Human renin inhibition by a diazoacyl reagent: Relationship of the enzyme to other proteinases

Human renin is inactivated by a diazoacyl compound (diazoacetylglycine ethyl ester; N₂CHCO-Gly-OEt) in the presence of Cu(II). The mechanism of the inactivation is presumably identical to that which has been determined for pepsin and several other proteinases: esterification of the β-carboxyl of an aspartic acid residue at the active site of the enzyme. Renin's inhibition by the diazoacyl reagent, its specificity toward a hydrophobic sequence, and its inhibition by pepstatin, all suggest a close relationship to the acid proteinases, especially pepsin and cathepsin D. However, renin, a neutral proteinase, would be better classified together with other diazoacyl-inhibited enzymes by active site rather than pH optimum. The term “aspartic proteinase” is suggested for this group of enzymes.     

Human immunodeficiency virus protease. Bacterial expression and characterization of the purified aspartic protease

The protease of human immunodeficiency virus has been expressed in Escherichia coli and purified to apparent homogeneity. Immunoreactivity toward anti-protease peptide sera copurified with an activity that cleaved the structural polyprotein gag p55 and the peptide corresponding to the sequence gag 128-135. The enzyme expressed as a nonfusion protein exhibits proteolytic activity with a pH optimum of 5.5 and is inhibited by the aspartic protease inhibitor pepstatin with a Ki of 1.1 microM. Replacement of the conserved residue Asp-25 with an Asn residue eliminates proteolytic activity. Analysis of the minimal peptide substrate size indicates that 7 amino acids are required for efficient peptide cleavage. Size exclusion chromatography is consistent with a dimeric enzyme and circular dichroism spectra of the purified enzyme are consistent with a proposed structure of the protease (Pearl, L.H., and Taylor, W.R. (1987) Nature 329, 351-354). These data support the classification of the human immunodeficiency virus protease as an aspartic protease, likely to be structurally homologous with the well characterized family that includes pepsin and renin.     

Modification of arginine and lysine in proteins with 2,4-pentanedione.

Primary amines react with 2,4-pentanedione at pH 6-9 to form enamines, N-alkyl-4-amino-3-penten-2-ones. The latter compounds readily regenerate the primary amine at low pH or on treatment with hydroxylamine. Guanidine and substituted guanidines react with 2,4-pentanedione to form N-substituted 2-amino-4,6-dimethylpyrimidines at a rate which is lower by at least a factor of 20 than the rate of reaction of 2,4-pentanedione with primary amines. Selective modification of lysine and arginine side chains in proteins can readily be achieved with 2,4-pentanedione. Modification of lysine is favored by reaction at pH 7 or for short reaction times at pH 9. Selective modification of arginine is achieved by reaction with 2,4-pentanedione for long times at pH 9, followed by treatment of the protein with hydroxylamine. The extent of modification of lysine and arginine side chains can readily be measured spectrophotometrically. Modification of lysozyme with 2,4-pentanedione at pH 7 results in modification of 3.8 lysine residues and less than 0.4 arginine residue in 24 hr. Modification of lysozyme with 2,4-pentanedione at pH 9 results in modification of 4 lysine residues and 4.5 arginine residues in 100 hr. Treatment of this modified protein with hydroxylamine regenerated the modified lysine residues but caused no change in the modified arginine residues. One arginine residue seems to be essential for the catalytic activity of the enzyme.     

Reinvestigation of the phenacyl bromide modification of alpha-chymotrypsin.

