Conformational change that accompanies pepsinogen activation observed in real time by fluorescence energy transfer

Pig pepsinogen has been reacted with N-carboxymethylisatoic anhydride to form N-carboxymethyl-anthraniloyl-(CMA-) pepsinogen, derivatized at Lysp18, Lysp23, Lysp27, Lysp30, and Lys320. Conformational change associated with activation was detected by following energy transfer from tryptophan residues of the pepsin moiety, excited at 295 nm, to CMA groups, monitored by emission above 415 nm. Efficiency of this energy transfer is a measure of conformational change. For this zymogen derivative the change in efficiency occurs with a first order rate constant of 0.041 s-1 at pH 2.4, 22 degrees, which equals the rate at which, following acidification, alkali-stable potential activity becomes alkali-labile. For the native zymogen the rate of this conversion had been shown to be identical to the rate of cleavage of the scissile bond of pepsinogen. Therefore, the correspondence in this derivative of the rates of conversion to alkali lability and change in energy transfer demonstrates that a conformational change accompanies the peptide bond cleavage of activation.     

Studies on the Mechanism of Activation of Pepsinogen

The mechanism of activation of pepsinogen was studied. It was found that no peptide bond cleavage occurred in the molecule of denatured pepsinogen at pH 2. It was inferred from this that a specific secondary and tertiary structure is formed in the molecule of pepsinogen in acid and that it might be necessary for the hydrolysis of the peptide bond. From the circular dichroism studies on pepsinogen and pepsin, it was found that there is a conformational change in the molecule of pepsinogen at pH 4.3~4.5 and that this change is followed by a gradual formation of pepsin.     

Mechanism of intramolecular activation of pepsinogen. Evidence for an intermediate delta and the involvement of the active site of pepsin in the intramolecular activation of pepsinogen.

Intramolecular pepsinogen activation is inhibited either by pepstatin, a potent pepsin inhibitor, or by purified globin from hemoglobin, a good pepsin substrate. Also, pepsinogen at pH 2 can be bound to a pepstatin-Sepharose column and recovered as native zymogen upon elution in pH 8 buffer. Kinetic studies of the globin inhibition of pepsinogen activation show that globin binds to a pepsinogen intermediate. This interaction gives rise to competitive inhibition of intramolecular pepsinogen activation. The evidence presented in this paper suggests that pepsinogen is converted rapidly upon acidification to the pepsinogen intermediate delta. In the absence of an inhibitor, the intermediate undergoes conformational change to bind the activation peptide portion of this same pepsinogen molecule in the active center to form an intramolecular enzyme-substrate complex (intermediate theta). This is followed by the intramolecular hydrolysis of the peptide bond between residues 44 and 45 of the pepsinogen molecule and the dissociation of the activation peptide from the pepsin. Intermediate delta apparently does not activate another pepsinogen molecule via an intermolecular process. Neither does intermediate delta hydrolyze globin substrate.     

A new substrate for porcine pepsin possessing cryptic fluorescence properties

A fluorescent substrate for porcine pepsin, 50-dimethylaminonaphthalene-1-sulfonyl (Dns)-Ala-Ala-Phe-Phe-3-[4-(N-CH3)-pyridyl]propyl-1-oxy ester has been synthesized. It is stable, soluble from pH 1 to 7, and is readily hydrolyzed by pepsin with values of 288 (+/- 40) s-1 for kcat, 0.039 mM (+/- 0.005) for Km, and 7510 s-1 mM-1 (+/- 500) for kcat/Km in sodium formate, pH 3.1. Kinetic studies were carried out by following the increased fluorescence (300-nm excitation, 525-nm emission) as hydrolysis occurred. The products of hydrolysis were identified and established that the peptide bond between the phenylalanine residues is cleaved by pepsin. The inhibition of pepsin catalysis by pepsinogen (1-12) activation peptide was studied in order to compare the inhibition of the reaction of pepsin with Dns-Ala-Ala-Phe-Phe-OP4P-CH3+ with that obtained by the standard milk-clotting assay. The inhibition results were comparable. Dns-Ala-Ala-Phe-Phe-OP4P-CH3+ should be a valuable tool for studies of pepsin because of its solubility over an extended pH range, its excellent turnover rate, and the ease with which the hydrolysis can be followed.     

