Molecular structure of elongated forms of electric eel acetylcholinesterase.

Molecular forms of acetylcholinesterase extracted from fresh electric organ tissue of the electric eel are elongated structures in which a multi-subunit head is connected to a fibrous tail. The principal form, 18 S acetylcholinesterase, is of molecular weight approximately 1,050,000, contains about 12 catalytic subunits in its head, has a tail approximately 500 Å long, and aggregates reversibly at low ionic strength. Trypsin converts it to an 11 S globular tetramer devoid of the tail and lacking the capacity to aggregate in low-salt solutions.Amino acid analysis shows that elongated forms of acetylcholinesterase contain significant amounts of hydroxyproline and hydroxylysine, characteristic components of collagen, which are absent from 11 S acetylcholinesterase.Collagenase converts 18 S acetylcholinesterase to a 20 S form which no longer aggregates in low salt. Purified 20 S acetylcholinesterase has about half the hydroxyproline and hydroxylysine contents of the 18 S enzyme, and physicochemical measurements indicate the formation of a more symmetrical molecular structure without marked reduction in molecular weight.Sodium dodecyl sulfate/polyacrylamide gel electrophoresis without reducing agent shows that in 18 S acetylcholinesterase half the catalytic subunits are present as dimers linked by disulfide bonds. The remaining subunits migrate as larger molecular species which contain significant amounts of hydroxylysine, are specifically modified by collagenase and are converted to dimers and monomers by trypsin.Sodium dodecyl sulfate/acrylamide gel electrophoresis with reducing agent reveals, in 18 S acetylcholinesterase, two polypeptides of molecular weights 45,000 and 47,000 which are absent in the 11 S tetramer. They are readily digested by collagenase under conditions which do not affect the catalytic subunits, with concomitant formation of a new 30,000 polypeptide.The above data can be rationalized by a model in which 18 S acetylcholinestorase contains three subunit tetramers, each linked by disulfides to one strand of a collagen triple helix. Sodium dodecyl sulfate detaches those subunit dimers which are not covalently linked to the tail; trypsin attacks the distal portion of the collagen triple helix releasing discrete tetramers, and collagenase specifically attacks the triple helix near its midpoint, producing a shortened structure in which the residual tail still holds the tetramers together, but destroying the capacity for self-association at low ionic strength. This latter property may be related to the postulated role of the tail in anchoring acetylcholinesterase to the fibrillar matrix of the basement membrane.     

Immunochemical studies of mammalian brain acetylcholinesterase.

Abstract— Specific antibodies were raised in rabbits to acetylcholinesterase (AChE) from bovine caudate nucleus and the‘native’(14S + 18S) and globular (11S) forms of AChE from eel electric tissue. All AChE preparations were purified by affinity chromatography to a specific activity of 100–400 mmol acetylthiocholine hydrolyzed/mg protein/h. Antigenic specificities of the different enzyme forms were studied by immunodiffusion, Immunoelectrophoresis and micro-complement fixation. Minor differences in antigenic determinants were observed between the different molecular forms of electric tissue AChE. In crossover experiments using both eel AChE and bovine caudate AChE antisera there was complete absence of cross reactivity between the mammalian brain AChE and the different molecular forms of the electric tissue enzyme. Brain AChE activity was inhibited up to 50% in the presence of its antiserum.     

The multiple forms of brain acetylcholinesterase

Summary Micro-polyacrylamide gradient electrophoresis followed by active staining is applied for the demonstration of the multiple forms of acetylcholinesterase. Among other advantages the very small samples that enable the analysis of well-defined brain material as well as the almost histochemical conditions of incubation enable its successful use in topochemical investigations of the multiple form pattern of brain acetylcholinesterase.The acetylcholinesterase of bovine nc. caudatus could be separated into 4 multiple forms and the pattern was analysed microdensitometrically. These forms differ in their molecular weight as well as well as in their degree of membrane binding. Increasing ionic strength (NaCl) is followed by changes in the pattern. This result is discussed as caused by aggregation of enzyme subunits.The research reported in this paper was supported by the Ministerium für Wissenschaft und Technik der DDR     

Active-site catalytic efficiency of acetylcholinesterase molecular forms in Electrophorus, torpedo, rat and chicken

