Structural studies on sulfated oligosaccharides derived from the carbohydrate-protein linkage region of chondroitin 6-sulfate proteoglycans of shark cartilage. I. Six compounds containing 0 or 1 sulfate and/or phosphate residues.

Shark cartilage proteoglycans bear predominantly chondroitin 6-sulfate. After exhaustive protease digestion, reductive beta-elimination, and subsequent chondroitinase ABC digestion, 13 hexasaccharide alditols, which are nonsulfated, sulfated, and/or phosphorylated, were obtained from the carbohydrate-protein linkage region. Six compounds, containing 0 or 1 sulfate and/or phosphate residue, represent approximately 40% of the isolated linkage hexasaccharide alditols. They were analyzed by chondroitinase ACII or alkaline phosphatase digestion in conjunction with high performance liquid chromatography, and by 500 MHz one- and two-dimensional 1H NMR spectroscopy. All six compounds have the conventional structure in common. Delta 4,5-GlcA beta 1-3GalNAc beta 1-4GlcA beta 1-3Gal beta 1-3Gal beta 1-4Xyl-ol One compound has no sulfate nor phosphate. Two of the monosulfated compounds have a O-sulfate on C-6 or on C-4 of the GalNAc residue. The third monosulfated compound has a novel O-sulfate on C-6 of the Gal residue attached to xylitol. The two phosphorylated compounds have O-phosphate on C-2 of Xyl-ol, and one of them has in addition sulfate on C-6 of GalNAc.     

Comparative study of various serine alkaline proteinases from microorganisms. Esterase activity against N-acylated peptide ester substrates

Hydrolyses of N-acylated peptide ester substrates by various serine alkaline proteinases from bacterial and mold origin were compared using Ac- or Z-(Ala)_m-X-OMe (m = 0-2 or 0-3; X = phenylalanine, alanine, and lysine) as esterase substrates. The results indicated that the esterase activities of these enzymes were markedly promoted by elongating the peptide chain from P₁ to P₂ or P₃ with alanine, irrespective of the kind of the amino acid residue at the P₁-position (amino acid residues in peptide substrates are numbered according to the system of Schechter and Berger (1)). The effect of the kind of amino acid residue at the P₂-position was further determined using Z-X-Lys-OMe (X = glycine, alanine, leucine, or phenylalanine) as esterase substrates. Alanine was the most efficient residue as X with subtilisins and Streptomyces fradiae Ib enzyme, while leucine or phenylalanine were most efficient with the enzymes from Streptomyces fradiae II, Aspergillus sojae, and Aspergillus melleus. All the serine alkaline proteinases tested in this study were sensitive to Z-Ala-Gly-PheCH₂Cl, the dependence of inhibition on the inhibitor concentration differed among the enzymes.     

A sensitive colorimetric assay for various proteases using naphthyl ester derivatives as substrates

A convenient and highly sensitive colorimetric assay for various proteases, such as trypsin, chymotrypsin, plasmin, thrombin, and urokinase is described. The substrates used are alpha-naphthyl ester derivatives of N alpha-tosyl-L-lysine, N alpha-acetylglycyl-L-ination of alpha-naphthol released from them. Use of these alpha-naphthyl ester derivatives made the method more sensitive than the use of the corresponding methyl or ethyl ester derivatives. The minimum detectable concentrations of trypsin, chymotrypsin, plasmin, thrombin and urokinase in this method were about 0.002 micrograms, 0.01 microgram, 0.002 CU, 0.01 IU, and 2 IU, respectively. The Km values of trypsin and thrombin for TLNE were 0.11 mM and 0.15 mM while those for TLME were 2.5 mM and 6.7 mM, respectively; the Km values of chymotrypsin for ATNE and ATEE were 0.18 mM and 0.7 mM, respectively; and the Km values of urokinase for AGLNE and AGLME were 0.17 mM and 4 mM, respectively. Zymograms of various proteases were easy to prepare using these alpha-naphthyl ester substrates, and zymograms of trypsin and chymotrypsin were made with TLNE and ATNE, respectively, as substrates.     

