Molecular cloning and nucleotide sequence of Streptomyces griseus trypsin gene.

Streptomyces griseus trypsin (E.C. 3.4.21.4) is one of the major extracellular proteinase, which is secreted by S. griseus. The gene encoding S. griseus trypsin was isolated from a S. griseus genomic library by using a synthetic oligonucleotide probe. Fragments containing the gene for S. griseus trypsin were characterized by hybridization and demonstration of proteolytic activity in S. lividans. Deduced amino acid sequence from the nucleotide sequence suggests that S. griseus trypsin is produced as a precursor, consisting of three portions; an amino-terminal pre sequence (32 amino acid residues), a pro sequence (4 residues), and the mature trypsin. The S. griseus trypsin consists of 223 amino acids with a computed molecular weight of 23,112. The existence of proline at the pro and mature junction suggests that the processing of S. griseus trypsin is non-autocatalytic.     

Trypsin from Pacifastacus leniusculus hepatopancreas: purification and cDNA cloning of the synthesized zymogen.

Trypsin was purified from crayfish, Pacifastacus leniusculus, hepatopancreas, and the gene that encoded this enzyme was cloned from a hepatopancreas cDNA library. Crayfish trypsin is synthesized as a zymogen according to the sequence of the putative precursor peptide. The authenticity of the trypsinogen is supported by the deduced amino acid sequence and confirmed by the N-terminal amino acid sequence of the mature protein. The enzyme has features characteristic of a trypsin, such as a specific binding pocket. Sequence comparison shows that crayfish trypsin is similar to those of other species, with the exception that six cysteine residues present in vertebrates are missing. Some structural characteristics, such as the length of the signal peptide and a calcium binding site, are similar to bacterial trypsin.     

Complete amino acid sequence of ovine salivary carbonic anhydrase

The primary structure of the secreted carbonic anhydrase from ovine salivary glands has been determined by automated Edman sequence analysis of peptides generated by cyanogen bromide and tryptic cleavage of the protein and Staphylococcus aureus V8 protease, trypsin, and alpha-chymotrypsin subdigests of the large cyanogen bromide peptides. The enzyme is a single polypeptide chain comprising 307 amino acids and contains two apparent sites of carbohydrate attachment at Asn-50 and Asn-239. The protein contains two half-cystine residues at 25 and 207 which appear to form an intramolecular disulfide bond. Salivary carbonic anhydrase shows 33% sequence identity with the ovine cytoplasmic carbonic anhydrase II enzyme, with residues involved in the active site highly conserved. Compared to the cytoplasmic carbonic anhydrases, the secreted enzyme has a carboxyl-terminal extension of 45 amino acids. This is the first report of the complete amino acid sequence of a secreted carbonic anhydrase (CA VI).     

Physicochemical characteristics of homogeneous bovine lung angiotensin I-converting enzyme. Comparison with human serum enzyme

Angiotensin I-converting enzyme was purified to electrophoretic homogeneity (12 units/mg) from bovine lung tissue and from human serum using an affinity gel described previously (Harris et al., (1981) Anal. Biochem. 111, 227-234). The isoelectric point (4.5), molecular weight (145 000), S20,W (8.1), amino acid composition and carbohydrate content of the lung enzyme are all similar to the values obtained for the human serum enzyme. The NH2-terminus of the lung enzyme (Ala) is different from that of the serum enzyme (Tyr) but the COOH-terminal sequences are identical (-Leu-Ser-OH). Pure bovine lung enzyme was reduced and carboxyamidomethylated with iodo (14C1) acetamide to the extent predicted by the number of cysteine residues. Since no radioactivity was incorporated into denatured enzyme that was not reduced, all of the cysteine residues must be in the form of disulfide bonds. Reverse-phase HPLC was used to separate peptides obtained from the lung enzyme after degradation with either trypsin or cyanogen bromide. The number of peptides resolved (42 after trypsin, 31 after cyanogen bromide), were only 20% fewer than the number predicted from the amino acid analysis and therefore the possibility that the converting enzyme (a single polypeptide chain) might be a fused dimer is excluded.     

Partial amino acid sequence of the glutamate dehydrogenase of human liver and a revision of the sequence of the bovine enzyme.

