Purification and properties of the membrane-bound acetylcholinesterase from adult rat brain

Immobilization of rat brain acetylcholinesterase on porous gold-nanoparticle-CaCO₃ hybrid material modified Au electrode for detection of organophosphorous insecticides

An acetylcholinesterase (AChE) purified from rat brain was immobilized onto gold nanoparticles (AuNPs) assembled on the surface of porous calcium carbonate (CaCO(3)) microsphere. The resulting AChE-AuNPs-CaCO(3) bioconjugate was mounted on the surface of Au electrode with the help of silica sol-gel matrix to prepare the working electrode. This electrode was connected to Ag/AgCl (3M/saturated KCl) as standard and Pt wire as an auxiliary electrode through a potentiostat to construct an organophosphorus (OP) biosensor. The biosensor was based on inhibition of AChE by OP compounds/insecticides. The biosensor showed optimum response at pH 7.0, 30°C, when polarized at +0.2V. Two OP compounds, malathion and chlorpyrifos could be detected in the range of 0.1-100 nM and 0.1-70 nM, respectively at 2.0-3.0% inhibition level of AChE. The sensor was reactivated by immersing it in 0.1 mM 2-pyridine aldoxime for 10 min. The detection limit of the sensor was 0.1 nM for both malathion and chlorpyrifos. The biosensor exhibited good reusability (50 times without considerable loss) and storage stability (50% within 60 days, when stored at 4°C).

Potencies and selectivities of inhibitors of acetylcholinesterase and its molecular forms in normal and Alzheimer's disease brain

Eight inhibitors of acetylcholinesterase (AChE), tacrine, bis-tacrine, donepezil, rivastigmine, galantamine, heptyl-physostigmine, TAK-147 and metrifonate, were compared with regard to their effects on AChE and butyrylcholinesterase (BuChE) in normal human brain cortex. Additionally, the IC50 values of different molecular forms of AChE (monomeric, G1, and tetrameric, G4) were determined in the cerebral cortex in both normal and Alzheimer's human brains. The most selective AChE inhibitors, in decreasing sequence, were in order: TAK-147, donepezil and galantamine. For BuChE, the most specific was rivastigmine. However, none of these inhibitors was absolutely specific for AChE or BuChE. Among these inhibitors, tacrine, bis-tacrine, TAK-147, metrifonate and galantamine inhibited both the G1 and G4 AChE forms equally well. Interestingly, the AChE molecular forms in Alzheimer samples were more sensitive to some of the inhibitors as compared with the normal samples. Only one inhibitor, rivastigmine, displayed preferential inhibition for the G1 form of AChE. We conclude that a molecular form-specific inhibitor may have therapeutic applications in inhibiting the G1 form, which is relatively unchanged in Alzheimer's brain.

Functional expression of a mammalian acetylcholinesterase in Pichia pastoris: comparison to acetylcholinesterase, expressed and reconstituted from Escherichia coli

The mature rat brain acetylcholinesterase gene (T subunit, AChE) was subcloned downstream of the temperature-inducible lambda promoter PL and fused to the signal peptide of the OmpA protein. Three different expression vectors were constructed: (i) pCompmA containing the mature AChE, (ii) pComp delta TA containing a truncated AChE and (iii) pComp delta TAH containing the truncated AChE C-terminal fused to a 6xHis-tag. With all expression vectors the overexpression of AChE in Escherichia coli resulted mainly in cytoplasmic inclusion bodies (IB). However, some activity was found in the periplasmic space. The inclusion bodies were refolded in vitro, yielding up to 1.42 U/mg IB of active AChE. The refolded AChE was partially purified (approx. 300-fold) by affinity chromatography with a specific activity of approx. 250 U/mg. Removing the cysteine residue near the C-terminus (truncated AChE, delta TAChE) assuming to affect the refolding, did not increase the amount of active enzyme obtained after refolding. Purification of denatured delta TAChE-6xHis prior to refolding by Ni-NTA-chromatography increased the refolding efficiency by a factor of 1.5. Functional expression and secretion of rat brain acetylcholinesterase into the medium was achieved in Pichia pastoris. By optimizing the culture conditions, 100 mU/ml AChE in the medium was produced. In this work we are describing the functional expression of a mammalian AChE in a microbial host in good yields for the first time. The physico-chemical properties of both, the bacterial and yeast expressed AChE were compared with those of the native AChE. The properties of the yeast expressed AChE and the native AChE were similar, whereas the E. coli expressed enzyme was found to be less stable and had different inhibition properties.

Methyl parathion activation by a partially purified rat brain fraction

Organophosphorus pesticides are one of the most commonly used insecticide classes. They act through a potent inhibition of acetylcholinesterase (AChE). Many of them must undergo transformation into the corresponding oxon analogs to inhibit AChE. This study showed that a brain tissue subfraction transformed methyl parathion (O,O-dimethyl O-p-nitrophenyl phosphorothioate) in vitro. Methyl parathion activation was assayed by solvent extraction of the products followed by HPLC and GC-MS analyses and, indirectly, by the inhibition of AChE present in the incubation mixture. The lack of impairment of AChE after 2 h of incubation of the brain subfraction with methyl parathion and, alternatively, with NADPH, CO, SKF 525-A, piperonyl butoxide or nitrogen indicated that this brain subfraction transformed methyl parathion without the involvement of a mixed-function oxidative pathway. The results from HPLC analysis did not show a peak corresponding to methyl paraoxon (O,O-dimethyl O-p-nitrophenylphosphate), but showed the production of an unidentified peak which eluted nearby standard methyl parathion (retention times of 10.65 and 8.86 min, respectively). GC-MS analysis suggested that the unidentified product could be a methyl parathion isomer.

