Foldase and inhibitor functionalities of the pepsinogen prosegment are encoded within discrete segments of the 44 residue domain.

Pepsin is initially produced as the zymogen pepsinogen, containing a 44 residue prosegment (PS) domain. When folded without the PS, pepsin forms a thermodynamically stable denatured state (refolded pepsin, Rp). To guide native folding, the PS binds to Rp, stabilizes the folding transition state, and binds tightly to native pepsin (Np), thereby driving the folding equilibrium to favor the native state. It is unknown whether these functionalities of the PS are encoded within the entire sequence or within discrete segments. PS residues 1p-29p correspond to a highly conserved region in pepsin-like aspartic proteases and we hypothesized that this segment is critical to PS-catalyzed folding. This notion was tested in the present study by characterizing the ability of various truncated PS peptides to bind Rp, catalyze folding from Rp to Np, and to inhibit Np. Four PS truncations were examined, corresponding to PS residues 1p-16p (PS1-16), 1p-29p (PS1-29), 17p-44p (PS17-44) and 30p-44p (PS30-44). The three PS functionalities could be ascribed primarily to discrete regions within the highly conserved motif: 1p-16p dictated Rp binding, 17p-29p dictated Np binding/inhibition, while the entire 1p-29p dictated transition state binding/catalyzing folding. Conversely, PS30-44 played no obvious role in PS-catalyzed folding; it is hypothesized that this more variable region may serve as a linker between PS1-29 and the mature domain. The high sequence conservation of PS1-29 and its role in catalyzing pepsin folding strongly suggest that there is a conserved PS-catalyzed folding mechanism shared by pepsin-like aspartic proteases with this motif.

[Physiological and clinical implications of gastric pepsinogens].

This review deals with pepsinogen metabolism, physiological role, and clinical implications. Effects of various factors, e.g H. pylori, on pepsinogen levels are considered. It is concluded that non-invasive screening of gastric precancer conditions provides a cost-effective and efficacious approach to the prevention of this pathology.

Purification and characterization of pepsinogens and pepsins from the stomach of rice field eel (Monopterus albus Zuiew).

Three pepsinogens (PG1, PG2, and PG3) were highly purified from the stomach of freshwater fish rice field eel (Monopterus albus Zuiew) by ammonium sulfate fractionation and chromatographies on DEAE-Sephacel, Sephacryl S-200 HR. The molecular masses of the three purified PGs were all estimated as 36 kDa using SDS-PAGE. Two-dimensional gel electrophoresis (2D-PAGE) showed that pI values of the three PGs were 5.1, 4.8, and 4.6, respectively. All the PGs converted into corresponding pepsins quickly at pH 2.0, and their activities could be specifically inhibited by aspartic proteinase inhibitor pepstatin A. Optimum pH and temperature of the enzymes for hydrolyzing hemoglobin were 3.0-3.5 and 40-45 °C. The K (m) values of them were 1.2 × 10⁻4 M, 8.7 × 10⁻5 M, and 6.9 × 10⁻5 M, respectively. The turnover numbers (k(cat)) of them were 23.2, 24.0, and 42.6 s⁻¹. Purified pepsins were effective in the degradation of fish muscular proteins, suggesting their digestive functions physiologically.

Pepsinogen-like activation intermediate of plasmepsin II revealed by molecular dynamics analysis.

Plasmepsins are pharmaceutically relevant aspartic proteases involved in haemoglobin degradation by the malaria causing parasites Plasmodium spp. They are translated as inactive proenzymes, with an elongated prosegment. On prosegment cleavage, plasmepsins undergo a series of hitherto unresolved conformational changes before becoming active. Here, the flexibility of plasmepsin and proplasmepsin and the activation process are investigated by multiple explicit water molecular dynamics simulations. The large N-terminal displacement and the interdomain shift from the proenzyme structure to active plasmepsin are promoted by essential dynamics sampling. An intermediate, stabilized by electrostatic interactions between the catalytic dyad and the N-terminus of mature plasmepsin, is observed along all activation trajectories. Notably, the stabilizing interactions in the activation intermediate of plasmepsin are similar to those in the X-ray structure of pepsinogen. In particular, the catalytic aspartates act as hydrogen bond acceptors for the N-terminal amino group and the Ser2 hydroxyl in plasmepsin, and the side chains of Lys36pro and Tyr9 in pepsinogen. The simulation results are used to suggest in vitro experiments to test the conformational transitions involved in the maturation of plasmepsin, and design small-molecule inhibitors.

