Peptide thioesters and 4-nitroanilides as substrates for porcine pancreatic kallikrein

A series of 14 4-nitroanilide substrates and 17 thioester substrates have been used to measure kinetic constants with porcine pancreatic kallikrein. All of the substrates have a P1 arginine residue. The 4-nitroanilide substrates consist of seven P2-glycine and seven P2-phenylalanine tripeptides. As expected from previous results, the phenylalanine series substrates were generally 100-fold 'better' than those in the glycine series. The S3 subsite was found to 'prefer' lysine or phenylalanine, whereas glutamic acid in this position was distinctly unfavourable. The thioester substrates consisted of various thioester derivatives of arginine as well as 12 dipeptides. These substrates exhibited kcat./Km values generally 1000 times higher than the P2-phenylalanine 4-nitroanilides. With the thioesters, a P2 phenylalanine or tryptophan residue yielded the best substrates, but some of the simple derivatives of arginine were nearly as good. A comparison of the kinetic constants of the thioester substrates between the porcine enzyme and human plasma kallikrein provides further evidence that these enzymes have a similar preference for bulky P2 residues, but otherwise are quite different enzymes. The thioester substrates are nearly as reactive as oxygen ester substrates such as acetylphenylalanylarginine methyl ester for the porcine enzyme [Levison & Tomalin (1982) Biochem. J. 203, 299-302; Fiedler (1983) Adv. Exp. Med. Biol. 156A, 263-274], and owing to the greater ease in assaying with the thioesters, they should find use in routine assays for the glandular kallikreins.     

Fluorogenic substrates for the enkephalin-degrading neutral endopeptidase (Enkephalinase)

Rat brain neutral endopeptidase ("Enkephalinase") was shown to hydrolyze a series of fluorogenic substrates of the general structure 2-aminobenzoyl-(amino acid)n- leucylalanylglycine -4- nitrobenzylamide . The hydrolysis of these substrates was competitively inhibited by Leu5-enkephalin, demonstrating that these are indeed substrates for the rat brain neutral endopeptidase. Cleavage of the fluorogenic substrates yielded leucylalanylglycine -4- nitrobenzylamide as a common product. In addition, a series of inhibitors previously shown to inhibit thermolysin-like enzymes inhibited the hydrolysis of both Leu5-enkephalin and the synthetic substrates. The results of this study (a) demonstrate that the enkephalin-degrading endopeptidase is similar in specificity to thermolysin, (b) provide a continuous sensitive assay system for the enzyme, and (c) point out the potential use of this substrate class for probing the specificity of the enzyme.     

Deacylation of acylamino compounds other than penicillins by the cell-bound penicillin acylase of Escherichia coli

1. The action of the penicillin acylase enzyme of Escherichia coli N.C.I.B. 8743 on non-penicillin substrates suggests that the enzyme is an amidohydrolase. 2. The rates of hydrolysis for a small group of penicillins closely parallel those for a corresponding series of N-acylglycines. 3. For a series of E. coli strains, ability to cause rapid hydrolysis of phenylacetylglycine is correlated with ability to hydrolyse benzylpenicillin. 4. Amides and N-acylglycines are hydrolysed to the corresponding acids. The phenylacetyl group is hydrolysed most readily. Benzamide and beta-phenylpropionamide are not substrates. In a series of aliphatic acylglycines only valeryl- and hexanoyl-glycine are substrates. 5. Acylated l- but not d-alpha-amino acids are hydrolysed. d-alpha-Hydroxyphenylacetamide is a better substrate than the l compound.     

Specificities of the enzymes of N-alkyltropane biosynthesis in Brugmansia and Datura

The enzymes N-methylputrescine oxidase (MPO), the tropine-forming tropinone reductase (TRI), the pseudotropine-forming tropinone reductase (TRII), the tropine:acyl-CoA transferase (TAT) and the pseudotropine:acyl-CoA transferase (PAT) extracted from transformed root cultures of Datura stramonium and a Brugmansia candida x aurea hybrid were tested for their ability to accept a range of alternative substrates. MPO activity was tested with N-alkylputrescines and N-alkylcadaverines as substrates. TRI and TRII reduction was tested against a series of N-alkylnortropinones, N-alkylnorpelletierines and structurally related ketones as substrates. TAT and PAT esterification tests used a series of N-substituted tropines, pseudotropines, pelletierinols and pseudopelletierinols as substrates to assess the formation of their respective acetyl and tigloyl esters. The results generally show that these enzymes will accept alien substrates to varying degrees. Such studies may shed some light on the overall topology of the active sites of the enzymes concerned.     

