The level of aryl acylamidase activity displayed by human butyrylcholinesterase depends on its molecular distribution

Butyrylcholinesterase (BuChE) and acetylcholinesterase (AChE) display both esterase and aryl acylamidase (AAA) activities. Their AAA activity can be measured using o-nitroacetanilide (ONA). In human samples depleted of acetylcholinesterase, we noticed that the ratio of amidase to esterase activities varied depending on the source, despite both activities being due to BuChE. Searching for an explanation, we compared the activities of BuChE molecular forms in samples of human colon, kidney and serum, and observed that BuChE monomers (G(1)) hydrolyzed o-nitroacetanilide much faster than tetramers (G(4)). This fact suggested that association might cause differences in the AAA site between single and polymerized subunits. This and other post-translational modifications in BuChE subunits probably determine their level of AAA activity. The higher amidase activity of monomers could justify the presence of single BuChE subunits in cells as a way to preserve the AAA activity of BuChE, which could be lost by oligomerization.     

Kinetic analysis of butyrylcholinesterase-catalyzed hydrolysis of acetanilides

The aryl-acylamidase (AAA) activity of butyrylcholinesterase (BuChE) has been known for a long time. However, the kinetic mechanism of aryl-acylamide hydrolysis by BuChE has not been investigated. Therefore, the catalytic properties of human BuChE and its peripheral site mutant (D70G) toward neutral and charged aryl-acylamides were determined. Three neutral (o-nitroacetanilide, m-nitroacetanilide, o-nitrophenyltrifluoroacetamide) and one positively charged (3-(acetamido) N,N,N-trimethylanilinium, ATMA) acetanilides were studied. Hydrolysis of ATMA by wild-type and D70G enzymes showed a long transient phase preceding the steady state. The induction phase was characterized by a hysteretic "burst". This reflects the existence of two enzyme states in slow equilibrium with different catalytic properties. Steady-state parameters for hydrolysis of the three acetanilides were compared to catalytic parameters for hydrolysis of esters giving the same acetyl intermediate. Wild-type BuChE showed substrate activation while D70G displayed a Michaelian behavior with ATMA as with positively charged esters. Owing to the low affinity of BuChE for amide substrates, the hydrolysis kinetics of neutral amides was first order. Acylation was the rate-determining step for hydrolysis of aryl-acetylamide substrates. Slow acylation of the enzyme, relative to that by esters may, in part, be due suboptimal fit of the aryl-acylamides in the active center of BuChE. The hypothesis that AAA and esterase active sites of BuChE are non-identical was tested with mutant BuChE. It was found that mutations on the catalytic serine, S198C and S198D, led to complete loss of both activities. The silent variant (FS117) had neither esterase nor AAA activity. Mutation in the peripheral site (D70G) had the same effect on esterase and AAA activities. Echothiophate inhibited both activities identically. It was concluded that the active sites for esterase and AAA activities are identical, i.e. S198. This excludes any other residue present in the gorge for being the catalytic nucleophile pole.     

On the active site for hydrolysis of aryl amides and choline esters by human cholinesterases

