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

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.     

Purification and characterization of rat pepsinogens whose contents increase with developmental progress.

Two pepsinogens, the contents of which increase with developmental progress, were purified from the gastric mucosa of the adult rat by ammonium sulfate fractionation and chromatography on DEAE-cellulose and DEAE-Sepharose CL-6B columns. The purified zymogens, designated as pepsinogens I and II, were each shown to be homogeneous by polyacrylamide gel disc electrophoresis. Pepsinogen II had a greater electrophoretic mobility toward the anode at pH 8.0 than pepsinogen I. The molecular weights of both zymogens were estimated to be 38,000 by SDS-polyacrylamide gel electrophoresis. The activated enzymes, pepsins I and II, each had the same molecular weight of 32,000. The pH optima for both enzymes were found to be 2.0. The enzymes showed high stabilities at pH 8.0, while they lost their activities within 60 min at pH 10.0. The enzymes were inhibited by pepstatin and diazoacetyl-DL-norleucine methyl ester (DAN). The activities of the enzymes in hydrolyzing N-acetyl-L-phenylalanyl-3,5-diiodo-L-tyrosine (APDT) were about 1/8 of that of porcine pepsin. These results suggest that pepsins I and II are very similar.     

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

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.     

Asian macaque pepsinogens and pepsins

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.     

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

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.     

The pathway of pepsin-catalysed transpeptidation. Evidence for the reactive species being the anion of the acceptor molecule

Several minor pepsinogens, present in extracts of bovine fundic mucosa obtained from the fourth stomach or abomasum, were separated from the main pepsinogen by chromatography on hydroxyapatite at pH7.3. The major pepsinogen and two of these minor pepsinogens were studied in detail. All three zymogens have N-terminal Ser-Val-, C-terminal -Val-Ala and not more than 1mol of glucose/mol of protein; no significant differences in amino acid composition were found. The pepsinogens differ in their organic phosphate content, which accounts for their chromatographic separation. By activation at 0 degrees C and pH2, a corresponding series of pepsins is formed. These enzymes were separated by hydroxyapatite chromatography at pH5.7. All the pepsins have N-terminal valine, C-terminal alanine and are free from carbohydrate. Again the only difference detected among them is in their organic phosphate content. The pepsins of high phosphate content are converted by an acid phosphatase in vitro into pepsins of low phosphate content.     

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

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.     

Molecular cloning of neonate/infant-specific pepsinogens from rat stomach mucosa and their expressional change during development

To clarify the nature of rat neonate/infant-specific pepsinogens, we carried out their purification and molecular cloning. Prochymosin was found to be the major neonatal pepsinogen. The general proteolytic activity of its active form, chymosin, was, however, lower than those of pepsins A and C which are predominant in adult animals. Molecular cloning of rat prochymosin cDNA was achieved along with cDNA for another neonate-specific pepsinogen, pepsinogen F, although determination of pepsinogen F in neonatal gastric mucosa was unsuccessful, presumably due to its lack of proteolytic activity or different proteolytic specificity. Northern blot analysis confirmed that genes for prochymosin and pepsinogen F are expressed only at neonatal/infant stages and the switching of gene expression to that of pepsinogen C occurred at late infant stages. A phylogenetic tree based on nucleotide sequences showed clearly that pepsinogens fall into four major groups, namely prochymosin and pepsinogen F of the neonate/infant and pepsinogens A and C of adult animals. Although, to date, prochymosin and pepsinogen F were believed to be expressed in only a limited number of mammals, the present results suggest that they might be expressed at the neonatal/infant stage in a variety of mammals.     

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

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.     