Tumor cell killing by macrophages activated in vitro with lymphocyte mediators. 5. Role of proteases, inhibitors, and substrates

The effect of protease inhibitors and substrates on the killing of tumor cells by in vitro activated macrophages was examined. Phenylmethylsulfonyl fluoride, a serine esterase inhibitor, and the active site titrants TPCK and TLCK (chloromethyl ketone derivatives of tosyl-l-phenylalanine and tosyl-l-lysine) inhibited macrophage-mediated cytotoxicity in a dose-dependent and irreversible fashion. The synthetic protease substrates, tosyl-lysine methyl ester and tosyl-arginine methyl ester and the natural esterase inhibitors soybean trypsin inhibitor and antithrombin III had no effect. These results suggest that an activated macrophage-associated esterase may play a modulating role in the cytolytic interaction between activated macrophages and tumor cells.     

Indigogenic substrates for detection and localization of enzymes

Indoxyl esters and glycosides are useful chromogenic substrates for detecting enzyme activities in histochemistry, biochemistry and bacteriology. The chemical reactions exploited in the laboratory are similar to those that generate indigoid dyes from indoxyl-beta-d-glucoside and isatans (in certain plants), indoxyl sulfate (in urine), and 6-bromo-2-S-methylindoxyl sulfate (in certain molluscs). Pairs of indoxyl molecules released from these precursors react rapidly with oxygen to yield insoluble blue indigo (or purple 6,6'-dibromoindigo) and smaller amounts of other indigoid dyes. Our understanding of indigogenic substrates was developed from studies of the hydrolysis of variously substituted indoxyl acetates for use in enzyme histochemistry. The smallest dye particles, with least diffusion from the sites of hydrolysis, are obtained from 5-bromo-, 5-bromo-6-chloro- and 5-bromo-4-chloroindoxyl acetates, especially the last of these three. Oxidation of the diffusible indoxyls to insoluble indigoid dyes must occur rapidly. This is achieved with atmospheric oxygen and an equimolar mixture of K(3)Fe(CN)(6) and K(4)Fe(CN)(6), which has a catalytic function. H(2)O(2) is a by-product of the oxidation of indoxyl by oxygen. In the absence of a catalyst, the indoxyl diffuses and is oxidized by H(2)O(2) (catalyzed by peroxidase-like proteins) in sites different from those of the esterase activity. The concentration of K(3)Fe(CN)(6)/K(4)Fe(CN)(6) in a histochemical medium should be as low as possible because this mixture inhibits some enzymes and also promotes parallel formation from the indoxyl of soluble yellow oxidation products. The identities and positions of halogen substituents in the indoxyl moiety of a substrate determine the color and the physical properties of the resulting indigoid dye. The principles of indigogenic histochemistry learned from the study of esterases are applicable to methods for localization of other enzymes, because all indoxyl substrates release the same type of chromogenic product. Substrates are commercially available for a wide range of carboxylic esterases, phosphatases, phosphodiesterases, aryl sulfatase and several glycosidases. Indigogenic methods for carboxylic esterases have low substrate specificity and are used in conjunction with specific inhibitors of different enzymes of the group. Indigogenic methods for acid and alkaline phosphatases, phosphodiesterases and aryl sulfatase generally have been unsatisfactory; other histochemical techniques are preferred for these enzymes. Indigogenic methods are widely used, however, for glycosidases. The technique for beta-galactosidase activity, using 5-bromo-4-chloroindoxyl-beta-galactoside (X-gal) is applied to microbial cultures, cell cultures and tissues that contain the reporter gene lac-z derived from E. coli. This bacterial enzyme has a higher pH optimum than the lysosomal beta-galactosidase of animal cells. In plants, the preferred reporter gene is gus, which encodes beta-glucuronidase activity and is also demonstrable by indigogenic histochemistry. Indoxyl substrates also are used to localize enzyme activities in non-indigogenic techniques. In indoxyl-azo methods, the released indoxyl couples with a diazonium salt to form an azo dye. In indoxyl-tetrazolium methods, the oxidizing agent is a tetrazolium salt, which is reduced by the indoxyl to an insoluble coloured formazan. Indoxyl-tetrazolium methods operate only at high pH; the method for alkaline phosphatase is used extensively to detect this enzyme as a label in immunohistochemistry and in Western blots. The insolubility of indigoid dyes in water limits the use of indigogenic substrates in biochemical assays for enzymes, but the intermediate indoxyl and leucoindigo compounds are strongly fluorescent, and this property is exploited in a variety of sensitive assays for hydrolases. The most commonly used substrates for this purpose are glycosides and carboxylic and phosphate esters of N-methylindoxyl. Indigogenic enzyme substrates are among many chromogenic reagents used to facilitate the identification of cultured bacteria. An indoxyl substrate must be transported into the organisms by a permease to detect intracellular enzymes, as in the blue/white test for recognizing E. coli colonies that do or do not express the lac-z gene. Secreted enzymes are detected by substrate-impregnated disks or strips applied to the surfaces of cultures. Such devices often include several reagents, including indigogenic substrates for esterases, glycosidases and DNAse.     