Oxygen and sulfur esters of "inverse substrates": different responses of amidinophenol and amidinothiophenol in the activation of the rate of tryptic hydrolysis of the inverse esters

Kinetic parameters for the trypsin-catalyzed hydrolysis of the oxygen and sulfur "inverse substrates," p-amidinophenyl and p-amidinothiophenyl acetates and trimethylacetates, have been compared. The results suggest that both series of compounds are hydrolyzed via an identical pathway. Appreciable differences, however, were observed in the efficiency of the acylation process in both series, possibly reflecting the spatial requirements of the enzyme's active site toward these substrates. As reported previously, acceleration in deacylation by a positively charged molecule is a characteristic feature of trypsin-catalyzed hydrolysis of "inverse substrates." In the present investigation, it was shown that p-amidinothiophenol is ineffective as an activator, whereas its oxygen counterpart behaves as a potent activator toward oxygen and sulfur substrates. It is assumed that some ionic interaction between the enzyme and the ligand molecule could prevent the rate enhancement.     

Detection of l-alanylaminopeptidase activity in microorganisms using fluorogenic self-immolative enzyme substrates

A series of fluorogenic enzymatic substrates that incorporate a self-immolative spacer were synthesised for the purpose of identifying l-alanylaminopeptidase activity in microorganisms in agar media. These substrates resulted in the generation of fluorescent microorganism colonies with Gram-negative microorganisms.     

Fluorescein monophosphates as fluorogenic substrates for protein tyrosine phosphatases

A series of novel fluorescein monophosphates aimed as substrates for protein tyrosine phosphatases (PTPs) were synthesized and evaluated against fluorescein diphosphate (FDP), the currently used fluorescent substrate for PTPs. In contrast to FDP, which is dephosphorylated to monophosphate and then to fluorescein in a sequential reaction, these monophosphates are dephosphorylated in a single step. This eliminates the complication in assaying PTPs due to the cleavage of the second phosphate group. The kinetic studies of these substrates with PTPs were performed and Michaelis-Menten parameters were obtained. These designed substrates have Km 0.03-0. 35 mM, kcat/Km of 3-100 mM-1 s-1 with CD45 and PTP1B. The results showed that the substrates with negative charge groups on the fluorescein have higher affinities for PTP1B, which are consistent with other observations. In this series, fluorescein monosulfate monophosphate (FMSP) was the best substrate observed. Since FMSP showed large increases in both absorption and fluorescence upon dephosphorylation by PTPs at pH>6.0, it is one of the most sensitive, stable and high affinity substrates reported for PTPs.     

Biotransformation of aliphatic and aromatic ketones,including several monoterpenoid ketones and their derivatives by five species of marine microalgae

The biotransformation of a series of aliphatic and aromatic ketones by five cultures of photosynthetic microalgae is reported. The test substrates include the monoterpenoid ketones carvone and menthone and a series of aromatic ketones related to and including acetophenone. All of the test organisms show some degree of specificity and stereoselectivity in the biotransformation of substrates.     

Fluorogenic l-alanylaminopeptidase substrates derived from 6-amino-2-hetarylquinolines and 7-amino-3-hetarylcoumarins and their potential applications in diagnostic microbiology

Six novel fluorogenic enzyme substrates for detecting l-alanylaminopeptidase activity in microorganisms have been prepared and evaluated in Columbia agar media. The substrates are l-alanyl derivatives of 6-amino-2-hetarylquinolines and 7-amino-3-hetarylcoumarins. Both the quinoline and coumarin series of substrates produced fluorescence in the presence of Gram-negative microorganisms. In contrast, fluorescence generation in the presence of the Gram-positive microorganisms and yeasts was limited or absent.     

A method for designing peptide substrates for proteases. Tripeptidyl-p-nitroanilide substrates for subtilisin Carlsberg.

