Are soluble and membrane-bound rat brain acetylcholinesterase different?

Salt-soluble and detergent-soluble acetylcholinesterases (AChE) from adult rat brain were purified to homogeneity and studied with the aim to establish the differences existing between these two forms. It was found that the enzymatic activities of the purified salt-soluble AChE as well as the detergent-soluble AChE were dependent on the Triton X-100 concentration. Moreover, the interaction of salt-soluble AChE with liposomes suggests amphiphilic behaviour of this enzyme. Serum cholinesterase (ChE) did not bind to liposomes but its activity was also detergent-dependent. Detergent-soluble AChE remained in solution below critical micellar concentrations of Triton X-100. SDS polyacrylamide gel electrophoresis of purified, Biobeads-treated and iodinated detergent-soluble 11 S AChE showed, under non reducing conditions, bands of 69 kD, 130 kD and >250 kD corresponding, respectively, to monomers, dimers and probably tetramers of the same polypeptide chain. Under reducing conditions, only a 69 kD band was detected. It is proposed that an amphiphilic environment stabilizes the salt-soluble forms of AChE in the brain in vivo and that detergent-soluble Biobeads-treated 11 S AchE possess hydrophobic domain(s) different from the 20 kD peptide already described.Abbreviations used AChE acetylcholinesterase - BSA bovine serum albumin - ChE serum (butyryl) cholinesterase - ConA-Sepharose concanavalin A-Sepharose 4B - DMAEBA-Sepharose dimethylaminoethylbenzoic acid-Sepharose 4B - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - TMA tetramethylammonium chloride     

A unique hydrophobic domain of rat brain globular acetylcholinesterase for binding to cell membranes

Both salt-soluble and detergent-soluble rat brain globular acetylcholinesterases (SS- and DS- AChE EC 3.1.1.7) are amphiphiles, as shown by detergent dependency of enzymatic activity and binding to liposomes. Proteinase K and papain treatment transformed SS-AChE and DS-AChE into forms that, in absence of detergent, no longer aggregated nor bound to liposomes. In contrast, phosphatidylinositol-specific phospholipase C had no effect on these properties. Labeling DS-AChE with 3-(trifluoromethyl)-3-(m-(¹²⁵I)-iodophenyl) diazirine ([¹²⁵I]TID) revealed, by polyacrylamide gel electrophoresis under reducing conditions, one single band of 69 kD apparent molecular mass. The same pattern was previously obtained with Bolton and Hunter reagent-labeled enzyme (1). Proteinase K treatment transformed the 11 S [¹²⁵I]TID labeled AChE into a 4 S form which no longer showed¹²⁵I-radioactivity and was unable to bind to liposomes. These results are compatible with the existence of a hydrophobic segment present both on salt-soluble and detergent-soluble 11 S AChE as well as on the minor forms 4 S and 7 S. This segment is not linked to the catalytic subunits by disulfide bounds in contrast to the 20 kD non-catalytic subunit described by Inestrosa et al. (2).Abbreviations used AChE acetylcholinesterase - SS-AChE salt-soluble AChE - DS-AChE detergent-soluble AChE - BSA bovine serum albumin - ChE serum (butyryl) cholinesterase - ConA-Sepharose concanavalin A-Sepharose 4B - DMAEBA-Sepharose dimethylaminoethylbenzoic acid-Sepharose 4B - PC-Chol-SA liposomes phosphatidylcholine-cholesterol-stearylamine liposomes - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - ¹²⁵I-TID 3-(trifluoromethyl)-3-(m-(¹²⁵I)-iodophenyl) diazirine     

Acetylcholinesterase in Mouse Neuroblastoma NB2A Cells: Analysis of Production, Secretion, and Molecular Forms