Cholinesterases, in addition to their well-known esterase action, also show an aryl acylamidase (AAA) activity whereby they catalyze the hydrolysis of amides of certain aromatic amines. The biological function of this catalysis is not known. Furthermore, it is not known whether the esterase catalytic site is involved in the AAA activity of cholinesterases. It has been speculated that the AAA activity, especially that of butyrylcholinesterase (BuChE), may be important in the development of the nervous system and in pathological processes such as formation of neuritic plaques in Alzheimer's disease (AD). The substrate generally used to study the AAA activity of cholinesterases is N-(2-nitrophenyl)acetamide. However, use of this substrate requires high concentrations of enzyme and substrate, and prolonged periods of incubation at elevated temperature. As a consequence, difficulties in performing kinetic analysis of AAA activity associated with cholinesterases have hampered understanding this activity. Because of its potential biological importance, we sought to develop a more efficient and specific substrate for use in studying the AAA activity associated with BuChE, and for exploring the catalytic site for this hydrolysis. Here, we describe the structure-activity relationships for hydrolysis of anilides by cholinesterases. These studies led to a substrate, N-(2-nitrophenyl)trifluoroacetamide, that was hydrolyzed several orders of magnitude faster than N-(2-nitrophenyl)acetamide by cholinesterases. Also, larger N-(2-nitrophenyl)alkylamides were found to be more rapidly hydrolyzed by BuChE than N-(2-nitrophenyl)acetamide and, in addition, were more specific for hydrolysis by BuChE. Thus, N-(2-nitrophenyl)alkylamides with six to eight carbon atoms in the acyl group represent suitable specific substrates to investigate further the function of the AAA activity of BuChE. Based on the substrate structure-activity relationships and kinetic studies, the hydrolysis of anilides and esters of choline appears to utilize the same catalytic site in BuChE.     

Distinct Effect of Benzalkonium Chloride on the Esterase and Aryl Acylamidase Activities of Butyrylcholinesterase

Acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) from vertebrates, other than their predominant acylcholine hydrolase (esterase) activity, display a genuine aryl acylamidase activity (AAA) capable of hydrolyzing the synthetic substrate o-nitroacetanilide to o-nitroaniline. This AAA activity is strongly inhibited by classical cholinesterase (ChE) inhibitors. In the present study, benzalkonium chloride (BAC), a cationic detergent widely used as a preservative in pharmaceutical preparations, has been shown to distinctly modulate the esterase and AAA activities of BChEs. The detergent BAC was able to inhibit the esterase activity of human serum and horse serum BChEs and AChEs from electric eel and human erythrocyte. The remarkable property of BAC was its ability to profoundly activate the AAA activity of human serum and horse serum BChEs but not the AAA activity of AChEs. Thus BAC seem to preferentially activate the AAA activity of BChEs alone. Results of the study using the ChE active site-specific inhibitor diisopropyl phosphorofluoridate indicated that BAC binds to the active site of ChEs. Furthermore, studies using a structural homolog of BAC indicated that the alkyl group of BAC is essential not only for its interaction with ChEs but also for its distinct effect on the esterase and AAA activities of BChEs. This is the first report of a compound that inhibits the esterase activity, while simultaneously activating the AAA activity, of BChEs. Copyright 2000 Academic Press.     

Interaction of metal chelators with different molecular forms of acetylcholinesterase and its significance in Alzheimer's disease treatment

The peripheral anionic site (PAS) of acetylcholinesterase (AChE) is involved in amyloid beta (Aβ) peptides aggregation of Alzheimer's disease (AD). AChE exhibits an aryl acylamidase (AAA) activity along with the well known esterase activity. Numerous studies have reported the beneficiary effect of metal chelators in AD treatment. Hence, a comparative study on the effect of metal chelators on both the esterase and AAA activity of AChE globular (G4 and G1) molecular forms was performed. The inhibitory effect of 1,10‐phenanthroline was high towards AChE esterase activity. The corresponding IC₅₀ values for esterase activity of G4 and G1‐form was 190 µM and 770 µM and for AAA activity it was 270 µM and 2.74 mM, respectively. Kinetic studies on both forms of AChE show that 1,10‐phenanthroline inhibits esterase in competitive and AAA activity in non‐competitive manner. Protection studies further revealed that the nature of 1,10‐phenanthroline inhibition on AChE is through its direct binding to protein rather than its metal chelation property. Molecular docking studies shows orientation of 1,10‐phenathroline in the PAS through hydrophobic interactions with the PAS residues (Trp286, Tyr124 and Tyr341) and hydrogen bonding with Phe295. Further molecular dynamics simulation of “hAChE‐1,10‐phenanthroline” complex revealed that both hydrogen and hydrophobic interaction contribute equally for 1,10‐phenanthroline binding to hAChE. Such an interaction of 1,10‐phenanthroline on PAS may hinder “AChE‐Aβ peptide” complex formation. Hence, 1,10‐phenanthroline can act as a lead molecule for developing drug(s) against AD ailment with dual functions namely, anti‐cholinesterase and anti‐amyloid aggregation potency in a single chemical entity. Proteins 2013. Proteins 2013; 81:1179–1191. © 2013 Wiley Periodicals, Inc.     