1. The kinetic parameters of 25 peptidyl-p-nitroanilide substrates were investigated with subtilisin Carlsberg as model enzyme. 2. For a series of 12 substrates, the contribution of various side chains to the affinity constant was computed by regression analysis. From these contributions the sequence of a new and better substrate, N-benzyloxycarbonyl-arginyl-norleucyl-norleucyl-p-nitroanilide (Z-Arg-Nle-Nle-Nan) was predicted. The compound was synthesized and assayed. Its calculated 1/Km value, 43.5 mM-1, was in a good agreement with the value of 40.0 mM-1 that was determined experimentally. 3. On expanding the series to 19 substrates, it was found that the productivity of enzyme-substrate binding is influenced primarily by those subsites which have a significantly greater contribution to the affinity constants than others. 4. The additivity principle applied reasonably well for the contribution of individual side chains to the kinetic parameters. This fact suggests that regression analysis can be used for the prediction of the amino acid sequence of better substrates than those already tested, probably not only for subtilisin but also for other proteolytic enzymes.     

Benzofuran-, benzothiophene-, indazole- and benzisoxazole-quinones: Excellent substrates for NAD(P)H:quinone oxidoreductase 1

A series of heterocyclic quinones based on benzofuran, benzothiophene, indazole and benzisoxazole has been synthesized, and evaluated for their ability to function as substrates for recombinant human NAD(P)H:quinone oxidoreductase (NQO1), a two-electron reductase upregulated in tumor cells. Overall, the quinones are excellent substrates for NQO1, approaching the reduction rates observed for menadione.     

A study of aspartyl proteases using intramolecularly quenched fluorogenic peptide substrates

A series of fluorogenic tetra-, penta-, and hexapeptide substrates of the general structure Abz-X-Phe-Phe-Y-Ded (or -pNa in place of -Ded), where X = Ala, Ala-Ala, or Val-Ala and Y = -, Ala, or Ala-Ala, were proposed. Kinetic parameters of hydrolysis of these substrates by pepsin, cathepsin D, human gastricsin, pig pepsin, calf chymosin, and aspergillopepsin A were determined. The compounds synthesized proved to be effective substrates for aspartyl proteases of diverse origins.     

A study of aspartyl proteases using intramolecularly quenched fluorogenic peptide substrates

A series of fluorogenic tetra-, penta-, and hexapeptide substrates of the general structure Abz-X-Phe-Phe-Y-Ded or (-pNa in place of -Ded), where X=Ala, Ala-Ala, or Val-Ala and Y=−, Ala, or Ala-Ala, were proposed. Kinetic parameters of hydrolysis of these substrates by pepsin, cathepsin D, human gastricsin, pig pepsin, calf chymosin, and aspergillopepsin A were determined. The compounds synthesized proved to be effective substrates for aspartyl proteases of diverse origins.     

Studies on lysophospholipases, V. The action of lysolecithin-hydrolyzing enzymes on lecithins and 1-acyl lysolecithins with varying fatty acid chain-length.

The activity of two purified lysolecithin-hydrolyzing enzymes on homologous series of synthetic lecithins containing two identical fatty acyl chains and of 1-acyl-lysolecithins has been measured as a function of substrate concentration. In general, enzymatic activity toward lecithins decreased with increasing chain length. Maximal hydrolysis rates for the lysolecithin series were measured with 1-dodecanoyllysolecithin. In this series increased affinities for substrates with increasing acyl-chain length was noticed. In the substrate concentration versus enzymatic velocity curves no breaks were observed at the critical micelle concentration of the various substrates. The initial site of attack during hydrolysis of short-chain lecithins was determined using 1-octanoyl-2pentanoyl-lecithin, 1-hexanoyl-2-hexyllecithin and 1 -hexyl-2-hexanoyllecithin. Both enzymes exhibited a pronounced preference for hydrolysis of the acyl ester bond at the 1-position. Especially the enzyme from beef pancreas seems to be suitable for the enzymatic preparation of 2-acyl lysolecithins from the corresponding short-chain lecithins.     

Substrate-selective mechanisms in biocatalysis demonstrated with a versatile and efficient aldolase antibody.

A structure-activity relationship study with a series of aldol substrates shows that the mechanism of the antibody 38C2-catalyzed retrograde aldol reaction depends on the nature of the substrate With electron-deficient substrates an early deprotonation precedes the C-C bond cleavage while with electron-rich substrates the catalytic mechanism involves an initial C-C bond cleavage leading to a positively charged intermediate.     

Real time kinetics of restriction endonuclease cleavage monitored by fluorescence resonance energy transfer.

