Your search keyword '"Kageyama, T."' showing total 28 results

1. Pepsinogens and pepsins from largemouth bass, Micropterus salmoides: purification and characterization with special reference to high proteolytic activities of bass enzymes.

Author

Miura Y, Kageyama T, and Moriyama A

Subjects

Amino Acid Sequence, Animals, Molecular Sequence Data, Pepsin A isolation & purification, Pepsinogens isolation & purification, Proteolysis, Stomach chemistry, Bass genetics, Pepsin A chemistry, Pepsinogens chemistry, Stomach enzymology

Abstract

Six pepsinogens were purified from the gastric mucosa of largemouth bass (Micropterus salmoides) by DEAE-Sephacel chromatography, Sephadex G-100 gel filtration, and Mono Q FPLC. The potential specific activities of two major pepsinogens, PG1-1 and PG2-2, against hemoglobin were 51 and 118 units/mg protein, respectively. The activity of pepsin 2-2 was the highest among the pepsins reported to date; this might be linked to the strongly carnivorous diet of the largemouth bass. The molecular masses of PG1-1 and PG2-2 were 39.0 and 41.0 kDa, respectively. The N-terminal amino acid sequences of PG1-1 and PG2-2 were LVQVPLEVGQTAREYLE- and LVRLPLIVGKTARQALLE-, respectively, showing similarities with those of fish type-A pepsinogens. The optimal pHs for hemoglobin-digestive activity of pepsins 1-1 and 2-2 were around 1.5 and 2.0, respectively, though both pepsins retained considerable activity at pHs over 3.5. They showed maximal activity around 50 and 40 °C, respectively. They were inhibited by pepstatin similarly to porcine pepsin A. The cleavage specificities clarified with oxidized insulin B chain were shown to be restricted to a few bonds consisting of hydrophobic/aromatic residues, such as the Leu(15)-Tyr(16), Phe(24)-Phe(25) and Phe(25)-Tyr(26) bonds. When hemoglobin was used as a substrate, the kcat/Km value of bass pepsin 2-2 was 4.6- to 36.8-fold larger than those of other fish pepsins. In the case of substance P, an ideal pepsin substrate mimic, the kcat/Km values were about 200-fold larger than those of porcine pepsin A, supporting the high activity of the bass pepsin., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

2. Differences in the P1' substrate specificities of pepsin A and chymosin.

Author

Kageyama H, Ueda H, Tezuka T, Ogasawara A, Narita Y, Kageyama T, and Ichinose M

Subjects

Animals, Haplorhini, Humans, Kinetics, Molecular Dynamics Simulation, Peptides chemistry, Peptides metabolism, Substrate Specificity, Chymosin metabolism, Pepsin A metabolism

Abstract

Porcine pepsin A and bovine chymosin are typical models of aspartic proteinases. The hydrolytic specificities of these proteinases, along with those of human pepsin A and monkey chymosin, were investigated with 29 peptide substrates that included various P1' variants of seven parent peptides. From these peptides, AFPLEF downward arrow FREL was preferred by pepsin A and chymosin, while its P1' variant, AFPLEF downward arrow EREL was preferred by bovine chymosin. Porcine and human pepsin A showed similar hydrolytic specificities, strongly preferring a hydrophobic/aromatic residue at P1' of any type of peptide. This specificity is well explained by the very hydrophobic nature of the S1' subsite that consists of Tyr(189), Ile(213), Ile(300), Met(289), Val/Leu(291) and Leu(298). The first three residues are well conserved in pepsin family enzymes. Although bovine and monkey chymosin showed similar P1' specificity, bovine chymosin preferred peptides having Glu at P1', while monkey chymosin preferred peptides having Lys at P1'. The dual characteristics of chymosin are due to the occurrence of polar/charged residues in the S1' subsite, such as Glu/Asp(289), Gln(298) and Lys/Gln(299), which are different from the S1' subsite of pepsin A. Molecular models suggest that Glu in position 289 of bovine chymosin and Asp in position 289 of monkey chymosin are responsible for the difference in P1' specificities between the chymosins.

Published

2010

3. Purification and characterization of pepsinogens from the gastric mucosa of African coelacanth, Latimeria chalumnae, and properties of the major pepsins.

Author

Tanji M, Yakabe E, Kageyama T, Yokobori S, Ichinose M, Miki K, Ito H, and Takahashi K

Subjects

Amino Acid Sequence, Animals, Dose-Response Relationship, Drug, Enzyme Activation, Molecular Sequence Data, Pepsin A chemistry, Pepsin A metabolism, Pepsinogens isolation & purification, Pepsinogens metabolism, Phylogeny, Sequence Homology, Amino Acid, Fishes genetics, Gastric Mucosa enzymology, Pepsin A genetics, Pepsinogens genetics

Abstract

Two major pepsinogens, PG1 and PG2, and one minor pepsinogen, PG3, were purified from the gastric mucosa of African coelacanth, Latimeria chalumnae (Actinistia). PG1 and PG2 were much less acidic than PG3. Their molecular masses were estimated by SDS-PAGE to be 37.0, 37.0 and 39.3 kD, respectively. When incubated at pH 2.0, PG1 and PG2 were converted autocatalytically to the mature pepsins through an intermediate form, whereas PG3 was converted to an intermediate form, but not to the mature pepsin autocatalytically. The N-terminal sequencing indicated that the 42 residue sequences of the propeptides of PG1 and PG2 were essentially identical with each other, but different from that of PG3. A phylogenetic tree based on the N-terminal propeptide sequences indicates that PG1 and PG2 belong to the pepsinogen A group, and PG3 to the pepsinogen C group. From the phylogenetic comparison, coelacanth PG1 and PG2 appear to be evolutionally closer to tetrapod pepsinogens A than ray-finned fish pepsinogens A, consistent with the traditional systematics. Pepsins 1 and 2 were essentially identical with each other and rather similar to mammalian pepsins A in the pH optimum toward hemoglobin (pH 2-2.5), the cleavage specificity toward oxidized insulin B chain and strong inhibition by pepstatin, except that they possessed a significant level of activity in the higher pH range unlike mammalian pepsins A.