Structure, molecular evolution, and hydrolytic specificities of largemouth bass pepsins.

The nucleotide sequences of largemouth bass pepsinogens (PG1, 2 and 3) were determined after molecular cloning of the respective cDNAs. Encoded PG1, 2 and 3 were classified as fish pepsinogens A1, A2 and C, respectively. Molecular evolutionary analyses show that vertebrate pepsinogens are classified into seven monophyletic groups, i.e. pepsinogens A, F, Y (prochymosins), C, B, and fish pepsinogens A and C. Regarding the primary structures, extensive deletion was obvious in S'1 loop residues in fish pepsin A as well as tetrapod pepsin Y. This deletion resulted in a decrease in hydrophobic residues in the S'1 site. Hydrolytic specificities of bass pepsins A1 and A2 were investigated with a pepsin substrate and its variants. Bass pepsins preferred both hydrophobic/aromatic residues and charged residues at the P'1 sites of substrates, showing the dual character of S'1 sites. Thermodynamic analyses of bass pepsin A2 showed that its activation Gibbs energy change (∆G(‡)) was lower than that of porcine pepsin A. Several sites of bass pepsin A2 moiety were found to be under positive selection, and most of them are located on the surface of the molecule, where they are involved in conformational flexibility. The broad S'1 specificity and flexible structure of bass pepsin A2 are thought to cause its high proteolytic activity.

Separation of porcine pepsinogen A and progastricsin. Sequencing of the first 73 amino acid residues in progastricsin.

Porcine pepsinogen A (EC 3.4.23.1) and progastricsin (EC 3.4.23.3) have been separated by chromatography on DEAE-cellulose followed by chromatography on DEAE-Sepharose. Agar gel electrophoresis at pH 6.0 showed the presence of three components of pepsinogen A and two of progastricsin. During activation at pH 2 a segment of 43 amino acid residues (the prosegment peptide) is cleaved from the N-terminus of progastricsin. The sequence of this was determined; in addition, the first 30 residues of gastricsin were sequenced. The sequence of the first 73 amino acid residues of progastricsin shows an overall identity with progastricsins from man, monkey and rat of 67%. The overall identity with other zymogens for gastric proteinases is 27%. The highly conserved Lys36p (pig pepsinogen A numbering) is changed to Arg in porcine progastricsin.

Pepsinogen synthesis during long-term culture of porcine chief cells.

The purpose of this study was to characterize time-dependent changes in pepsinogen (PG) synthesis of porcine gastric chief cells during long-term monolayer culture. Porcine chief cells were isolated by pronase/collagenase treatment of fundic mucosa and enriched by density gradient and counterflow centrifugation. PG isoenzymes were identified in [L-35S]methionine-labelled cultured chief cells by native polyacrylamide gel electrophoresis followed by phosphor imager analysis, protease detection and immunoblots with specific PG A and C antibodies. The obtained results suggest that porcine chief cell cultures, after an initial settling period, reached an approximate steady state in total protein content and synthesis as well as in PG content and isoenzyme pattern from days 3 to 9 of culture. The latter was characterized by the presence of at least two PG A and two PG C isoenzymes. During the supposed steady-state total PG synthesis averaged out at 34 +/- 2% of total protein synthesis, as detected by [L-35S]methionine incorporation, due to the synthesis of, mainly, PG A2 and, to a much lesser extent, PG C and A1. In line with an active secretion, PG A2 proportion was on average significantly higher in released (44 +/- 3%) than in intracellular labelled proteins (19 +/- 2%). In addition, PG release from chief cells cultured for 6 and 9 days could be stimulated by cholecystokinin-octapeptide. These data suggest that porcine chief cells in monolayer culture are a model well suited for the quantitative and qualitative characterization of PG isoenzyme synthesis and release during long-term investigations, for which an establishment of a culture steady state appears to be a useful prerequisite.

