Synthesis and hydrolysis by cysteine and serine proteases of short internally quenched fluorogenic peptides

We developed sensitive substrates for cysteine proteases and specific substrates for serine proteases based on short internally quenched fluorescent peptides, Abz-F-R-X-EDDnp, where Abz (ortho-aminobenzoic acid) is the fluorescent donor, EDDnp [N-(ethylenediamine)-2,4-dinitrophenyl amide] is the fluorescent quencher, and X are natural amino acids. This series of peptides is compared to the commercially available Z-F-R-MCA, where Abz and X replace carbobenzoxy (Z) and methyl-7-aminocoumarin amide (MCA), respectively; and EDDnp can be considered a P(2)' residue. Whereas MCA is the fluorescent probe and cannot be modified, in the series Abz-F-R-X-EDDnp the amino acids X give the choice of matching the specificity of the S(1)' enzyme subsite, increasing the substrate specificity for a particular protease. All Abz-F-R-X-EDDnp synthesized peptides (for X = Phe, Leu, Ile, Ala, Pro, Gln, Ser, Lys, and Arg) were assayed with papain, human cathepsin L and B, trypsin, human plasma, and tissue kallikrein. Abz-F-R-L-EDDnp was the best substrate for papain and Abz-F-R-R-EDDnp or Abz-F-R-A-EDDnp was the more susceptible to cathepsin L. Abz-F-R-L-EDDnp was able to detect papain in the range of 1 to 15 pM. Human plasma kallikrein hydrolyzed Abz-F-R-R-EDDnp with significant efficiency (k(cat)/K(m) = 1833 mM(-1) s(-1)) and tissue kallikrein was very selective, hydrolyzing only the peptides Abz-F-R-A-EDDnp (k(cat)/K(m) = 2852 mM(-1) s(-1)) and Abz-F-R-S-EDDnp (k(cat)/K(m) = 4643 mM(-1) s(-1)). All Abz-F-R-X-EDDnp peptides were resistant to hydrolysis by thrombin and activated factor X.     

Cyclic, Linear, Cycloretro-Isomer, and Cycloretro-Inverso Peptides Derived from the C-Terminal Sequence of Bradykinin as Substrates or Inhibitors of Serine and Cysteine Proteases

We investigated the inhibition of trypsin, human tissue (hK1) and human plasma kallikrein (HuPK), papain, and cathepsin L, B, and X by synthetic cyclic, cycloretro-isomer, cycloretro-inverso, and linear peptides derived from the C-terminal sequence of bradykinin. c(FSPFRG) and Ac-FSPFRG-NH2 were taken as the references for cyclic and linear peptides, respectively. Longer and more flexible analogs of them with addition of 2, 3, or 4 Gly and cycloretro-isomer and cycloretro-inverso analogs of c(FSPFRG) and c(GGGFSPFRG) were obtained and assayed. The susceptibility to hydrolysis of the peptides to all proteases was also examined. The highest affinities were found for c(FSPFRG) with hK1, Ac-GGFSPFRG-NH2 with HuPK, and psi (NHCO) c(fspfrG) with cathepsin L. The Ki values for cathepsin B and X with cyclic peptides were lower than those of linear peptides. The serine proteases hydrolyzed all linear and cyclic peptides, except c(FSPFRG) and c(GFSPFRG). The cysteine proteases hydrolyzed only the linear peptides, which were poor substrates. Although the Ki values obtained in the current work were in the microM range, the cyclic and cycloretro-inverso peptides seem to be a promising approach to develop efficient and resistant to hydrolysis inhibitors for the kallikreins and lysosomal cysteine proteases.     

Microassay for proteolytic enzymes using a new radioactive anilide substrate

The synthesis of benzoyl-dl-arginine [³H]anilide hydrochloride is described and it is shown to be a sensitive substrate for papain and trypsin. The virtual stability of the radioactive anilide to spontaneous hydrolysis serves to assay submicrograms of both trypsin and papain. Rates as low as 16 pmoles of anilide hydrolyzed per minute can be measured when used in a continuous radioactive assay.     