The active sites of acetylcholinesterase multiple forms from four widely different zoological species (Electrophorus, Torpedo, rat and chicken) were titrated using a stable, irreversible phosphorylating inhibitor (O-ethyl-S2-diisopropylaminoethyl methyl-phosphonothionate). In all cases, we found that within a given species, the molecular forms we examined were equivalent in their catalytic activity per active site. As pure preparations of the molecular forms of Electrophorus acetylcholinesterase were available, we were able to establish that one inhibitor molecule binds per monomer unit for each of them. This had already been shown by several authors for the tetrameric globular form, but not for the tailed molecules. Analysis of the phosphorylation reaction showed that they are equally reactive. Under our experimental conditions, their turnover number per site was 4.4 x 10(7) mol of acetylthiocholine hydrolysed . h-1 at 28 degrees C, pH 7.0. The corresponding value was less than half for Torpedo (1.64 x 10(7) mol . h-1), and again lower for rat (1.32 x 10(7) mol . h-1) and chicken (1.05 x 10(7) mol . h-1). In the case of rat acetylcholinesterase, the activity per active site of solubilized (with or without Triton X-100) and membrane-bound enzyme were identical. We discuss the implications of these findings with respect to the quaternary structure of acetylcholinesterase, and to the physico-chemical state and physiological properties of its molecular forms.     

The multiple forms of brain acetylcholinesterase

Summary The pattern of the multiple forms of the acetylocholinesterase (AChE, E.C. 3.1.1.7) of the rat brain is investigated using polyacrylamide gradient micro-gel electrophoresis with regard to a possible functional importance of this individual forms. The patterns of the AChE-forms of selected regions of the CNS are compared and certain differences could be shown. After increased cholinergic input (into the hippocampus by electrical stimulation of the nc. septi medialis) an aggregation of AChE subunits is detectable. Subletal intoxication with an irreversible inhibitor of AChE is followed by a faster recovery of the smaller forms. A suggestion of a possible functional role of the multiple forms of AChE is discussed.The research reported in this paper was supported by the Ministerium für Wissenschaft und Technik der DDR     

Molecular forms of acetylcholinesterase in mammalian smooth muscles

A comparative study of the molecular forms of acetylcholinesterase (AChE) was made in various smooth muscles (intestine, vas deferens, ciliary body, iris, nictitating membrane retractor, ureter, arteries, anococcygeus muscles) of some mammals (cat, guinea-pig, rat, rabbit, mouse), seeking for a correlation between the presence of 16 S (asymmetric, tailed) form of AChE in smooth muscles and their type of innervation defined by morphological criteria, as well as by the nature of the main neurotransmitters involved in their neuroeffector junctions. Contrary to previous assertions, many smooth muscles contain 16 S AChE, although all those examined here exhibited a proportion clearly less than that of striated muscles. There are large species-specific and individual variations in the percentage of 16 S AChE. The highest percentages of 16 S AChE were found in ciliary and iris muscles, which are provided with an individual (= multiunit) cholinergic innervation. The vas deferens muscles, which are also individually, but noradrenergically innervated contain practically no 16 S AChE. In the muscles having a fascicular (= unitary) innervation, the differences are striking: 16 S AChE is in rather high amount in intestine muscle layers, whereas it is very low or virtually absent in ureter or arterial muscles. Thus, the type of innervation is not clearly involved in the amount of 16 S AChE present in smooth muscles. As for the nature of neurotransmitter a clear correlation exists only in the case of individual innervation, in which only one neurotransmitter is involved or largely predominant.     

Purification of native forms of eel acetylcholinesterase: active site determination

The 14 and 18 S forms of acetylcholinesterase from the electric organ of Electrophorus electricus were purified by chromatography on an N-methyl-3-aminopyridinium derivative of Affi-Gel 202. a further increase in purity was seen when these forms were separated by density gradient sedimentation subsequent to the affinity step. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate demonstrated that the 14 and 18 S forms were highly purified following these procedures. Using [³H]diisopropyl fluorophosphate labeling and separation of labeled enzyme from unreacted [³H]diisopropyl fluorophosphate by gel filtration, active site numbers of 8.3 and 11.4 were determined for the 14 and 18 S forms, respectively. These numbers compare to 4.2 active sites determined for the 11.8 S globular form of acetylcholinesterase. These results are in accord with a proposed model of two and three tetrameric structures comprising the head groups of the 14 and 18 S forms of electric tissue acetylcholinesterase.     

Ecdysterone induces acetylcholinesterase in mammalian brain

The effects of ecdysterone on brain acetylcholinesterase (AChE) in immature and adult rats of both sexes have been studied in in vitro conditions. Ecdysterone produced an increase of AChE in rat brain slices. The most remarkable effect was found in immature male rats. In vitro assay using a purified AChE from electric eel showed no effect. Pretreatment with cycloheximide or actinomycin D abolished the ecdysterone action on brain AChE. These results support the idea that induction of AChE may be involved in the heterophilic action of ecdysterone.     