Biochemical characterization of sheep platelet acetylcholinesterase after detergent solubilization

The biochemical characterization of detergent-solubilized acetylcholinesterase (AChE) from subcellular particles of sheep platelets and the effects of different effectors on AChE activity from solubilized platelet crude membranes have been undertaken and studied. Solubilization of AChE with detergent increased the thermal stability of the enzyme from all particulate fractions. Solubilized AChE from the mitochondria-granule fraction was the most thermostable at 55 degrees C. The Km values against acetylthiocholine chloride and the Arrhenius plot obtained were very similar for the AChE from all the solubilized fractions. There were no differences in the ability of solubilized AChE from different subcellular fractions to bind concanavalin A (Con A). In solubilized platelet crude membranes, benzyl alcohol was a potent AChE inhibitor at a concentration of 10(-2) M, whereas ethanol was not. Mg2+ cations and, to a lesser extent, Ca2+ and Mn2+ cations, activated AChE at concentrations higher than 1 mM. Serine hydrolase inhibitors and cholinesterase-specific inhibitors were very effective in the inactivation of AChE, whereas EDTA and EGTA had no effect. Of all the monosaccharides tested, only N-acetylneuraminic acid exerted an inhibitory effect on AChE activity. Immobilized-lectin binding studies demonstrated the interaction of solubilized crude membrane-bound AChE with Con A, lentil lectin and wheat germ agglutinin. Taken together, these data suggest the presence of a unique form of the membrane-bound AChE which has at least alpha-mannose and N-acetylglucosamine residues in the glycan chain.

Regional variation in expression of acetylcholinesterase mRNA in adult rat brain analyzed by in situ hybridization

To investigate the molecular basis of regional variation in expression of brain acetylcholinesterase (AChE; EC 3.1.1.7), steady-state levels of AChE activity and mRNA were examined. Relative AChE activity in Triton extracts from six areas of the rat brain varied as follows: cortex < cerebellum < medulla < pons-midbrain < thalamus < striatum. In contralateral samples from the same brains, AChE mRNA was assessed by Northern blotting with random-primed 32P-labeled cDNA. The regional abundance of the major 2.4-kb AChE transcript differed from that of the enzyme activity: cortex < striatum < cerebellum < medulla < thalamus < pons-midbrain. In situ hybridization with a 33P-labeled antisense AChE oligonucleotide provided evidence for high levels of AChE message in cells of the nucleus basalis, nucleus accumbens, neostriatum, substantia nigra, motor nucleus of the facial nerve, and spinal nucleus of the trigeminal nerve. In the caudate-putamen, large, heavily labeled neurons were not numerous, but they were approximately as frequent as the cholinergic interneurons revealed by choline acetyltransferase immunocytochemistry. The relatively low number of these AChE-expressing cells probably explains the relative dearth of AChE mRNA-like material in the neostriatum.

Comparison of standard chromatographic procedures for the optimal purification of soluble human brain acetylcholinesterase

With the view of purifying soluble human brain acetylcholinesterase (AChE) into its separate isoforms, various preparative chromatographic procedures were compared. Chromatofocusing of cerebrospinal fluid (CSF) AChE revealed two major activity peaks, whilst that of caudate nucleus AChE showed one major peak. Both CSF and caudate nucleus AChE eluted at isoelectric points (pI) of between 5.5 and 5.2. Chromatofocusing failed to separate AChE into its individual isoforms, based on qualitative isoelectric focusing. Preparative purification by affinity chromatography showed a better AChE yield with the use of procainamide as a ligand, vis-à-vis acridinium. Maximum recovery for CSF and caudate nucleus AChE was 10 and 43% using acridinium and procainamide, respectively. Qualitative analysis by SDS-PAGE of affinity-purified AChE revealed four major bands between 50 and 62 kDa, corresponding to the catalytic subunits of AChE as verified by an anti-AChE polyclonal antibody. A size-exclusion column also allowed brain AChE purification, with the latter eluting at a putative molecular mass of 310 kDa. Unfortunately, cation-exchange using the state-of-the-art SMART system failed to separate AChE into its isoforms. AChE aggregation is given as one major obstacle precluding good resolution of isoforms.

Potentiation effect of choline esters on choline-catalysed decarbamoylation of dimethylcarbamoyl-acetylcholinesterase

The choline esters potentiated the choline-catalysed decarbamoylation of dimethylcarbamoyl-acetylcholinesterase in proportion to the length of acyl group, although esters containing an acyl chain longer than the hexanoyl group exhibited a corresponding decrease in the potentiation. In structural requirement analysis it was found that both the quaternary ammonium moiety and the ester bond were important for the effective acceleration of choline-catalysed decarbamoylation. In general, the respective thiocholine ester was found to be more effective than the corresponding choline ester. Whereas the binding affinity (Ka) of choline in the decarbamoylation was not significantly altered, the maximum decarbamoylation rate (kr(max.)) of choline was greatly enhanced in the presence of choline esters or thiocholine esters. Along with the above observation, the isotope solvent effect, the effect of ionic strength and the antagonism studies demonstrate that the choline esters or thiocholine esters may interact with one of peripheral anionic sites, and thereby make the choline-catalysed decarbamoylation more favourable.

Separation in a single step by affinity chromatography of cholinesterases differing in subunit number

We describe an affinity chromatography method in which dimethylaminoethylbenzoic acid-Sepharose 4B is used, making it possible to separate in one step the molecular forms of globular acetylcholinesterase (AChE, EC 3.1.1.7) or butyrylcholinesterase (ChE, EC 3.1.1.8). A crude extract containing these enzymes was deposited onto the chromatography gel, washed, and eluted by a linear gradient of tetramethylammonium chloride (0-0.3 M). With rat brain AChE, two well-separated peaks were eluted in the presence of 1% Triton X-100; the first peak corresponded to 4 S forms and the second to 11 S forms. This separation was very efficient for salt-soluble activity and less efficient for the detergent-soluble AChE. In this case, the 4 S peak represented only 6.5% of total detergent-soluble activity and was cross-contaminated by the 11 S form. Rat serum ChE was efficiently separated into two peaks of 7 S and 11 S. This method could potentially be adapted to separate other multimeric proteins with varying numbers of affinity sites.