Site-selective glycosylation of subtilisin Bacillus lentus causes dramatic increases in esterase activity

Using site directed mutagenesis combined with chemical modification, we have developed a general and versatile method for the glycosylation of proteins which is virtually unlimited in the scope of proteins and glycans that may be conjugated and in which the site of glycosylation and the nature of the introduced glycan can be carefully controlled. We have demonstrated the applicability of this method through the synthesis of a library of 48 glycosylated forms of the serine protease subtilisin Bacillus lentus (SBL) as single, pure species. As part of our ongoing program to tailor the activity of SBL for use in peptide synthesis, we have screened these enzymes for activity against the esterase substrate succinyl-Ala-Ala-Pro-Phe-S-benzyl. Gratifyingly, 22 enzymes displayed greater than wild type (WT) activity. Glycosylation at positions 62, in the S2 pocket, resulted in five glycosylated forms of SBL that were 1.3- to 1.9-fold more active than WT. At position 217, in the S1' pocket, all glycosylations increased kcat/KM up to a remarkable 8.4-fold greater than WT for the glucosylated enzyme L217C-S-beta-Glc(Ac)3. Furthermore, the ratio of amidase to esterase activity, (kcat/KM)esterase/(kcat/KM)amidase (E/A), is increased relative to wild type for all 48 glycosylated forms of SBL. Again, the most dramatic changes are observed at positions 62 and 217 and L217C-S-beta-Glc(Ac)3 has an E/A that is 17.2-fold greater than WT. The tailored specificity and high activity of this glycoform can be rationalized by molecular modeling analysis, which suggests that the carbohydrate moiety occupies the S1' leaving group pocket and enhances the rate of deacylation of the acyl-enzyme intermediate. These glycosylated enzymes are ideal candidates for use as catalysts in peptide synthesis as they have greatly increased (kcat,KM)esterase and severely reduced (kcat/KM)amidase and will favor the formation of the amide bond over hydrolysis.     

Differential effect of pressure and temperature on the catalytic behaviour of wild-type human butyrylcholinesterase and its D70G mutant.

The combined action of temperature (10-35 degrees C) and pressure (0. 001-2 kbar) on the catalytic activity of wild-type human butyrylcholinesterase (BuChE) and its D70G mutant was investigated at pH 7.0 using butyrylthiocholine as the substrate. The residue D70, located at the mouth of the active site gorge, is an essential component of the peripheral substrate binding site of BuChE. Results showed a break in Arrhenius plots of wild-type BuChE (at Tt approximately 22 degrees C) whatever the pressure (dTt/dP = 1.6 +/- 1.5 degrees C.kbar-1), whereas no break was observed in Arrhenius plots of the D70G mutant. These results suggested a temperature-induced conformational change of the wild-type BuChE which did not occur for the D70G mutant. For the wild-type BuChE, at around a pressure of 1 kbar, an intermediate state, whose affinity for substrate was increased, appeared. This intermediate state was not seen for the mutant enzyme. The wild-type BuChE remained active up to a pressure of 2 kbar whatever the temperature, whereas the D70G mutant was found to be more sensitive to pressure inactivation (at pressures higher than 1.5 kbar the mutant enzyme lost its activity at temperatures lower than 25 degrees C). The results indicate that the residue D70 controls the conformational plasticity of the active site gorge of BuChE, and is involved in regulation of the catalytic activity as a function of temperature.     