Internally quenched fluorescent peptide libraries with randomized sequences designed to detect endopeptidases

Identification of synthetic peptide substrates for novel peptidases is an essential step for their study. With this purpose we synthesized fluorescence resonance energy transfer (FRET) peptide libraries Abz (or MCA)-GXXXXXQ-EDDnp and Abz (or MCA)-GXXZXXQ-EDDnp, where X consists of an equimolar mixture of all amino acids, the Z position is fixed with one of the proteinogenic amino acids (cysteine was excluded), Abz (ortho-aminobenzoic acid) or MCA ([7-amino-4-methyl]coumarin) is the fluorescence donor and Q-EDDnp (glutamine-[N-(2,4-dinitrophenyl)-ethylenediamine]) is the fluorescence acceptor. The peptide libraries MCA-GXXX↓XXQ-EDDnp and MCA-GXXZ↓XXQ-EDDnp were cleaved as indicated (↓) by trypsin, chymotrypsin, cathepsin L, pepsin A, and Eqolisin as confirmed by Edman degradation of the products derived from the digestion of these libraries. The best hydrolyzed Abz-GXXZXXQ-EDDnp sublibraries by these proteases, including Dengue 2 virus NS2B-NS3 protease, contained amino acids at the Z position that are reported to be well accepted by their S(1) subsite. The pH profiles of the hydrolytic activities of these canonical proteases on the libraries were similar to those reported for typical substrates. The FRET peptide libraries provide an efficient and simple approach for detecting nanomolar concentrations of endopeptidases and are useful for initial specificity characterization as performed for two proteases secreted by a Bacillus subtilis.     

(S)-Thiirancarboxylic acid as a reactive building block for a new class of cysteine protease inhibitors

For (S)-thiirancarboxylic acid a second-order rate constant of k2nd = 222 M(-1) min(-1) for the irreversible inhibition of papain was determined. The ethyl and methyl ester do not inhibit the enzyme time-dependently. An improved synthesis of enantiomerically pure thiirancarboxylic acid is described. It is shown that thiirancarboxylates can be substrates for serine proteases (alpha-chymotrypsin) and esterases (pig liver esterase) and even for metallo proteases (thermolysin).     

Kinetics of hydrolysis of phenylthiazolones of arginine, homoarginine, norarginine, and canaavanine by trypsin.

Phenylthiazolones (PTAs) of arginine and its homologs and analogs, homoarginine, norarginine (alpha-amino-gamma-guanidinobutyric acid), canavanine, and gamma-hydroxyarginine, were prepared. A steady-state kinetic analysis of the trypsin [EC 3.4.21.4]-catalyzed hydrolysis reactions was carried out and the kinetic parameters for these internal thioesters were compared with those for normal linear ester substrates. PTA-gamma-hydroxyarginine was so labile that hydrolysis by the enzyme could not be followed. PTA-arginine has a specificity constant (Kcat/Km) comparable to that for the Nalpha-unblocked arginine ester substrate, though the value is about 0.1% of that for a specific ester substrate, Nalpha-tosylarginine methyl ester. PTA derivatives of canavanine and homoarginine were hydrolyzed with Kcat/Km walues of the same order of magnitude as that for PTA-arginine. However, PTA-noraginine was much less susceptible to tryptic hydrolysis that PTA-homoarginine, while the linear esters of norarginine are known to be more susceptible than those of homoarginine.     

Sensitive assay of cysteine proteinases using new peptide p-nitroanilides

N-Succinyl-glycyl-leucyl-cystein(S-benzyl) p-nitroanilide and N-succinyl-leucyl-leucyl-cystein(S-benzyl) p-nitroanilide were found to be very sensitive substrates for the assay of papain, ficin, and bromelain. These p-nitroanilides were hydrolyzed only very slightly by chymotrypsin, but not detectably by trypsin.     

Interactions of derivatives of guanidinophenylalanine and guanidinophenylglycine with Streptomyces griseus trypsin

The rates of hydrolysis of the ester, amide and anilide substrates of p-guanidino-L-phenylalanine (GPA) by Streptomyces griseus trypsin (S. griseus trypsin) were compared with those of arginine (Arg) substrates. The specificity constant (kcat/km) for the hydrolysis of GPA substrates by the enzyme was 2-3-times lower than that for arginine substrates. The kcat and Km values for the hydrolysis of N alpha-benzoyl-p-guanidino-L-phenylalanine ethyl ester (Bz-GPA-OEt) by S. griseus trypsin are in the same order of magnitude as those of N alpha-benzoyl-L-arginine ethyl ester (Bz-Arg-OEt), although both values for the former when hydrolyzed by bovine trypsin are higher by one order of magnitude than those for the latter. The specificity constant for the hydrolysis of Bz-GPA-OEt by S. griseus trypsin is much higher than that for N alpha-benzoyl-p-guanidino-L-phenylglycine ethyl ester (Bz-GPG-OEt). As with the kinetic behavior of bovine trypsin, low values in Km and kcat were observed for the hydrolysis of amide and anilide substrates of GPA by S. griseus trypsin compared with those of arginine substrates. The rates of hydrolysis of GPA and arginine substrates by S. griseus trypsin are about 2- to 62-times higher than those obtained by bovine trypsin. Substrate activation was observed with S. griseus trypsin in the hydrolysis of Bz-GPA-OEt as well as Bz-Arg-OEt, whereas substrate inhibition was observed in three kinds of N alpha-protected anilide substrates of GPA and arginine. In contrast, no activation by the amide substrate of GPA could be detected with this enzyme.     