Studies on the Mechanism of Activation of Pepsinogen

Experiments were carried out on the effects of substrate or competitive inhibitor on the rate of appearance of N-terminal isoleucine residue of pepsin and peptides released from pepsinogen in its conversion to pepsin. Assumptions were made from these experiments, that an active site is initially formed in pepsinogen by acidification of its solution, and that peptide bond between 41-glutamyl and 42-isoleucyl residues locates in the juxtaposition to the active site forming an intramolecular enzyme-substrate complex. Thus, N-terminal tail of pepsinogen is released by a hydrolysis catalyzed by its own active site.

It was Indeed ascertained in this study that neither a small amount of pepsin which could be accompanied by pepsinogen preparation used contributes to the initial step of hydrolysis of pepsinogen nor pepsin formed accelerates the following activation process.

Therefore, it was concluded that the conversion of pepsinogen to pepsin is self-degrad-ation process.     

Activation mechanism of monkey and porcine pepsinogens A. One-step and stepwise activation pathways and their relation to intramolecular and intermolecular reactions

The activation of Sepharose-bound monkey pepsinogen A under acidic conditions proceeded by cleavage of the Leu47-Ile48 bond, indicating the occurrence of the intramolecular one-step activation, although the rate of cleavage was very slow. On the other hand the activation of monkey pepsinogen A in solution was highly dependent on pepsinogen concentration and the addition of exogenous pepsin A accelerated the rate of activation, indicating the predominance of intermolecular reaction. The cleavage site, however, was also restricted to the Leu47-Ile48 bond. Thus, apparently exclusive one-step activation occurred in monkey pepsinogen. The activation of porcine pepsinogen A in solution was also dependent on pepsinogen concentration and the addition of exogenous pepsin A accelerated the rate of activation. The major cleavage site by the exogenously added pepsin was the Leu44-Ile45 bond. Therefore the site most susceptible to the intermolecular attacks was the bond connecting the activation segment and the pepsin moiety in both monkey and porcine pepsinogens. In porcine pepsinogen, however, a part of the zymogen was activated through the intermediate form, and an intramolecular reaction was suggested to be involved in the generation of this form. These results showed that in both pepsinogens A the intramolecular reaction occurred, first yielding pepsin A or the intermediate form, which then acted intermolecularly on the remaining pepsinogen or the intermediate form to complete the activation in a short time. A molecular mechanism for the activation reaction was proposed to explain consistently the experimental results.     

ISOLATION,CRYSTALLIZATION, AND PROPERTIES OF SWINE PEPSINOGEN

1. A method is described for the preparation of pepsinogen from swine gastric mucosae which consists of extraction and fractional precipitation with ammonium sulfate solutions followed by two precipitations with a copper hydroxide reagent under particular conditions. Crystallization as very thin needles takes place at 10°C., pH 5.0 and from 0.4 saturated ammonium sulfate solution containing 3–5 mg. protein nitrogen per milliliter. 2. Solubility measurements, fractional recrystallization, and fractionation experiments based on separation after partial heat or alkali denaturation and after partial reversal of heat or alkali denaturation failed to reveal the presence of any protein impurity. 3. The properties of the enzymatically inactive pepsinogen were studied and compared with the properties of crystalline pepsin. The properties of pepsinogen which are similar to those of pepsin are: molecular weight, absorption spectrum, tyrosine-tryptophane content, and elementary analysis. The properties in which they differ are: enzymatic activity, crystalline form, amino nitrogen, titration curve, pH stability range, specific optical rotation, isoelectric point, and the reversibility of heat or alkali denaturation. 4. Conversion of pepsinogen into pepsin at pH 4.6 was found to be autocatalytic; i.e., the pepsin formed catalyzes the reaction. Conversion of pepsinogen into pepsin is accompanied by the splitting off of a portion of the molecule containing 15–20 per cent of the pepsinogen nitrogen.     