The glutamate dehydrogenase from a single human liver has been studied. The subunit size was found to be 55,200 +/- 1,500 by sedimentation equilibrium. The partial specific volume is 0.732 as calculated from the amino acid composition. The sequence was determined by isolation of peptides after cyanogen bromide (CNBr) cleavage; the fraction containing the largest peptides was hydrolyzed by trypsin after maleylation. Studies on these peptides accounted for 454 residues of the 505 residues that are presumably present in the protein. For the 51 residues that were not represented in isolated peptides, we have tentatively assumed that the sequence is the same as that of the bovine enzyme. Methionine and arginine residues in these peptides could be placed on the basis of the specificity of cleavage by CNBr or trypsin. In all, 349 residues were placed in sequence, and were aligned by homology with the corresponding peptides of the bovine and chicken enzymes. From the present information, there are 24 known differences in sequence between the human and bovine enzymes and 41 between the human and chicken enzymes. In addition, the human enzyme contains 4 additional residues at the NH2 terminus as compared to the bovine enzyme. In a peptide from the human enzyme, an additional residue, isoleucine 385, was detected by automated Edman degradation. Reinvestigation of the bovine sequence demonstrated that this residue is also present in the bovine enzyme (and presumably in the chicken enzyme also). Residue 384 of the bovine enzyme, previously reported as Glx has now been shown to be glutamine.     

Effect of poly(ADP-ribose) formation on DNA synthesis in chick-embryo-liver nuclei. Possible mechanism of template activation.

The complete amino acid sequence of bovine phospholipase A2 (EC 3.1.1.4) was determined. This enzyme has a molecular weight of 13 782 and consists of a single polypeptide chain of 123 amino acids cross-linked by seven disulfide bridges. The main fragmentation of the polypeptide chain was accomplished by digesting the reduced and thialaminated derivative of the protein with trypsin, staphylococcal protease and cyanogen bromide. A number of chymotryptic peptides were used for alignment and to obtain overlaps of at least two residues. The sequence of the peptides was determined by Edman degradation by means of direct phenylthiohydantoin identification in combination with identification as dansyl amino acids. Although 71% of all residues of phospholipase A2 from bovine, porcine and equine sources are conserved, bovine phospholipase A2 differs from the others by the total number of residues and by substitutions at 20 (porcine) and 33 (equine) positions.     

Complete amino acid sequence of streptokinase and its homology with serine proteases

The complete amino acid sequence of streptokinase has been determined by automated Edman degradation of its cyanogen bromide and proteolytic fragments. The protein consists of 415 amino acid residues. Sequence microheterogeneity was found at two positions. The NH2-terminal 245 residues of streptokinase are homologous to the sequences of several serine proteases including bovine trypsin and Streptomyces griseus proteases A and B. The sequence alignment suggests that the active-site histidine-57 has changed to a glycine in streptokinase. The other active-site residues, aspartyl-102 and serine-195, are, however, present at the expected positions. Streptokinase also contains internal sequence homology between the NH2-terminal 173 residues and a COOH-terminal 162-residue region between residues 254 and 415. Moderate homology in predicted secondary structures also exists between these two regions. Although streptokinase is not a protease, these observations suggest that it has evolved from a serine protease by gene duplication and fusion. A COOH-terminal region of about 80 residues is apparently deleted from the second half of the duplicated structures. These observations further suggest that the three-dimensional structure of streptokinase likely contains two independently folded domains, each homologous to serine proteases.     

Molecular cloning of the E1 beta subunit of the rat branched chain alpha-ketoacid dehydrogenase.

We determined the cDNA sequence of the mRNA for antithrombin III (AT III) from sheep liver. It encodes a protein of 465 amino acids, including a signal peptide of 32 amino acids. The amino acid sequence of the mature protein shows a sequence identity of 89.1%, 95.6% and 85.0% to the human, bovine and rabbit equivalents, respectively. Cysteine residues involved in disulfide bonds as well as potential glycosylation sites are conserved between the four species. In contrast, the amino acid sequence of the signal peptide shows a smaller identity, i.e., 68.7% and 56.3% compared to the human and rabbit preprotein, respectively.     

Two new extracellular serine proteases from Streptomyces fradiae.

1. Two new extracellular serine proteases have been purified to homogeneity from Streptomyces fradiae. 2. On amino acid sequencing, striking homology is observed between the first enzyme and Streptomyces griseus Protease A, and the second enzyme and S. griseus trypsin. 3. The sequence information shows for the first time that structurally and enzymatically related serine proteases are extracellularly expressed by different Streptomycetes. 4. Differential keratinolytic substrate specificity among these two microbes are probable due to a difference in disulfide reduction capacity.     