Kinetic analysis of calcium activation of brain acetylcholinesterase forms.

Calcium activation of acetylcholine hydrolysis by bovine brain acetylcholinesterase (Acetylcholine hydrolase, EC 3.1.1.7) forms has been analyzed in terms of changes in kinetic constants and thermodynamic activation parameters. De-acetylation was determined to be the major rate-influencing step in acetylcholine hydrolysis by both 60 000- and 240 000-dalton forms of the brain enzyme and 10 mM Ca2+ increased the rate constant for this step (k+3) by approximately 30% for both forms. For the smaller acetylcholinesterase form the effects of Ca2+ on de-acetylation was equivalent to its effect on the overall rate constant (k) and occurred without an effect on pK. In the case of the 240 000-dalton species, the overall rate constant was increased by Ca2+ by 33% at pH 8.0 and 81% at pH 7.25 and involved a pK shift of -0.2 pH units. For both enzyme forms the rate constants for acetylation (k+2) were increased by Ca2+. Thermodynamic analysis suggested that Ca2+ activation of the acetylation step was entropically driven. Differences between the two enzymes forms in terms of Ca2+ appear to result from association of low molecular weight species.     

Multiple forms of acetylcholinesterase from pig brain

1. A number of methods of solubilization of pig brain acetylcholinesterase (EC 3.1.1.7) were studied. The multiple enzymic forms of the resultant preparations were examined by polyacrylamide-gel electrophoresis. 2. Butanol extraction, Nagarase treatment and ultrasonication proved unsuitable as preparatory methods, but detergent treatment (Triton X-100, Triton X-100-KCl and lysolecithin) gave good yields. 3. Separation of soluble enzyme in three systems of polyacrylamide-gel electrophoresis were compared and the relative advantages are discussed. 4. By using a 6% (w/v) gel and continuous buffer system two forms of acetylcholinesterase were detected in Triton X-100-solubilized enzyme, but the incorporation of a sample and spacer gel and a discontinuous buffer system resolved this into four components. The forms of the soluble enzyme extracted by different methods differed in mobility. 5. With gradient polyacrylamide-gel electrophoresis between two and six forms were detected, depending on the method used for extraction. The average molecular weights of the five forms most frequently found were 60000, 130000, 198000, 266000 and 350000. 6. Treatment of the Triton X-100-extracted enzyme with 2.5m-urea altered the pattern and evidence of dissociation was observed. 7. The results are discussed in the light of present theories on the molecular structure of acetylcholinesterase.     

Analysis of the forms of acetylcholinesterase from adult mouse brain.

The solubilization of 80% of the acetylcholinesterase activity of mouse brain was performed by repeated 2h incubations of homogenates at 37 degrees C in an aqueous medium. Analysis of the soluble extract by gel filtration on Sephadex G-200 showed that up to 80% of the enzyme activity was eluted in a peak which was estimated to consist of molecules of about 74000mol.wt. This peak was called the monomer form of the enzyme. After 3 days at 4 degrees C, the soluble extract was re-analysed and was eluted from the column in four peaks of about 74000, 155000, 360000 and 720000 mol.wt. Since the total activity of the enzyme in these peaks was the same as that in the predominantly monomer elution profile of fresh enzyme, we concluded that the monomer had aggregated, possibly into dimers, tetramers and octomers. Extracts of the enzyme were analysed by polyacrylamide-gel electrophoresis and the resulting multiple bands of enzyme activity on gels were shown to separate according to their molecular sizes, that is by molecular sieving. All these forms had similar susceptibilities to the inhibitors eserine, tetra-isopropyl pyrophosphoramide and compound BW 284c51 [1,5-bis-(4-allyldimethylammoniumphenyl)pentan-3-one dibromide]. Thus the forms of the enzyme in mouse brain which can be detected by gel filtration and polyacrylamide-gel electrophoresis may all be related to a single low-molecular-weight form which aggregates during storage. This supports similar suggestions made for the enzyme in other locations.     

Lamprey brain contains globular and asymmetric forms of acetylcholinesterase

To obtain more information about the evolution of acetylcholinesterase in the vertebrates, we studied the cholinesterase activity from the brain of the lamprey Petromyzon marinus. We found that the enzyme is true acetylcholinesterase and that 98% of it is present in the G₄ globular form. Only 1% of the enzyme was found distributed among the asymmetric forms A₄, A₈ and A₁₂; an additional 1% of the activity could not be extracted from the brain. The identity of the asymmetric forms was confirmed by collagenase digestion. These data demonstrate that asymmetric acetylcholinesterase is present in the CNS of organisms representing all classes of vertebrates. However, our results are inconsistent with an evolutionary trend that has been observed for vertebrate brain acetylcholinesterase.     