Butyrylcholinesterase activity and molecular components in thymus of healthy and merosin-deficient Lama2dy mice

The laminin-alpha2 chain, referred to as merosin, forms part of the laminin-2 heterotrimer (alpha2beta1gamma1), which is principally expressed in the basement membrane of muscle. Nearly half of patients suffering from congenital muscular dystrophy (CMD) have abnormalities in the laminin-alpha2 chain (LAMA2) gene, and the merosin-deficient Lama2dy mouse shows CMD. The expression of merosin in thymus, the abnormalities in the gland of Lama2dy mice, and the presence of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) in thymus prompted us to study the possible effects of the deficiency of merosin on thymus BuChE. We found that, while AChE activity decreased by approximately 50% in merosin-deficient thymus, the deficiency had little effect on BuChE activity. About 65% of thymus BuChE activity was extracted with a saline buffer and 30% with 1% Triton X-100. Sedimentation analyses and phenyl-agarose chromatography showed that thymus contained amphiphilic BuChE monomers (G(1)(A),44%) and dimers (G(2)(A),33%), and hydrophilic tetramers (G(4)(H),23%). Binding assays with various plant lectins revealed differences between the oligoglycans linked to BuChE tetramers and lighter components. The deficiency of merosin had no effect on the biosynthesis of thymus BuChE as judged by the lack of major changes between control and Lama2dy mice thymuses in the distribution of BuChE molecules and the level of lectin binding. The detoxifying action of BuChE, its role as a backup to AChE, and the relevance of the cholinergic dialogue between T cells and stromal cells for T lymphocyte proliferation, maturation and survival support a physiological function for BuChE in thymus.     

枯草蛋白酶E的定点突变及其对酶性质的影响

用定点突变的方法研究S221C/P225A,N118S/S221C/P225A,D60N/S221C/P225A和Q103R/S221C/P225A突变对蛋白酶活性,酯酶活性与蛋白酶活性之比的影响。结果表明：S221C/P225A突变使蛋白酶活性比枯草蛋白酶E低73000多倍,酯酶活性与蛋白酶活性之比是Subtiligase的3倍;N118S/S221C/P225A突变使蛋白酶活性和酯酶活性分别比S221C/P225A突变下降3.6倍和15倍,酯酶与蛋白酶活性之比下降4倍,同时增加变体酶的热稳定性;D60N/N118S/S221C/P225A突变使蛋白酶活性比N118S/S221C/P225A突变体下降15倍,但对酯酶活性几乎没有影响,酯酶与蛋白酶活性之比增加14倍,分别是S221C/P225A突变体和Subtiligase的3.3倍和10.3倍;但是,Q103R/N118S/S221C/P225A突变使蛋白酶活性比N118S/S221C/P225A突变体增加5倍,酯酶活性下降55倍,酯酶与蛋白酶活性之比下降1000倍。     

The level of butyrylcholinesterase activity increases and the content of the mRNA remains unaffected in brain of senescence-accelerated mouse SAMP8

Looking at cholinesterases (ChEs) changes in age-related mental impairment, the expression of ChEs in brain of senescence accelerated-resistant (SAMR1) and senescence accelerated-prone (SAMP8) mice was studied. Acetylcholinesterase (AChE) activity was unmodified and BuChE activity increased twofold in SAMP8 brain. SAMR1 brain contained many AChE-T mRNAs, less BuChE and PRiMA mRNAs and scant AChE-R and AChE-H mRNAs. Their content unchanged in SAMP8 brain. Amphiphilic (G(4)(A)) and hydrophilic (G(4)(H)) AChE and BuChE tetramers, besides amphiphilic dimers (G(2)(A)) and monomers (G(1)(A)) were identified in SAMR1 brain and their distribution was little modified in SAMP8 brain. Blood plasma does not seem to provide the excess of BuChE activity in SAMP8 brain; it probably arises from glial cell changes owing to astrocytosis.     

