxylic acid but does not require the presence of ribosomes or GTP. The incorporated leucine has a free NH2 group, and it is not released by leucine aminopeptidase or carboxypeptidase A. It is linked to the acceptor protein through a bond that is too alkali labile and too hydroxylamine labile to be a peptide bond. The simplest interpretation of the results consists in proposing that an ester bond is formed between the leucine and the side chain of a serine, threonine, or tyrosine in the acceptor protein.
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PMID:Transfer ribonucleic acid dependent but ribosome-independent leucine incorporation into rat brain protein. 717 78

Equilibrium sedimentation experiments of the native acid phosphatase indicate a dimer-tetramer dissociating nonequilibrating system with a dimer Mr = 180,000 g/mol. The hydrolysis of nitrophenylphosphate was used to determine the sedimentation coefficient of the active species. The s20,w value for the species which degrades nitrophenylphosphate is 13.52 +/- 0.46 S in 1% sucrose and 13.72 +/- 0.11 S in 1.3 M sodium chloride, corresponding to the Svedberg value of the tetramer species. Several lines of evidence are presented which, together with previous data, indicate that the Schizosaccharomyces pombe nonspecific acid phosphatase is composed of 4 identical or nearly identical polypeptide chains: a, equilibrium sedimentation analysis of the enzyme in denaturing agents indicates the presence of homogeneous material having Mr = 90,800 g/mol; b, digestion with carboxypeptidase A releases 0.82 mol of tyrosine/monomer molecular weight. Concomitant phosphatase inactivation occurred during the splitting off of the tyrosyl terminal residue. Furthermore, a unique NH2-terminal residue (histidine) was determined.
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PMID:Molecular properties and active form of nonspecific acid phosphatase from Schizosaccharomyces pombe. 721 63


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