Binding of pepsinogen to the 78 kDa gastrin binding protein.

An endogenous ligand of the 78 kDa gastrin-binding protein (GBP) has been purified from detergent extracts of porcine gastric mucosal membranes by ion exchange chromatography and preparative gel electrophoresis. The ligand bound to the GBP with high affinity (mean IC50 value of 0.31+/-0.09 microgram/ml, or 8 nM), as assessed by inhibition of cross-linking of iodinated gastrin2,17 to the GBP. Both the N- and C-terminal halves of the GBP, which had been expressed individually as glutathione-S-transferase fusion proteins in Escherichia coli, and purified on glutathione-agarose beads, bound the ligand. Two peptides derived from the ligand were purified by reversed-phase high-performance liquid chromatography (HPLC), and characterised by mass spectrometry and Edman sequencing. The peptides were 97% and 100% identical, respectively, to amino acids 119-157 and 199-219 of porcine pepsinogen A. Commercial samples of pepsinogen also bound to the GBP, with a mean IC50 value of 3.9+/-1. 2 micrograms/ml (100 nM). We conclude that the ligand is closely related, but not identical, to pepsinogen A.

Refined structure of porcine pepsinogen at 1.8 A resolution.

The molecular structure of porcine pepsinogen at 1.8 A resolution has been determined by a combination of molecular replacement and multiple isomorphous phasing techniques. The resulting structure was refined by restrained-parameter least-squares methods. The final R factor [formula: see text] is 0.164 for 32,264 reflections with I greater than or equal to sigma (I) in the resolution range of 8.0 to 1.8 A. The model consists of 2785 protein atoms in 370 residues, a phosphoryl group on Ser68 and 238 ordered water molecules. The resulting molecular stereochemistry is consistent with a well-refined crystal structure with co-ordinate accuracy in the range of 0.10 to 0.15 A for the well-ordered regions of the molecule (B less than 15 A2). For the enzyme portion of the zymogen, the root-mean-square difference in C alpha atom co-ordinates with the refined porcine pepsin structure is 0.90 A (284 common atoms) and with the C alpha atoms of penicillopepsin it is 1.63 A (275 common atoms). The additional 44 N-terminal amino acids of the prosegment (Leu1p to Leu44p, using the letter p after the residue number to distinguish the residues of the prosegment) adopt a relatively compact structure consisting of a long beta-strand followed by two approximately orthogonal alpha-helices and a short 3(10)-helix. Intimate contacts, both electrostatic and hydrophobic interactions, are made with residues in the pepsin active site. The N-terminal beta-strand, Leu1p to Leu6p, forms part of the six-stranded beta-sheet common to the aspartic proteinases. In the zymogen the first 13 residues of pepsin, Ile1 to Glu13, adopt a completely different conformation from that of the mature enzyme. The C alpha atom of Ile1 must move approximately 44 A in going from its position in the inactive zymogen to its observed position in active pepsin. Electrostatic interactions of Lys36pN and hydrogen-bonding interactions of Tyr37pOH, and Tyr90H with the two catalytic aspartate groups, Asp32 and Asp215, prevent substrate access to the active site of the zymogen. We have made a detailed comparison of the mammalian pepsinogen fold with the fungal aspartic proteinase fold of penicillopepsin, used for the molecular replacement solution. A structurally derived alignment of the two sequences is presented.

Crystal and molecular structures of human progastricsin at 1.62 A resolution.