Published

2007

4. Roles of Tyr13 and Phe219 in the unique substrate specificity of pepsin B.

Author

Kageyama T

Subjects

Animals, Binding Sites, Dogs, Humans, Hydrolysis, Kinetics, Models, Molecular, Mutation genetics, Pepsin A genetics, Phenylalanine genetics, Protein Structure, Tertiary, Structural Homology, Protein, Substrate Specificity, Tyrosine genetics, Pepsin A chemistry, Pepsin A metabolism, Phenylalanine metabolism, Tyrosine metabolism

Abstract

Pepsin B is known to be distributed throughout mammalia, including carnivores. In this study, the proteolytic specificity of canine pepsin B was clarified with 2 protein substrates and 37 synthetic octapeptides and compared with that of human pepsin A. Pepsin B efficiently hydrolyzed gelatin but very poorly hydrolized hemoglobin. It was active against only a group of octapeptides with Gly at P2, such as KPAGF/LRL and KPEGF/LRL (arrows indicate cleavage sites). In contrast, pepsin A hydrolyzed hemoglobin but not gelatin and showed high activity against various types of octapeptides, such as KPAEF/FRL and KPAEF/LRL. The specificity of pepsin B is unique among pepsins, and thus, the enzyme provides a suitable model for analyzing the structure and function of pepsins and related aspartic proteinases. Because Tyr13 and Phe219 in/around the S2 subsites (Glu/Ala13 and Ser219 are common in most pepsins) appeared to be involved in the specificity of pepsin B, site-directed mutagenesis was undertaken to replace large aromatic residues with small residues and vice versa. The Tyr13Ala/Phe219Ser double mutant of pepsin B was found to demonstrate broad activity against hemoglobin and various octapeptides, whereas the reverse mutant of pepsin A had significantly decreased activity. According to molecular modeling of pepsin B, Tyr13 OH narrows the substrate-binding space and a peptide with Gly at P2 might be preferentially accommodated because of its high flexibility. The hydroxyl can also make a hydrogen bond with nitrogen of a P3 residue and fix the substrate main chain to the active site, thus restricting the flexibility of the main chain and strengthening preferential accommodation of Gly at P2. The phenyl moiety of Phe219 is bulky and narrows the S2 substrate space, which also leads to a preference for Gly at P2, while lowering the catalytic activity against other peptide types without making a hydrogen-bonding network in the active site.

Published

2006

5. Role of S'1 loop residues in the substrate specificities of pepsin A and chymosin.

Author

Kageyama T

Subjects

Amino Acid Sequence, Animals, Cattle, Cebidae, Chymosin antagonists & inhibitors, Chymosin genetics, Humans, Hydrolysis, Molecular Sequence Data, Mutagenesis, Site-Directed, Oligopeptides metabolism, Pepsin A antagonists & inhibitors, Pepsin A genetics, Protein Structure, Secondary genetics, Recombinant Proteins antagonists & inhibitors, Recombinant Proteins biosynthesis, Recombinant Proteins genetics, Substrate Specificity genetics, Chymosin chemistry, Pepsin A chemistry

Abstract

Proteolytic specificities of human pepsin A and monkey chymosin were investigated with a variety of oligopeptides as substrates. Human pepsin A had a strict preference for hydrophobic/aromatic residues at P'1, while monkey chymosin showed a diversified preferences accommodating charged residues as well as hydrophobic/aromatic ones. A comparison of residues forming the S'1 subsite between mammalian pepsins A and chymosins demonstrated the presence of conservative residues including Tyr(189), Ile(213), and Ile(300) and group-specific residues in the 289-299 loop region near the C terminus. The group-specific residues consisted of hydrophobic residues in pepsin A (Met(289), Leu/Ile/Val(291), and Leu(298)) and charged or polar residues in chymosins (Asp/Glu(289) and Gln/His/Lys(298)). Because the residues in the loop appeared to be involved in the unique specificities of respective types of enzymes, site-directed mutagenesis was undertaken to replace pepsin-A-specific residues by chymosin-specific ones and vice versa. A yeast expression vector for glutathione-S-transferase fusion protein was newly developed for expression of mutant proteins. The specificities of pepsin-A mutants could be successfully altered to the chymosin-like preference and those of chymosin mutants, to pepsin-like specificities, confirming residues in the S'1 loop to be essential for unique proteolytic properties of the enzymes. An increase in preference for charged residues at P'1 in pepsin-A mutants might have been due to an increase in the hydrogen-bonding interactions. In chymosin mutants, the reverse is possible. The changes in the catalytic efficiency for peptides having charged residues at P'1 were dominated by k(cat) rather than K(m) values.

Published

2004

6. Primary structure, unique enzymatic properties, and molecular evolution of pepsinogen B and pepsin B.

Author

Narita Y, Oda S, Moriyama A, and Kageyama T

Subjects

Animals, Base Sequence, Cloning, Molecular, Dogs, Enzyme Activation physiology, Enzyme Stability physiology, Hydrogen-Ion Concentration, Hydrolysis, Molecular Sequence Data, Pepsin A isolation & purification, Pepsinogens isolation & purification, Phylogeny, Sequence Analysis, DNA, Sequence Analysis, Protein, Sequence Homology, Amino Acid, Stomach chemistry, Stomach enzymology, Substrate Specificity physiology, Evolution, Molecular, Pepsin A chemistry, Pepsin A genetics, Pepsinogens chemistry, Pepsinogens genetics

Abstract

Purification of pepsinogen B from dog stomach was achieved. Activation of pepsinogen B to pepsin B is likely to proceed through a one-step pathway although the rate is very slow. Pepsin B hydrolyzes various peptides including beta-endorphin, insulin B chain, dynorphin A, and neurokinin A, with high specificity for the cleavage of the Phe-X bonds. The stability of pepsin B in alkaline pH is noteworthy, presumably due to its less acidic character. The complete primary structure of pepsinogen B was clarified for the first time through the molecular cloning of the respective cDNA. Molecular evolutional analyses show that pepsinogen B is not included in other known pepsinogen groups and constitutes an independent cluster in the consensus tree. Pepsinogen B might be a sister group of pepsinogen C and the divergence of these two zymogens seems to be the latest event of pepsinogen evolution., (Copyright 2002 Elsevier Science (USA).)