Molecular properties of acetylcholinesterase in mouse spleen

The presence of acetylcholinesterase (AChE) mRNA and activity in the tissues and cells involved in immune responses prompted us to investigate the level and pattern of AChE components in spleen. AChE activity was higher in mouse spleen (0.46 +/- 0.13 micromol of acetylthiocholine split per hour and per mg protein) than in muscle or heart, but lower than in brain. The spleen was essentially free of butyrylcholinesterase (BuChE) activity. About 40% of spleen AChE was extracted with a saline buffer, and a further 40% with 1% Triton X-100. Sedimentation analyses, the splitting of subunits in AChE dimers, phosphatidylinositol-specific phospholipase C (PIPLC) exposure, and phenyl-agarose chromatography showed that hydrophilic (G1H, 43%) and amphiphilic AChE monomers (G1A, 36%), as well as amphiphilic dimers (G2A, 21%), occurred in spleen. All these molecules bound to fasciculin-2-Sepharose, although the extent of binding was higher for G1H (77%) than for G1A (63%) or G2A (48%) forms. Differences in the extent to which wheat germ lectin (WGA) adsorbed with AChE of mouse spleen and of erythrocyte allowed us to discard the blood origin of spleen AChE activity. A 62 kDa protein was labeled in spleen samples using antibodies against human AChE. The protein was attributed to AChE monomers since its size was the same, regardless of whether disulfide bonds were reduced or not. Since cholinergic stimulation modulates proliferation/maturation of lymphoid cells, AChE may be important for regulating the level of acetylcholine (ACh) in the neighborhood of cholinergic receptors (AChR) in spleen and other lymphoid tissues.     

The expression of cholinesterases in human renal tumours varies according to their histological types

The change in the expression of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) activities in neoplastic colon and lung prompted us to study the possible effect of cancer on the expression of cholinesterases (ChEs) in kidney. Samples of papillary renal cell carcinoma (pRCC), conventional RCC (cRCC), chromophobe RCC (chRCC) and renal oncocytoma (RON), beside adjacent non-cancerous tissues, were analyzed. In pRCC both AChE and BuChE activities were statistically increased; in cRCC and chRCC only AChE activity increased and in RON neither AChE nor BuChE activities were affected. Abundant amphiphilic AChE dimers (G(2)(A)) and fewer monomers (G(1)(A)) were identified in healthy kidney as well as in all tumour classes. Incubation with PIPLC revealed glycosylphosphatidylinositol in AChE forms. BuChE is distributed between principal G(4)(H), fewer G(1)(H), and much fewer G(4)(A) and G(1)(A) species. RT-PCR showed similar amounts of AChE-H, AChE-T and BuChE mRNAs in healthy kidney. Their levels increased in pRCC but not in the other tumour types. The data support the idea that, as in lung tumours, in renal carcinomas expression of ChE mRNAs, biosynthesis of molecular components and level of enzyme activity change according to the specific kind of cell from which tumours arise.     

The nature of differences in amidase and esterase activities of some acyltrypsins]

Specific trypsin substrates (esters, anilides, amides, peptides) were shown to accelerate deacetylation of monoacetylated trypsin. The amidase activity of monoacetyl-, monopropyonyl-, and tetraformyl-trypsin was not manifested if the amidase activity of native enzyme was suppressed in these preparations by the ester substrates (benzoylarginine ethyl ester or p-nitrophenyl acetate). Therefore the differences in the residual amidase and esterase activities of these acylated trypsin preparations found earlier did not contradict the universality of the acylenzyme mechanism. These differences are due to the strong deacylating effect of specific substrate in its complex with the enzyme modified with nonspecific acyl residue. The latter fact is suggested to be an experimental confirmation of the "induced fit" hypothesis.     