The modification of alpha-chymotrysin with phenacyl bromide has been reinvestigated over a wide pH range. Evidence is presented that indicates that the nature of the phenacyl-modified enzymes prepared by this reaction is dependent upon the pH of the reaction medium. The phenacyl alpha-chymotrypsin produced at low pH is most probably the Met-192 phenacylsulfonium salt, as proposed earlier, since it readily undergoes dealkylation using 2-mercaptoethanol. However, the phenacyl-enzyme prepared at neutral pH possesses a much reduced enzymatic activity and does not react with 2-mercaptoethanol to regenerate native alpha-chymotrypsin. In addition, incubation of the Met-192 phenacyl sulfonium enzyme at neutral pH causes a smooth irreversible change to the new phenacyl-enzyme as monitored by changes in enzymatic activity, susceptibility to dealkylation using 2-mercaptoethanol, and ultraviolet difference absorption spectral properties. The stoichiometries of both the low and neutral pH modification reactions have been determined, using [carbonyl-14C]phyenacyl bromide, to be 1 phenacyl group/enzyme molecule. In efforts to obtain information about the nature and mechanism of formation of the phenacyl alpha-chymotrypsin produced at neutral pH, alkylation reactions of modified alpha-chymotrypsins produced by His-57 functionalization with tosylphenylalanine chloromethyl ketone and by Met-192 oxidation to the sulfoxide have been investigated. The combined results of these studies have been initially interpreted in terms of a neutral pH, phenacyl bromide modification resulting in formation of a new modified enzyme via the Met-192 sulfonium salt.     

Spatial proximity of a tyrosyl and a lysyl residue in the active site region of yeast 3-phosphoglycerate kinase.

The effect of 7-chloro-4-nitrobenzofurazan on yeast 3-phosphoglycerate kinase causes a modification of one tyrosyl residue concomitantly with a total loss of activity of the enzyme. The modification is not accompanied by any significant conformational change. A total protection against inactivation is observed with the substrates : furthermore, AMP, tripolyphosphate and pyrophosphate afford an effective protection. At pH 9, a shift in the absorbance spectrum of the tyrosine O-nitrobenzofurazan derivative of 3-phosphoglycerate kinase is observed. It can be related to the transfer of the reagent from tyrosine to lysine. The N-nitrobenzofurazan derivative is also completely inactive. It is concluded that a lysine residue is located close to the essential tyrosyl residue.     

The modification of tryptophan in bovine thrombin.

2-Hydroxy-5-nitrobenzyl bromide, at a 100-fold molar excess, was observed to react withthrombin at pH 4.0 to give a modified enzyme which possessed 20% of the fibrinogen clotting activity and 80% of the esterase activity compared to a control preparation. Spectrophotometric analysis of the modified protein indicated that this effect on catalytic activity was associated with the incorporation of 1 mol of reagent per mol of thrombin. Amino acid analysis showed no loss of amino acids other than tryptophan. The reaction of N-bromosuccinimide with thrombin at 2-fold molar excess resulted in the modification of one tryptophan per mol of enzyme with the loss of 80% of the fibrinogen clotting activity with, as above, a considerably smaller loss of esterase activity. Oxidation of thrombin with N-bromosuccinimide decreased the extent of subsequent tryptophan modification with 2-hydroxy-5-nitrobenzyl bromide. Thrombin modified with 2-hydroxy-5-nitrobenzyl bromide showed a 3-4 fold increase in Km and a decrease in V for the ester substrate. The reaction of thrombin with 2-acetoxy-5-nitrobenzyl bromide, a substrate analogue, also resulted in the inactivation of the enzyme. The data are interpreted to show the presence of a tryptophan residue at or near the enzyme's substrate binding site.     

Studies on Lotus Seed Protease

Some physicochemical and enzymic properties of the purified lotus seed protease were investigated. The molecular weight determined from sedimentation-diffusion studies and by Sephadex G-100 gel-filtration was 36,800 and 35,500, respectively. The enzyme gave a typical ultraviolet spectrum of protein and its isoelectric point was found to be in a range of pH 3~4. The enzyme was stabilized at pH 6 in Tris-hydrochloric acid buffer by the addition of cupric ion. The inhibitory function of some reagents, especially that of potassium permanganate, and acetylation of the enzyme revealed that the tyosine residue in this enzyme protein might play some important role in the enzyme activity. Lotus seed protease was found to be fairly similar to pepsin in some properties.     