Published

2002

7. Multiplicities and some enzymatic characteristics of ape pepsinogens and pepsins.

Author

Narita Y, Oda S, Takenaka O, and Kageyama T

Subjects

Amino Acids analysis, Animals, Digestion, Electrophoresis, Electrophoresis, Polyacrylamide Gel, Hemoglobins metabolism, Hydrogen-Ion Concentration, Molecular Weight, Pepsin A chemistry, Pepsin A classification, Pepsinogens chemistry, Pepsinogens classification, Hominidae metabolism, Pepsin A isolation & purification, Pepsinogens isolation & purification, Stomach enzymology

Abstract

Pepsinogen levels in ape stomachs were comparable to those in macaques and significantly higher than those in the stomachs of other mammals, including carnivores and ruminants. The occurrence of multiple forms of pepsinogens was remarkable. Nine, sixteen, eight, and fourteen pepsinogens were purified or partially purified from the gastric mucosa of a gibbon, orang-utan, gorilla, and chimpanzee, respectively. Most of these were type-A pepsinogens, and only one type-C pepsinogen was identified in each ape. The two types could be readily distinguished by staining for proteolytic activity on polyacrylamide gel electrophoresis (PAGE) in the presence/absence of pepstatin. Type-A pepsinogens were further divided into two subtypes. One subtype, constituting a major group of pepsinogens in apes, exhibited high hemoglobin-digestive activity. The other subtype was specified by a relatively high content of Lys and low hemoglobin-digestive activity. It is likely that pepsinogen-A genes have been duplicated several times as hominoids, including humans, evolved in the primate lineage. The presence of multiple pepsinogens in apes might be advantageous in the efficient digestion of a wide variety of foods.

Published

2000

8. Purification and characterization of goat pepsinogens and pepsins.

Author

Suzuki M, Narita Y, Oda S, Moriyama A, Takenaka O, and Kageyama T

Subjects

Abomasum chemistry, Amino Acid Sequence, Amino Acids analysis, Animals, Dose-Response Relationship, Drug, Goats, Hydrogen-Ion Concentration, Molecular Sequence Data, Pepsin A chemistry, Pepsinogen A chemistry, Sequence Homology, Amino Acid, Pepsin A isolation & purification, Pepsinogen A isolation & purification

Abstract

Three type-A and two type-C pepsinogens, namely, pepsinogens A-1, A-2, A-3, C-1, and C-2, were purified from adult goat abomasum. Their relative levels in abomasal mucosa were 27, 19, 14, 25, and 15%, respectively. Amino acid compositions were quite similar between isozymogens of respective types, but different between the two types especially in the Glx/Asx and Leu/Ile ratios. NH2-terminal amino acid sequences of pepsinogens A-3 and C-2 were SFFKIPLVKKKSLRQNLIEN- and LVKIPLKKFKSIRETM-, respectively. Pepsins A and C showed maximal hemoglobin-digestive activity at around pH 2 and 3, respectively, and specific activities of pepsins C were higher than those of pepsins A. Two subtypes of pepsin A were obvious, namely pepsin A-2/3 which maintains its activity in the weakly acidic pH region over pH 3 and pepsin A-1, which does not. Hydrolysis of oxidized insulin B chain by goat pepsins A occurred primarily at Ala14-Leu15 and Leu15-Tyr16 bonds.

Published

1999

9. Molecular cloning, expression and characterization of an Ascaris inhibitor for pepsin and cathepsin E.

Author

Kageyama T

Subjects

Amino Acid Sequence, Animals, Ascaris suum genetics, Base Sequence, Cathepsin E, Cloning, Molecular, DNA, Complementary, Kinetics, Molecular Sequence Data, Open Reading Frames, Protease Inhibitors pharmacology, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins pharmacology, Saccharomyces cerevisiae, Sequence Alignment, Sequence Homology, Amino Acid, Ascaris suum metabolism, Cathepsins antagonists & inhibitors, Pepsin A antagonists & inhibitors, Protease Inhibitors chemistry, Protease Inhibitors metabolism

Abstract

Molecular cloning of a cDNA for a pepsin inhibitor in the round worm, Ascaris suum, was achieved. The ORF was found to encode a 20-residue potential signal peptide and a 149-residue inhibitor moiety. Northern analysis showed the mRNA for the inhibitor to be expressed in the body wall and not in the viscera. To obtain the active inhibitor, we constructed a yeast expression vector, pYES2API, containing the inducible galactosidase promoter and a DNA fragment encoding a fusion protein of the yeast alpha-factor leader and the Ascaris pepsin inhibitor. The active inhibitor was secreted in the culture medium, the yield being approximately 3 mg x l(-1) x day(-1), and purified by a two-step procedure that included HPLC. The inhibitor inactivated pepsin A and cathepsin E almost completely at amounts equimolar with the enzymes, but was 100-fold less effective against pepsin C and did not act on cathepsin D and renin. Ki values for the inhibition of pepsin A and cathepsin E were in the nanomolar range below pH 5. Since the inhibitor activity was lost by modification of specific Lys residues, including Lys110, an electrostatic interaction between these Lys residues and Asp/Glu residues of pepsin A or cathepsin E was thought to be essential for the inhibition.

Published

1998

10. Pepsinogens and pepsins from house musk shrew, Suncus murinus: purification, characterization, determination of the amino-acid sequences of the activation segments, and analysis of proteolytic specificities.

Author

Narita Y, Oda S, Moriyama A, Takenaka O, and Kageyama T

Subjects

Amino Acid Sequence, Amino Acids analysis, Animals, Enzyme Activation, Hydrolysis, Molecular Sequence Data, Molecular Weight, Pepstatins metabolism, Protease Inhibitors metabolism, Shrews, Substrate Specificity, Endopeptidases metabolism, Pepsin A isolation & purification, Pepsinogens isolation & purification

Abstract

Three pepsinogens, namely, pepsinogens A, C-1, and C-2, were purified from gastric mucosa of adult house musk shrew (Suncus murinus) by conventional chromatographic and gel filtration procedures. The molecular masses were 40, 39, and 41 kDa for pepsinogens A, C-1, and C-2, respectively. Pepsinogen C-2 contains an Asn-linked carbohydrate chain(s) of about 2 kDa. Each pepsinogen was converted to pepsin through an intermediate form under acidic conditions. By NH2-terminal sequence analysis of these protein species, the amino acid sequences of activation segments (proparts) of pepsinogens A and C-1 were determined to be LYKVPLVKKKSLRQNLIENGLLKDFLAKHNVNPASKYFPTE and KVTKVTLKKFKSIRENLREQGLLEDFLKTNHYDPAQKYHFGDF, respectively. The similarity of these two sequences is nearly 50%. Each pepsin cleaved preferentially peptide bonds between hydrophobic and aromatic amino acids, or bonds on either side of these amino acids. Although each activation segment had several sites susceptible to pepsin action, activation proceeded by limited cleavages of the segment, presumably due to the steric inflexibility of the segment in native pepsinogen. The activity of pepsin A was inhibited completely in the presence of a more than equimolar amount of pepstatin, while a hundred-molar excess amount of pepstatin was needed for the complete inhibition of the activity of pepsins C-1 and C-2.