Flu virion as a substrate for proteolytic enzymes

The proteolysis of flu virions of the strain A/Puerto Rico/8/34 (subtype H1N1) by enzymes of various classes was studied to develop an approach to the study of the structural organization and interaction of the basic protein components of the virion environment: hemagglutinin (HA), transmembrane homotrimeric glycoprotein, and matrix protein M1 forming a layer under the lipid membrane. Among the tested proteolytic enzymes and enzymic preparations (thermolysin, trypsin, chymotrypsin, subtilisin Carlsberg, pronase, papain, and bromelain), the cysteine proteases bromelain and papain and the enzymic preparation pronase efficiently deleted HA ectodomains, while chymotrypsin, trypsin, and subtilisin Carlsberg deleted only a part of them. An analysis by MALDI TOF mass spectrometry allowed us to locate the sites of HA hydrolysis by various enzymic preparations. Bromelain, papain, trypsin, and pronase split the polypeptide chain after the K177 residue located before the transmembrane domain (HA2 185-211). Subtilisin Carlsberg hydrolyzed the peptide bond at other neighboring points: after L178 (a basic site) or V176. The hydrolytic activity of bromelain measured by a highly specific chromogenic substrate of cysteine proteases Glp-Phe-Ala-pNA was almost three times higher in the presence of 5 mM beta-mercaptoethanol than in the presence of 50 mM. However, the complete removal of exodomains of HA, HA, and low-activity enzyme by the HA high- and low-activity enzyme required identical time intervals. In the absence of the reducing reagent, the removal of HA by bromelain proceeded a little more slowly and was accompanied by significant fragmentation of protein Ml1. The action of trans-epoxysuccinyl-L-leucylamido)butane (E-64), a specific inhibitor of cysteine proteases, and HgCl2 on the hydrolysis of proteins HA and M1 by bromelain was investigated.     

Hymenolepis diminuta: interactions of the isolated brush border membrane with proteolytic enzymes

Proteins of the isolated brush border membrane of Hymenolepis diminuta were hydrolyzed in vitro by chymotrypsin, papain, pepsin, subtilopeptidase A (= subtilisin Carlsberg), and trypsin. Neither proteolytic nor amidase activity was demonstrable in the isolated membrane using proteinaceous (casein and hemoglobin) or chromogenic (benzoyl-arginine-p-nitroanilide and succinyl-alanyl-alanyl-propyl-phenylalanine p-nitroanilide) substrates, and the membrane preparation did not inhibit the proteolytic and amidase activities of these enzymes. Thus, the isolated tegumental membrane of H. diminuta is not inherently resistant to the action of proteolytic enzymes, and it does not inhibit proteolytic activity. In control incubations containing only buffer, the alkaline phosphatase activity of the brush border membrane decreased in a time dependent manner, but in the presence of chymotrypsin, subtilopeptidase A, and trypsin, the membrane retained greater alkaline phosphatase activity (pepsin and papain could not be tested for this effect on alkaline phosphatase activity). A similar time dependent decrease in activity was also noted for each of the proteolytic enzymes in control assays, but subtilopeptidase A and papain retained greater activity in the presence of the isolated membrane preparation when these assays were compared to controls.     

The Bsmoc group as a novel scaffold for the design of irreversible inhibitors of cysteine proteases

Carbamate and ester derivatives of the 1,1-dioxobenzo[b]thiophen-2-ylmethyloxycarbonyl (Bsmoc) scaffold react readily with thiols via a Michael addition at rates not significantly affected by the nature of the carboxylic or carbamic acid leaving group. These Michael acceptors are irreversible inhibitors of the cysteine proteases papain and human liver cathepsin B, displaying first-order kinetics with respect to inhibitor concentration. In contrast, none of the Bsmoc derivatives inhibited porcine pancreatic elastase, a serine protease.     