Comparative studies on the primary structure of acetylcholinesterases from bovine caudate nucleus and bovine erythrocytes

1. Comparison of partial amino acid sequences of G2-acetylcholinesterase (AChE) from bovine erythrocytes and G4-AChE from bovine caudate nucleus revealed no differences in primary structure between the two enzymes. The first 33 residues of the N-terminal sequences were identical. 2. In addition, the amino acid sequences of four peptides generated by tryptic and cyanogen bromide cleavage were identical for bovine erythrocyte and brain AChE, suggesting one identical major coding exon for the adult bovine AChE forms. Comparison of these sequences with that of fetal bovine serum AChE (Doctor et al., 1988), showed differences in residues 16, 181, 212, and 216. 3. Deglycosylation studies of the two adult enzyme forms revealed that the core protein of erythrocyte AChE has an approximately 4 kDa lower molecular mass than brain AChE. This most probably reflects differences in the C-terminal sequences of the two enzymes.

Cholinotoxic effects of aluminum in rat brain

The in vivo and in vitro effects of Al on the cholinergic system of rat brain were studied. The amount of Al accumulated after the chronic, intraperitoneal administration of aluminium gluconate (Al-G) or AlCl3, both at a dose of 1 mg/ml/100 g of body weight, increased in the frontal and parietal cortices, the hippocampus, and the striatum. Significantly decreased choline acetyltransferase activities after chronic Al treatment were measured in the parietal cortex, the hippocampus, and the striatum, but not in the frontal cortex. The acetylcholinesterase activity was not changed significantly in any brain area investigated. Both Al-G and AlCl3 administrations resulted in a general decrease (to 40-70% of the control values) in the specific l-[3H]nicotine binding, involving all brain areas studied. The specific (-)-[3H]quinuclidinyl benzilate binding was reduced (to 40-60% of the control values) only after 25 days of Al treatment. Al-G and AlCl3 were equivalent in eliciting these reductions in vitro studies revealed different alterations of the cholinergic system in response to Al treatment. No changes were observed either in choline acetyltransferase activity or in cholinergic receptor bindings. Both Al-G and Al2(SO4)3 treatments, however, exhibited a biphasic effect on the acetylcholinesterase activity. At low Al concentrations (10(-8)-10(-6) M), the activity was slightly increased, whereas at higher concentrations (10(-6)-10(-4) M), it was inhibited by a maximum of 25% as compared to the controls. Thus, these cholinotoxic effects are probably due not to a direct interaction between the metal and the cholinergic marker proteins, but rather to a manifestation and consequence of its neurodegenerative effects.

Modes of attachment of acetylcholinesterase to the surface membrane

Acetylcholinesterase (AChE) occurs in multiple molecular forms differing in their quaternary structure and mode of anchoring to the surface membrane. Attachment is achieved by post-translational modification of the catalytic subunits. Two such mechanisms are described. One involves attachment to catalytic subunit tetramers, via disulfide bridges, of a collagen-like fibrous tail. This, in turn, interacts, primarily via ionic forces, with a heparin-like proteoglycan in the extracellular matrix. A second such modification involve the covalent attachment of a single phosphatidylinositol molecule at the carboxyl-terminus of each catalytic subunit polypeptide; the diacylglycerol moiety of the phospholipid serves to anchor the modified enzyme hydrophobically to the lipid bilayer of the plasma membrane. The detailed molecular structure of these two classes of acetylcholinesterase are discussed, as well as their biosynthesis and mode of anchoring.

Two-site immunoassay for acetylcholinesterase in brain, nerve, and muscle

Two-site methods were developed for immunoassay of acetylcholinesterase (AChE; EC 3.1.1.7) in crude extracts of rat and human tissues. A radiometric assay for human AChE utilized a specific monoclonal AChE antibody adsorbed to polystyrene microtiter wells at alkaline pH. AChE bound strongly to this antibody after 24 h at 4 degrees C. Bound enzyme was detected with an 125I-labeled antibody against a different AChE epitope. The assay signal was quasi-linearly related to AChE concentration in purified and crude samples, with a detection threshold near 100 pg. Tetrameric and dimeric AChE behaved equivalently in the assay. Two-site methods with a different pair of species-selective antibodies worked equally well for immunoassay of rat AChE. Assays of the rat enzyme showed that immunoreactivity was lost as rapidly as enzyme activity during heating to 54 degrees C. On the other hand, immunoreactivity was preserved despite loss of enzyme activity after exposure to anticholinesterases or trypsin. A biotinylated second antibody detected by alkaline-phosphatase-conjugated avidin was used to develop an AChE enzyme-linked immunosorbent assay (ELISA) with a sensitivity similar to that of the radiometric assay. Either the ELISA or the radiometric immunoassay may be useful whenever proteolysis or other mechanisms are suspected of dissociating enzyme activity and immunoreactivity. In denervated muscle and ligated peripheral nerve, application of the two-site method showed closely parallel variations in immunoreactivity and enzyme activity.

Tetrameric detergent-soluble acetylcholinesterase from human caudate nucleus: subunit composition and number of active sites

Purified tetrameric detergent-soluble acetylcholinesterase (DS-AChE) from human caudate nucleus was analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the absence as well as in presence of a reducing agent. Staining for protein revealed a main band at 66,000 daltons (light monomer) with additional bands at 78,000 daltons (heavy monomer) as well as 130,000 and 150,000 daltons (light and heavy dimers). The same four polypeptides were also detected by Western blotting and by autoradiography of [3H]diisopropylphosphoryl enzyme. Labeling of the enzyme with 3-trifluoromethyl-3-(m-[125I]-iodophenyl)diazirine showed that the heavy monomer contained the hydrophobic anchor of the enzyme, whereas the light monomer was practically not labeled. The hydrophobic anchor was susceptible to proteolytic degradation by proteinase K. The functional molarity of DS-AChE was determined by two independent methods. Four active sites for the tetrameric enzyme were estimated. The turnover number per site was 1.7 X 10(7) mol of acetylthiocholine iodide hydrolyzed X h-1.