Published

1997

11. Non-mammalian vertebrate pepsinogens and pepsins: isolation and characterization.

Author

Takahashi K, Tanji M, Yakabe E, Hirasawa A, Athauda SB, and Kageyama T

Subjects

Amino Acid Sequence, Animals, Binding Sites, Cathepsin D chemistry, Chick Embryo, Enzyme Precursors chemistry, Enzyme Precursors isolation & purification, Humans, Isoenzymes chemistry, Isoenzymes isolation & purification, Mammals, Molecular Sequence Data, Pepsinogens genetics, Phylogeny, Sequence Homology, Amino Acid, Turtles, Vertebrates, Pepsin A chemistry, Pepsin A isolation & purification, Pepsinogens chemistry, Pepsinogens isolation & purification

Published

1995

12. Asian macaque pepsinogens and pepsins.

Author

Kageyama T

Subjects

Amino Acids analysis, Animals, Asia, Body Weight, Enzyme Stability, Female, Hydrogen-Ion Concentration, Isoenzymes chemistry, Isoenzymes isolation & purification, Isoenzymes metabolism, Male, Organ Size, Pepsin A chemistry, Pepsin A isolation & purification, Pepsinogens chemistry, Pepsinogens isolation & purification, Species Specificity, Swine, Gastric Mucosa enzymology, Macaca metabolism, Pepsin A metabolism, Pepsinogens metabolism

Abstract

Five pepsinogens were purified from the gastric mucosa of eight species of Asian macaques. The chromatographic behavior of each pepsinogen was essentially the same but differed from human and other mammalian pepsinogens. The major pepsinogen in each species was pepsinogen A-1, accounting for 29-48% of the total. Amino acid compositions and some enzymatic properties of derived pepsins were similar for the various monkey species. This high degree of similarity confirms that these species are closely related to one another.

Published

1994

13. Purification, characterization, and amino acid sequences of pepsinogens and pepsins from the esophageal mucosa of bullfrog (Rana catesbeiana)

Author

Yakabe E, Tanji M, Ichinose M, Goto S, Miki K, Kurokawa K, Ito H, Kageyama T, and Takahashi K

Subjects

Amino Acid Sequence, Animals, Base Sequence, Chromatography, Gel, Chromatography, Ion Exchange, Cloning, Molecular, DNA genetics, DNA isolation & purification, Electrophoresis, Polyacrylamide Gel, Enzyme Activation, Humans, Immunodiffusion, Isoenzymes metabolism, Kinetics, Molecular Sequence Data, Molecular Weight, Mucous Membrane enzymology, Pepsin A genetics, Pepsin A metabolism, Pepsinogens genetics, Pepsinogens metabolism, Phylogeny, Rana catesbeiana, Restriction Mapping, Esophagus enzymology, Isoenzymes isolation & purification, Pepsin A isolation & purification, Pepsinogens isolation & purification

Abstract

Two pepsinogens (pepsinogens 1 and 2) were purified from the esophageal mucosa of the bullfrog (Rana catesbeiana), and their molecular weights were determined to be 40,100 and 39,200, respectively, by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The NH2-terminal 70-residue sequences of both pepsinogens are the same, including the 36-residue activation segment. Furthermore, a cDNA clone encoding frog pepsinogen was obtained and sequenced, which permitted deduction of the complete amino acid sequence (368 residues) of one of the pepsinogen isozymogens. The calculated molecular weight of the protein (40,034) coincided well with the values obtained by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. These results are incompatible with the previous report (Shugerman R. P., Hirschowitz, B. I., Bhown, A. S., Schrohenloher, R. E., and Spenney, J. G. (1982) J. Biol. Chem. 257, 795-798) that the major pepsinogen isolated from the bullfrog esophageal gland is a unique "mini" pepsinogen with a molecular weight of approximately 32,000-34,000. The two pepsinogens were immunologically indistinguishable from each other and related to human pepsinogen C. The deduced amino acid sequence was also more homologous with those of pepsinogens C than those of pepsinogens A and prochymosin. These results indicate that the frog pepsinogens belong to the pepsinogen C group. They were both glycoproteins, and therefore, this is the first finding of carbohydrate-containing pepsinogens C. Both pepsinogens were activated to pepsins in the same manner by an apparent one-step mechanism. The resulting pepsins were enzymatically indistinguishable from each other, and their properties resembled those of tuna pepsins.

Published

1991

14. Monkey pepsinogens and pepsins. Monkey pepsinogens and pepsins. V. Purification, Characterization, and amino-terminal sequence determination of crab-eating monkey pepsinogens and pepsins.

Author

Kageyama T and Takahashi K

Subjects

Amino Acid Sequence, Animals, Hydrogen-Ion Concentration, Macaca fascicularis, Molecular Weight, Pepsinogens isolation & purification, Gastric Mucosa enzymology, Pepsin A metabolism, Pepsinogens metabolism