Activation of spin-labeled chicken pepsinogen

Chicken pepsinogen has been spin-labeled by the attachment of four nitroxides to epsilon-amino groups near the protein's amino terminus. Acidification results in a bond cleavage, generating a nonlabeled, enzymatically active protein. Electron spin resonance spectra of the spin-labeled zymogen, acidified in the presence or absence of pepstatin, are identical and indicate that the nitroxides are quite mobile, compared to the nonacidified zymogen. This mobilization is interpreted as the freeing of the peptide to which the spin-labels are attached, from the protein, subsequent to the acidification that causes a peptide bond cleavage. The rate at which the peptide leaves the protein is 1 order of magnitude slower than the cleavage of the peptide bond, measured by the rate of appearance of milk-clotting activity (first-order rate constants of 0.3 min-1 vs. 6 min-1 at pH 2, 22 degrees C). The inclusion of pepstatin, at molar ratios above 2 during activation, decreases the rate of peptide leaving. These observations, and those previously reported for activation of spin-labeled pig pepsinogen, are incorporated into a model of pepsinogen activation.     

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

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.     

Isolation of an activation intermediate and determination of the amino acid sequence of the activation segment of human pepsinogen A

Upon activation of human pepsinogen A at pH 2.0 in the presence of pepstatin, an intermediate form was generated together with pepsin A. This activation intermediate could be separated from pepsinogen A and pepsin A by DE-32 cellulose chromatography at pH 5.5. It had a molecular weight intermediate between those of pepsinogen A and pepsin A, and contained about half the number of basic amino acid residues in pepsinogen A. It had phenylalanine as the amino(N)-terminal amino acid, and was deduced to be generated by release of N-terminal 25 residue segment from pepsinogen A. Amino acid sequence determination of the N-terminal portions of pepsinogen A and the intermediate from enabled us to elucidate the entire acid sequence of the 47-residue activation peptide segment as follow: [Formula: see text]. On the other hand, upon activation of pepsinogen A at pH 2.0 in the absence of pepstatin, cleavage of the activation segment occurred at several additional bonds. In addition, upon activation both in the presence and in the absence of pepsitatin, an additional activation intermediate, designated pepsin A', was formed in minor quantities. This form was identical with pepsin A, except that it had an additional Pro-Thr-Leu sequence preceding the N-terminal valine of pepsin A.     

Purificaton and characterization of a pepsinogen and its pepsin from proventriculus of the Japanese quail

A crude extract of the proventriculus of the Japanese quail gave at least five bands of peptic activity at pH 2.2 on polyacrylamide gel electrophoresis. The main component, constituting about 40% of the total acid protease activity, was purified to homogeneity by hydroxyapatite and DEAE-Sepharose column chromatographies. At below pH 4.0, the pepsinogen was converted to a pepsin, which had the same electrophoretic mobility as one of the five bands of peptic activity present in the crude extract. The molecular weights of the pepsinogen and the pepsin were 40 000 and 36 000, respectively. Quail pepsin was stable in alkali up to pH 8.5. The optimal pH of the pepsin on hemoglobin was pH 3.0. The pepsin had about half the milk-clotting activity of purified porcine pepsin, but the pepsinogen itself had no activity. The hydrolytic activity of quail pepsin on N-acetyl-L-phenylalanyl-3,5-diiodo-L-tyrosine was about 1% of that of porcine pepsin. Among the various protease inhibitors tested, only pepstatin inhibited the proteolytic activity of the pepsin. The amino acid composition of quail pepsinogen was found to be rather similar to that of chick pepsinogen C, and these two pepsinogens possessed common antigenicity.     