Solubilization and partial characterization of acetylcholinesterase from the sarcotubular system of skeletal muscle

Attempts were made to solubilize acetylcholinesterase (AChE) from microsomal membranes isolated from rabbit white muscle. The preparative procedure included a step in which the microsomes were incubated in a solution containing high salt concentration (0.6 M KCl). About 15% of the total enzyme activity could be solubilized with dilute buffer. Addition of EDTA (1 mM), EGTA (1 mM) or NaCl (0.5 and 1 M) to the extraction buffer did not improve the solubilization yield. Several non-ionic detergents and biliary salts were then used to bring the enzyme into solution. Triton X-100, C12E9 (dodecylnonaethylenglycol monoether) and biliary salt, above their critical micellar concentration, proved to be very effective as solubilizing agents. The occurrence of multiple molecular forms in detergent-soluble AChE was investigated by means of molecular sieving, centrifugation analysis, and slab gel electrophoresis. Experiments on gel filtration showed that, during the process, half of the enzyme was transformed into aggregates, the rest of the activity appearing as peaks with Stokes radii ranging from 3.7 to 7.9 nm. Both ionic strength and detergent nature modify the number and relative proportion of these peaks. Centrifugation analysis of Triton-saline-soluble AChE yielded molecular forms of 4.8S, 10-11S, and 13.5S, whereas deoxycholate extracts revealed species of 4.8S, 10S, and 15S, providing that gradients were prepared with 0.5 M NaCl. In the absence of salt, forms of 6.5-7.5S, 10S, and 15S were measured. The lightest species was always the predominant form. Slab gel electrophoresis showed several bands (68,000-445,000). The 4.8S component only yielded bands of 65,000-70,000.(ABSTRACT TRUNCATED AT 250 WORDS)

Monoclonal antibodies against chicken brain acetylcholinesterase. Their use in immunopurification and immunochemistry to demonstrate allelic variants of the enzyme

Acetylcholinesterase (AChE) from 1-day chicken brain was enriched over 2000-fold by affinity chromatography using N-methylacridinium-Sepharose. This preparation was used to prepare monoclonal antibodies (mAb) directed against AChE, of which two were extensively characterised for further application. Both mAbs bound to the enzyme from the chicken with high affinity (Kd approximately 8 X 10(-10) M) and one mAb, in addition, recognised AChE from quail brain and muscle. Neither mAb cross-reacted with mammalian or fish AChE. Both mAbs recognised AChE in the endplate region of adult chicken skeletal muscle and bound with equal affinity to the three major oligomeric forms found in early ambryonic muscle. One mAb was used to immunopurify chicken brain AChE to homogeneity (over 12000-fold enrichment), with nearly complete recovery of the enzyme and without detectable proteolytic breakdown. The other mAb recognised AChE after immunoblotting and was used to screen crude brain extracts from individual chickens for allelic variations. Evidence is presented to show that two allelic forms occur, represented in SDS-PAGE by a doublet polypeptide of Mr approximately 110,000, this pattern is maintained after deglycosylation of the N-linked oligosaccharides. This variation was found throughout development and in both the brain and the muscle of individuals. We conclude that the gene encoding the catalytic subunit of chicken AChE is polymorphic with either one or two equally active alleles being expressed.

Soluble form of acetylcholinesterase from rabbit enterocytes: comparison of its molecular properties with those of the plasma membrane species

A soluble form of acetylcholinesterase was shown to be present in rabbit enterocytes. The enzyme was obtained from a high-speed supernatant (105,000 X g centrifugation) after homogenization of intestinal mucosa without detergent. It was shown to possess no obvious hydrophobic character and could be classified as a low-salt-soluble (LSS) acetylcholinesterase. Sucrose gradient centrifugation revealed a single enzyme species with a sedimentation coefficient of 3.9 +/- 0.2S. By gel filtration performed in HPLC the enzyme was eluted as a protein corresponding to an Mr of 72,000 +/- 3,000. It could be precipitated with concanavalin A by affinoelectrophoresis, but the catalytic activity was not affected by the lectin. Our results are consistent with a G1 globular form for this soluble acetylcholinesterase which differs very clearly from detergent-soluble forms also found recently in the plasma membranes of rabbit enterocytes.

Ultrastructural and biochemical evidence of the trimeric nature of frog virus 3 (FV3) six-coordinated capsomers

Image analysis of freeze-etch replicas of cylindrical aberrant forms of FV3 provided evidence for three morphological subunits protruding from the six-coordinated capsomers. Negatively stained capsomers displayed both triangular and hexagonal profiles which suggests that their innermost portion is pseudohexagonal. Images from underfocused micrographs of capsomers are indicative of a central channel. The trimeric nature of the capsomer has been established by electrophoresis in the presence of Triton X-100, which showed that the molecular weight of the nondissociated capsomer is about 140,000 whereas that of the polypeptide itself is 48,000. This trimeric association does not occur via disulfide bonds, and inside the capsomers there are no free amino groups accessible to the usual bifunctional reagents. Thus, the chemical nature of the interpolypeptide bonds inside the trimers is still unknown. We have previously estimated the triangulation number (T) of FV3 to be 147 or 133 (Darcy-Tripier et al., 1984). The present study, using optical diffraction of the facets of FV3, allowed a better determination of the angle of skewness and is in favor of T = 133 (h = 9, k = 4, 18 degrees).