Assay of apical membrane enzymes based on fluorogenic substrates.

A series of enzymatic rate assays are described. The assays are based on coumarin derivatives that are fluorogenic substrates for the enzymes dipeptidase IV, aminopeptidase N, alkaline phosphatase, and gamma-glutamyltransferase. These simple assays are rapid and offer improved sensitivity over established colorimetric methods. The substrates have apparent affinities for the enzymes of 5-250 microM. L-Glutamic acid gamma-(7-amido-4-methylcoumarin) is characterized as a substrate of gamma-glutamyltransferase on the basis of inhibition of enzymatic cleavage when the glycylglycine acceptor molecule is omitted and inhibition of the enzymatic reaction by addition of glycine. Assay conditions for the four enzymes are established such that less than 0.6% of the substrate is consumed, fluorescence is proportional to enzymatic product, and results may be directly compared to established colorimetric assays. Intestinal epithelial cells are used both to establish appropriate assay conditions and to demonstrate the utility of the assays.     

Hydrolysis of ester substrates of trypsin and chymotrypsin by barley carboxypeptidase

Purified barley carboxypeptidase exhibits high activity against a number of N-substituted amino acid esters, which are commonly used as synthetic substrates for mammalian and microbial proteinases. The proteinases of barley, on the contrary, do not hydrolyse these compounds. Because many other plants contain carboxypeptidases closely resembling the barley enzyme, we conclude that synthetic ester substrates should not be used to detect proteinase activity in extracts of higher plants. Plant carboxypeptidases also liberate C-terminal tryptophan from α-casein. Therefore, casein also is an unreliable substrate for plant proteinases.     

Acid hydrolases in HeLa cells: comparison of methods for light microscopy

To distinguish lysosome populations of HeLa cells, acid phosphatase, beta-glucuronidase, arylsulfatase and esterase were demonstrated using various substrates and couplers with different fixations, pHs and inhibitors. The substrates chosen were for acid phosphatase, naphthol AS-BI phosphate with fast red violet LB at pH 4.6; for beta-glucuronidase, naphthol AS-BI beta-D-glucuronide with fast red violet LB at pH 4.4; for arylsulfatase, p-nitrocatechol sulfate, with lead as the capturing ion, at pH 4.8 and 5.6; and for esterase, naphthol AS-D acetate with fast blue BB at pH 6.5. In the azo-dye methods, the coupling was always simultaneous and results were satisfactory with unfixed cells. For optimal demonstration of arylsulfatase, cells were fixed in glutaraldehyde in 0.1 M cacodylate buffer pH 7.2, 2% for 24 hr or 6.25% for 2 hr, and washed for 1-9 days in 0.1 M veronal acetate buffer pH 7.2, 7.5% with respect to sucrose. Two groups of lysosomes were distinguished. One comprised small bodies, probably primary lysosomes, which lay in a cluster near the nucleus. They had quite stable membranes and were mostly acid phosphatase-positive. They sometimes contained beta-glucuronidase or esterase, but rarely arylsulfatase. The other group included all the acid hydrolase-positive bodies scattered throughout the rest of the cytoplasm. They were mostly larger, with more labile membranes, and contained beta-glucuronidase, esterase or arylsulfatase, but rarely acid phosphatase.     

Specificity studies on enteropeptidase substrates related to the N-terminus of trypsinogen.