The mouse neuroblastoma cell line NB2A produces cellular and secreted acetylcholinesterase (AChE). After incubation of the cells for 4 days the ratio between AChE secreted into the medium and AChE in the cells was 1:1. The cell-associated enzyme could be subdivided into soluble AChE (25%) and detergent-soluble AChE (75%). Both extracts contained predominantly monomeric AChE (4.6S) and minor amounts of tetrameric AChE (10.6S), whereas the secreted AChE in the culture supernatant contained only the tetrameric form. All forms were partially purified by affinity chromatography. It could be demonstrated that the secretory and the intracellular soluble tetramers were hydrophilic, whereas the detergent-soluble tetramer was an amphiphilic protein. On the other hand the soluble and the detergent-soluble monomeric forms were amphiphilic and their activity depended on the presence of detergent. By digestion with proteinase K amphiphilic monomeric and tetrameric AChE could be converted to a hydrophilic form that no longer required detergent for catalytic activity. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of [3H]diisopropylfluorophosphate-labelled AChE gave one band at 64 kilodaltons (kD) under reducing conditions and two additional bands at 120 kD and 140 kD under nonreducing conditions.     

Amphiphilic Detergent-Soluble Acetylcholinesterase from Torpedo marmorata: Characterization and Conversion by Proteolysis to a Hydrophilic Form

The membrane-bound acetylcholinesterase (AChE) from the electric organ of Torpedo marmorata was solubilized by Triton X-100 or by treatment with proteinase K and purified to apparent homogeneity by affinity chromatography. Although the two forms differed only slightly in their subunit molecular weight (66,000 and 65,000 daltons, respectively), considerable differences existed between native and digested detergent-soluble AChE. The native enzyme sedimented at 6.5 S in the presence of Triton X-100 and formed aggregates in the absence of detergent. The digested enzyme sedimented at 7.5 S in the absence and in the presence of detergent. In contrast to the detergent-solubilized AChE, the proteolytically derived form neither bound detergent nor required amphiphilic molecules for the expression of catalytic activity. This led to the conclusion that limited digestion of detergent-soluble AChE results in the removal of a small hydrophobic peptide which in vivo is responsible for anchoring the protein to the lipid bilayer.     

Purification of rat adipose tissue lipoprotein lipase by affinity chromatography.

Lipoprotein lipase (EC 3.1.1.3) from rat adipose tissue was purified by affinity chromatography with heparin-Sepharose. Elution was carried out with buffered solutions of increasing NaCl molarity. Proteins without affinity for heparin were eluted with 0.5 M NaCl, while lipoprotein lipase activity was eluted as two peaks with 1.16 M NaCl (In earlier work on human adipose tissue (Etienne et al. (1974) C.R. Acad. Sc. Paris 279, 1487-1490) two fractions with lipoprotein lipase activity were also obtained). Phospholipase activity was detected in the fraction eluted with buffered 0.5 M NaCl and containing proteins without affinity for heparin. On feeding the fasting rats with fresh cream or glucose two peaks were also obtained, but the first peak had clearly increased while the second one had remained virtually unchanged.     

Soluble and membrane-bound acetylcholinesterases in Mytilus galloprovincialis (Pelecypoda: Filibranchia) from the northern Adriatic sea

Three forms of acetylcholinesterase (AChE) were detected in samples of the bivalve mollusc Mytilus galloprovincialis collected in sites of the Adriatic sea. Apart from the origin of the mussels, two spontaneously soluble (SS) AChE occur in the hemolymph and represent about 80% of total activity, perhaps hydrolyzing metabolism-borne choline esters. These hydrophilic enzymes (forms A and B) copurified by affinity chromatography (procainamide-Sepharose gel) and were separated by sucrose gradient centrifugation. They are, respectively, a globular tetramer (11.0-12.0 S) and a dimer (6.0-7.0 S) of catalytic subunits. The third form, also purified from tissue extracts by the same affinity matrix, proved to be an amphiphilic globular dimer (7.0 S) with a phosphatidylinositol tail giving cell membrane insertion, detergent (Triton X-100, Brij 96) interaction and self-aggregation. Such an AChE is likely functional in cholinergic synapses. All three AChE forms show a good substrate specificity and are inactive on butyrylthiocholine. Studies with inhibitors showed low inhibition by eserine and paraoxon, especially on SS forms, high sensitivity to 1,5-bis(4-allyldimethylammoniumphenyl)-pentan-3-one dibromide (BW284c51) and no inhibition with propoxur and diisopropylfluorophosphate (DFP). The ChE forms in M. galloprovincialis are possibly encoded by different genes. Some kinetic features of these enzymes suggest a genetic polymorphism.     