Reversal of the deoxyhypusine synthesis reaction. Generation of spermidine or homospermidine from deoxyhypusine by deoxyhypusine synthase

Deoxyhypusine synthase catalyzes the first step in hypusine (N epsilon-(4-amino-2-hydroxybutyl)lysine) synthesis in a single cellular protein, eIF5A precursor. The synthesis of deoxyhypusine catalyzed by this enzyme involves transfer of the 4-aminobutyl moiety of spermidine to a specific lysine residue in the eIF5A precursor protein to form a deoxyhypusine-containing eIF5A intermediate, eIF5A(Dhp). We recently discovered the efficient reversal of deoxyhypusine synthesis. When eIF5A([3H]Dhp), radiolabeled in the 4-aminobutyl portion of its deoxyhypusine residue, was incubated with human deoxyhypusine synthase, NAD, and 1,3-diaminopropane, [3H]spermidine was formed by a rapid transfer of the radiolabeled 4-aminobutyl side chain of the [3H]deoxyhypusine residue to 1,3-diaminopropane. No reversal was observed with [3H]hypusine protein, suggesting that hydroxylation at the 4-aminobutyl side chain of the deoxyhypusine residue prevents deoxyhypusine synthase-mediated reversal of the modification. Purified human deoxyhypusine synthase also exhibited homospermidine synthesis activity when incubated with spermidine, NAD, and putrescine. Thus it was found that [14C]putrescine can replace eIF5A precursor protein as an acceptor of the 4-aminobutyl moiety of spermidine to form radiolabeled homospermidine. The Km value for putrescine (1.12 mM) as a 4-aminobutyl acceptor, however, is much higher than that for eIF5A precursor (1.5 microM). Using [14C]putrescine as an acceptor, various spermidine analogs were evaluated as donor substrates for human deoxyhypusine synthase. Comparison of spermidine analogs as inhibitors of deoxyhypusine synthesis, as donor substrates for synthesis of deoxyhypusine (or its analog), and for synthesis of homospermidine (or its analog) provides new insights into the intricate specificity of this enzyme and versatility of the deoxyhypusine synthase reaction.     

Chemical studies on yeast hexokinase. Specific modification of a single tyrosyl residue with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide.

1. Of the 15 tyrosyl residues/subunit of yeast hexokinase A (ATP:D-hexose 6-phosphotransferase) only one residue is specifically modified at pH 8.0 with 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide hydrochloride. 2. The acylation of this single tyrosyl residue leads to the loss of the enzyme activities (hexokinase and ATPase) by a first-order process, which can be fully reversed by treatment with hydroxylamine. 3. ATP does not protect the enzyme against chemical modification and inactivation; however, glucose exerts a noticeable though indirect protection effect against chemical modification and inactivation. 4. The chemically modified enzyme, purified by column chromatography, has 14% of the activity of the native enzyme, but the Km for ATP-Mg or glucose remains unchanged as does the pH optimum of activity. Results of conformational studies (ultracentrifugation, fluorescence, thermostability and chemical reactivity of the sulfhydryl groups) indicate that the decrease of enzyme activity due to the modification of the tyrosyl residue is related to a localized perturbation of the enzyme active-center region.     

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.     

Crystal structure of aspartic proteinase from Irpex lacteus in complex with inhibitor pepstatin

The crystal structure of Irpex lacteus aspartic proteinase (ILAP) in complex with pepstatin (a six amino acid residue peptide-like inhibitor) was determined at 1.3A resolution. ILAP is a pepsin-like enzyme, widely distributed in nature, with high milk-clotting activity relative to proteolytic activity. The overall structure was in good topological agreement with pepsin and other aspartic proteases. The structure and interaction pattern around the catalytic site were conserved, in agreement with the other aspartic proteinase/inhibitor complex structures reported previously. The high-resolution data also supported the transition state model, as proposed previously for the catalytic mechanism of aspartic proteinase. Unlike the other aspartic proteinases, ILAP was found to require hydrophobic residues either in the P(1) or P(1') site, and also in the P(4) and/or P(3) site(s) for secondary interactions. The inhibitor complex structure also revealed the substrate binding mechanism of ILAP at the P(3) and P(4) site of the substrate, where the inserted loop built up the unique hydrophobic pocket at the P(4) site.     