Immobilized electric eel acetylcholinesterase. I. Kinetics of acetylcholinesterase trapped in polyacrylamide membranes.

Techniques are described for the trapping of electric eel acetylcholinesterase in polyacrylamide gel. The activity of the trapped enzyme was substantially reduced, the effect being due to inhibition by acrylamide, but the emzyme immobilized in polyacrylamide was considerable more stable than that in free solutionma kinetic study was made of the hydrolysis of acetylthiocholine, covering a range of membrane thicknesses, enzyme concentrations, substrate concentrations and temperatures. The results were interpreted with reference to the theoretical treatment of Sundaram, Tweedale and Laidler, and of Kobayaski and Laidler, and provided support for those treatments; Clear evidence was obtained for diffusion control with the thicker membranes. An activation energy was obtained for the diffusion of the substrate within the membrane, by combining the temperature results for thick and thin membranes at low substrate concentrations. The results lead to the conclusion that the in vivo kinetics of acetylcholinesterase are largely diffusion-free in muscle filaments, but are substantially diffusion-controlled in fibrils and fibers.     

Preferential inhibition of acetylcholinesterase molecular forms in rat brain

The effect of eight different acetylcholinesterase inhibitors (AChEIs) on the activity of acetylcholinesterase (AChE) molecular forms was investigated. Aqueous-soluble and detergent-soluble AChE molecular forms were separated from rat brain homogenate by sucrose density sedimentation. The bulk of soluble AChE corresponds to globular tetrameric (G₄), and monomeric (G₁) forms. Heptylphysostigmine (HEP) and diisopropylfluorophosphate were more selective for the G₁ than for the G₄ form in aqueous-soluble extract. Neostigmine showed slightly more selectivity for the G₁ form both in aqueous- and detergent-soluble extracts. Other drugs such as physostigmine, echothiophate, BW284C51, tetrahydroaminoacridine, and metrifonate inhibited both aqueous- and detergent-soluble AChE molecular forms with similar potency. Inhibition of aqueous-soluble AChE by HEP was highly competitive with Triton X-100 in a gradient, indicating that HEP may bind to a detergent-sensitive non-catalytic site of AChE. These results suggest a differential sensitivity among AChE molecular forms to inhibition by drugs through an allosteric mechanism. The application of these properties in developing AChEIs for treatment of Alzheimer disease is considered.Special issue dedicated to Dr. Morris H. Aprison.     

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.     

The multiple forms of brain acetylcholinesterase. II. A suggestion of their functional importance

The pattern of the multiple forms of the acetylocholinesterase (AChE, E.C. 3.1.1.7) of the rat brain is investigated using polyacrylamide gradient micro-gel electrophoresis with regard to a possible functional importance of this individual forms. The patterns of the AChE-forms of selected regions of the CNS are compared and certain differences could be shown. After increased cholinergic input (into the hippocampus by electrical stimulation of the nc. septi medialis) an aggregation of AChE subunits is detectable. Subletal intoxication with an irreversible inhibitor of AChE is followed by a faster recovery of the smaller forms. A suggestion of a possible functional role of the multiple forms of AChE is discussed.     

The preparation and kinetic properties of multiple forms of chicken brain acetylcholinesterase

A method for preparing various forms of acetylcholinesterase (A ChE) from chicken brain has been developed and they have been characterized in terms of kinetic parameters such as K_m, rate constant (k), turnover number (k_p), specificity constant (k_sp), V_max and half-life (t_1/2). The solubility experiments show that, there are two major forms of A ChE i.e. water-soluble and membrane-bound A ChE (MBA ChE). The MBA ChE shows several subforms, and on the basis of percentage activity only three MBA ChE forms have been selected for complete characterization by various kinetic parameters. It was found that these three forms of MBA ChE demonstrate significant differences in their kinetic properties.     

The multiple forms of brain acetycholinesterase. III. Implications for the histochemical demonstration of acetylcholinesterase

The multiple forms of acetylcholinesterase (AChE, E.C. 3.1.1.7) have been investigated with regard to their histochemical demonstrability. Their pattern is influenced by buffer treatment, fixation, and by incubation conditions causing aggregation and disaggregation as well as loss or inactivation of individual forms. The standard histochemical method for AChE preferentially demonstrates the high molecular forms. Most of the oligomer forms are washed out or inactivated. A selective demonstration of the highly aggregated forms is possible either by inhibition of the oligomers with diisopropylfluoridate (DFP) or by specifically dissolving them out. No reason could be found for the selective demonstration of the low molecular weight forms.