The specificity of the synthetic substrate Gly-[L-Asp]4-L-Lys 2-naphthylamide originally developed for the assay of enteropeptidase (EC 3.4.21.9), was investigated with partially purified aminopeptidase. Our results indicate that, not only enteropeptidase, but also the concerted action of the aminopeptidases of the rat small intestine, can rapidly release 2-naphthylamine from the substrate. A previously undescribed, highly active, dipeptidylaminopeptidase, which hydrolyses a Gly-Asp dipeptide from the N-terminus of the substrate, was detected in rat small intestine. The resulting [L-Asp]3-L-Lys 2-naphthylamide fragment is then degraded by a combination of aminopeptidase A and N to yield free 2-naphthylamine. Thus the present substrate cannot be regarded as being specific for enteropeptidase, and its use leads to an over-estimation of enteropeptidase activity in homogenates and extracts of intestinal tissue. In order to prevent this non-specific hydrolysis by aminopeptidases, stereoisomeric substrates with the sequence L-Ala-D-Asp-[L-Asp]3-L-Lys methyl ester, D-Ala-[L-Asp]4-L-Lys methyl ester and L-Ala-[Asp]4-L-Lys methyl ester were synthesized and tested as alternative substrates by their ability to inhibit the enteropeptidase-catalysed activation of trypsinogen.     

Alkaline serine proteinases D and E of Streptomyces griseus K-1.

Two DFP-sensitive alkaline proteinases with strong esterase activity toward Ac-(Ala)3-OMe, designated as alkaline serine proteinases D and E, were purified pronase, a protease mixture from St. griseus K-1. Each was shown to be homogeneous by acrylamide disc gel electrophoresis. The molecular weights of these enzymes were estimated to be about 27,000 be gel filtration. Studies on their actions on acyl-tl-amino acid methyl or ethyl esters indicated that proteinases D and E both exhibited a broad substrate specificity and hydrolyzed the ester bonds of esters containing Trp, Tyr, Phe, Leu, and Ala. The esterase activities of both enzymes toward Ac-(Ala)3-OMe were the highest among proteinases so far isolated from various sources. Proteinases D and E also lacked cystine residues in their molecules, being entirely different from alkaline serine proteinases A, B, and C in pronase. Some differences were , however, observed between them as regards pH stability, behavior on CM-cellulose, mobility on polyacrylamide electrophoresis, and amidase activity toward Suc-(Ala)3-pNA.     

DIFFERENCES IN ENZYME CONTENT OF AZUROPHIL AND SPECIFIC GRANULES OF POLYMORPHONUCLEAR LEUKOCYTES : I. Histochemical Staining of Bone Marrow Smears

Histochemical procedures for PMN granule enzymes were carried out on smears prepared from normal rabbit bone marrow, and the smears were examined by light microscopy. For each of the enzymes tested, azo dye and heavy metal techniques were utilized when possible. The distribution and intensity of each reaction were compared to the distribution of azurophil and specific granules in developing PMN. The distribution of peroxidase and six lysosomal enzymes (acid phosphatase, arylsulfatase, β-galactosidase, β-glucuronidase, esterase, and 5'-nucleotidase) corresponded to that of azurophil granules. Progranulocytes contained numerous reactive granules, and later stages contained only a few. The distribution of one enzyme, alkaline phosphatase, corresponded to that of specific granules. Reaction product first appeared in myelocytes, and later stages contained numerous reactive granules. The results of tests for lipase and thiolacetic acid esterase were negative at all developmental stages. Both types of granules stained for basic protein and arginine. It is concluded that azurophil and specific granules differ in their enzyme content. Moreover, a given enzyme appears to be restricted to one of the granules. The findings further indicate that azurophil granules are primary lysosomes, since they contain numerous lysosomal, hydrolytic enzymes, but the nature of specific granules is uncertain since, except for alkaline phosphatase, their contents remain unknown.     

Proteolytic activity in the insulin receptor

When a highly purified preparation of rat liver insulin receptor is incubated with trypsin, the receptor develops hydrolytic activity towards N alpha-benzoyl-L-arginine ethyl ester, N alpha-p-tosyl-L-arginine methyl ester, and N alpha-benzoyl-DL-arginine-p-nitroanilide, (compounds which are synthetic substrates of trypsin). The activity toward N alpha-benzoyl-DL-arginine-p-nitroanilide is inhibited by soybean trypsin inhibitor but not by N alpha-p-tosyl-L-lysil chloromethyl ketone. These data are consistent with the presence of proteolytic activity in the insulin receptor specific for the bonds whose carbonyl functions are provided by arginine but not by lysine. Furthermore we found that the esterase activity toward N alpha-benzoyl-L-arginine ethyl ester in the presence of trypsin is enhanced by insulin, and that the concentration of insulin that produced the half maximum stimulation is of the same magnitude as the dissociation constant for the soluble receptor. These data suggest that the insulin receptor is a zymogen, activated by trypsin, and based on its specific activity, may be the protease which releases a peptide chemical mediator of intracellular action of insulin.     