The crystal and molecular structures of human progastricsin (hPGC) have been determined using multiple isomorphous replacement methods and anomalous scattering in conjunction with a phased translation function. The structure has been refined to a conventional R-factor (= sigma parallel Fo magnitude of - magnitude of Fc parallel / sigma magnitude of Fo magnitude of) of 0.179 with data to 1.62 A resolution. The first 37 amino acid residues of the prosegment are similar in conformation to the equivalent residues of porcine pepsinogen (pPGN). As in pPGN, the N zeta atom of Lys37p sits between the active-site carboxylate groups of Asp32 and Asp217, thereby preventing catalysis. The side-chains of Tyr38p and Tyr9 sit in the S1' and S1 substrate-binding pockets of hPGC, respectively, in an analogous manner to what is observed in porcine pepsinogen. There are large conformational differences centered around the region containing residues Arg39p to Pro6, relative to the equivalent region in the structure of pPGN. Two surface loops in the vicinity of this segment are also displaced relative to those in pPGN and in mature aspartic proteinases (Phe71 to Thr81 (the "flap"), and Tyr125 to Thr131). In hPGC, Tyr75 O eta does not make its usual hydrogen bond to Trp39 N epsilon 1. Rather, the "flap" containing Tyr75 is excluded from the active site by the polypeptide segment Arg39p to Pro6. However, the conformation of the inhibitory segment, Lys37p to Tyr38p, is virtually identical with that observed in pPGN. Hence the structures of these two proteins indicate that aspartic proteinase zymogens keep themselves inactive at neutral pH by a very similar mechanism in human progastricsin and porcine pepsinogen. This similarity likely carries over to all members of both the pepsinogen A and C families of aspartic proteinase zymogens.

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

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.

Conformational instability of the N- and C-terminal lobes of porcine pepsin in neutral and alkaline solutions.

Pepsin contains, in a single chain, two conformationally homologous lobes that are thought to have been evolutionarily derived by gene duplication and fusion. We have demonstrated that the individual recombinant lobes are capable of independent folding and reconstitution into a two-chain pepsin or a two-chain pepsinogen (Lin, X., et al., 1992, J. Biol. Chem. 267, 17257-17263). Pepsin spontaneously inactivates in neutral or alkaline solutions. We have shown in this study that the enzymic activity of the alkaline-inactivated pepsin was regenerated by the addition of the recombinant N-terminal lobe but not by the C-terminal lobe. These results indicate that alkaline inactivation of pepsin is due to a selective denaturation of its N-terminal lobe. A complex between recombinant N-terminal lobe of pepsinogen and alkaline-denatured pepsin has been isolated. This complex is structurally similar to a two-chain pepsinogen, but it contains an extension of a denatured pepsin N-terminal lobe. Acidification of the complex is accompanied by a cleavage in the pro region and proteolysis of the denatured N-terminal lobe. The structural components that are responsible for the alkaline instability of the N-terminal lobe are likely to be carboxyl groups with abnormally high pKa values. The electrostatic potentials of 23 net carboxyl groups in the N-terminal domain (as compared to 19 in the C-terminal domain) of pepsin were calculated based on the energetics of interacting charges in the tertiary structure of the domain. The groups most probably causing the alkaline denaturation are Asp11, Asp159, Glu4, Glu13, and Asp118.(ABSTRACT TRUNCATED AT 250 WORDS)

Rearranging the domains of pepsinogen.

Most eukaryotic aspartic protease zymogens are synthesized as a single polypeptide chain that contains two distinct homologous lobes and a pro peptide, which is removed upon activation. In pepsinogen, the pro peptide precedes the N-terminal lobe (designated pep) and the C-terminal lobe (designated sin). Based on the three-dimensional structure of pepsinogen, we have designed a pepsinogen polypeptide with the internal rearrangement of domains from pro-pep-sin (native pepsinogen) to sin-pro-pep. The domain-rearranged zymogen also contains a 10-residue linker designed to connect sin and pro domains. Recombinant sin-pro-pep was synthesized in Escherichia coli, refolded from 8 M urea, and purified. Upon acidification, sin-pro-pep autoactivates to a two-chain enzyme. However, the emergence of activity is much slower than the conversion of the single-chain zymogen to a two-chain intermediate. In the activation of native pepsinogen and sin-pro-pep, the pro region is cleaved at two sites between residues 16P and 17P and 44P and 1 successively, and complete activation of sin-pro-pep requires an additional cleavage at a third site between residues 1P and 2P. In pepsinogen activation, the cleavage of the first site is rate limiting because the second site is cleaved more rapidly to generate activity. In the activation of sin-pro-pep, however, the second site is cleaved slower than the first, and cleavage of the third site is the rate limiting step.(ABSTRACT TRUNCATED AT 250 WORDS)

Ostrich pepsinogens I and II: purification, activation and chemical and immunochemical characterization of the enzymes from the proventriculus.