Use of enhanced green fluorescent protein to determine pepsin at high sensitivity

A fluorometric assay for pepsin and pepsinogen was developed using enhanced green fluorescent protein (EGFP) as a substrate. Acid denaturation of EGFP resulted in a complete loss of fluorescence that was completely reversible on neutralization. In the proteolytic assay procedure, acid-denatured EGFP was digested by pepsin or activated pepsinogen. After neutralization, the remaining amount of undigested EGFP refolded and was determined by fluorescence. Under standard digestion conditions, 4.8-24.0 ng pepsin or pepsinogen was used. Using porcine pepsin as a standard, 38+/-6.7 ng EGFP was digested per min-1 ng pepsin-1. Activated porcine pepsinogen revealed a similar digestion rate (37.2+/-5.2 ng EGFP min-1 ng activated pepsinogen-1). The sensitivity of the proteolysis assay depended on the time of digestion and the temperature. Increasing temperature and incubation time allowed quantification of pepsin or pepsinogen in a sample even in the picogram range. The pepsin-catalyzed EGFP digestion showed typical Michaelis-Menten kinetics. Km and Vmax values were determined for the pepsin and activated pepsinogen. Digestion of EGFP by pepsin revealed distinct cleavage sites, as analyzed by SDS-PAGE.     

Immunochemical Studies on the Components of the Pepsinogen System

Rabbit antisera to pepsin and pepsinogen were characterized by several immunological criteria. Both antisera inhibited the rennet activity of pepsin. Antipepsinogen protected pepsin from alkaline denaturation. Using antipepsinogen, precipitin analysis at pH 5.5 indicated that the native enzyme resembles the precursor more closely than did the denatured enzyme. However, all three proteins have some antigenic sites in common. Both antisera reacted more efficiently with their homologous antigens. When measured by C' fixation, the pepsinogen-antipepsinogen system was inhibited by pepsin and to a greater degree, by the activation mixture and the pepsin-inhibitor complex. Pepsin-antipepsin was inhibited by pepsinogen. The specificity of these two antibodies toward pepsin and pepsinogen conformation was used to measure the disappearance of pepsinogen and the concomitant appearance of pepsin during autocatalytic conversion at pH 4.6. The experimental results obtained during the conversion could be duplicated by using varying proportions of pepsin and pepsinogen in the model system. The potentialities of employing these antisera to detect conformational changes such as the unmasking of the pepsin moiety in pepsinogen molecules modified by physical or chemical reagents are discussed.     

Modification of swine pepsin and pepsinogen by p-nitrophenyldiazonium chloride

It was found that at pH 5.2 and 40-fold excess of p-nitrophenyldiazonium chloride the inhibitor incorporation into the porcine pepsin molecule involves 1.9 residues, one residue being bound to tyrosine 189. Besides, tyrosines 44, 113, 154 and 174 enter the reaction. Modified pepsin retains 25% of the native enzyme activity. In the pepsinogen molecule the degree of tyrosine 189 modification diminishes 5 times; of 1.5 inhibitor molecules incorporated into the protein 0.78 residues are bound to tyrosine 113. The potential proteolytic activity of modified pepsinogen towards haemoglobin cleavage makes up to 60% of the original one. It is concluded that the activation peptide in the pepsinogen molecule masks the substrate binding site bearing tyrosine 189, thus preventing its modification with p-nitrophenyldiazonium chloride. The activation peptide in the pepsinogen molecule is presumably located in the vicinity of the wide loop bend carrying tyrosine residue 113, which may be the reason for the decreased pKa value of this residue and of its increased reactivity in the azocoupling reaction.     

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.     