Amplification and detection of substrates for protein carboxyl methyltransferases in PC12 cells.

A strategy that facilitates the identification of substrates for protein carboxyl methyltransferases that form "stable" methyl esters, i.e., those that remain largely intact during conventional polyacrylamide gel electrophoresis is described. Rat PC12 cells were cultured in the presence of adenosine dialdehyde (a methylation inhibitor) to promote the accumulation of hypomethylated proteins. Nonidet P-40 cell extracts were then incubated in the presence of S-[methyl-3H]adenosyl-L-methionine to label methyl-accepting sites via endogenous methyltransferases. After labeled proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, gel slices were incubated in 4 N methanesulfonic acid or 6 N HCl to hydrolyze methyl esters. The resulting [3H]methanol was detected by trapping in liquid scintillation fluid. Seven carboxyl methylated proteins were observed with masses ranging from 18 to 96 kDa. Detection of five of these proteins required prior treatment of cells with adenosine dialdehyde, while methyl incorporation into one protein at 18 kDa was substantially enhanced by the treatment. The use of acidic conditions for methyl ester hydrolysis has an important advantage over assays that utilize alkaline hydrolysis conditions. In PC12 cells, and possibly other cell types where there are significant levels of arginine methylation, the methanol signal becomes obscured by high levels of volatile methylamines generated under the alkaline conditions. Carrying out diffusion assays under acidic conditions eliminates this interference. Adenosine dialdehyde, by virtue of increasing the methyl-accepting capacity of substrates for protein carboxyl methyltransferases, in combination with a more selective assay for carboxyl methylation, should prove useful in the isolation and characterization of new protein carboxyl methyltransferases and their substrates.     

Acid Hydrolases in Hela Cells: Comparison of Methods for Light Microscopy

TO distinguish lysosome populations of HeLa cells, acid phosphatase, /8-glu-curonidase, arylsulfatase and esterase were demonstrated using various substrates and couplers with different fixations, pHs and inhibitors. The substrates chosen were for acid phosphatase, naphthol AS-BI phosphate with fast red violet LB at pH 4.6; for β-glucuronidase, naphthol AS-BI β-D-glucuronide with fast red violet LB at pH 4.4; for arylsulfatase, p-nitrocatechol sulfate, with lead as the capturing ion, at pH 4.8 and 5.6; and for esterase, naphthol AS-D acetate with fast blue BB at pH 6.5. In the azo-dye methods, the coupling was always simultaneous and results were satisfactory with unfixed cells. For optimal demonstration of arylsulfatase, cells were fixed in glutaraldehyde in 0.1 M cacodylate buffer pH 7.2, 2% for 24 hr or 6.25% for 2 hr, and washed for 1-9 days in 0.1 M veronal acetate buffer pH 7.2, 7.5% with respect to sucrose. Two groups of lysosomes were distinguished. One comprised small bodies, probably primary lysosomes, which lay in a cluster near the nucleus. They had quite stable membranes and were mostly acid phosphatase-positive. They sometimes contained β-glucuronidase or esterase, but rarely arylsulfatase. The other group included all the acid hydrolase-positive bodies scattered throughout the rest of the cytoplasm. They were mostly larger, with more labile membranes, and contained β-glucuronidase, esterase or arylsulfatase, but rarely acid phosphatase.     

Hydrolytic enzyme substrates. 3. Phosphomonoesterase substrates

This report documents the use of a new and sensitive colorimetric method for measuring phosphomonoesterase activity. The substrates are the phosphate esters of 4-(p-nitrophenoxy)-1,2-butanediol (PNB), 4-(2,4-dinitrophenoxy)-1,2-butanediol (DNB) and 3-(p-nitrophenoxy)-1,2-propanediol (PNG). The key intermediate in the assay is the nitrophenoxy diol which is obtained by enzyme hydrolysis of its phosphate ester. Periodate oxidation of this substance in solution containing methylamine quantitatively yields its nitrophenolate ion whose concentration is determined colorimetrically. The amount of nitrophenolate ion is thus equivalent to the amount of nitrophenoxy diol whose concentration is a function of the phosphomonoesterase activity in the assay sample. The unhydrolyzed phosphomonoester is completely stable to periodate and the hydrolytic conditions used in the assay. The enzymes used to test the substrates were E. coli alkaline phosphomonoesterase and wheat germ phosphomonoesterase. These new esters were all better substrates than the glycerol phosphate esters. Their Michaelis-Menten constants were determined for E. coli phosphomonoesterase.     