Structure and development of rabbit pepsinogens. Stage-specific zymogens, nucleotide sequences of cDNAs, molecular evolution, and gene expression during development

In order to clarify the structure and development of rabbit pepsinogens, purification and molecular cloning of these proteins were performed at various developmental stages. Several pepsinogens were isolated, and they were classified as pepsinogens F and M, and into pepsinogen groups I, II, and III. The relative levels and specific activities of the various pepsinogens changed significantly during development. Pepsinogens F and M were present only at the early postnatal stage, and their level was higher than those of other pepsinogens at this stage. Pepsinogens in groups I, II, and III were the predominant zymogens at the late postnatal stage. cDNA clones encoding all of these pepsinogens were obtained, with the exception of pepsinogens I and M, and the nucleotide sequences were determined. Each cDNA contained a leader region (signal peptide), a pro-region (activation segment), and a pepsin region, of 15, 44, and 328 residues, respectively, with the exception of the cDNA for pepsinogen F in which the pro- and pepsin regions were composed of 43 and 330 residues, respectively. Pepsinogens in groups II and III exhibited a high degree of similarity with one another, whereas many substitutions were found in pepsinogen F. A unique substitution in the activation segment of pepsinogen F, namely, Gly----Asp at position 21, was found, which made the structural features of this segment more specific. A phylogenic tree was constructed from the differences in nucleotide sequences and showed clearly that each pepsinogen in groups II and III could be classified as pepsinogen A, a major pepsinogen in mammals. Pepsinogen F diverged significantly from these groups and may be a new type of pepsinogen. Northern analysis revealed that the expression of the gene for pepsinogen F was restricted to the early postnatal stage, and the expression of genes for pepsinogens in groups II and III was detected predominantly at later stages, a result that shows the switching of gene expression from fetal pepsinogen to adult pepsinogens during development.     

Partial characterization of pepsins and gastricsins and their zymogens from human and toad gastric mucosae.

1. Three zymogens have been isolated from human gastric mucosae and two from the stomachs of the toad Caudiverbera caudiverbera. 2. Human zymogens I and III were immunologically related and cross-reacted with antisera prepared against porcine pepsinogen. The third, (II), showed no cross-reactivity. 3. Human zymogens I and III and toad zymogen ZII gave rise to two human pepsins and to a pepsin-like enzyme, respectively. 4. Human zymogen II (gastricsinogen) and toad zymogen ZI gave rise to human gastricsin and to a gastricsin-like enzyme respectively. 5. The toad enzymes showed much greater stability at neutral and alkaline pH values than the human enzymes.     

Aspartic proteinases in fishes and aquatic invertebrates

1. The literature on molecular properties and physiological role of aspartic proteinases in fishes and aquatic invertebrates has been reviewed. 2. Pepsins have not been detected in invertebrates, and apparently cathepsin D, as well as other cathepsins, act both as digestive and lysosomal enzymes in many of these animals. The molecular properties of invertebrate cathepsin D correspond with cathepsin D in fishes and mammalians. 3. Fishes with a true stomach have pepsinogen secretion. Fish pepsins have higher pH optimum and are less stable in strong acid conditions than mammalian pepsins. They are very efficient at low temperatures, but less thermostable than mammalian pepsins. 4. Many fishes have two significantly different pepsins: Pepsin I and Pepsin II, which digest haemoglobin at a maximal rate in the pH ranges 3-4 and 2-3 respectively. Usually the pI of Pepsin I is in the range 6.5-7, whereas pI of Pepsin II is about 4. 5. Fish Pepsin I and cathepsin D have very similar molecular properties, and a hypothesis proposing that cathepsin D is the ancestor enzyme of aspartic proteinases in higher animals is presented.     

Purification and characterization of goat pepsinogens and pepsins

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.     

New world monkey pepsinogens A and C, and prochymosins. Purification, characterization of enzymatic properties, cDNA cloning, and molecular evolution