The primary structure of Aspergillus niger acid proteinase A

The complete amino acid sequence of the acid proteinase A, a non-pepsin type acid proteinase from the fungus Aspergillus niger var. macrosporus, was determined by protein sequencing. The enzyme was first dissociated at pH 8.5 into a light (L) chain and a heavy (H) chain, and the L chain was sequenced completely. Further sequencing was performed with the reduced and pyridylethylated or aminoethylated derivative of the whole protein, using peptides obtained by digestions with Staphylococcus aureus V8 protease, trypsin, chymotrypsin, and lysylendopeptidase. The location of the two disulfide bonds was determined by analysis of cystine-containing peptides obtained from a chymotryptic digest of the unmodified protein. These results established that the protein consists of a 39-residue L chain and a 173-residue H chain that associate noncovalently to form the native enzyme of 212 residues (Mr 22,265). This is, to our knowledge, the first time that such a protein with a rather short peptide chain associated noncovalently has been found. No sequence homology is found with other acid or aspartic proteinases, except for Scytalidium lignicolum acid proteinase B, an enzyme unrelated to pepsin by sequence, which has about 50% identity with the present enzyme. These two enzymes, however, are remarkably different from each other in some structural features.     

Alpha 1,3 galactosyltransferase: new sequences and characterization of conserved cysteine residues

Nucleotide sequences were determined for alpha1,3 galactosyltransferases (alpha1,3 GalTs) from several species (bat, mink, dog, sheep, and dolphin) and compared with those previously determined for this enzyme and members of the alpha1,3 galactosyl/N-acetylgalactosyltransferase (alpha1,3 Gal(NAc)Ts) family of enzymes. Sequence comparison of the newly characterized alpha1,3 GalT nucleotide and predicted amino acid sequences with those previously characterized for other alpha1,3GalT enzymes demonstrated a remarkable level of sequence identity at the nucleotide and amino acid level. The identity of each sequence as an alpha1,3 GalT was confirmed by expressing the encoded protein and characterizing the resulting enzyme. The alpha1,3 GalTs have a significant degree of sequence homology with A and B transferases, the alpha1,3 GalNAcT that catalyzes the synthesis of Forssman antigen, and the recently cloned iso-globotriaosylceramide synthase. Among the conserved residues, there are two Cys residues. To determine if these conserved residues are free or involved in the formation of a disulfide bond, bovine alpha1,3 GalT was characterized by chemical modification and mass spectrometry. Each peptide containing a Cys residue was chemically labeled with an alkylating reagent demonstrating that these enzymes do not contain disulfide bonds. Similar results have recently been reported for A and B transferases (Yen et al., 2000, J. Mass. Spectrom., 35, 990-1002). Thus, the highly conserved Cys residues found in these members of the alpha1,3 Gal(NAc)Ts family of enzymes are likely involved in other important aspects of enzyme structure/function within this enzyme family.     

The primary structure of cassowary (Casuarius casuarius) goose type lysozyme

The complete amino acid sequence of cassowary (Casuarius casuarius) goose type lysozyme was analyzed by direct protein sequencing of peptides obtained by cleavage with trypsin, V8 protease, chymotrypsin, lysyl endopeptidase, and cyanogen bromide. The N-terminal residue of the enzyme was deduced to be a pyroglutamate group by analysis with a LC/MS/MS system equipped with the oMALDI ionization source, and then confirmed by a glutamate aminopeptidase enzyme. The blocked N-terminal is the first reported in this enzyme group. The positions of disulfide bonds in this enzyme were chemically identified as Cys4-Cys60 and Cys18-Cys29. Cassowary lysozyme was proved to consist of 185 amino acid residues and had a molecular mass of 20408 Da calculated from the amino acid sequence. The amino acid sequence of cassowary lysozyme compared to that of reported G-type lysozymes had identities of 90%, 83%, and 81%, for ostrich, goose, and black swan lysozymes, respectively. The amino acid substitutions at PyroGlu1, Glu19, Gly40, Asp82, Thr102, Thr156, and Asn167 were newly detected in this enzyme group. The substituted amino acids that might contribute to substrate binding were found at subsite B (Asn122Ser, Phe123Met). The amino acid sequences that formed three alpha-helices and three beta-sheets were completely conserved. The disulfide bond locations and catalytic amino acid were also strictly conserved. The conservation of the three alpha-helices structures and the location of disulfide bonds were considered to be important for the formation of the hydrophobic core structure of the catalytic site and for maintaining a similar three-dimensional structure in this enzyme group.     