NMR structure of Citrobacter freundii AmpD,comparison with bacteriophage T7 lysozyme and homology with PGRP domains

AmpD is a bacterial amidase involved in the recycling of cell-wall fragments in Gram-negative bacteria. Inactivation of AmpD leads to derepression of beta-lactamase expression, presenting a major pathway for the acquisition of constitutive antibiotic resistance. Here, we report the NMR structure of AmpD from Citrobacter freundii (PDB accession code 1J3G). A deep substrate-binding pocket explains the observed specificity for low molecular mass substrates. The fold is related to that of bacteriophage T7 lysozyme. Both proteins bind zinc at a conserved site and require zinc for amidase activity, although the enzymatic mechanism seems to differ in detail. The structure-based sequence alignment identifies conserved features that are also conserved in the eukaryotic peptidoglycan recognition protein (PGRP) domains, including the zinc-coordination site in several of them. PGRP domains thus belong to the same fold family and, where zinc-binding residues are conserved, may have amidase activity. This hypothesis is supported by the observation that human serum N-acetylmuramyl-L-alanine amidase seems to be identical with a soluble form of human PGRP-L.     

Affinity chromatography of human gamma-thrombin on fibrin-agarose

gamma-Thrombin was produced during autolysis or limited proteolysis of coagulant gamma-thrombin. This thrombin form loses its ability to coagulate fibrinogen but preserves the esterase and amidase activity on the low-molecular-weight synthetic substrates. This evidences for the integrity of the active site of gamma-thrombin and for the integrity break of the enzyme molecule region responsible for the binding with fibrinogen. gamma-Thrombin with the minimal coagulating activity, possessing high esterase and amidase activity is obtained. Fibrin-agarose possessing affinity to gamma-thrombin and specifically not binding gamma-thrombin was used to remove admixtures of the coagulant gamma-thrombin from the preparations of gamma-thrombin obtained during the enzyme autolysis.     

Substrate activation in acetylcholinesterase induced by low pH or mutation in the pi-cation subsite

Substrate inhibition is considered a defining property of acetylcholinesterase (AChE), whereas substrate activation is characteristic of butyrylcholinesterase (BuChE). To understand the mechanism of substrate inhibition, the pH dependence of acetylthiocholine hydrolysis by AChE was studied between pH 5 and 8. Wild-type human AChE and its mutants Y337G and Y337W, as well as wild-type Bungarus fasciatus AChE and its mutants Y333G, Y333A and Y333W were studied. The pH profile results were unexpected. Instead of substrate inhibition, wild-type AChE and all mutants showed substrate activation at low pH. At high pH, there was substrate inhibition for wild-type AChE and for the mutant with tryptophan in the pi-cation subsite, but substrate activation for mutants containing small residues, glycine or alanine. This is particularly apparent in the B. fasciatus AChE. Thus a single amino acid substitution in the pi-cation site, from the aromatic tyrosine of B. fasciatus AChE to the alanine of BuChE, caused AChE to behave like BuChE. Excess substrate binds to the peripheral anionic site (PAS) of AChE. The finding that AChE is activated by excess substrate supports the idea that binding of a second substrate molecule to the PAS induces a conformational change that reorganizes the active site.     

Concentration-dependent reversible activation-inhibition of human butyrylcholinesterase by tetraethylammonium ion.

Tetraalkylammonium (TAA) salts are well known reversible inhibitors of cholinesterases. However, at concentrations around 10 mm, they have been found to activate the hydrolysis of positively charged substrates, catalyzed by wild-type human butyrylcholinesterase (EC 3.1.1.8) [Erdoes, E.G., Foldes, F.F., Zsigmond, E.K., Baart, N. & Zwartz, J.A. (1958) Science 128, 92]. The present study was undertaken to determine whether the peripheral anionic site (PAS) of human BuChE (Y332, D70) and/or the catalytic substrate binding site (CS) (W82, A328) are involved in this phenomenon. For this purpose, the kinetics of butyrylthiocholine (BTC) hydrolysis by wild-type human BuChE, by selected mutants and by horse BuChE was carried out at 25 degreeC and pH 7.0 in the presence of tetraethylammonium (TEA). It appears that human enzymes with more intact structure of the PAS show more prominent activation phenomenon. The following explanation has been put forward: TEA competes with the substrate at the peripheral site thus inhibiting the substrate hydrolysis at the CS. As the inhibition by TEA is less effective than the substrate inhibition itself, it mimics activation. At the concentrations around 40 mm, well within the range of TEA competition at both substrate binding sites, it lowers the activity of all tested enzymes.     

