A new approach to the use of fluorogenic dinitrophenyl-containing substrates for determining the proteolytic activity of aspartyl proteinases

A method for the determination of proteolytic activity of aspartyl proteinases using known colored fluorogenic substrates was developed. The technique utilizes the chromophore properties of the dinitrophenyl (DNP) group. The approach proposed comprises separation of the initial peptide and subsequent measurement of absorption of the solution of the DNP-containing C-terminal fragment, produced by its enzymatic cleavage, at 360 nm. This method was used to determine the activity of calf chymosin, the pepsins from various sources, and the commercial preparations containing a mixture of enzymes without preliminary desalting. The method is simple and applicable under plant conditions.     

Characterization of recombinant camel chymosin reveals superior properties for the coagulation of bovine and camel milk

Enzymatic milk coagulation for cheese manufacturing involves the cleavage of the scissile bond in kappa-casein by an aspartic acid protease. Bovine chymosin is the preferred enzyme, combining a strong clotting activity with a low general proteolytic activity. In the present study, we report expression and enzymatic properties of recombinant camel chymosin expressed in Aspergillus niger. Camel chymosin was shown to have different characteristics than bovine chymosin. Camel chymosin exhibits a 70% higher clotting activity for bovine milk and has only 20% of the unspecific protease activity for bovine chymosin. This results in a sevenfold higher ratio of clotting to general proteolytic activity. The enzyme is more thermostable than bovine chymosin. Kinetic analysis showed that half-saturation is achieved with less than 50% of the substrate required for bovine chymosin and turnover rates are lower. While raw camel milk cannot be clotted with bovine chymosin, a high clotting activity was found with camel chymosin.     

A new approach to the use of fluorogenic dinitrophenyl-containing substrates for determining the proteolytic activity of aspartyl proteinases

A method for the determination of proteolytic activity of aspartyl proteinases using known colored fluorogenic substrates was developed. The technique utilizes the chromophore properties of the dinitrophenyl (DNP) group. The approach proposed comprises separation of the initial peptide and subsequent measurement of absorption of the solution of the DNP-containing C-terminal fragment, produced by its enzymatic cleavage, at 360 nm. This method was used to determine the activity of calf chymosin, the pepsins from various sources, and the commercial preparations containing a mixture of enzymes without preliminary desalting. The method is simple and applicable under plant conditions.     

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.     

Isolation and partial characterization of prochymosin and chymosin from cat

Extracts of cat gastric mucosa contain a zymogen that after activation shows partial immunochemical identity with chymosin (EC 3.4.23.4) from calf. Cat prochymosin has been purified by column chromatography and gel filtration, and cat chymosin was obtained after acid activation of the zymogen. The enzyme showed the optimum of general proteolytic activity at pH 2.5. The amino acid compositions of cat prochymosin and chymosin were similar to those of the corresponding proteins from calf. The first 27 residues of both cat prochymosin and chymosin have been sequenced. Among these 54 positions only 13 differences have been observed between the proteins from cat and calf. The results support the hypothesis that the chymosins form a group of neonatal gastric proteases with high milk-clotting activity, but with such weak general proteolytic activity that postnatal uptake of IgG is not hindered.     

The first step in the activation of chicken pepsinogen is similar to that of prochymosin.

Chicken pepsinogen was incubated at pH2.5 with pepstatin. The zymogen activated itself by a sequential mechanism and an intact peptide derived from residues 1-26 in the protein was released in the first step. This peptide was found to inhibit the milk-clotting activities of pig and chicken pepsins and calf chymosin but to different extents.     

Purification and characterization of pepsins A1 and A2 from the Antarctic rock cod Trematomus bernacchii

The Antarctic notothenioid Trematomus bernacchii (rock cod) lives at a constant mean temperature of -1.9 degrees C. Gastric digestion under these conditions relies on the proteolytic activity of aspartic proteases such as pepsin. To understand the molecular mechanisms of Antarctic fish pepsins, T. bernacchii pepsins A1 and A2 were cloned, overexpressed in Escherichia coli, purified and characterized with a number of biochemical and biophysical methods. The properties of these two Antarctic isoenzymes were compared to those of porcine pepsin and found to be unique in a number of ways. Fish pepsins were found to be more temperature sensitive, generally less active at lower pH and more sensitive to inhibition by pepstatin than their mesophilic counterparts. The specificity of Antarctic fish pepsins was similar but not identical to that of pig pepsin, probably owing to changes in the sequence of fish enzymes near the active site. Gene duplication of Antarctic rock cod pepsins is the likely mechanism for adaptation to the harsh temperature environment in which these enzymes must function.     