Monoclonal antibodies to rat brain acetylcholinesterase: comparative affinity for soluble and membrane-associated enzyme and for enzyme from different vertebrate species

Seven unique monoclonal antibodies were generated to rat brain acetylcholinesterase. Upon density gradient ultracentrifugation, immunoglobulin complexes with the monomeric enzyme appeared as single peaks of acetylcholinesterase activity with a sedimentation coefficient approximately 3S greater than that of the free enzyme. This behavior is consistent with the assumption of one binding site per enzyme molecule. Apparent dissociation constants of these antibodies for rat brain acetylcholinesterase calculated on the basis of this assumption ranged from about 10 nM to more than 1,000 nM. Some of the antibodies were less able to bind the membrane-associated enzyme that required detergent for solubilization than the naturally soluble acetylcholinesterase of detergent-free brain extracts. Species cross-reactivity was investigated with crude brain extracts from mammals (human, mouse, rabbit, guinea pig, cow, and cat) and from other vertebrates (chicken, frog, and electric eel). Three antibodies bound rat acetylcholinesterase exclusively; one had nearly the same affinity for all mammalian acetylcholinesterases investigated; the remaining three showed irregular binding patterns. None of the antibodies recognized frog and electric eel enzyme. Pooled antibody was found to be suitable for specific immunofluorescence staining of large neurons in the ventral horn of the rat spinal cord and smaller cells in the caudate nucleus. Other potential applications of these antibodies are discussed.

The solubilization of platelet membrane-bound acetylcholinesterase and aryl acylamidase by exogenous or endogenous phosphatidylinositol specific phospholipase C

Phosphatidylinositol specific phospholipase C from Staphylococcus aureus could solubilize acetylcholinesterase up to 55% from sheep platelets in the presence of ethylenediaminetetra acetic acid (EDTA). The endogenous phosphatidylinositol specific phospholipase C of platelets activated by deoxycholate (at 3-5 mM) could also solubilize the enzyme to a similar extent. The solubilized enzyme could be further purified to apparent homogeneity by affinity chromatography without the use of any detergents. It is suggested that phosphatidylinositol specific phospholipase C will be a useful tool in the solubilization of acetylcholinesterase from mammalian sources and its purification free of detergents. The present study also demonstrates the parallel behaviour of acetylcholinesterase and aryl acylamidase in platelets confirming their identity.

Immunochemical differences among molecular forms of acetylcholinesterase in brain and blood

Molecular forms of acetylcholinesterase (acetylcholine acetylhydrolase, EC 3.1.1.7) differ in their solubility properties as well as in the number of their catalytic subunits. We used monoclonal antibodies to investigate the structure of acetylcholinesterase forms in brain, erythrocytes and serum of rats, rabbits and other mammals. Two antibodies were found to bind tetrameric acetylcholinesterase in preference to the monomeric enzyme. These antibodies also displayed lower affinity for certain forms of 'soluble' brain acetylcholinesterase than for the 'membrane-associated' counterparts. Furthermore, one of them was virtually lacking in affinity for the membrane-associated enzyme of erythrocytes. The basis for the antibody specificity was not fully determined. However, the immunochemical results were supported by measurements of enzyme thermolability, which showed that the catalytic activity of 'soluble' acetylcholinesterase was comparatively heat-resistant. These observations point toward structural differences among the solubility classes of acetylcholinesterase.

Molecular forms of acetylcholinesterase from human caudate nucleus: comparison of salt-soluble and detergent-soluble tetrameric enzyme species

Extraction of human caudate nucleus under high-ionic-strength conditions solubilized 20-30% of total acetylcholinesterase (AChE) activity. Density gradient centrifugation revealed monomeric (5.0 S) and tetrameric (11.0 S) enzyme species. The purified, tetrameric salt-soluble (SS) AChE sedimented at 10.6 S and did not bind detergents. It showed an immunochemical reaction of identity with the detergent-soluble (DS) AChE species from human caudate nucleus and human erythrocytes, but did not cross-react with antibodies raised against human serum cholinesterase. The remaining activity was solubilized under low-ionic-strength conditions in the presence of 1.0% Triton X-100. The purified tetrameric, DS-AChE sedimented at 10.0 S as detergent-protein mixed micelle and on extensive removal of the detergent this enzyme formed defined aggregates by self-micellarization. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions revealed that the salt-soluble and detergent-soluble tetrameric enzyme species both contained a heavy and a light dimer; under reducing conditions mainly one band corresponding to the light subunit was seen. Molecular weights of 300,000 dalton and 280,000 dalton were calculated for SS-AChE and DS-AChE, respectively. Limited digestion of DS-AChE with proteinase K led to isolation of an enzyme that no longer bound detergents and lacked the intersubunit disulfide bridges.

Activation and inactivation of bovine caudate acetylcholinesterase by trivalent cations

Kinetic analysis of the interaction of trivalent cations with mammalian brain acetylcholinesterase revealed at least three distinct concentration-dependent effects on enzyme activity. Acetylcholinesterase was purified from bovine caudate nucleus by affinity chromatography to a specific activity of 1.1 mmoles acetylthiocholine X hr-1 X (mg protein)-1. The cations studied included the chloride salts of lanthanum, terbium, yttrium and scandium in low and high ionic strength buffers (2 mM Pipes +/- 0.1 M NaCl). At low ionic strength, high affinity noncompetitive or allosteric activation was observed at very low cation concentrations (1-10 microM); at higher concentrations (50-200 microM) these cations were noncompetitive inhibitors; and at 200-500 microM they exerted a mixed competitive-noncompetitive inhibition. Activation by low cation concentrations was not evident in high ionic strength buffers, while enzyme inhibition by all the trivalent cations was similar at low and high ionic strength. Inhibition by all of the multivalent cations was fully reversed by a 10-fold excess of EDTA or by a 100-fold dilution of the inhibited enzyme. The water-soluble carboxyl group affinity reagent, 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide, was shown to specifically block the activating effect of the multivalent cations supporting the suggestion that the beta- or "activator" peripheral anionic sites (P1) involve a carboxyl group outside the enzyme active site.