Pepsinogens A and C, and prochymosin were purified from four species of adult New World monkeys, namely, common marmoset (Callithrix jacchus), cotton-top tamarin (Saguinus oedipus), squirrel monkey (Saimiri sciureus), and capuchin monkey (Cebus apella). The occurrence of prochymosin was quite unique since this zymogen is known to be neonate-specific and, in primates, it has been thought that the prochymosin gene is not functional. No multiple form has been detected for any type of pepsinogen except that two pepsinogen-A isozymogens were identified in capuchin monkey. Pepsins A and C, and chymosin hydrolyzed hemoglobin optimally at pH 2-2.5 with maximal activities of about 20, 30, and 15 units/mg protein. Pepsins A were inhibited in the presence of an equimolar amount of pepstatin, and chymosins and pepsins C needed 5- and 100-fold molar excesses of pepstatin for complete inhibition, respectively. Hydrolysis of insulin B chain occurred first at the Leu15-Tyr16 bond in the case of pepsins A and chymosins, and at either the Leu15-Tyr16 or Tyr16-Leu17 bond in the case of pepsins C. The presence of different types of pepsins might be advantageous to New World monkeys for the efficient digestion of a variety of foods. Molecular cloning of cDNAs for three types of pepsinogens from common marmoset was achieved. A phylogenetic tree of pepsinogens based on the nucleotide sequence showed that common marmoset diverged from the ancestral primate about 40 million years ago.     

Comparative pepstatin inhibition studies on individual human pepsins and pepsinogens 1,3 and 5(gastricsin) and pig pepsin A

Human gastric juice contains 3 major proteolytic components (pepsins1,3 and 5 or gastricsin). Pepsin 1 is increased in peptic ulcer and it's properties are relatively poorly understood. Studies with pepstatin the highly specific aspartic-protease inhibitor have therefore been carried out on individual active and proenzymes to assess any enzymic similarities. Human pepsin 1 was inhibited with high affinity similar to pepsin 3, whereas pepsin 5(gastricsin) was at least 40 times less sensitive. Inhibition of human pepsinogens 1,3 and 5 and pig pepsinogen A showed similar trends to the active enzymes. Studies using Sephadex gel filtration showed that pepstatin does not bind to pepsinogens and inhibition arises from pepstatin binding the pepsins released upon activation. Pepstatin inhibition was shown to be relatively independent of pH between 1.5 and 3.8 although at higher pH inhibition was less effective. The evidence suggests that pepsin 1 is similar to pepsin 3 and pepstatin inhibits by a one to one molecular binding to the active site. The explanation for the reduced affinity of pepstatin to pepsin 5(gastricsin) needs further study by co-crystallisation X-ray analysis.     

Comparative Pepstatin Inhibition Studies on Individual Human Pepsins and Pepsinogens 1,3 and 5(gastricsin) and Pig Pepsin A

Human gastric juice contains 3 major proteolytic components (pepsins1,3 and 5 or gastricsin). Pepsin 1 is increased in peptic ulcer and it's properties are relatively poorly understood. Studies with pepstatin the highly specific aspartic-protease inhibitor have therefore been carried out on individual active and proenzymes to assess any enzymic similarities. Human pepsin 1 was inhibited with high affinity similar to pepsin 3, whereas pepsin 5(gastricsin) was at least 40 times less sensitive. Inhibition of human pepsinogens 1,3 and 5 and pig pepsinogen A showed similar trends to the active enzymes. Studies using Sephadex gel filtration showed that pepstatin does not bind to pepsinogens and inhibition arises from pepstatin binding the pepsins released upon activation. Pepstatin inhibition was shown to be relatively independent of pH between 1.5 and 3.8 although at higher pH inhibition was less effective. The evidence suggests that pepsin 1 is similar to pepsin 3 and pepstatin inhibits by a one to one molecular binding to the active site. The explanation for the reduced affinity of pepstatin to pepsin 5(gastricsin) needs further study by co-crystallisation X-ray analysis.     