Abstract

Pepsinogens were purified from the gastric mucosa of the crab-eating monkey, Macaca fascicularis. Eight pepsinogens were shown to be present disc-electrophoretically and they were termed pepsinogens I-a, I-b, III-1-a, III-1-b, III-2-a, III-2-b, III-3, and C, based on the nomenclature used for Japanese monkey pepsinogens. The molecular weights were 43,000 for pepsinogens I-a and I-b, 40,000 for pepsinogens III-1-a, III-1-b, III-2-a, III-2-b, and III-3, and 38,000 for pepsinogen C, as determined by sodium dodecyl sulfate-polyacrylamide disc gel electrophoresis. Pepsinogens I-a and I-b contained carbohydrate amounting to about 4-5% by weight. Each was activated to pepsin by acidification at pH 2.0. Pepsinogen III-1 (a mixture of III-1-a and III-1-b) yielded a single pepsin, i.e. pepsin III-1, and pepsinogen III-2 (a mixture of III-2-a and III-2-b) also gave a single pepsin, i.e. pepsin III-2. The molecular weights were estimated to be 38,000 for pepsins I-a and I-b, 35,000 for pepsins III-1, III-2, and III-3, and 34,000 for pepsin C. Optimal pHs toward acid-denatured hemoglobin were 1.9, 2.3, 2.0, 2.0, and 2.3 for pepsins I-a, III-1, III-2, III-3, and C, respectively. Pepstatin, diazoacetyl-DL-norleucine methyl ester (DAN), 1,2-epoxy-3-(p-nitrophenoxy)propane (EPNP), and p-bromophenacyl bromide inhibited each pepsin. Amino acid compositions of the pepsinogens and pepsins were determined. Pepsinogen C and pepsin C were distinct from the other pepsinogens and pepsins in their high ratios of glutamic acid to aspartic acid, and leucine to isoleucine. Amino acid sequences of the amino (N)-terminal 14 residues of pepsinogens were determined by the manual Edman procedure. One to three substitutions of amino acids were observed in the 14-residue segments among the pepsinogens except for pepsinogen C. There were 7 amino acid substitutions between pepsinogens C and III-3. These results suggest that the amino acid substitutions in the N-terminal region contribute considerably to the heterogeneity of pepsinogens.

Published

1980

15. [Relationship between serum pepsinogen levels and gastric acid-pepsin secretion].

Author

Chang CM, Miki K, Furihata C, Kageyama T, Ichinose M, Niwa H, Oka H, Matsushima T, and Takahashi K

Subjects

Female, Humans, Male, Middle Aged, Peptic Ulcer metabolism, Radioimmunoassay, Gastric Acid metabolism, Pepsin A metabolism, Pepsinogens blood

Published

1983

16. Purification and characterization of pepsinogens and pepsins from Asiatic black bear, and amino acid sequence determination of the NH2-terminal 60 residues of the major pepsinogen.

Author

Kageyama T, Moriyama A, and Takahashi K

Subjects

Amino Acid Sequence, Animals, Carbohydrates analysis, Chemical Phenomena, Chemistry, Chromatography, DEAE-Cellulose, Gastric Mucosa analysis, Molecular Weight, Peptide Hydrolases analysis, Carnivora metabolism, Pepsin A isolation & purification, Pepsinogens isolation & purification, Ursidae metabolism

Abstract

Five pepsinogens were purified to homogeneity from the gastric mucosa of Asiatic black bear and termed pepsinogens I-1, I-2, II-1, II-2, and III. Pepsinogen II-1 was the major component and accounted for more than half of the total pepsinogens. Their molecular weights were estimated to be 40,000 for pepsinogens I-1 and I-2, 38,000 for pepsinogens II-1 and II-2, and 42,000 for pepsinogen III. They resembled each other in amino acid composition, except that pepsinogens I-1 and I-2 contained larger numbers of basic residues than the others. Pepsinogen III was a glycoprotein containing about 3.7% carbohydrate. Each was activated to the corresponding pepsin and their enzymatic characteristics were investigated. The optimal pH against hemoglobin was about 2.2 for pepsin I-1, and about 2.5 for pepsins II-1, II-2, and III. Each pepsin was inhibited by pepstatin as well as porcine pepsin and also by diazoacetyl-DL-norleucine methyl ester, 1,2-epoxy-3-(p-nitrophenoxy)-propane, and p-bromophenacyl bromide. Each pepsin could hydrolyze N-acetyl-L-phenylalanyl-3,5-diiodo-L-tyrosine, but the specific activity was much lower than that of porcine pepsin. Activation peptides corresponding to residues 1-43, 1-25, and 26-43 were isolated from an activation mixture of pepsinogen II-1. The amino acid sequences of these peptides and of the NH2-terminal portions of pepsinogen II-1 and pepsin II-1 were determined, resulting in the complete NH2-terminal 60-residue sequence of pepsinogen II-1.

Published

1983

17. Identification of monkey lung procathepsin D-II as a pepsinogen-C-like acid protease zymogen.

Author

Moriyama A, Kageyama T, and Takahashi K

Subjects

Amino Acids analysis, Animals, Cathepsin D, Electrophoresis, Polyacrylamide Gel, Enzyme Activation, Hydrogen-Ion Concentration, Immunochemistry, Macaca, Peptide Hydrolases, Rabbits, Structure-Activity Relationship, Cathepsins isolation & purification, Enzyme Precursors isolation & purification, Lung enzymology, Pepsin A, Pepsinogens

Abstract

Procathepsin D-II (Mr = 37 500) was purified from Japanese monkey lung at pH 7.0, and was shown to be converted to the active form, cathepsin D-II (Mr = 33 000) via an intermediate (Mr = 35 500) upon treatment at pH 3.0 and 14 degrees C. Procathepsin D-II was shown to be the inactive precursor of cathepsin D-II based on the following results: the former was inactive toward heat-denaturated casein at pH 5.4 whereas the latter was active; the former was not inactivated by diazoacetyl-DL-norleucine methyl ester in the presence of Cu2+ ion at pH 6.0 whereas the latter was inactivated rapidly under the same conditions; and the former had no affinity to pepstatin-Sepharose between pH 5 and 7 whereas the latter was adsorbed to it. With a rabbit antiserum against procathepsin D-II, cathepsin D-II, pepsinogen C and pepsin C of Japanese monkey were each found to give a single precipitin line which fused completely with each other on agarose plate. On the other hand, cathepsin D-I purified from the monkey lung, and pepsinogens A (I, II, III-1, III-2 and III-3) obtained from the monkey gastric mucosa failed to precipitate with the antiserum. With the antiserum against the monkey pepsinogen C, the same results were obtained. Further, procathepsin D-II and pepsinogen C were shown to have the same amino-terminal amino acid sequence, Ala-Val-Val-Lys-Val-Pro-Leu-Lys-Lys-Phe-Lys-. All these results indicate a strong similarity of procathepsin D-II and cathepsin D-II to pepsinogen C and pepsin C, respectively.