Gastric antibacterial efficiency is different for pepsin A and C

The gastric lumen represents a bactericidal barrier, whose major components are an acidic pH and a family of isoenzymes of the gastric aspartate protease, pepsin. To evaluate whether specific pepsins are specialized in antibacterial protection, we tested their effects on the gastric pathogen Helicobacter pylori. In a recent study we found pepsin to affect the motility of the bacteria, one of its most important virulence factors. We were able to show that the antibacterial effect of pepsin occurs in two phases: rapid loss of motility and subsequent destruction. In the present study we used the rapid pepsin-induced bacterial immobilization as a marker of antibacterial efficiency. The proteolytic activity of different pepsins was normalized to values between 2 and 200 U/ml in the hemoglobin degradation test of Anson, performed at pH 2 and 5. We found that pepsin C completely inactivates H. pylori at proteolytic activities of 2 (pH 5) and 20 (pH 2) U/ml. In contrast, the activities of pepsin A and chymosin required to affect Helicobacter motility were ten times higher.     

Gastric proteases of the Greenland cod Gadus ogac. II. Structural properties

Three gastric proteases were isolated from the stomach mucosa of the Greenland cod (Gadus ogac). The cod proteases were all less stable to heating and protease 1 retained less activity at 5 degrees C when the pH was greater than 5 in comparison with porcine pepsin. The activities of cod proteases 1 and 2, with hemoglobin as the substrate, were doubled in the presence of 25 mM NaCl, while cod protease 3 and porcine pepsin were not stimulated by the salt. The cod proteases did not cross-react with antibodies raised against porcine pepsin. However, some cross-reactivity was noted with antibodies raised against proteases from psychotrophic pseudomonads. The molecular weights of all the cod proteases were in the range of 36,000-38,000. The amino acid compositions of the cod proteases as compared by the Metzger difference index differed from the mammalian gastric proteases by about the same extent that pepsin, gastricsin, and chymosin differ from each other. Of the cod enzymes, protease 1 differed from mammalian gastric proteases, while cod proteases 3 was more like chymosin with respect to amino acid composition. Cod protease 1 had the lowest hydrophobicity index and chymosin had the highest. The hydrophobicity indices of cod proteases 2 and 3 were intermediate between that of porcine pepsin and bovine chymosin. It is suggested that the Greenland cod proteases represent less differentiated forms of gastric proteases than the mammalian pepsins, gastricsins, and chymosins.     

Purification and characterization of pepsins from the arctic fish capelin (Mallotus villosus)

Two pepsins from the stomach of the arctic fish capelin (Mallotus villosus) have been isolated and characterized. The purification was achieved by ammonium sulphate precipitation, ion exchange chromatography and gel filtration. Both pepsins resemble mammalian pepsins regarding pepstatin sensitivity, amino acid composition, stability and specific activity. The major capelin pepsin has optimum activity at significantly higher pH than is common for mammalian pepsins, and the optimum pH is different with different substrates. Both pepsins have relatively high activity at low temperatures. The pepsins have mol. wt of about 25,000 which is significantly lower than that of mammalian pepsins.     