The synthesis, purification, and evaluation of a chromophoric substrate for pepsin and other aspartyl proteases: design of a substrate based on subsite preferences

A convenient chromophoric assay for porcine pepsin has been developed using a new synthetic substrate. The sequence of this substrate was chosen based on the known subsite preferences for this enzyme. The peptide contains a phenylalanyl-p-nitrophenylalanine sequence at the reactive site. Cleavage of this bond yields a change in absorbance at 310 nm of between 1700 and 2000 per mole. This allows kinetic data to be obtained readily and accurately. The products of cleavage have been identified by isolation of a peptide fragment by high-performance liquid chromatography. Values of kcat, Km, and kcat/Km of 94 +/- 6 s-1, 0.13 +/- .04 mM, and 815 +/- 210 s-1/mM-1 were obtained at pH 3.0 and 37 degrees C. The peptide is soluble over the pH range from 2 to 7, thus facilitating determination of the pH dependence of the kinetic parameters. The substrate is also valuable in studying the inhibition of pepsin.     

N-terminal portion acts as an initiator of the inactivation of pepsin at neutral pH.

Porcine pepsin, an aspartic protease, is unstable at neutral pHs where it rapidly loses activity, however, its zymogen, pepsinogen, is stable at neutral pHs. The difference between the two is the presence of the prosegment in pepsinogen. In this study, possible factors responsible for instability were investigated and included: (i) the distribution of positively charged residues on the surface, (ii) an insertion of a peptide in the C-terminal domain and (iii) the dissociation of the N-terminal fragment of pepsin. Mutations to change the number and the distribution of positive charges on the surface had a minor effect on stability. No effect on stability was observed for the deletion of a peptide from the C-terminal domain. However, mutations on the N-terminal fragment had a major impact on stability. At pH 7.0, the N-fragment mutant was inactivated 5.8 times slower than the wild-type. The introduction of a disulfide bond between the N-terminal fragment and the enzyme body prevented the enzyme from denaturing. The above results showed that the inactivation of pepsin was initiated by the dissociation of the N-fragment and that the sequence of this portion was a major determinant for enzyme stability. Through this study, we have created porcine pepsin with increased pH stability at neutral pHs.     

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

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.     

Early events of pepsinogen activation

Stopped-flow measurements both with native pig pepsinogen and with a fluorescent derivative, labeled near the carboxyl terminus with a toluidinylnaphthalenesulfonyl (TNS) group at Lys364, show rapid fluorescence changes following acidification. The rate constants observed by intrinsic fluorescence of the native zymogen are distinctly greater than those exhibited by the TNS derivative in the pH range examined. The rate constants for two early events in the activation of the derivative increase as the pH decreases from pH 3 to pH 2. The fluorescent intensities of these two processes also vary with pH. Because the ratios of these amplitudes fit the Henderson-Hasselbalch equation, it is concluded that the two processes represent concurrent events, rather than sequential ones. It is proposed that a protonation separates two forms of the zymogen. The conjugate acid undergoes the slower event, whereas the conjugate base, which predominates at pH 3, undergoes the faster event. It is proposed that both these pathways result in activation.     

Molecular characteristics of pepsinogen and pepsin from duck glandular stomach

1. Two procedures were developed for the preparation of duck pepsinogen, an enzyme from the family of aspartic proteases (EC 3.4.23.1) and its zymogen. 2. The amino acid composition, sugar content and the partial N- and C-terminal sequences of both the enzyme and the zymogen were determined. These sequences are highly homologous with the terminal sequences of chicken pepsin(ogen). 3. Duck pepsinogen and pepsin are unlike other pepsin(ogen)s in being relatively stable in alkaline media: pepsinogen is inactivated at pH 12.1, pepsin at pH 9.6. 4. Duck pepsin is inhibited by diazoacetyl-D,L-norleucine methyl ester (DAN), 1,2-epoxy-3(p-nitrophe-noxy)propane (EPNP), pepstatin and a synthetic pepsin inhibitor Val-D-Leu-Pro-Phe-Phe-Val-D- Leu. The pH-optimum of duck pepsin determined in the presence of synthetic substrate is pH 4. 5. Duck pepsin has a marked milk-clotting activity whereas its proteolytic activity is lower than that of chicken pepsin. 6. The activation of duck pepsinogen is paralleled by two conformational changes. The activation half-life determined in the presence of a synthetic substrate at pH 2 and 14 degrees C is 20 sec.