Published

1983

18. Monkey pepsinogens and pepsins. VI. One-step activation of Japanese monkey pepsinogen to pepsin.

Author

Kageyama T and Takahashi K

Subjects

Animals, Chemical Phenomena, Chemistry, Enzyme Activation drug effects, Hydrogen-Ion Concentration, Macaca, Pepstatins pharmacology, Spectrophotometry, Ultraviolet, Pepsin A biosynthesis, Pepsinogens metabolism

Abstract

When Japanese monkey pepsinogen was activated at pH 2.0 in the absence of pepstatin, the activation segment of the amino(N)-terminal 47 residues was released as a single intact polypeptide. This clearly shows that the pepsinogen was activated to pepsin directly. This direct activation was called a 'one-step' process. On the other hand, when pepsinogen was activated at pH 2.0 in the presence of pepstatin, an appreciable amount of pepsinogen was converted to an intermediate form between pepsinogen and pepsin, although a part of pepsinogen was activated directly to pepsin. The intermediate form was generated by releasing the N-terminal 25 residues of pepsinogen. This activation through the intermediate form is thought to be a 'two-step' or 'stepwise-activating' process involving a bimolecular reaction between pepstatin-bound pepsinogen and free pepsin.

Published

1982

19. A comparative study on the NH2-terminal amino acid sequences and some other properties of six isozymic forms of human pepsinogens and pepsins.

Author

Athauda SB, Tanji M, Kageyama T, and Takahashi K

Subjects

Amino Acid Sequence, Carbohydrates analysis, Enzyme Activation, Gastric Mucosa enzymology, Humans, Molecular Sequence Data, Phosphates analysis, Isoenzymes isolation & purification, Isoenzymes metabolism, Pepsin A isolation & purification, Pepsin A metabolism, Pepsinogens isolation & purification, Pepsinogens metabolism

Abstract

Six pepsinogen isozymogens, including five forms of pepsinogen A (PGA) and an apparently single form of pepsinogen C (PGC), were isolated simultaneously from the purified total pepsinogen fraction of human gastric mucosa by fast protein liquid chromatography on a Mono Q column, and their NH2-terminal amino acid sequences and some other properties were compared. Upon activation at pH 2.0, all the isozymogens were converted to the corresponding pepsins in a stepwise manner through intermediate forms. The activation rates and the cleavage sites in the activation peptide segment to generate intermediate forms were significantly different among the isozymogens. The NH2-terminal 85-residue amino acid sequences of these isozymogens were determined, including the sequences of the activation peptide segments and the NH2-terminal regions of the corresponding pepsins. Differences in amino acid sequence were found at positions 43 and 77 among the pepsinogen A isozymogens; the residue at position 43 was Lys in PGA-5, PGA-4, and PGA-3a, and Glu in PGA-3 and PGA-2, and the residue at position 77 was Leu in PGA-5 and PGA-4 and Val in PGA-3 and PGA-2. Phosphate was not found in any of the isozymogens. The corresponding pepsins also showed significant variations in properties such as specific activities toward synthetic and protein substrates, pH dependence of activity, susceptibility to various inhibitors, and thermal and alkaline stabilities.

Published

1989

20. Monkey pepsinogens and pepsins. VII. Analysis of the activation process and determination of the NH2-terminal 60-residue sequence of Japanese monkey progastricsin, and molecular evolution of pepsinogens.

Author

Kageyama T and Takahashi K

Subjects

Amino Acid Sequence, Animals, Biological Evolution, Enzyme Activation, Humans, Macaca physiology, Molecular Weight, Mutation, Species Specificity, Enzyme Precursors metabolism, Pepsin A metabolism, Pepsinogens genetics

Abstract

Japanese monkey progastricsin was shown to be activated to gastricsin exclusively by a two-step process through an intermediate form. The occurrence of this process was substantiated by the isolation of the intermediate form and released peptides. By NH2-terminal sequence analyses of these protein and peptide species, the amino acid sequence of the 43-residue activation segment (propart) was determined to be as follows: (Formula: see text) The NH2-terminal 26-residue peptide was released first, resulting in generation of the intermediate form. The subsequent release of peptides, residues Nos. 27-40 and 27-43, generated two gastricsins as the final products. This two-step process of activation of Japanese monkey progastricsin is in striking contrast to the one-step activation process occurring exclusively for pepsinogen A of the same monkey species. The course of molecular evolution of pepsinogens including progastricsins was deduced from the amino acid sequences of their activation segments by constructing phylogenic trees. The trees divided pepsinogens into 3 clusters, i.e., pepsinogens A, progastricsins and prochymosin, showing that these three groups diverged from one another very early on in the course of the evolution of pepsinogens.

Published

1985

21. Occurrence of two different pathways in the activation of porcine pepsinogen to pepsin.

Author

Kageyama T and Takahashi K

Subjects

Amino Acids analysis, Animals, Chemical Phenomena, Chemistry, Enzyme Activation, Peptide Fragments isolation & purification, Swine, Pepsin A biosynthesis, Pepsinogens metabolism

Abstract

Activation of porcine pepsinogen at pH 2.0 was found to proceed simultaneously by two different pathways. One pathway is the direct conversion process of pepsinogen to pepsin, releasing the intact activation segment. The isolation of the released 44-residue segment was direct evidence of this one-step process. At pH 5.5 the segment bound tightly to pepsin to form a 1:1 pepsin-activation segment complex, which was chromatographically indistinguishable from pepsinogen. The other is a stepwise-activating or sequential pathway, in which pepsinogen is activated to pepsin through intermediate forms, releasing activation peptides stepwisely. These intermediate forms were isolated and characterized. The major intermediate form was shown to be generated by removal of the amino-terminal 16 residues from pepsinogen. The released peptide mixture was composed of two major peptides comprising residues 1-16 and 17-44, and hence the stepwise-activating process was deduced to be mainly a two-step process.

Published

1983

22. Monkey pepsinogens and pepsins. III. Carbohydrate moiety of Japanese monkey pepsinogens and the amino acid sequence around the site of its attachment to protein.