The activity of arylsulfatase A and B on tyrosine O-sulfates.

L-Tyrosine O-sulfate was hydrolyzed by pure human arylsulfatase A (arylsufate sulfohydrolase, EC 3.1.6.1). The rate of hydrolysis was 1/20 of the rate with nitrocatechol sulfate, but was comparable to the rate with cerebroside sulfate. The reaction was optimal at pH 5.3--5.5 and displayed zero order kinetics with time and enzyme concentration. The Km was about 35 mM. The enzyme showed no stereospecificity and hydrolyzed D-tyrosine O-sulfate with Km and V similar to those for the L-isomer. Arylsulfatase B was less than 5% as effective as arylsulfatase A in catalyzing the hydrolysis of the tyrosine sulfates. The daily urinary excretion of tyrosine sulfate by a patient with metachromatic leukodystrophy (arylsulfatase A deficiency) was comparable to the excretion by control subjects. The biological relevance of the tyrosine sulfatase activity of arylsulfatase A remains uncertain.     

Acid and neutral hydrolases in Trypanosoma cruzi. Characterization and assay.

Twelve acid hydrolases, 4 near-neutral hydrolases, and alkaline phosphatase were demonstrated in 0.34 M sucrose homogenates of Trypanosoma cruzi strain Y: p-nitrophenylphosphatase and alpha-naphthylphosphatase, with optimum pH at approximately 6.0; alpha=ga;actpsodase. beta=ga;actpsodase. beta=g;icpsodase, N-acetyl-beta-glucosaminidase, cathepsin A and peptidase I and III, with optimum pH between 5.0 and 6.0; and arylsulfatase, cathepsin D, alpha-arabinase and alpha-mannosidase with optimum pH at approximately 4.0. alpha-Glucosidase, glucose-6-phosphatase and peptidase II had optimum pH at approximately 7.0. beta-Glycerophosphatase had a broad pH-activity curve from 4,0 to 7.4, with maximum activity at pH 7.0. The main kinetic characteristics of these enzymes and their quantitative assay methods were studied. No activity was detected for alpha-fucosidase, beta-xylosidase, beta-glucuronidase, elaidate esterase, acid lipase, and alkaline phosphodiesterase.     

QUANTITATIVE ESTIMATION OF LYO- AND DESMOENZYMES IN TISSUE SECTIONS WITH AND WITHOUT FIXATION

1. Tissue sections eight microns thick were exposed to various experimental conditions used in histochemistry, and the effect upon the activities of esterase, the phosphatases, leucine aminopeptidase, β-glucuronidase, and arylsulfatase was determined colorimetrically. 2. Significant differences were found in the amounts of the lyo and desmo fractions of these enzymes. The desmo components were found to be for esterase, alkaline phosphatase, leucine aminopeptidase, acid phosphatase, β-glucuronidase, and arylsulfatase, ⅓, 2/3, 2/3, ½, ⅛, and ⅛ of the total enzymatic activity respectively. 3. Variations in the time and in the temperature at which diffusion was studied and of the pH and salt concentration of the solution into which the sections were placed, resulted in differences in the amount of enzymatic activity which remained in the tissue section. Some enzyme loss by diffusion was noted even after fixation of the tissue section. 4. The significance of the findings with respect to some of the concepts of localization of enzymes in tissue sections was discussed.     

A general high-performance liquid chromatography-based assay for the hydrolysis of N-acyl glutamates.

A rapid and simple HPLC assay has been developed to separate and quantify N-acyl glutamates and the corresponding carboxylic acids of the acyl moiety. This method was specifically developed to assay hydrolytic activity for glutamate carboxypeptidases. Although established assays for specific substrates of such enzymes exist, they may not be amenable for examining the hydrolytic activity of new substrate probes. This assay was developed to accommodate such probes.