Pepsinogens and pepsins from Japanese seabass (Lateolabrax japonicus)

Three pepsinogens (PG1, PG2, PG3) were highly purified from the stomach of Japanese seabass (Lateolabrax japonicus) by ammonium sulfate fractionation, DEAE-Sephacel anion exchange column chromatography and Sephacryl S-200 gel-filtration. Two dimensional polyacrylamide gel electrophoresis (2D-PAGE) analysis revealed that the molecular masses of the three PGs were 35, 37, and 34kDa, and their isoelectric points were 5.3, 5.1, and 4.7, respectively. Zymography analysis showed that the three pepsinogens had different mobilities and enzymatic activities under native conditions. Pepsinogens converted into their active form pepsins under pH 2.0 by one-step pathway or stepwise pathway. All three pepsins were completely inhibited by pepstatin A, a typical aspartic proteinase inhibitor. The N-terminal amino acid sequences of the three pepsinogens were determined to the 30th, 30th and 28th amino acid residue and those of their corresponding active form pepsins were also determined to the 19th, 18th and 20th amino acid residue, respectively. All amino acid sequences of Japanese seabass PGs revealed high identities to reported fish and mammalian pepsinogens. The effective digestion of fish and shrimp muscular proteins by pepsins indicated their physiological function in the degradation of food proteins.     

Structural and phylogenetic comparison of three pepsinogens from Pacific bluefin tuna: molecular evolution of fish pepsinogens

The amino acid sequences of three pepsinogens (PG1, PG2 and PG3) of Pacific bluefin tuna (Thunnus orientalis) were deduced by cloning and nucleotide sequencing of the corresponding cDNAs. The amino acid sequences of the pre-forms of PG1, PG2 and PG3 were composed of a signal peptide (16 residues each), a propeptide (41, 37 and 35 residues, respectively) and a pepsin moiety (321, 323 and 332 residues, respectively). Amino acid sequence comparison and phylogenetic analysis indicated that PG1 and PG2 belong to the pepsinogen A family and PG3 to the pepsinogen C family. Homology modeling of the three-dimensional structure suggested that the remarkably high specific activity of PG2 toward hemoglobin, which had been found previously, was partly due to a characteristic deletion of several residues in the S1'-loop region that widens the space of the active site cleft region so as to accommodate protein and larger polypeptide substrates more efficiently. Including the tuna and all other fish pepsinogen sequences available to date, the molecular phylogenetic comparison was made with reference to evolution of fish pepsinogens. It was suggested that functional divergences of pepsinogens (pepsins) occurring in fishes as well as in mammals, correlated with differences in various aspects of fish physiology.     

Two glycosulfatases from the liver of a marine gastropod, Charonia lampas. Partial purification and properties.

Two glycosulfatases [EC 3.1.6.3], I and II, were purified 31.3- and 33.9-fold respectively, from a crude extract of the liver of Charonia lampas. The purification was carried out by the following chromatographic procedures; phosphocellulose, Sephadex G-150, Concanavalin A-Sepharose and isoelectric focussing. The enzyme preparations obtained were practically free from arylsulfatase [EC 3.1.6.1] contamination. Both glycosulfatases are probably glycoproteins differing in their carbohydrate moieties. The molecular weights of glycosulfatase I and II were estimated to be about 112,000 and 79,000 respectively. They had the same optimum pH of 5.5, and the same Km value of 25.0 mM for glucose 6-sulfate.     

Difference of activation processes and structure of activation peptides in human pepsinogens A and progastricsin

The activation processes of two human pepsinogens A (pepsinogens 3 and 5) and progastricsin were compared with special attention to pepsinogens 3 and 5. Each zymogen was converted to pepsin in a stepwise manner through intermediate forms. In pepsinogens A, the major cleavage site was the Leu23-Lys24 bond and this cleavage was suggested to occur intramolecularly. When each of the pepsins A was added to the corresponding pepsinogen A exogenously, the latter was rapidly converted to pepsin, releasing the 47-residue intact activation segment. In this case, the Leu47-Val48 bond connecting the activation segment with the pepsin moiety was cleaved by an intermolecular reaction. On the other hand, when the pepsinogen A-pepstatin complex was attacked by each corresponding pepsin A added exogenously, significant cleavage by an intermolecular reaction occurred at the Asp25-Phe26 bond, generating the Phe26-intermediate form. These shifts of the cleavage sites in pepsinogens A depending on the activation conditions are likely to correlate with the conformation of the activation segment. These results can be explained consistently in terms of a proposed molecular model of activation.