Author

Kageyama T and Takahashi K

Subjects

Amino Acid Sequence, Amino Acids analysis, Animals, Carbohydrates analysis, Glycopeptides analysis, Haplorhini, Peptide Fragments analysis, Protein Binding, Pepsin A, Pepsinogens

Abstract

Purified Japanese monkey pepsinogens I and II contain carbohydrate as a part of the enzyme molecule. By gel filtration on Sephadex G-100, chromatography on DE-32 cellulose, and polyacrylamide disc gel electrophoresis, the carbohydrate moiety could not be separated from the enzyme protein, and the content did not decrease on repeated chromatography. Glycopeptides were obtained by successive digestion of pepsinogens with thermolysin and aminopeptidases and isolated by chromatography on Sephadex G-25 and G-50. Identification and determination of carbohydrate components was performed by paper and gas-liquid chromatographies. The presence of 4 glucosamines, 6 galactoses, 6--8 mannoses, and 8--11 fucoses per molecule of the glycopeptide of both pepsinogens was observed, of which the high content of fucose is especially unique. The molecular weight of the carbohydrate chains should be around 4,000--5,000. The amino acid sequence of a major glycopeptide was deduced to be Ile-Gly-Ile-Gly-Thr-Pro-Gln-Ala-Asn, in which the asparagine residue is the site of attachment of the carbohydrate chain.

Published

1978

23. Monkey pepsinogens and pepsins. IV. The amino acid sequence of the activation peptide segment of Japanese monkey pepsinogen.

Author

Kageyama T and Takahashi K

Subjects

Amino Acid Sequence, Animals, Cattle, Chemical Phenomena, Chemistry, Enzyme Activation, Kinetics, Macaca, Peptide Fragments analysis, Species Specificity, Swine, Pepsin A metabolism, Pepsinogens metabolism

Abstract

The complete amino acid sequence of the activation peptide segment of the major component of Japanese monkey pepsinogens was determined. The pepsinogen was converted to pepsin by incubation at pH 2.0 and 14 degrees C for 17 min. The activation peptides were separated from the resulting pepsin and purified by chromatography on columns of sulfopropyl (SP)-Sephadex. One 25-residue peptide and two 22-residue peptides were isolated and their amino acid sequences were determined. The results showed that the former peptide was derived from the amino-terminal half (residues no. 1 to 25) and the latter peptides from the carboxyl-terminal half (residues no. 26 to 47) of the activation segment. The latter two peptides were identical except for a single amino acid replacement. The complete amino acid sequence of the whole activation peptide segment was thus deduced as follows: Ile1-Ile-Tyr-Lys-Val-Pro-Leu-Val-Arg-Lys10-Lys-Ser-Leu-Arg-Arg-Asn-Leu-Ser-Glu- His20-Gly-Leu-Leu-Lys-Asp-Phe-Leu-Lys-Lys-His30-Asn-Leu-Asn-Pro-Ala-Ser-Lys-Tyr -Phe-Pro40-LysGln-Ala-Glu-Ala-Pro-Thr-Leu47. The whole chain was composed of 47 residues, and cleaved into two polypeptides by the cleavage of Asp25-Phe26 bond during activation. Two amino acids were detected at residue-41, i.e., glutamine and lysine, indicating the presence of two closely related pepsinogens in the sample used. The total number of residues (47) of the whole activation peptide segment is 3 and 2 residues larger than those of porcine pepsinogen and bovine pepsinogen, respectively. The differences are 15 and 22 residues as compared with porcine pepsinogen and bovine pepsignogen, respectively.

Published

1980

24. Rabbit pepsinogens. Purification, characterization, analysis of the conversion process to pepsin and determination of the NH2-terminal amino-acid sequences.

Author

Kageyama T and Takahashi K

Subjects

Amino Acid Sequence, Animals, Chemical Phenomena, Chemistry, Chromatography methods, Enzyme Activation, Gastric Mucosa analysis, Pepsinogens metabolism, Rabbits, Pepsin A biosynthesis, Pepsinogens isolation & purification

Abstract

Six pepsinogens were purified from the gastric mucosa of adult rabbits by chromatographies on DEAE-cellulose, DEAE-Sephacel and Sephadex G-150. They were designed as pepsinogen I, pepsinogens II-1, II-2, II-3, and II-4, and pepsinogen III, based on their chromatographic behaviors. Each pepsinogen was converted to pepsin at pH 2.0 and 14 degrees C. The resulting pepsins had roughly similar enzymatic properties. However, activation processes appeared to differ significantly among them. Pepsinogen I was converted to an active intermediate form by sequentially releasing the NH2-terminal 25 or 26 residues. This active form was fairly stable and no further conversion occurred on further incubation for several hours. Pepsinogens II were converted to pepsins partly sequentially through intermediate forms and partly directly releasing the NH2-terminal 44 residues as a single intact polypeptide. Pepsinogen III appeared to be converted to pepsin directly without forming intermediate species. The amino acid sequences of the activation segments of these pepsinogens were determined together with the sequences in the NH2-terminal regions of the resulting pepsins. Five distinct sequences were identified, indicating that most of these pepsinogens are the products of different genes.

Published

1984

25. Tuna pepsinogens and pepsins. Purification, characterization and amino-terminal sequences.

Author

Tanji M, Kageyama T, and Takahashi K

Subjects

Amino Acid Sequence, Amino Acids analysis, Animals, Electrophoresis, Polyacrylamide Gel, Enzyme Activation, Humans, Hydrogen-Ion Concentration, Immunodiffusion, Kinetics, Molecular Sequence Data, Molecular Weight, Pepsin A isolation & purification, Pepsinogens isolation & purification, Turtles, Biological Evolution, Fishes metabolism, Gastric Mucosa enzymology, Pepsin A metabolism, Pepsinogens metabolism, Tuna metabolism

Abstract

Three pepsinogens (pepsinogens 1, 2, and 3) were purified from the gastric mucosa of the North Pacific bluefin tuna (Thunnus thynuus orientalis). Their molecular masses were determined to be 40.4 kDa, 37.8 kDa, and 40.1 kDa, respectively, by SDS/polyacrylamide gel electrophoresis. They contained relatively large numbers of basic residues when compared with mammalian pepsinogens. Upon activation at pH 2.0, pepsinogens 1 and 2 were converted to the corresponding pepsins, in a stepwise manner through intermediate forms, whereas pepsinogen 3 was converted to pepsin 3 directly. The optimal pH of each pepsin for hemoglobin digestion was around 2.5. N-acetyl-L-phenylalanyl-L-diiodotyrosine was scarcely hydrolyzed be each pepsin. Pepstatin, diazoacetyl-DL-norleucine methyl ester in the presence of Cu2+, 1,2-epoxy-3-(p-nitrophenoxy)propane and p-bromophenacyl bromide inhibited each pepsin, although the extent of inhibition by each reagent differed significantly among the three pepsins. The amino acid sequences of the activation segments of these pepsinogens were determined together with the sequences of the NH2-terminal regions of pepsins. Similarities in the activation segment region among the three tuna pepsinogens were rather low, ranging over 28-56%. A phylogenetic tree for 16 aspartic proteinase zymogens including the three tuna pepsinogens was constructed based on the amino acid sequences of their activation segments. The tree indicates that each tuna pepsinogen diverged from a common ancestor of pepsinogens A and C and prochymosin in the early period of pepsinogen evolution.