Pepsins are a series of gastric proteases secreted as inactive precursors (pepsinogens) which are active at acidic pH. The aim of this study was to purify ostrich pepsin(ogen)s and to compare their biochemical and immunological characteristics with those of pepsin(ogen)s of mammalian and avian origin. Ostrich pepsinogens were purified by ammonium sulphate fractionation, Toyopearl Super Q-650S chromatography and rechromatography, and hydroxylapatite chromatography of a pH 8.0 mucosal extract. Pepsins were obtained through acidification, and purified by chromatography on SP-Sephadex C-50. Amino acid compositions, N-terminal sequences, Ouchterlony double-diffusion as well as Western blot analysis were performed. Two pepsinogens were isolated and purified from the proventriculus of the ostrich, pepsinogens I and II. Both pepsinogens and pepsins were purified to homogeneity as shown by PAGE and SDS-PAGE, with SDS-PAGE revealing M(r) values of 40,400 and 41,900 for pepsinogens I and II, respectively. SDS-PAGE revealed M(r) values of 36,000 and 36,300 for ostrich pepsins I and II, respectively. Ostrich pepsinogens I and II were found to have identical N-terminal sequences, with Asp as N-terminal amino acid. Amino acid compositions were obtained for both pepsinogens, with ostrich pepsinogen I being slightly smaller in size with a total of 356 residues compared to 371 for ostrich pepsinogen II. Pepsinogen II showed a pI of 4.29. Ostrich pepsinogens I and II were found to be immunologically separate entities, and no cross-reactivity was observed between anti-(ostrich pepsinogen I/II) sera and porcine pepsin/pepsinogen. The study indicates that only two pepsinogens are present in the ostrich. They differ in terms of electrophoretic mobility, molecular mass and immunological reactivity, but have been found to have identical N-terminal sequences. It is concluded that both pepsinogens belong to the pepsinogen A class of aspartyl proteases (EC 3.4.23.1).

Heat denaturation of pepsinogen in a water-ethanol mixture.

The effect of ethanol and pH on thermodynamic parameters and cooperativity of pepsinogen heat denaturation was studied by scanning microcalorimetry. Addition of 20% ethanol decreases the protein denaturation temperature by 10.7 degrees C at pH 6.4 and 15.8 degrees C at pH 8.0. It also decreases the denaturation heat capacity increment from 5.8 to 4.2 kcal/K.mol. The dependences of calorimetric denaturation enthalpy on denaturation temperature both in water and 20% ethanol are linear and intersect at about 95 degrees C. In 20% ethanol the pH shift from 5.9 to 8.0 results in a decreased number of cooperative domains in pepsinogen. This process causes no changes either in the secondary structure or in the local surroundings of aromatic amino acids. It is concluded that ethanol addition does not affect the cooperativity of pepsinogen denaturation substantially until the pH change provokes redistribution of charges in the protein molecule.

The primary structure of the major pepsinogen from the gastric mucosa of tuna stomach.

The complete primary structure of the major component of tuna pepsinogens was determined by conventional protein chemistry methods. It was composed of a prosegment of 37 residues and a pepsin moiety of 323 residues, having a relative molecular mass of 39,364. The essential aspartyl residues in the active site and the three disulfide bonds common to other pepsinogens were conserved; however, several unique substitutions and/or deletions characteristic of tuna pepsinogen were found at various positions, especially in the prosegment and subsite regions, as compared with the sequences of other pepsinogens, which may affect the rate of activation of the zymogen, and/or the catalytic function and substrate specificity of the enzyme. Tuna pepsinogen is the least acidic among pepsinogens. The sequence identity between tuna pepsinogen and other pepsinogens ranged from 45 to 52%. A phylogenetic tree based on the primary structures suggested that tuna pepsinogen diverged from the pepsinogen A and prochymosin groups in an early period of pepsinogen evolution.

The renal handling of pepsinogen A isozymogens in man.