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.     

An aspartic acid residue at the active site of pepsin. The isolation and sequence of the heptapeptide

Pepsin reacts stoicheiometrically with the active-site-directed irreversible inhibitor N-diazoacetyl-l-phenylalanine methyl ester, with concomitant loss of all proteolytic and peptidolytic activity. The reagent esterifies a unique aspartic acid residue in pepsin, which is in the sequence:Ile-Val-Asp-Thr-Gly-Thr-Ser     

米黑毛霉(M.miehei)天冬氨酸蛋白酶的研究

用硫酸铵分部盐析及离子交换层析技术从米黑毛霉半固体培养物的浸提液中提纯了天冬氨酸蛋白酶,酶活力收率为19.5％,,比活力达3080SU/mg蛋白,提纯8.5倍。用聚丙烯酰胺凝胶电泳、SDS-凝胶电泳、等电聚焦、双向免疫扩散及免疫电泳等方法鉴定该酶均一。本文还报道了关于该酶生化性质、动力学性质及化学修饰的研究结果。该酶以天冬氨酸为其活性的必需基团,系一典型的天冬氨酸蛋白酶。     

The purification and properties of a single chicken pepsinogen fraction and the pepsin derived from it

1. Evidence is given for the presence of at least five pepsinogens in a crude extract of mixed chicken stomachs. One of these was purified and could be activated to yield a single pepsin. 2. The molecular weights of the pepsinogen and pepsin were 36000 and 34000 respectively. The pepsin associated at low pH values and low ionic strength. 3. The amino acid analyses of both proteins are given. The pepsin was devoid of phosphate but contained carbohydrate. 4. The N-terminal amino acids of pepsinogen and pepsin were serine and threonine respectively. Five amino acids were released by carboxypeptidase A and it was deduced that serine may be the C-terminal one. 5. Each protein contained one thiol group per molecule as determined by titration with p-chloromercuribenzoate. The rate of the reaction was very rapid with pepsin, but much slower with pepsinogen, although the same group appeared to react in both instances. The enzymic activity of pepsin was unaffected by the modification. 6. The isoionic point of the pepsin was close to pH4.0 and the enzyme was stable for long periods at pH values up to 7.0. 7. The enzyme hydrolysed bisphenyl sulphite almost as rapidly as did pig pepsin A.     

The mitochondrial ATPase. Evidence for a single essential tyrosine residue.

1. Evidence is presented which indicates that inactivation of the mitochondrial ATPase from bovine heart by the reagent 4-chloro-7-nitrobenzofurazan results from modification of one tyrosine residue per enzyme molecule. Activity can be restored by a variety of sulphydryl reagents. 2. In sodium dodecyl sulphate, the nitrogenzofurazan group on tyrosine is transfered to newly exposed sulphydryl groups on the enzyme. 3. The rate of transfer of the nitrobenzofurazan moiety from theenzyme to sulphydryl compounds is compared with that for transfer from the model compound N-acetyl-tyrosine-0(7-nitrobenzo-furazan) ethyl ester, the synthesis and properties of which are also described. 4. The ligands ATP and ADP exert a protective effect on the rate of reaction between the mitochondrial ATPase and 4-chloro-7-nitrobenzofurazan. The variation in rate of this reaction with change in pH has also been examined and a pKa of 9.5 estimated for the tyrosine residue. 5. The modification does not prevent substrate binding as judged by changes in the fluorescence of aurovertin, an antibiotic with specific affinity for mitochondiral ATPases. 6. When the ATPase activity of submitochondrial particles is inhibited by 4-chloro-7-nitrobenzo-furazan, there is a parallel decrease in the extent of the energy-linked fluorescence enhancement of 1-anilino-naphthalene-8-sulphonate induced by ATP hydrolysis. Both ATPase activity and the fluorescence enhancement are restored by sluphydryl reagents.     