Two-step immunoaffinity purification of acetylcholinesterase from rabbit brain

Acetylcholinesterase (AChE; EC 3.1.1.7) extracted in 1% Triton X-100 from rabbit brain was purified 2,000-fold by chromatography on agarose conjugated with a monoclonal antibody directed against human red blood cell cholinesterase. After elution from the immunoadsorbent with pH 11 buffer, the preparation was purified further by affinity chromatography on phenyltrimethylammonium-Sepharose 4B with decamethonium elution. Overall yield of purified enzyme was 37% of the AChE originally solubilized, with a specific activity of 2,950 units/mg protein. Electrophoresis under reducing conditions in 7.5% sodium dodecyl sulfate polyacrylamide gels revealed only one silver-staining polypeptide band. A streamlined purification procedure enabled the isolation of electrophoretically homogeneous AChE to be completed in fewer than 7 days, at yields exceeding 50%. Electrophoretic analysis of purified AChE indicated an apparent MW of 71,000 for the monomeric subunit. Gel filtration and sucrose density gradient centrifugation in the presence of Triton X-100 showed little difference between the properties of the native and the purified enzyme. The molecular mass of the main species was estimated from the gel filtration and sedimentation data to be 280,000 daltons. Kinetic parameters of the purified protein (Km = 0.16 +/- 0.01 mM) were close to those of the native enzyme (Km = 0.12 +/- 0.01 mM) when examined with acetylthiocholine iodide as substrate. The two-step immunopurification procedure presented in this communication offers a convenient route to homogeneous neural AChE in quantities useful for detailed biochemical and immunochemical study.

Polymorphism and immunochemical cross-reactivity of acetylcholinesterases from the brains of human, dog, hog, bovine and horse

In the caudate nucleus of the species tested about 20% of the acetylcholinesterase was salt soluble and sedimented in sucrose density gradient centrifugation as monomeric 5 S and tetrameric 10 S enzyme. About 80% was solubilized by micellar concentrations of Triton X-100 and sedimented as a tetrameric 10 S species in the presence of detergent but formed aggregates in the absence thereof. All the enzyme displayed poor cross-reactivity with a precipitating assay (Ouchterlony) but in a solid phase non-precipitating assay the cross-reactivity could be quantified and ranged from 96 to less than 1% depending on the species.

Change in the distribution of acetylcholinesterase molecular forms in Hirschsprung's disease

Density gradient ultracentrifugation shows that two molecular forms of acetylcholinesterase (4S and 10S) can be distinguished in the bowels of both normal subjects and Hirschsprung's disease patients. In this disease, besides the very large elevation of acetylcholinesterase activity, the relative distribution of the heavy and light forms was also changed. In the affected bowel the 10S/4S ratio was 2.5 times higher than the normal value. It is assumed that the accumulation of the 10S form might be a response of the intestine to this pathological state. It is also suggested that the increase in the heavy form is closely connected with the nerve fibre proliferation in the aganglionic megacolon.

Bovine nucleus caudatus acetylcholinesterase: active site determination and investigation of a dimeric form obtained by selective proteolysis

The number of catalytic subunits of purified bovine nucleus caudatus acetylcholinesterase (E.C. 3.1.1.7) has been determined by active site labelling with [3H]diisopropyl fluorophosphate ([3H]DFP). The 10.5 S, 16 S, and 20 S forms were estimated to contain two, four, and six active sites, respectively, per molecule. A 4.8 S form, which showed a weak amphiphile-dependent activity behavior, was obtained by selective proteolytic digestion with pronase. The inability of the purified 4.8 S form to aggregate after detergent removal, and the molecular mass in the range of 130-165 kD under nondenaturating conditions, indicate that this form is a dimeric form, lacking those hydrophobic regions responsible for aggregation.

An immunological study of rat acetylcholinesterase: comparison with acetylcholinesterases from other vertebrates

We have examined the immunoreactivity of acetylcholinesterase from different vertebrate species with a rabbit antiserum raised against the purified rat brain hydrophobic enzyme (G4 form). We found no significant interaction with enzymes from Electrophorus, Torpedo, chicken, and rabbit. The antiserum reacted with acetylcholinesterases from the brains of the other mammalian species studied, with titers decreasing in the following order: rat = mouse greater than human greater than bovine. The serum was inhibitory with murine and human acetylcholinesterases, but not with the bovine enzyme. The inhibition was partially depressed in the presence of salt (e.g., 1 M NaCl). In those species whose acetylcholinesterase was recognized by the antiserum, both soluble and detergent-soluble fractions behaved in essentially the same manner, interacting with the same antibodies. The apparent immunoprecipitation titer was decreased in the presence of salt, and it did not make any difference whether NaCl was included in the solubilization procedure or added to the extracts. Both G1 and G4 forms of acetylcholinesterase in the soluble and detergent-soluble fractions were recognized by the antiserum, and in the case of the human enzyme, by monoclonal antibodies produced against human erythrocyte acetylcholinesterase. However, the monomer G1 showed a clear tendency to form smaller complexes and precipitate less readily than the tetramer G4. Although we cannot exclude the existence of significant differences between the various molecular forms of acetylcholinesterase, our results are consistent with the hypothesis that they all derive from the same gene or set of genes by posttranslational modifications.

Anticholinesterase action of a bromine compound isolated from human cerebrospinal fluid

L-1- Methylheptyl -gamma- bromoacetoacetate was found to be a competitive inhibitor of the acetylcholinesterases (electric eel, Ki = 17.2 microM; rat brain, Ki = 32.6 microM) and of butyrylcholinesterase (horse serum, Ki = 1.2 microM). The L-isomer was a more effective inhibitor than the D-isomer. The bromine atom at the gamma-position of the acidic moiety, the specific length of the carbon chain constituting the secondary alcohol moiety, and the presence of the ketone radical at the acidic moiety of the ester were necessary for the anticholinesterase action. 1- Methylheptyl -gamma- bromoacetoacetate formed a complex with acetylcholinesterase or butyrylcholinesterase without hydrolysis of its own molecule.