Amphibian pepsinogens: purification and characterization of xenopus pepsinogens, and molecular cloning of Xenopus and bullfrog pepsinogens

Two pepsinogens (Pg C and Pg A) were isolated from the stomach of adult Xenopus laevis by Q-Sepharose, Sephadex G-75, and Mono-Q column chromatographies. Autolytic conversion and activation of the purified Pgs into the pepsins were examined by acid treatment. We determined the amino acid sequences from the NH2-termini of Pg C, pepsin C, Pg A, and pepsin A. Based on the sequences, the cDNAs for Pg C and Pg A were cloned from adult stomach RNA, and the complete amino acid sequences of the Pg C and Pg A were predicted. In addition, a Pg A cDNA was cloned from the stomach of adult bullfrog Rana catesbeiana, and the primary structure of the Pg A was predicted. Molecular phylogenetic analysis showed that such anuran Pg C and Pg A belong to the Pg C group and the Pg A group in vertebrates, respectively. The molecular properties of Pg C and Pg A, such as size, sequences of the activation peptide and active site, profile of autolytic activation, and pH dependency of proteolytic activity of the activated forms, pepsin C and pepsin A, resemble those of Pgs found in other vertebrates. However, the hemoglobin-hydrolyzing activity of Xenopus pepsin C is completely inhibited in the presence of equimolar pepstatin, an inhibitor of aspartic proteinases. Thus, the Xenopus pepsin C differs significantly from other vertebrate pepsins C in its high susceptibility to pepstatin, and closely resembles A-type pepsins.     

Characterization of a chymosin-like pepsin from the dogfish Scyliorhinus canicula

1. Pepsin II extracted from the gastric mucosa of Scyliorhinus canicula has been characterized and compared to calf chymosin. 2. The kcat and Km of the dogfish enzyme for the synthetic hexapeptide Leu-Ser-Phe(NO2)-Nle-Ala-Leu-OMe have been determined. The kcat/Km ratio is close to that of calf chymosin. Its milk-clotting efficiency is however 21-fold lower than that of calf chymosin. 3. The proteolytic activity against haemoglobin is optimal at pH 2.5. It clots the milk up to pH 6.8. 4. The dogfish pepsin II shows relatively better activity at low temperatures than calf chymosin.     

Multiple forms of horse pepsin

Using ion-exchange and affinity chromatography and isoelectrofocusing, eight forms of pepsin with pI 1.6, 1.8, 2.1, 2.3, 2.6, 2.8, 3.2 and 3.6, were isolated from horse gastric juice. The molecular weights, amino acid composition, N-terminal sequence and functional activity of these multiple forms were determined. Partial primary structure of tryptic peptides of pepsin with pI 2.3 was investigated. The analyzed partial sequences of the forms with pI 1.8, 2.1, 2.3, and 2.6 have identical structures which differ from the amino acid sequence of pepsin with pI 3.2 by four substituents. In terms of their functional activity, horse pepsins differ only insignificantly. Presumably, the pepsins under study (at least the forms with pI 1.8, 2.1, 2.3, 2.6 and 3.2) arose comparatively recently as a result of duplication of the common precursor gene and exist at an early stage of structural and functional divergence. As far as their primary structure and functional properties are concerned, these pepsins are more related to pepsin A than to other isoenzymes of gastric aspartyl proteinases of mammalia, e. g., gastricsin or chymosin.     

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

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.     

The pepsins from human gastric mucosal extracts

1. The pepsins and pepsinogens of the gastric mucosal extracts of two normal subjects, of seven patients with gastric adenocarcinoma and of two patients with duodenal ulcer have been investigated by agar-gel electrophoresis and by ion-exchange chromatography. 2. Of the eight zones of proteolytic activity that have previously been reported in normal human gastric juice, seven can be detected in activated fundic mucosal extracts. Of these seven, four can be attributed to discrete pepsins, numbered 1, 3a, 3 and 5. 3. Zone 7 results from the activity of one or more enzymes that are alkali-stable and are best referred to as gastric proteinases rather than as pepsins. Zone 7 is much more evident in mucosal extracts than in gastric juice. 4. Zones 4 and 6 may result respectively from the activity of a pepsin-inhibitor complex and of an unactivated zymogen. 5. It was not possible, by the chromatographic methods employed, to separate satisfactorily the individual pepsins from activated extracts or their precursors from unactivated extracts, so that the ascribing of a pepsin to a specific zymogen must be considered tentative. Even so, pepsin 3 appears to arise from at least two major precursors, if not from three, whereas pepsins 1 and 5 each arise from a single major precursor. 6. Pyloric mucosal extracts contain principally zone 5 but also zones 6 and 7. These zones in general behave similarly to the corresponding zones of fundic extracts, but pyloric pepsin 5 migrates slightly faster on agar-gel electrophoresis than does fundic pepsin 5 and is a different enzyme. Zones 1 to 4 are absent.     