Enantiomer effects of huperzine A on the aryl acylamidase activity of human cholinesterases

1. Acetylcholinesterase (AChE, EC 3.1.1.7) and butyrylcholinesterase (BuChE, EC 3.1.1.8) are serine hydrolase enzymes that catalyze the hydrolysis of acetylcholine.2. (–) Huperzine A is an inhibitor of AChE and is being considered for the treatment of Alzheimer's disease.3. In addition to esterase activity, AChE and BuChE have intrinsic aryl acylamidase activity.4. The function of aryl acylamidase is unknown but has been speculated to be important in Alzheimer pathology.5. Kinetic effects of (–) huperzine A and ( ±)$ huperzine A on the aryl acylamidase activity of human cholinesterases were examined.6. (–) Huperzine A inhibited the aryl acylamidase activities of both AChE and BuChE.7. (±) Huperzine A inhibited this function in AChE but stimulated BuChE aryl acylamidase suggesting that the (+) enantiomer is a powerful activator of this enzyme activity.8. The two huperzine enantiomers may prove to be useful tools to examine the function of aryl acylamidase activity, including its role in Alzheimer pathology.     

Substrate activation in acetylcholinesterase induced by low pH or mutation in the π-cation subsite

Substrate inhibition is considered a defining property of acetylcholinesterase (AChE), whereas substrate activation is characteristic of butyrylcholinesterase (BuChE). To understand the mechanism of substrate inhibition, the pH dependence of acetylthiocholine hydrolysis by AChE was studied between pH 5 and 8. Wild-type human AChE and its mutants Y337G and Y337W, as well as wild-type Bungarus fasciatus AChE and its mutants Y333G, Y333A and Y333W were studied. The pH profile results were unexpected. Instead of substrate inhibition, wild-type AChE and all mutants showed substrate activation at low pH. At high pH, there was substrate inhibition for wild-type AChE and for the mutant with tryptophan in the π-cation subsite, but substrate activation for mutants containing small residues, glycine or alanine. This is particularly apparent in the B. fasciatus AChE. Thus a single amino acid substitution in the π-cation site, from the aromatic tyrosine of B. fasciatus AChE to the alanine of BuChE, caused AChE to behave like BuChE. Excess substrate binds to the peripheral anionic site (PAS) of AChE. The finding that AChE is activated by excess substrate supports the idea that binding of a second substrate molecule to the PAS induces a conformational change that reorganizes the active site.     

A HISTOCHEMICAL ENZYME KINETIC SYSTEM APPLIED TO THE TRYPSIN-LIKE AMIDASE AND ESTERASE ACTIVITY IN HUMAN MAST CELLS

A method for the determination of enzyme kinetic constants V_m, K_m, and K_i in a histochemical system has been devised. As a substitute for the reciprocal of the reaction velocity, the times necessary to reach a fixed amount of end product (the initial visible color) in a tissue site at various substrate concentrations are plotted, according to the method of Lineweaver and Burk, against the reciprocal of the substrate concentrations. The technique as applied to trypsin-like esterase and amidase activities in human mast cells indicates that a single enzyme or closely related enzymes in this site are responsible for the hydrolysis of both the amide and ester substrates and that typical trypsin substrates act as competitive inhibitors of their hydrolysis. Parallel biochemical studies were performed to evaluate the effect of certain aspects of the experimental histochemical method on a purified homospecific enzyme. The relative kinetic constants derived by the histochemical method afford a further means of characterizing enzymic activity in a histochemical system.