Trypsin-like Hatching Enzyme of Mouse Blastocysts: Evidence for Its Participation in Hatching Process before Zona Shedding of Embryos6

Effects of twelve protease inhibitors on hatching of mouse embryos were investigated. Mouse hatching was strongly or moderately inhibited by trypsin inhibitors including p-toluenesulfonyl-Lys-CH₂Cl (TLCK) and chicken ovomucoid, while inhibitors for chymotrypsin and elastase showed weak or no inhibition. These results indicate the participation of a trypsin-like protease in the hatching of mouse embryos as a hatching enzyme., Since TLCK is the strongest and an irreversible inhibitor for the enzyme, timing of the participation of the hatching enzyme in the hatching process was examined by pulse treatment of embryos with TLCK before and during the zona shedding. The results indicated that a trypsin-like hatching enzyme functions before, but not during, the zona shedding of embryos, especially during a 15 h period immediately before the beginning of the shedding.     

Do Alkylating Agents Modify the Histidine Residue of the Desensitized Butyrylcholinesterase?

Tosylphenylalanine chloromethyl ketone (TPCK) and tosyllysine chloromethyl ketone (TLCK) are irreversible modifiers of histidine which is located in the catalytic triad of chymotrypsin and trypsin, respectively. The effects of TPCK and TLCK on the histidine in the catalytic triad of the desensitized butyrylcholinesterase (BChE), prepared from human serum by heating at 45°C for 24 h, were investigated in detail. It is found that these reagents do not modify, but reversibly inhibit the desensitized enzyme as a function of time. Just as it is for the native enzyme, TPCK is a hyperbolic mixed-type inhibitor of the desensitized BChE with K_i, a and ß values of 0.017 ± 0.003 mM, 3.942 ± 1.125 and 0.524 ± 0.070, respectively. However, TLCK is the pure competitive inhibitor of the desensitized BChE with a K_i value of 0.008 ± 0.000 mM, while it is hyperbolic mixed-type inhibitor of the native form. These findings show that the conformation of the active site cavity of desensitized BChE is different from that of the native enzyme.     

The site of action of N-alpha-tosyl-L-lysyl-chloromethyl-ketone (TLCK) on cloned cytotoxic T lymphocytes

N-alpha-tosyl-L-lysyl-chloromethyl-ketone (TLCK), an irreversible inhibitor of trypsin-like serine proteases, is a potent, nontoxic inhibitor of cytotoxic T lymphocyte (CTL) activity with half-maximal inhibition of an alloreactive CTL clone occurring at [TLCK] = 30 microM. We have utilized TLCK as an affinity probe for functionally important CTL surface molecules by raising rabbit antibodies specific for the tosyl group and employing them as immunoprecipitating reagents. When 125I-labeled cloned CTL were treated with TLCK, immunoprecipitation with rabbit anti-tosyl antibodies and analysis by polyacrylamide gel electrophoresis revealed a small number of TLCK-binding proteins. Prior alkylation of radiolabeled CTL with iodoacetamide inhibited TLCK binding only slightly, suggesting that TLCK binding did not occur via free sulfhydryl groups. Thymocytes and a second CTL clone both had very similar patterns of TLCK-binding proteins; in contrast the TLCK-binding proteins of B cells differed greatly. Sequential immunoprecipitation experiments identified the predominant CTL TLCK-binding protein as T200. Lymphocyte function-associated antigen-1 also reacted with TLCK but to a lesser extent. The inhibitory role of cell-surface bound TLCK (vs intracellular TLCK) was demonstrated by protection experiments using Concanavalin A, a reversible ligand of the CTL cell surface. These experiments suggest that T200 may be required for cytotoxic activity of CTL.     

A kinetic study of the irreversible inhibition of an enzyme measured in the presence of coupled enzymes. Fluorescein isothiocyanate as inhibitor of the adenosinetriphosphatase activity from sarcoplasmic reticulum

A systematic procedure for the kinetic study of irreversible inhibition, when the enzymatic activity is measured in the presence of a coupled enzyme system, has been developed and analyzed. Simultaneous variation of the enzyme and inhibitor concentrations, maintaining a constant ratio between them, is recommended. The methodology is established to estimate the kinetic constants corresponding to the irreversible inhibitor. This approach is illustrated by the study of the inhibition of fluorescein isothiocyanate on the Ca2+-ATPase activity from sarcoplasmic reticulum measured in the presence of pyruvate kinase and lactate dehydrogenase as auxiliary enzymes. Treatment of the experimental data has been carried out by non-linear regression.     