[Properties and characterization of soluble forms of lymphocyte acetylcholinesterase from an ox]

Two soluble forms of AChE from lymphocyte membrane have been obtained, the Triton solubilized Sd form and the high molar salt solubilized Ss form. They present similar Km (0.10 mM). Hydrodynamic properties of these forms have been studied on saccharose gradients with and without detergent or salt. A similar sedimentation coefficient has been found for these two forms (5.7 S). Lymphocyte plasma membrane AChE is a dimeric form (G2). Without detergent, the Sd form shows multiple secondary forms due to main form polymerization. Increase of NaCl concentration (2M) gives rise to a partial dissociation of these polymers. In the same conditions, the Ss form is not affected. The Ss form centrifugated on cesium chloride gradient has a higher density than the Sd form. These two forms have been treated by HPLC: the Stokes radii are respectively 7.1 nm for the Sd form and 4.5 nm for the Ss form. The molecular weights have been estimated at 175 000 for the Sd form and 105 000 for the Ss form. Pronase enzymatic digestion shows that the Ss form is more rapidly inactivated than the Sd form. Phospholipase C inhibits the Ss form and indicates that this form is a lipid-enzyme complex. The Sd form presents a different behaviour: this form is first activated, and afterwards inhibited by phospholipase C. This behaviour could be due to a more preponderant lipidic environment for the Sd form. The Sd form is probably a detergent-lipid-enzyme complex with an important hydrophobocity. These two forms can be explained by a different association between the enzyme and the phospholipids at the plasma membrane.

Terbium binding to rat brain acetylcholinesterase. A fluorescence probe of anionic sites

Studies are in progress to characterize the nature of ligand interactions at peripheral anionic sites on mammalian brain AChE, including the beta-anionic or "accelerator" anionic sites where enzyme activity is increased upon Ca2+ binding. Terbium was studied as a fluorescence probe of Ca2+ binding sites in partially purified AChE from whole rat brain. Scatchard analysis of Tb3+ binding in low ionic strength (2 mM) Pipes buffer revealed at least two populations of sites: high affinity sites with Kd(app) approximately 7.6 microM and low-affinity sites with a Kd(app) approximately 49.6 microM. Low-affinity binding was selectively inhibited by 50 mM NaCl; high-affinity binding was completely inhibited by 2 mM CaCl2; and all the bound Tb3+ could be displaced by 1 mM EDTA. The heterogeneity of Tb3+ binding sites is consistent with the multiple, concentration-dependent effects of Tb3+ on enzyme activity.

Multiple molecular forms of acetylcholinesterase in the nematode Caenorhabditis elegans

Extracts of the nematode Caenorhabditis elegans contain five molecular forms of acetylcholinesterase (AChE) activity that can be separated by a combination of selective solubilization, velocity sedimentation, and ion-exchange chromatography. These are called form IA (5.2s), form IB (4.9s), form II (6.7s), form III (11.3s), and form IV (13.0s). All except form III are present in significant amounts in rapidly prepared extracts and are probably native; form III is probably derived autolytically from form IV. Most of forms IA and IB can be solubilized by repeated extractions without detergent, whereas forms II, III, and IV require detergent for effective solubilization and may therefore be membrane-bound. High salt concentrations are not required for, and do not aid in, the solubilization of these forms. For all forms, molecular weights and frictional ratios have been estimated by a combination of gel permeation chromatography and velocity sedimentations in both H2O and D2O. The molecular weight estimates range from 83,000 to 357,000 and only form II shows extensive asymmetry. The separated forms have been characterized with respect to substrate affinity, substrate specificity, inhibitor sensitivity, thermal inactivation, and detergent sensitivity. Judging by these properties, C. elegans is like other invertebrates in that none of its cholinesterase forms resembles either the "true" or the "pseudo" cholinesterase of vertebrates. However, internal comparison of the C. elegans forms clearly distinguishes forms IA, III, and IV as a group from forms IB and II; the former are therefore designated "class A" forms, the latter "class B" forms. Genetic evidence indicates that separate genes control class A and class B forms, and that these two classes overlap functionally. Several factors, including kinetic properties, molecular asymmetry, molecular size, and solubility, all suggest that a molecular model of the multiple cholinesterase forms observed in vertebrate electric organs probably does not apply in C. elegans. Potential functional roles and subunit structures of the multiple AChE forms within each C. elegans class are discussed.

Isolation and characterization of a trypsin-like serine proteinase from the membranes of Walker 256 carcino-sarcoma cells

A serine proteinase was isolated from Walker-256-carcino-sarcoma plasma-membrane-enriched preparations by affinity chromatography employing soya-bean trypsin inhibitor as the ligand. This enzyme was termed 'memsin' owing to its membrane location and trypsin-like substrate specificity. Analysis of this preparation by steric-exclusion high-pressure liquid chromatography (h.p.l.c.) resulted in a single peak of enzyme activity. Calculations of the rates of inactivation of memsin by peptidyl-chloromethanes and comparison with rate constants obtained with other serine proteinases indicated that memsin closely resembled trypsin and acrosin. Digestion of oxidized ribonuclease by memsin and analysis of the resulting peptides by h.p.l.c. yielded a chromatogram that was very similar to one generated by a tryptic digest of oxidized ribonuclease. This enzyme could possibly play a role in tumour-cell invasion.

Comparative affinity chromatography of acetylcholinesterases from five vertebrate species

The efficacy of N-methylacridinium affinity chromatography in the purification of acetylcholinesterases from chicken, rat, calf and human brain and from the electric organ of the electric fish Torpedo marmorata has been investigated. Retention of the enzymes on the N-methylacridinium columns exceeded 90% in all instances except for the chicken enzyme, where 40-80% retention was observed depending on the acridinium concentration. Sucrose density gradient centrifugation profiles revealed no difference between the distribution of molecular forms in the crude extracts and in the partially purified fractions eluted from the columns by decamethonium iodide.