The kinetics of PaeR7 endonuclease-catalysed cleavage reactions of fluorophor-labeled oligonucleotide substrates have been examined using fluorescence resonance energy transfer (FRET). A series of duplex substrates were synthesized with an internal CTCGAG PaeR7 recognition site and donor (fluorescein) and acceptor (rhodamine) dyes conjugated to the opposing 5' termini. The time-dependent increase in donor fluorescence resulting from restriction cleavage of these substrates was continuously monitored and the initial rate data was fitted to the Michaelis-Menten equation. The steady state kinetic parameters for these substrates were in agreement with the rate constants obtained from a gel electrophoresis-based fixed time point assay using radiolabeled substrates. The FRET method provides a rapid continuous assay as well as high sensitivity and reproducibility. These features should make the technique useful for the study of DNA-cleaving enzymes.     

Evaluation of alpha-cyanoesters as fluorescent substrates for examining interindividual variation in general and pyrethroid-selective esterases in human liver microsomes

Carboxylesterases hydrolyze many pharmaceuticals and agrochemicals and have broad substrate selectivity, requiring a suite of substrates to measure hydrolytic profiles. To develop new esterase substrates, a series of alpha-cyanoesters that yield fluorescent products upon hydrolysis was evaluated for use in carboxylesterase assays. The use of these substrates as surrogates for Type II pyrethroid hydrolysis was tested. The results suggest that these novel analogs are appropriate for the development of high-throughput assays for pyrethroid hydrolase activity. A set of human liver microsomes was then used to determine the ability of these substrates to report esterase activity across a small population. Results were compared against standard esterase substrates. A number of the esterase substrates showed correlations, demonstrating the broad substrate selectivity of these enzymes. However, for several of the substrates, no correlations in hydrolysis rates were observed, suggesting that multiple carboxylesterase isozymes are responsible for the array of substrate hydrolytic activity. These new substrates were then compared against alpha-naphthyl acetate and 4-methylumbelliferyl acetate for their ability to detect hydrolytic activity in both one- and two-dimensional native electrophoresis gels. Cyano-2-naphthylmethyl butanoate was found to visualize more activity than either commercial substrate. These applications demonstrate the utility of these new substrates as both general and pyrethroid-selective reporters of esterase activity.     

Substrate specificities of insulin and epidermal growth factor receptor kinases

The abilities of insulin and EGF stimulated protein kinases to phosphorylate a series of exogenous substrates were compared using wheat germ lectin purified preparations of solubilized rat liver membranes. Three different kinds of substrates were found: substrates phosphorylated primarily by insulin stimulated kinase, substrates phosphorylated primarily by EGF stimulated kinase and substrates phosphorylated by both kinases to a similar extent. These results indicate that the insulin and the EGF receptor kinase have different, but overlapping, substrate specificities. In vivo, phosphorylation of cellular proteins by various hormone receptor kinases may be part of the signal transmission process for actions of the hormones. Different substrate specificities of kinases of different hormone receptors may therefore represent an important mechanism to preserve the specificity of the hormonal signal at the post receptor level.     

Transported Substrate Determines Exchange Rate in the Multidrug Resistance Transporter EmrE

EmrE, a small multidrug resistance transporter, serves as an ideal model to study coupling between multidrug recognition and protein function. EmrE has a single small binding pocket that must accommodate the full range of diverse substrates recognized by this transporter. We have studied a series of tetrahedral compounds, as well as several planar substrates, to examine multidrug recognition and transport by EmrE. Here we show that even within this limited series, the rate of interconversion between the inward- and outward-facing states of EmrE varies over 3 orders of magnitude. Thus, the identity of the bound substrate controls the rate of this critical step in the transport process. The binding affinity also varies over a similar range and is correlated with substrate hydrophobicity within the tetrahedral substrate series. Substrate identity influences both the ground-state and transition-state energies for the conformational exchange process, highlighting the coupling between substrate binding and transport required for alternating access antiport.     

Substrate optimization for monitoring cathepsin C activity in live cells

A series of peptidic fluorogenic substrates were synthesized to develop a flow cytometry assay (FACS) to monitor the proteolytic activity of cathepsin C in live cells. Of the 16 substrates tested, (NH(2)-aminobutyric-homophenylalanine)(2)-rhodamine demonstrated the best reactivity and selectivity profile in the FACS assay using the B721 human B-lymphoblastoid cell line. The resulting FACS assay was validated through correlation of the IC(50) values with a competitive radiolabeling assay against a series of small molecule inhibitors of cathepsin C.