Kinetic characterization of an enzymatic irreversible inhibition measured in the presence of coupling enzymes. The inhibition of adenosine triphosphatase from sarcoplasmic reticulum by fluorescein isothiocyanate

A kinetic study of the irreversible inhibition of an enzyme measured in the presence of a coupling enzyme system has been carried out to assess the type of mechanism of the irreversible inhibition. By using the algebraic criteria proposed here it should be possible to discriminate between these mechanisms and to calculate their corresponding kinetic constants. An experimental design has been developed and applied to fluorescein isothiocyanate as inhibitor of the ATPase activity from sarcoplasmic reticulum.     

Tosyl-lysyl chloromethylketone detects conformational changes in the catalytic unit of adenylate cyclase induced by receptor and G-protein stimulation

Incubation of striatal membranes with tosyl-lysyl chloromethylketone (TLCK) led to the irreversible inactivation of adenylate cyclase. However, under conditions where an interaction between the catalytic unit of adenylate cyclase and the alpha-subunit of the stimulatory G-protein GS were promoted, then the ability of TLCK to inhibit adenylate cyclase was markedly attenuated. The potency of stimulatory ligands, functioning through GS, to attenuate the sensitivity of adenylate cyclase to inactivation by TLCK was paralleled by their potency to activate adenylate cyclase. The local anaesthetic and membrane-fluidizing agent benzyl alcohol amplified GS-mediated stimulation of adenylate cyclase activity, whilst diminishing the ability of GS-mediated coupling to attenuate inactivation of adenylate cyclase by TLCK. In the absence of GS-mediated coupling, benzyl alcohol exerted only a small stimulatory effect on adenylate cyclase activity and had little effect on the ability of TLCK to inactivate this enzyme. We suggest that TLCK modifies a reactive group at or near the active site of adenylate cyclase which causes the functional inactivation of this enzyme. The reactivity of this group appears to be markedly affected by conformational changes elicited through coupling of adenylate cyclase to GS.     

Inactivation of medium-chain acyl-CoA dehydrogenase by oct-4-en-2-ynoyl-CoA

Mitochondrial medium-chain acyl-CoA dehydrogenase is a key enzyme for the beta-oxidation of fatty acids, which catalyzes the FAD-dependent oxidation of a variety of acyl-CoA substrates to the corresponding trans-2-enoyl-CoA thioesters. Oct-4-en-2-ynoyl-CoA was identified as a new irreversible inhibitor of acyl-CoA dehydrogenase, and kinetic parameters K(I) and k(inact) were determined to be 11 microM and 0.025 min(-1), respectively. Triple bond between C2 and C3 of the inhibitor was identified as the functional group responsible for enzyme inactivation, and Michael addition is proposed as the mechanism for this inactivation, which is a new pathway for inactivation of MCAD by inhibitors. The inhibitor may become a lead for further development for treating non-insulin-dependent diabetes mellitus.     

Nucleotide and bivalent cation specificity of the insulin-granule proton translocase

3-(4-[(3-Chlorophenyl)methoxy]phenyl)-5-[(methylamino)methyl]-2- oxazolidinone methanesulphonate (compound MD 780236) is a selective inhibitor of the B-form of monoamine oxidase. Inhibition involves an initial non-covalent interaction between enzyme and inhibitor followed by a time-dependent process resulting in irreversible inhibition. The initial, reversible, phase of inhibition was found to be competitive with respect to phenethylamine and 5-hydroxytryptamine, and a comparison of the Ki values indicated the affinity of the inhibitor for the B-form of the enzyme to be some 7-fold greater than its affinity for the A-form. This selectivity was considerably enhanced by preincubation of the enzyme and inhibitor. Time courses showed that complete inhibition was not achieved under conditions where the inhibitor concentration was over 100-fold greater than that of the enzyme. Assay of the activity of monoamine oxidase by determining the release of hydrogen peroxide fluorometrically showed compound MD 780236 to be a substrate for, as well as an inhibitor of, monoamine oxidase, and kinetic analysis revealed that the rate of product formation was some 530-fold greater than that of the process leading to irreversible inhibition of the B-form of the enzyme.     

Bromopyruvate, a potential affinity label for octopine dehydrogenase

Bromopyruvate, an analogue of pyruvate, one of the substrates of octopine dehydrogenase, was tested as an inhibitor of the enzyme. Provided both the coenzyme and the second substrate, arginine, were present, bromopyruvate rapidly inactivated the enzyme. This inactivation was irreversible, obeyed pseudo-first order kinetics and exhibited a rate saturation effect. Pyruvate protected the enzyme against inactivation by bromopyruvate and these compounds competed for the same site. Bromopyruvate also behaved as a true substrate for the enzyme. This reagent thus exhibits the kinetic characteristics of a good affinity label for octopine dehydrogenase.     