Stability profiles of nepenthesin in urea and guanidine hydrochloride: comparison with porcine pepsin A

Nepenthesin, an aspartic endopeptidase from the pitcher fluid of Nepenthes, was found to be markedly less stable than porcine pepsin A when treated with urea or guanidine hydrochloride. This is in sharp contrast with its remarkably high pH/temperature stability as compared with porcine pepsin A. No protein with such a stability profile has been reported to date.     

Mutational analysis of residues in two consensus motifs in the active sites of cathepsin E

Cathepsin E, an intracellular aspartic proteinase of the pepsin family, is composed of two homologous domains, each containing the catalytic Asp residue in a consensus DTG motif. Here we examine the significance of residues in the motifs of rat cathepsin E by substitution of Asp98, Asp283, and Thr284 with other residues using site-directed mutagenesis. Each of the mutant proenzymes, as well as the wild-type protein, was found in culture media and cell extracts when heterologously expressed in human embryonic kidney 293T cells. The single mutants D98A, D283A, and D283E, and the double mutants D98A/D283A and D98E/D283E showed neither autocatalytic processing nor enzymatic activities under acidic conditions. However, the D98E and T284S mutants retained the ability to transform into the mature forms, although they exhibited only about 13 and 40% of the activity of the wild-type enzyme, respectively. The K(m) values of these two mutants were similar to those of the wild-type enzyme, but their k(cat) values were greatly decreased. The K(i) values for pepstatin and the Ascaris pepsin inhibitor of the mutants and the wild-type enzyme were almost the same. The circular dichroism spectra of the two mutants were essentially the same as those of the wild-type enzyme at various pH values. These results indicate that (i) Asp98, Asp283, and Thr284 are indeed critical for catalysis, and (ii) the decrease in the catalytic activity of D98E and T284S mutants is brought about by an effect on the kinetic process from the enzyme-substrate complex to the release of the product.     

Arginine-specific modification of rabbit muscle phosphoglucose isomerase: Differences in the inactivation by phenylglyoxal and butanedione and in the protection by substrate analogs

Rabbit muscle phosphoglucose isomerase was modified with phenylglyoxal or 2,3-butanedione, the reaction with either reagent resulting in loss of enzymatic activity in a biphasic mode. At slightly alkaline pH butanedione was found to be approximately six times as effective as phenylglyoxal. The inactivation process could not be significantly reversed by removal of the modifier. Competitive inhibitors of the enzyme protected partially against loss of enzyme activity by either modification. The only kind of amino acid residue affected was arginine. However, more than one arginine residue per enzyme subunit was found to be susceptible to modification by the dicarbonyl reagents. From protection experiments it was concluded (i) that both modifiers react specifically with an arginine in the phosphoglucose isomerase active site and nonspecifically with one or more arginine residues elsewhere in the enzyme molecule, (ii) that modification at either loci causes loss of catalytic activity, and (iii) that butanedione has a higher preference for active site arginine than for arginine residues outside of the catalytic center whereas the opposite is true for phenylglyoxal.     

Functional tyrosyl residues of carboxypeptidase A. The effect of protein structure on the reactivity of tyrosine-198

Coupling of bovine carboxypeptidase A with diazotized 5-amino-1H-tetrazole increases esterase activity, decreases peptidase activity slightly, and modifies one tyrosyl residue. Subsequent nitration of the azoenzyme has no further effect on esterase activity, decreases peptidase activity markedly, and modifies a second tyrosyl residue. Analysis of the azopeptides isolated from a chymotrypsin digest of the doubly modified enzyme by affinity, ion exchange, and high pressure liquid chromatography indicates that the principal residue modified by diazo-1H-tetrazole is Tyr-248. Analysis of the nitropeptides isolated by similar procedures indicates that nitration occurs mainly at Tyr-198. This residue becomes susceptible to modification only as a consequence of a conformational change that accompanies azo coupling of Tyr-248. These results describe a unique example of the influence of protein structure on the reactivity of functional amino acid residues and illustrate an important aspect of chemical modification of enzymes.