N-succinyl-alanyl-methionyl-S-benzylcysteine p-nitroanilide as a sensitive substrate for assaying activity of cysteine proteinases

N-Succinyl-alanyl-methionyl-S-benzylcysteine p-nitroanilide has been found to be a very sensitive chromogenic substrate for the assay of cysteine proteinase papain, ficin and bromelain. N-Succinyl-alanyl-S-benzylcysteine p-nitroanilide and N-succinyl-alanyl-alanyl-S-benzylcysteine p-nitroanilide are also suitable for this purpose. These substrates were hydrolyzed only very slightly or not hydrolyzed at all by trypsin.     

Activities of native and tyrosine-69 mutant phospholipases A2 on phospholipid analogues. A reevaluation of the minimal substrate requirements

The role of Tyr-69 of porcine pancreatic phospholipase A2 in substrate binding was studied with the help of proteins modified by site-directed mutagenesis and phospholipid analogues with a changed head-group geometry. Two mutants were used containing Phe and Lys, respectively, at position 69. Modifications in the phospholipids included introduction of a sulfur at the phosphorus (thionophospholipids), removal of the negative charge at phosphorus (phosphatidic acid dimethyl ester), and reduction (phosphonolipids) or extension (diacylbutanetriol choline phosphate) of the distance between the phosphorus and the acyl ester bond. Replacement of Tyr-69 by Lys reduces enzymatic activity, but the mutant enzyme retains both the stereospecificity and positional specificity of native phospholipase A2. The Phe-69 mutant not only hydrolyzes the Rp isomer of thionophospholipids more efficiently than the wild-type enzyme, but the Sp thiono isomer is hydrolyzed too, although at a low (approximately 4%) rate. Phosphonolipids are hydrolyzed by native phospholipase A2 about 7 times more slowly than natural phospholipids, with retention of positional specificity and a (partial) loss of stereospecificity. The dimethyl ester of phosphatidic acid is degraded efficiently in a calcium-dependent and positional-specific way by native phospholipase A2 and by the mutants, indicating that a negative charge at phosphorus is not an absolute substrate requirement. The activities on the phosphatidic acid dimethyl ester of native enzyme and the Lys-69 mutant are lower than those on the corresponding lecithin, in contrast to the Phe-69 mutant, which has equal activities on both substrates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and Properties of Cystathionine [gamma]-Synthase from Wheat (Triticum aestivum L.)

Cysthathionine [gamma]-synthase (CS), an enzyme involved in methionine biosynthesis, was purified from an acetone powder prepared from wheat (Triticum aestivum L.). After several chromatographic steps and radiolabeling of the partially purified enzyme with sodium cyanoboro[3H]hydride, a single polypeptide with a molecular weight of 34,500 was isolated by sodium dodecyl sulfate-high performance electrophoresis chromatography. Since the molecular weight of the native enzyme was 155,000, CS apparently consists of four identical subunits. The pyridoxal 5[prime]-phosphate-dependent forward reaction has a pH optimum of 7.5 and follows a hybrid ping-pong mechanism with Km values of 3.6 mM and 0.5 mM for L-homoserine phosphate and L-cysteine, respectively. L-Cysteine methyl ester, thioglycolate methyl ester, and sodium sulfide were also utilized as thiol substrates. The latter observation suggests that CS and phosphohomoserine sulfhydrase might be a single enzyme. CS does not seem to be a regulatory enzyme but was irreversibly inhibited by DL-propargylglycine (Ki = 45 [mu]M, Kinact = 0.16 min-1). Furthermore, the homoserine phosphate analogs 4-(phosphonomethyl)-pyridine-2-carboxylic acid, Z-3-(2-phosphonoethen-1-yl)pyridine-2-carboxylic acid, and DL-E-2-amino-5-phosphono-3-pentenoic acid acted as reversible competitive inhibitors with Ki values of 45, 40, and 1.1 [mu]M, respectively.     