Primary structure and disulfide bridge location of arrowhead double-headed proteinase inhibitors.

Two arrowhead proteinase inhibitors (inhibitors A and B) were characterized and their primary structures were determined. Both inhibitors A and B are double-headed and multifunctional protease inhibitors. Inhibitor A inhibits an equimolar amount of trypsin and chymotrypsin simultaneously and weakly inhibits kallikrein. Inhibitor B inhibits two molecules of trypsin simultaneously and inhibits kallikrein more strongly than does inhibitor A. The amino acid sequences of inhibitors A and B were determined by sequencing the reduced and S-carboxamidomethylated proteins and their peptides produced by cyanogen bromide or proteolytic lysylendopeptidase or Staphylococcus aureus V8 protease cleavage. Inhibitors A and B consist of 150 amino acid residues with three disulfide bonds (Cys 43-Cys 89, Cys 110-Cys 119, and Cys 112-Cys 115) and share 90% sequence identity, with 13 different residues. Since the primary structures are totally different from those of all other serine protease inhibitors so far known, these inhibitors might be classified into a new protease inhibitor family.     

Complete amino acid sequence of the catalytic chain of human complement subcomponent C1-r

The amino acid sequence of human C1-r b chain hs been determined, from sequence analysis performed on fragments obtained by CNBr cleavage, dilute acid hydrolysis, tryptic cleavage of the succinylated protein, and subcleavages by staphylococcal protease. The polypeptide chain contains 242 amino acids (Mr 27 096), and the sequence shows strong homology with other mammalian serine proteases. The histidine, aspartic acid, and serine residues of the active site (His-57, Asp-102, and Ser-195 in bovine chymotrypsinogen) are located at positions 39, 94, and 191, respectively. The chain which lacks the "histidine-loop" disulfide bridge, contains five half-cystine residues, of which four (positions 157-176 and 187-217) are homologous to residues involved in disulfide bonds generally conserved in serine proteases, whereas the half-cystine residue at position 114 is likely to be involved in the single disulfide bridge connecting the catalytic b chain to the n-terminal a chain. Two carbohydrate moieties are attached to the polypeptide chain, both via asparagine residues at positions 51 and 118.     

Bovine brain acetylcholinesterase primary sequence involved in intersubunit disulfide linkages

Three distinct classes of membrane-bound acetylcholinesterases (AChEs) have been identified. A12 AChE is composed of 12 catalytic subunits that are linked to noncatalytic collagen-like subunits through intersubunit disulfide bonds. G2 AChE is localized in membranes by a glycoinositol phospholipid covalently linked to the C-terminal amino acid. Brain G4 AChE involves two catalytic subunits linked by a direct intersubunit disulfide bond while the other two are disulfide-linked to a membrane-binding 20-kDa noncatalytic subunit. Molecular cloning studies have so far failed to find evidence of more than one AChE gene in any organism although alternative splicing of torpedo AChE mRNA results in different C-terminal sequences for the A12 and G2 AChE forms. Support for a single bovine AChE gene is provided in this report by amino acid sequencing of the N-terminal domains from the G2 erythrocyte, G4 fetal serum, and G4 brain AChE. Comparison of the 38-amino acid sequences reveals virtually complete identity among the three AChE forms. Additional extensive identity between the fetal serum and brain AChEs was demonstrated by sequencing several brain AChE peptides isolated by high performance liquid chromatography after trypsin digestion of nitrocellulose blots of brain AChE catalytic subunits. Cysteines involved in intersubunit disulfide linkages in brain AChE were reduced selectively with dithiothreitol in the absence of denaturants and radioalkylated with iodoacetamide. The observed sequence of the major radiolabeled tryptic peptide was C*SDL, where C* was the radioalkylated cysteine residue. This sequence is precisely the same as that observed at the C terminus of fetal bovine serum AChE and shows close homology to the C-terminal sequence of torpedo A12 AChE. We conclude that the mammalian brain G4 AChEs utilize the same exon splicing pattern as the A12 AChEs and that factors other than the primary sequence of the AChE catalytic subunits dictate assembly with either the collagen-like or the 20-kDa noncatalytic subunits.     

Isolation and nucleotide sequence of cDNA clone for bovine pancreatic anionic trypsinogen. Structural identity within the trypsin family.