Clinical Use of Aromatase Inhibitors: Current Data and Future Perspectives

Abstract

A systematic procedure for the kinetic study of irreversible inhibition when the enzyme is consumed in the reaction which it catalyses, has been developed and analysed. Whereas in most reactions the enzymes are regenerated after each catalytic event and serve as reusable transacting effectors, in the consumed enzymes each catalytic center participates only once and there is no enzyme turnover. A systematic kinetic analysis of irreversible inhibition of these enzyme reactions is presented. Based on the algebraic criteria proposed in this work, it should be possible to evaluate either the mechanism of inhibition (complexing or non-complexing), or the type of inhibition (competitive, non-competitive, uncompetitive, mixed non-competitive). In addition, all kinetic constants involved in each case could be calculated. An experimental application of this analysis is also presented, concerning peptide bond formation in vitro. Using the puromycin reaction, which is a model reaction for the study of peptide bond formation in vitro and which follows the same kinetic law as the enzymes under study, we have found that: (i) the antibiotic spiramycin inhibits the puromycin reaction as a competitive irreversible inhibitor in a one step mechanism with an association rate constant equal to 1.3 × 10⁴M^-1s^-1 and, (ii) hydroxylamine inhibits the same reaction as an irreversible non-competitive inhibitor also in a one step mechanism with a rate constant equal to 1.6 × 10^-3 M^-1s^-1.     

Ill-conditioning associated with the "end-point" method for the determination of kinetic parameters describing irreversible enzyme inactivation by an unstable inhibitor

Study of the complete time-course of irreversible enzyme inhibition by an unstable inhibitor yields more information than can be obtained by recording data only at the end point of reaction. Time-course analysis of co-operative irreversible enzyme inhibition by an unstable inhibitor has been shown to be considerably less susceptible to ill-conditioning than the "end-point" method for the determination of kinetic parameters describing inactivation. As a result, mechanisms that cannot be distinguished by the "end-point" method are readily differentiated by time-course analysis without the need to isolate intermediate species.     

Inhibition of lentil copper/TPQ amine oxidase by the mechanism-based inhibitor derived from tyramine

Copper amine oxidase from lentil (Lens esculenta) seedlings was shown to catalyze the oxidative deamination of tyramine and three similar aromatic monoamines, benzylamine, phenylethylamine and 4-methoxyphenylethylamine. Tyramine, an important plant intermediate, was found to be both a substrate and an irreversible inhibitor of the enzyme whereas the other amines were not inhibitory. In the course of tyramine oxidation the enzyme gradually became inactivated with the concomitant appearance of a new absorption at 560 nm due to the formation of a stable adduct. Inactivation took place only in the presence of oxygen and was probably due to the reaction of the enzyme with the oxidation product of tyramine, p-hydroxyphenylacetaldehyde. The kinetic data obtained in this study indicate that tyramine represents a new interesting type of physiological mechanism-based inhibitor for plant copper amine oxidases.     

Modulation of the biologic activities of IgE-binding factor. IV. Identification of glycosylation-enhancing factor as a kallikrein-like enzyme

Stimulation of normal rat splenic T cells with pertussigen (lymphocytosis-promoting factor, LPF, from Bordetella pertussis) resulted in the release of a soluble factor that enhanced the glycosylation of IgE-binding factors during their biosynthesis. The soluble factor was detected by the ability of a culture filtrate of LPF-stimulated spleen cells to switch a T cell hybridoma, 23A4, from the formation of unglycosylated IgE-binding factor to the formation of glycosylated IgE-binding factor. The glycosylation-enhancing factor (GEF) had affinity for D-galactose, and the binding of the factor to hybridoma cells via a cell surface galactose was essential for modulation of IgE-binding factors. The GEF was inactivated by irreversible inhibitors of serine proteases such as phenylmethylsulfonyl fluoride, diisopropylfluorophosphate, and p-nitrophenyl ethylpentylphosphonate but was not affected by nonphosphorylating analogues of the organophosphorus compounds. Benzamidine, a competitive and reversible inhibitor of trypsin, also inhibited the glycosylation of IgE-binding factors by GEF. The factor could be purified by absorption to p-aminobenzamidine agarose followed by elution with benzamidine. The capacity of GEF to enhance the glycosylation of IgE-binding factors was inhibited by synthetic substrates of trypsin but not by substrates of chymotrypsin, indicating that GEF is a trypsin-like enzyme. Indeed, trypsin, plasmin, and kallikrein enhanced the glycosylation of IgE-binding factors during their biosynthesis. An inhibitor of trypsin-like enzyme(s), N-alpha-p-tosyl-L-lysine chloromethylketone (TLCK), inhibited trypsin and plasmin but not kallikrein, and TLCK failed to inhibit the GEF-mediated enhancement of glycosylation. It was also found that bradykinin, the biologically active product of cleavage of kininogen by kallikrein, enhanced the glycosylation of IgE-binding factors. The results indicate that GEF is a kallikrein-like enzyme.     