Pepsinogen A (PGA) isozymogens are low molecular weight proteins that are present in serum and urine. The differences in the molecular structure of PGA-isozymogens involve only 2-4 amino acid substitutions. In a previous study, performed in 13 subjects only, a remarkable difference between the fractional renal clearances of the main PGA-isozymogens (PGA-3, PGA-4 and PGA-5) has been demonstrated. The aim of the present study was to further investigate these differences in fractional clearance between PGA-isozymogens and to determine whether these differences are caused by differences in glomerular sieving. For this purpose the fractional clearances of PGA-isozymogens were measured in 57 subjects. In accordance with the previous study, the median fractional clearance of PGA-5 (13%) was lower than the median fractional clearance of PGA-4 (17%; p < 0.02) and the median fractional clearance of PGA-4 was lower than the median fractional clearance of PGA-3 (26%; p < 0.001). The glomerular sieving coefficients of PGA-isozymogens were measured in 11 subjects during an elective heart catheterization by means of the fractional renal extraction method. No significant difference between the glomerular sieving coefficients of PGA-isozymogens could be demonstrated, being 0.81 for PGA-3, 0.96 for PGA-4 and 0.84 for PGA-5. It is concluded that the differences in renal handling between PGA-isozymogens must be explained by differences in tubular reabsorption. These differences in tubular reabsorption between PGA-isozymogens support the hypothesis that positively charged amino acid residues of proteins are involved in the tubular protein reabsorption.

Isolation of pepsinogen A from gastric mucosa of bullfrog, Rana catesbeiana.

Two pepsinogens, named pepsinogens II-2 and III, were purified from the gastric mucosa of the bullfrog, Rana catesbeiana. The two pepsinogens were distinct from each other with respect to activation rate, sensitivity to pepstatin, amino acid composition, immunogenicity and NH2-terminal sequence. The analysis of NH2-terminal sequence showed that pepsinogen II-2 is identical to progastricsin from the bullfrog esophagus. Pepsinogen III was thought to be pepsinogen A, which has so far not been found in the bullfrog.

Human procathepsin D: three-dimensional model and isolation.

Human procathepsin D was isolated from medium of human breast cancer cell line ZR-75-1 potentiated with estrogen. The isolation involved both immunoaffinity chromatography and ion-exchange chromatography. The affinity chromatography employed polyclonal antibodies raised against a synthetic activation peptide of human cathepsin D. We have started preliminary crystallization trials using the isolated material. A model of human procathepsin D was also built using coordinates of human cathepsin D and pig pepsinogen. The model aids understanding of multiple roles played by activation peptides of aspartic proteinases and will be used as a starting model for molecular replacement.

Purification and partial characterization of canine pepsinogen A and B.

OBJECTIVE: To purify and partially characterize various isoforms of canine pepsinogen (PG) from gastric mucosa. SAMPLE POPULATION: Stomachs obtained from 6 euthanatized dogs. PROCEDURE: Mucosa was scraped from canine stomachs, and a crude mucosal extract was prepared and further purified by use of weak anion-exchange chromatography, hydroxyapatite chromatography, size-exclusion chromatography, and strong anion-exchange chromatography. Pepsinogens were characterized by estimation of molecular weights, estimation of their isoelectric points (IEPs), and N-terminal amino acid sequencing. RESULTS: Two different groups of canine PG were identified after the final strong anion-exchange chromatography: PG A and PG B. Pepsinogens differed in their molecular weights and IER Pepsinogen B appeared to be a dimer with a molecular weight of approximately 34,100 and an IEP of 4.9. Pepsinogen A separated into several isoforms. Molecular weights for the various isoforms of PG A ranged from 34,200 to 42,100, and their IEPs ranged from 4.0 to < 3.0. The N-terminal amino acid sequence for the first 25 amino acid residues for PG A and B had good homology with the amino acid sequences for these proteins in other species. CONCLUSIONS AND CLINICAL RELEVANCE: Canine PG B and several isoforms of canine PG A have been purified. Availability of these PGs will facilitate development of immunoassays to measure PG in canine serum as a potential diagnostic marker for gastric disorders in dogs.