Published

1988

26. Analysis of the activation of pepsinogen in the presence of protein substrates and estimation of the intrinsic proteolytic activity of pepsinogen.

Author

Kageyama T

Subjects

Amino Acid Sequence, Animals, Enzyme Activation, Hemoglobins analysis, Hydrogen-Ion Concentration, Kinetics, Macaca, Molecular Sequence Data, Muramidase analysis, Swine, Temperature, Time Factors, Pepsin A biosynthesis, Pepsinogens metabolism

Abstract

Monkey pepsinogen A, monkey progastricsin, and porcine pepsinogen A were activated in the presence of two different protein substrates, namely, reduced and carboxymethylated lysozyme and hemoglobin. In each case, an extensive delay in activation was observed. The intermolecular activation reaction required for the generation of pepsin or gastricsin was strongly inhibited and this inhibition was essentially responsible for the delay. However, the intramolecular reaction required for the generation of the intermediate forms of the proenzymes was scarcely affected. The delay was longer at pH 3.0 than at pH 2.0. Irrespective of the delay in activation of pepsinogen, the digestion of substrates proceeded rapidly, evidence of the significant proteolytic activity of pepsinogen itself. Kinetic experiments demonstrated that pepsinogen changed from an enzymatically inactive species to an active species before the release of the activation segment. The proteolytic activity of the active pepsinogen was highest at pH 2.0, at 37 degrees C and the activity under these conditions was comparable to that of pepsin.

Published

1988

27. Pepsinogens and pepsins from gastric mucosa of Japanese Monkey. Purification and characterization.

Author

Kageyama T and Takahashi K

Subjects

Amino Acids analysis, Animals, Female, Haplorhini, Macaca, Male, Molecular Weight, Pepsinogens isolation & purification, Pepstatins pharmacology, Protein Denaturation, Gastric Mucosa enzymology, Pepsin A metabolism, Pepsinogens metabolism

Abstract

Five pepsinogens were purified from gastric mucosa of Japanese monkey by DEAE-cellulose column chromatography and Sephadex G-100 gel filtration. Each was shown to be homogeneous by polyacrylamide disc gel electrophoresis. They were designated as pepsinogens I, II, III-1, III-2, and III-3, respectively, based on the elution profile on DEAE-cellulose chromatography. The molecular weights of pepsinogens I and II were 48,000 and 43,000, respectively, and those of the other three were 40,000. Each pepsinogen was converted to pepsin [EC 3.4.23.1] by acidification, and some characteristics, e.g. the pH dependence of activity, sensitivity to various inhibitors, stability to alkali, and hydrolytic activity toward N-acetyl-L-phenylalanyl-3,5-diiodo-L-tyrosine (APDT), were determined. The characteristics of pepsins I and II were the same, and those of pepsins III-1, III-2, and III-3 were similar. Pepsin III-3 showed high stability to alkali (pH 8.0), while the others were less stable. Each pepsin hydrolyzed APDT and was inhibited by acid protease-specific inhibitors, e.g. pepstain, diazoacetyl-DL-norleucine methyl ester (DAN), 1,2-epoxy-3-(p-nitrophenoxy)propane (EPNP), and p-bromophenacyl bromide. The compositions of pepsins I and II were the same, indicating that they are the same protein, and those of pepsins III-1, III-2, and III-3 resembled that of human pepsin. The diversity of pepsinogens and pepsins is discussed in comparison with pepsinogens and pepsins from other animals.

Published

1976

28. Pepsinogen C and pepsin C from gastric mucosa of Japanese monkey. Purification and characterization.

Author

Kageyama T and Takahashi K

Subjects

Amino Acids analysis, Animals, Azo Compounds pharmacology, Epoxy Compounds pharmacology, Haplorhini, Hydrogen-Ion Concentration, Macaca, Molecular Weight, Nitrophenols pharmacology, Norleucine analogs & derivatives, Norleucine pharmacology, Pepsinogens isolation & purification, Pepstatins pharmacology, Phenylacetates pharmacology, Gastric Mucosa enzymology, Pepsin A metabolism, Pepsinogens metabolism

Abstract

A new pepsinogen component, pepsinogen C, was purified from the gastric mucosa of Japanese monkey. The chromatographic behavior of this component on DE-32 cellulose was coincident with that of pepsinogen III-2 previously reported (1), and final purification was performed by large-scale polyacrylamide disc gel electrophoresis. The molecular weight was 35,000 as determined by gel filtration. The ratios of glutamic acid to aspartic acid and of leucine to isoleucine were higher than those of other Japanese monkey pepsinogens. The activated form, pepsin C, had a molecular weight of 27,000 and contained a large number of glutamic acid residues. The optimal pH for hemoglobin digestion was 3.0. Pepsin C could scarcely hydrolyze the synthetic substrate, N-acetyl-L-phenylalanyl-3, 5-diiodo-L-tyrosine (APDT). 1, 2-Epoxy-3-(p-nitrophenoxy)propane (EPNP), p-bromophenacyl bromide, and diazoacetyl-DL-norleucine methyl ester (DAN) inhibited pepsin C [EC 3.4.23.3] in the same way as pepsin III-3 of Japanese monkey. The susceptibility to pepstatin of pepsin C was lower than that of pepsin III-3, and 500 times more pepstatin was required for the same inhibitory effect. The classification and nomenclature of Japanese monkey pepsinogens and pepsins are discussed.

Published

1976