Inhibition of monoamine oxidase by substituted hydrazines

1. The initial rate of inhibition of monoamine oxidase by phenethylhydrazine was shown to be similar, in pH-dependence and kinetic properties, to the oxidation of that compound by monoamine oxidase. 2. The time-course of irreversible inhibition of monoamine oxidase by phenethylhydrazine lags behind that of reversible inhibition. 3. Hydralzine was shown to be a reversible competitive inhibitor of monoamine oxidase, but phenylhydrazine is an irreversible inhibitor. Inhibition by the latter compound is not affected by the absence of oxygen, and the presence of substrate exerts no protective action. 4. Hydrazine does not inhibit monoamine oxidase unless a substrate and oxygen are present. 5. Phenethylidenehydrazine was found to be a time-dependent inhibitor of monoamine oxidase and the rate of inhibition was hindered by increasing oxygen concentration. 6. A mechanism for the inhibition of the enzyme by phenethylhydrazine is proposed in which the product of oxidation of this compound is a potent reversible inhibitor and an irreversible inhibitor of the enzyme. A computer simulation of such a mechanism predicts time-courses of inhibition that are in reasonable agreement with those observed experimentally.     

N-alpha-Tosyl-L-lysine chloromethyl ketone and N-alpha-tosyl-L-phenylalanine chloromethyl ketone inhibit protein kinase C

TLCK (N-alpha-tosyl-L-lysine chloromethyl ketone) inhibits protein kinase C whether or not the enzyme is under the regulation of Ca2+ and phospholipid. TLCK (IC50 = 1 mM) is a much more potent inhibitor of protein kinase C than TPCK (N-alpha-tosyl-L-phenylalanine chloromethyl ketone) (IC50 = 8 mM), suggesting that the lysyl moiety of TLCK may be specifically recognized by the active site of protein kinase C. These results extend the evidence that the active site of protein kinase C recognizes basic amino acids, and suggest that the active sites of protein kinase C and the cAMP-dependent protein kinase, which is also inhibited by TLCK and TPCK, are structurally related.     

Half-time analysis of the kinetics of irreversible enzyme inhibition by an unstable site-specific reagent

The half-time method for the determination of Michaelis parameters from enzyme progress-curve data (Wharton, C.W. and Szawelski, R.J. (1982) Biochem. J. 203, 351-360) has been adapted for analysis of the kinetics of irreversible enzyme inhibition by an unstable site-specific inhibitor. The method is applicable to a model in which a product (R) of the decomposition of the site-specific reagent, retaining the chemical moiety responsible for inhibitor specificity, binds reversibly to the enzyme with dissociation constant Kr: (formula; see text). Half-time plots of simulated enzyme inactivation time-course data are shown to be unbiased, and excellent estimates of the apparent second-order rate constant for inactivation (k +2/Ki) and Kr can be obtained from a series of experiments with varying initial concentrations of inhibitor. Reliable estimates of k +2 and Ki individually are dependent upon the relative magnitudes of the kinetic parameters describing inactivation. The special case, Kr = Ki, is considered in some detail, and the integrated rate equation describing enzyme inactivation shown to be analogous to that for a simple bimolecular reaction between enzyme and an unstable irreversible inhibitor without the formation of a reversible enzyme-inhibitor complex. The half-time method can be directly extended to the kinetics of enzyme inactivation by an unstable mechanism-based (suicide) inhibitor, provided that the inhibitor is not also a substrate for the enzyme.     

Exogenous and endogenous protease inhibitors in the gut of the fall armyworm larvae,Spodoptera frugiperda

A dose‐dependent inhibition of endogenous trypsin and aminopeptidase occurs in the lumen of Spodoptera frugiperda after feeding L6 larvae exogenous inhibitors soybean trypsin inhibitor (SBTI), tosyl‐L‐lysine chloromethyl ketone‐HCl (TLCK), or bestatin, respectively, for 3 days. TLCK inhibits trypsin in tissue extracts and in secretions more strongly than SBTI. The aminopeptidase released into the lumen (containing the peritrophic membrane) is strongly inhibited by bestatin, but the membrane‐bound enzyme is not. A bound enzyme may be more resistant to an inhibitor than unbound. A cross‐class elevation of aminopeptidase activity occurs in response to ingested trypsin inhibitor, but there was no cross‐class effect of aminopeptidase inhibitor (bestatin) on trypsin activity. An endogenous trypsin and aminopeptidase inhibitor is present in the lumen and ventricular cells. The strength of the endogenous trypsin inhibition seems to be in the same range as that resulting from ingestion of the exogenous inhibitor SBTI. In some insect species, considerable trypsin secretion occurs in unfed as well as in fed animals, and endogenous protease inhibitors might function to protect the ventricular epithelium by inactivation of trypsin when less food is available. © 2010 Wiley Periodicals, Inc.