A cDNA clone encoding an anionic form of bovine trypsinogen was isolated from a pancreatic cDNA library. The corresponding 855-nucleotide mRNA contains a short 5' noncoding region of 8 nucleotides and a long 3' noncoding region of 56 nucleotides in addition to a poly(A) tail of at least 50 nucleotides. The deduced amino acid sequence for the anionic pretrypsinogen (247 residues) includes the N-terminal 15-amino-acid signal peptide followed by an 8-amino-acid activation peptide. The zymogen (232 residues) contains an additional C-terminal serine, compared with the amino acid sequence of bovine cationic trypsinogen. The identity between the anionic and cationic forms of bovine trypsinogen (65%) is lower than that existing between the anionic protein and other mammalian anionic trypsinogens (73-85%), suggesting that trypsin gene duplication in mammals occurred prior to the evolutionary events responsible for the species divergence. Bovine pancreatic anionic trypsin possesses all the key amino acids characteristic of the serine protease family.     

Amino acid sequence of a unique protease from the crayfish Astacus fluviatilis

The amino acid sequence of a protease from the crayfish Astacus fluviatilis has been determined from overlapping sets of peptides derived largely by cleavage at Met, Lys, or Arg residues. The protein comprises 200 amino acid residues in a single polypeptide chain, corresponding to a molecular mass of 22,614 daltons. Two disulfide bonds link Cys-42 to Cys-198 and Cys-64 to Cys-84. The sequence of this invertebrate protease appears to be unique since it has no homologous relationship to any of the known protein sequences.     

The amino acid sequence and reactive site of a single-headed trypsin inhibitor from wheat endosperm

The sequence of a trypsin inhibitor, isolated from wheat endosperm, is reported. The primary structure was obtained by automatic sequence analysis of the S-alkylated protein and of purified peptides derived from chemical cleavage by cyanogen bromide and digestion withStaphylococcus aureus V8 protease. This protein, named wheat trypsin inhibitor (WTI), which is comprised of a total of 71 amino acid residues, has 12 cysteines, all involved in disulfide bridges. The primary site of interaction (reactive site) with bovine trypsin has been identified as the dipeptide arginyl-methionyl at positions 19 and 20. WTI has a high degree of sequence identity with a number of serine proteinase inhibitors isolated from both cereal and leguminous plants. On the basis of the findings presented, this protein has been classified as a single-headed trypsin inhibitor of Bowman-Birk type.     

Partial amino acid sequence of porcine elastase II. Active site and the activation peptide regions

The partial amino acid sequence of porcine elastase II, isolated from crude trypsin Type II, was determined. The enzyme consists of two polypeptide chains, a light chain composed of 11 residues, and a heavy chain (Mr = 23 500) with four intrachain disulfide bridges; the two chains are held together by one interchain disulfide bond. Elastase II was fragmented into several peptides by chemical cleavages with CNBr at the two methionine residues, 99 and 180 (chymotrypsinogen numbering), and with hydroxylamine at the peptide bond following DIP-Ser195. About 50% of the sequence was determined and the positions of 120 amino acids were located, including the light chain residues and most of the active site residues. The partial sequence shows 64% difference between porcine elastase II and elastase I and only 26% difference between porcine elastase II and bovine chymotrypsin B.     

Glyceraldehyde-3-phosphate dehydrogenase. Investigation on the regions responsible for self-assembly of subunits

1. In glyceraldehyde-3-phosphate dehydrogenase (GAPDH) (EC 1.2.1.12) the four S-loop form the core of the tetramer. 2. Amino acid sequence of the S-loop of the regions of GAPDH from carp muscle was established through the analysis of tryptic digests of the enzyme treated alternatively with bromocyanate and o-iodosobenzoic acid. 3. Enzyme had been oxidized with performic acid. After treatment with trypsin the peptide mixture was fractionated into fragments. 4. CNBr cleavage of this enzyme was performed after S-carboxymethylation. The respective cyanogen bromide fragments have been isolated and characterized. 5. The procedure of protein fragmentation by o-iodosobenzoic acid used to split tryptophanyl peptide bonds. 6. Each peptide obtained after enzymatic or chemical fragmentation was purified to homogeneity by Bio-Gel or Sephadex chromatography, high voltage electrophoresis and descending paper chromatography and characterized by electrochromatography, N- and C-terminal sequence and amino acid composition. 7. The results are compared with those obtained from studies on GAPDH from other sources.