Identification of serine esterases in tissue homogenates

Serine esterases react with [3H]diisopropylphosphofluoridate ([3H]DFP) to produce radioactive adducts that can be resolved by denaturing slab gel electrophoresis. To identify an esterase or its catalytic subunit, a potential substrate was included in the reaction mixture with the expectation that it would suppress the enzyme's reaction with [3H]DFP. The nature of the enzyme could be inferred from the character of the substrates that suppress labeling. The validity of this analytical method was tested with two serine proteases, trypsin and alpha-chymotrypsin, and two serine esterases, acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE), and several of their natural or model substrates or inhibitors. Application of the method to complex biological systems was tested with chicken embryo brain microsomes. Trypsin labeling with [3H]DFP was suppressed by alpha-N-benzoyl-l-arginine ethyl ester (BAEE) and poly-l-lysine but not by benzoyl-l-tyrosine ethyl ester (BTEE). [3H]DFP labeling of chymotrypsin was suppressed by both BAEE and BTEE. Labeling of AChE and BuChE was suppressed by their natural and some related substrates and inhibitors. [3H]DFP reacted with brain microsomes to produce nine distinct radioactive bands. When the relevant substrates and inhibitors of AChE were included in the reaction mixtures, labeling of only the 95-kDa band was suppressed, implicating it as AChE. Labeling of the 85- and 79-kDa bands was inhibited by butyrylcholine, suggesting that these proteins have BuChE activity.     

Chromogenic and fluorogenic glycosylated and acetylglycosylated peptides as substrates for serine, thiol and aspartyl proteases.

We synthesized short chromogenic peptidyl-Arg-p-nitroanilides containing either (Galbeta)Ser or (Glcalpha,beta)Tyr at P2 or P3 sites as well as O-acetylated sugar moieties and studied their hydrolysis by bovine trypsin, papain, human tissue kallikrein and rat tonin. For comparison, the susceptibility to these enzymes of Acetyl-X-Arg-pNa and Acetyl-X-Phe-Arg-pNa series, in which X was Ala, Phe, Gln and Asn were examined. We also synthesized internally quenched fluorescent peptides with the amino acid sequence Phe8-His-Leu-Val-Ile-His-Asn14 of human angiotensinogen, in which [GlcNAcbeta]Asn was introduced before Phe8 and/or after His13 and ortho-aminobenzoic acid (Abz) and N-[2-, 4-dinitrophenyl]-ethylenediamine (EDDnp) were attached at N- and C-terminal ends as a donor/receptor fluorescent pair. These peptides were examined as substrates for human renin, human cathepsin D and porcine pepsin. The chromogenic substrates with hydrophilic sugar moiety increased their susceptibility to trypsin, tissue kallikrein and rat tonin. For papain, the effect of sugar depends on its position in the substrate, namely, at P3 it is unfavorable, in contrast to the P2 position that resulted in increasing affinity, as demonstrated by the higher inhibitory activity of Ac-(Gal3)Ser-Arg-pNa in comparison to Ac-Ser-Arg-pNa, and by the hydrolysis of Ac-(Glcalpha,beta)Tyr-Arg-pNa. On the other hand, the acetylation of sugar hydroxyl groups improved hydrolysis of the susceptible peptides to all enzymes, except tonin. The P'4 glycosylated peptide [Abz-F-H-L-V-I-H-(GIcNAcbeta)N-E-EDDnp], that corresponds to one of the natural glycosylation sites of angiotensinogen, was shown to be the only glycosylated substrate susceptible to human renin, and was hydrolysed with lower K(m) and higher k(cat) values than the same peptide without the sugar moiety. Human cathepsin D and porcine pepsin are more tolerant to substrate glycosylation, hydrolysing both the P'4 and P4 glycosylated substrates.     

Examination of the contribution of vacuolar proteases to intracellular protein degradation in Chara corallina.

The contribution of proteases in the central vacuole of Chara corallina internodal cells to overall cellular protein degradation was examined. I measured the decrease in the trichloroacetic acid (TCA)-precipitable radioactivity in the cell for a 6-d chase period after labeling cellular proteins with [3H]leucine. The kinetics of [3H]leucine-labeled protein disappearance showed that the half-life of the cellular soluble proteins was 4 to 5 d. This value did not change when cells were treated with (2S,3S)-trans-epoxysuccinyl-L-leucylamido- 3-methyl-butane ethyl ester, a permeant inhibitor of cysteine proteases. This inhibitor mostly inhibited bovine serum albumin-degrading activity in the vacuole. I also measured the release of TCA-soluble radioactivity from the TCA-insoluble fraction in the cell. This experiment showed that 13% of [3H]leucine-labeled cellular proteins were degraded in 1 d. This value agreed well with the half-life obtained for soluble proteins in the above experiment. This value did not change even when both trans-epoxysuccinyl-L-leucylamido-(4-guanidino)butane, a cysteine protease inhibitor, and pepstatin A, an aspartic protease inhibitor, were introduced into the vacuole. With this operation, bovine serum albumin-degrading activity in the vacuole was almost completely inhibited. These data suggest that the cytoplasmic but not the vacuolar proteases contribute to cellular protein turnover in Chara internodal cells.     