On the effect of mutations in bovine or camel chymosin on the thermodynamics of binding κ‐caseins

Bovine and camel chymosins are aspartic proteases that are used in dairy food manufacturing. Both enzymes catalyze proteolysis of a milk protein, κ‐casein, which helps to initiate milk coagulation. Surprisingly, camel chymosin shows a 70% higher clotting activity than bovine chymosin for bovine milk, while exhibiting only 20% of the unspecific proteolytic activity. By contrast, bovine chymosin is a poor coagulant for camel milk. Although both enzymes are marketed commercially, the disparity in their catalytic activity is not yet well understood at a molecular level, due in part to a lack of atomistic resolution data about the chymosin—κ‐casein complexes. Here, we report computational alanine scanning calculations of all four chymosin—κ‐casein complexes, allowing us to elucidate the influence that individual residues have on binding thermodynamics. Of the 12 sequence differences in the binding sites of bovine and camel chymosin, eight are shown to be particularly important for understanding differences in the binding thermodynamics (Asp112Glu, Lys221Val, Gln242Arg, Gln278Lys. Glu290Asp, His292Asn, Gln294Glu, and Lys295Leu. Residue in bovine chymosin written first). The relative binding free energies of single‐point mutants of chymosin are calculated using the molecular mechanics three dimensional reference interaction site model (MM‐3DRISM). Visualization of the solvent density functions calculated by 3DRISM reveals the difference in solvation of the binding sites of chymosin mutants.     

Partial purification of pepsins from adult and juvenile salmon fish Oncorhynchus keta. Effect of NaCl on proteolytic activities

1. Two pepsins, designated Pepsin I and Pepsin II, were isolated and partially characterized from the stomach of the adult stage salmon Oncorhynchus keta. This stage is developed in a marine environment. 2. One pepsin, designated Pepsin II, was isolated from the stomach of the juvenile stage salmon Oncorhynchus keta. This stage is developed in an estuarine environment. 3. The enzymes were partially purified by ammonium sulfate precipitation, ion exchange chromatography and gel filtration. 4. Pepsins I and II from adults and Pepsin II from juvenile showed proteolytic activity on acid-denatured hemoglobin with a pH optimum of 3. 5. The mol. wt determined by gel filtration on Sephadex G-100 of Pepsin I from juvenile species was found to be 32,000 whereas a value of 27,000 was determined for Pepsin II from juvenile and adult fish. 6. In contrast with Pepsin II, Pepsin I was activated by NaCl. It is suggested that the appearance of NaCl-activated pepsin would represent and adaptive response of the organism to the change from a low to a high salinity environment.     

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.     

Purification and characterization of milk clotting enzyme from goat (Capra hircus)

Chymosin, the major component of rennet (milk clotting enzyme), is an acid protease produced in the fourth stomach of milk-fed ruminants including goat and sheep in the form of an inactive precursor prochymosin. It is responsible for hydrolysis of kappa-casein chain in casein micelles of milk and therefore, used as milk coagulant in cheese preparation. The present investigation was undertaken to purify and characterize goat (Capra hircus) chymosin for its suitability as milk coagulant. The enzyme was extracted from abomasal tissue of kid and purified nearly 30-fold using anion exchanger and gel filtration chromatography. Goat chymosin resolved into three major active peaks, indicating possible heterogeneity when passed through DEAE-cellulose ion exchange column. The purified enzyme had a molecular mass of 36 kDa on SDS-PAGE, which was further confirmed by Western blot analysis. The purified enzyme preparation was stable up to 55 degrees C with maximum activity at 30 degrees C. The milk clotting activity was decreased steadily as pH is increased and indicated maximum activity at pH 5.5. Proteolytic activity of goat chymosin increased with incubation time at 37 degrees C. Goat chymosin was found to be more thermostable than cattle chymosin and equally stable to buffalo chymosin.