Properties of acetylcholinesterase in lobster axonal membrane

1. Acetylcholinesterase (AChE) activity of axonal membrane vesicles prepared from lobster (Homarus americanus) walking leg nerve is about 200 mumol ACh/hr/mg protein. 2. The enzyme is a membrane-bound glycoprotein that can be solubilized by lysolecithin and digitonin but is rapidly inactivated by Triton X-100 and other nonionic detergents. 3. The walking leg nerve enzyme contrasts most markedly with postsynaptic AChE in its lack of inhibition by excess substrate and its poor susceptibility to peripheral anionic site ligands. 4. Axonal AChE is competitively blocked by eserine sulfate (1 microM) and by low concentrations of procaine (0.1-0.5 mM). 5. Lidocaine, a tertiary amine, and its quaternary ammonium derivative QX-314 are equipotent non-competitive enzyme inhibitors (Kiapp 2-3 mM), while the primary amine compound GX-HCl is totally inactive. 6. Calcium (10 50 mM), propidium (1 microM) and decamethonium (1 microM), peripheral anionic site ligands in the synaptic enzyme, do not protect the axonal enzyme against inhibition by local anesthetics. 7. Although it is possible that this enzyme is an isozyme of the true AChE of excitable membranes, or that it is an incomplete enzyme fragment, it is also possible that there is a unique membrane-bound AChE present in large quantities in crustacean peripheral nerve.

An amphiphile-dependent form of human brain caudate nucleus acetylcholinesterase: purification and properties

Different forms of acetylcholinesterase (AChE), EC 3.1.1.7, were demonstrated in human brain caudate nucleus. One form was solubilized at high ionic strength, the other with Triton X-100. The detergent-extractable form was purified to homogeneity by affinity chromatography. This form of AChE is amphiphile-dependent; i.e., it was active only in the presence of amphiphiles (detergents or lipids). Further, the enzyme was shown to bind detergents and to interact hydrophobically with Phenyl-Sepharose. In the presence of detergents the enzyme is a tetramer (subunit molecular weight, 78,000) which aggregates on the removal of detergents. Human brain AChE showed a reaction of identity with human erythrocyte AChE in crossed-line immunoelectrophoresis. The high-salt-soluble brain enzyme did not cross-react with the erythrocyte enzyme. The two classes of AChE seem not to be related, as they show no common antigenic determinant.

Serotonin-sensitive aryl acylamidase activity of platelet acetylcholinesterase

Serotonin-sensitive aryl acylamidase (AAA, EC 3.5.1.13) was purified to apparent homogeneity from sheep platelets by affinity chromatography and it was shown to be associated with the platelet acetylcholinesterase (AChE, EC 3.1.1.7). The basis for the association of the two enzymes was the following. Both enzyme activities co-eluted from the affinity columns with constant ratios of specific activities and percentage recoveries. Both enzymes co-migrated on gel electrophoresis. Both enzymes co-eluted during sepharose 6B gel filtration. Potent inhibitors of AChE such as bis(4-allyldimethyl ammoniumphenyl) pentan-3-one dibromide (BW 284C51), neostigmine and eserine also inhibited AAA potently. Both enzymes lost significant activity on treatment with deoxycholate or taurodeoxycholate and the loss could be partly restored by a mixture of phospholipids. The platelet AAA was specifically inhibited by serotonin and to a lesser extent by tryptamine but not by several other amines. It was also inhibited by acetylcholine and several of its analogues and homologues. It is suggested that in the platelets the two enzymes (AAA and AChE) are probably identical.

Aggregation properties of the acetylcholinesterase from the central nervous system of Manduca sexta

The CNS of the tobacco hornworm, Manduca sexta, provides a rich source of true acetylcholinesterase (AChE, acetylcholine, hydrolase, EC 3.1.1.7). Optimal extraction of the enzyme was obtained with a nonionic detergent at high ionic strength (1% Triton X-100, 0.5 M NaCl). Velocity sedimentation of the Triton + salt-extracted enzyme demonstrated a single peak whose sedimentation coefficient was dependent upon the enzyme concentration layered on top of the gradient. When more than 20 units were applied to the gradient, a sedimentation coefficient of 8.6 S (205,000) was obtained, and extrapolation to zero units yielded a 5.7 S (110,500) species. Sedimentation in the absence of detergents (1.0 M NaCl or 10 mM phosphate buffer, pH 7.4) yielded pelleted enzyme and species with mean values of 18.6 S (650,000) and 17.5 S (600,000), respectively. The detergent-extracted enzyme also demonstrated a concentration-dependent size in gel filtration experiments. When less than 300 units were applied to the column, a single species was recovered, with a molecular radius of 40.15 +/- 2.08 A (108,000) or 43.4 +/- 2.38 A (117,000) calculated by different methods. If the sample contained 300 to 1,300 units, two species were observed, with molecular radii of 40.15 +/- 2.08 A or 43.4 +/- 2.38 A and 78.4 +/- 3.94 A (319,000) or 80.25 +/- 3.01 A (326,000). Velocity sedimentation and gel filtration of AChE have demonstrated that the enzyme has a minimum molecular weight of approximately 110,000 and also exists as higher-molecular-weight aggregates of this value.

Heterogeneity of rat brain acetylcholinesterase: a study by gel filtration and gradient centrifugation

According to their solubilization properties, two classes of acetylcholinesterases (AChE) can be detected in the adult rat brain: a "soluble" species (easily solubilized without detergent), and a membrane-bound species (solubilized only in the presence of detergent). The latter was found to be homogeneous by gel filtration (Stokes radius 8.05 +/- 0.35 nm) and sucrose gradient centrifugation (9.75 +/- 0.2 S) in the presence of Triton X-100. The "soluble" AChE gives three stable species in the presence of the same detergent with Stokes radii and sedimentation constants of 10.9 +/- 0.5 nm and 16 +/- 2S; 6.75 +/- 0.30 nm, and 10.7 +/- 0.4 S; 5.37 +/- 0.35 nm and 4.37 +/- 0.1 S. Co-chromatography and co-sedimentation or the reduction and alkylation of disulfide bridges show that all the soluble species are different from the membrane-bound AChE. The possibility that soluble and membrane-bound AChE are completely different molecules is discussed.