Characterization of cuticle-degrading proteases produced by the entomopathogen Metarhizium anisopliae

Two chymoelastases and three trypsinlike proteases were separated from culture filtrates of the entomopathogen Metarhizium anisopliae. A chymoelastase (Pr1) (pI 10.3 Mr 25,000) and trypsin (Pr2) (pI 4.42, Mr 28,500) were purified to homogeneity by ammonium sulphate precipitation, isoelectric focusing, and affinity chromatography. Inhibition studies showed that both enzymes possessed essential serine and histidine residues in the active site. Pr1 shows greater activity than Pr2 or mammalian enzymes against locust cuticle and also possesses activity vs elastin. Pr1 shows a broad primary specificity toward amino acids with hydrophobic side groups in synthetic ester and amide substrates. The kinetic properties of Pr1 demonstrate a preference for extended peptide chains with the active site recognising at least five substrate residues. The S5 and S4 subsites show a preference for negatively charged succinyl and hydrophobic acetyl groups, respectively. The S3 and S2 subsites both discriminated in favor of alanine and against proline. Pr2 rapidly hydrolyzed casein and synthetic substrates containing arginine or lysine. It possessed little or no activity vs cuticle, elastin, or synthetic substrates for chymotrypsin and elastase. Specific active site inhibitors confirmed the similarities between Pr2 and trypsin.     

Trypsin inactivation by intact Hymenolepis diminuta (Cestoda): some characteristics of the inactivated enzyme

In the presence of intact Hymenolepis diminuta, trypsin was inactivated; intact worms had no apparent effect on subtilisin, pepsin, or papain. Inactivation of trypsin was demonstrable using azoalbumin as a substrate, but the inactivated enzyme retained full catalytic activity against benzoyl-DL-arginine-p-nitroanilide, p-tosyl-L-arginine methyl ester (low molecular weight synthetic trypsin substrates) and p-nitro-p-guanidinobenzoate (an active site titrant). Inactivation was not reversible under conditions of heating, freezing and thawing, or prolonged dialysis of the enzyme. Analyses of inactivated 3H-trypsin by cationic and SDS-polyacrylamide gel electrophoresis, and gel chromatography failed to indicate the presence of a high molecular weight trypsin inhibitor associated with the inactivated enzyme; no low molecular weight, dissociable inhibitor was demonstrable following thermal denaturation of the inactivated enzyme. Analyses of trypsin after incubation in the presence of pulse-labeled worms also failed to demonstrate the presence of any inhibitor of worm origin associated with the inactivated enzyme. The data suggest that inactivation is the result of a small structural or conformational change in the enzyme molecule, a change which partially (rather than totally) inactivates the enzyme towards protein substrates.     

Biochemical characterization of digestive proteases and carbohydrases of the carob moth,Ectomyelois ceratoniae (Zeller) (Lepidoptera: Pyralidae)

Digestive proteinases and carbohydrases of Ectomyelois ceratoniae (Zeller) larvae were investigated using appropriate substrates and inhibitors. Midgut pH in larvae was determined to be slightly alkaline. Midgut extracts showed optimum activity for proteolysis of hemoglobin at pH 9–12. Midgut proteinases also hydrolyzed the synthetic substrates of trypsin, chymotrypsin, and elastase at pH 8–11. Maximum digestive α-amylase activity was also observed at pH 8–11. However, optimum activity for α- and β-glucosidase occurred at pH 5–8. Alpha- and β-galactosidases optimum activities occurred at pH 5 and pH 6, respectively. Inhibitors of serine proteases were effective on midgut serine proteases (trypsin and chymotrypsin proteases). Zymogram analyses revealed at least five bands of total proteolytic activity in the larval midgut. Protease-specific zymogram analyses revealed at least four, two, and one isozymes for trypsin-, chymotrypsin-, and elastase-like activities respectively. Two α-amylase isozymes were found in the midgut of fifth instar larvae and in the whole bodies of 1st through 5th instar larvae. Zymogram studies also revealed the presence of one and two bands of activity for β- and α-glucosidase, respectively. Recycling of α-amylase and proteases in the larval midgut was not complete. At least one isozyme of trypsin, chymotrypsin, elastase, and α-amylase were not recycled and were observed in the larval hindgut.