HETEROGENEITY OF ACETYLCHOLINESTERASE IN NEUROBLASTOMA

Abstract– Multiple forms of acetylcholine hydrolyzing activity have been observed in Triton X-100 treated homogenates of mouse neuroblastoma cells. All these forms appear to be the true acetylcholinesterase, AChE (EC 3.1.17): they are substrate-inhibited; hydrolyze acetylcholine > acetyl-β-methylcholine ≫ butrylcholine and are preferentially inhibited by specific AChE inhibitors. Almost all of the cell AChE activity is membrane associated, but readily 'solubilized' by Triton X-100 and as such appears free of membrane contamination. With the aid of affinity chromatography the 'solubilized' neuroblastoma AChE has been partially purified (490-fold) to a specific activity of 34,300 nmol/min/mg protein.
Four active neuroblastoma AChE species appear upon acrylamide gel electrophoresis (with MWs of 64,000; 116,000; 186,000 and 284,000) while three species (4S, 6S and 9.6S) have been found upon sucrose gradient sedimentation analysis. We have determined that the 4S form migrates on acrylamide as the 116,000 MW species and the 9.6S form contains, in equal amounts, the 186,000 and 284,000 MW acrylamide species. Numerous active AChE forms are seen on Sepharose 6B chromatography. From comparing the crude, 4S, 9.6S and partially purified AChEs on acrylamide gels, sucrose gradients and Sepharose, mouse neuroblastoma appears to contain active AChE units which are capable of multiple types of dissociation and reassociation. An attempt is made to correlate all the observed AChE forms as well as relate this data to that known about AChE obtained from other sources.     

Characterization of acetylcholinesterase molecular forms in slow and fast muscle of rat

Multiple molecular forms of acetylcholinesterase (AChE EC 3.1.1.7) from fast and slow muscle of rat were examined by velocity sedimentation. The fast extensor digitorum longus muscle (EDL) hydrolyzed acetylcholine at a rate of 110 mumol/g wet weight/hr and possessed three molecular forms with apparent sedimentation coefficients of 4S, 10S, and 16S which contribute about 50, 35, and 15% of the AChE activity. The slow soleus muscle hydrolyzed acetylcholine at a rate of 55 mumol/g wet weight/hr and has a 4S, 10S, 12S, and 16S form which contribute 22, 18, 34, and 26% of AChE activity, respectively. A single band of AChE activity was observed when a 1M NaCl extract with CsCl (0.38 g/ml) was centrifuged to equilibrium. Peak AChE activity from EDL and SOL extracts were found at 1.29 g/ml. Resedimentation of peak activity from CsCl gradients resulted in all molecular forms previously found in both muscles. Addition of a protease inhibitor phenylmethylsulfonyl chloride did not change the pattern of distribution. The 4S form of both muscles was extracted with low ionic strength buffer while the 10S, 12S, and 16S forms required high ionic strength and detergent for efficient solubilization. All molecular forms of both muscles have an apparent Km of 2 x 10(-4) M, showed substrate inhibition, and were inhibited by BW284C51, a specific inhibitor of AChE. The difference between these muscles in regards to their AChE activity, as well as in the proportional distribution of molecular forms, may be correlated with sites of localization and differences in the contractile activity of these muscles.     

Cyclic nucleotide phosphodiesterase activities from pig coronary arteries. Lack of interconvertibility of major forms

DEAE-cellulose chromatography, with or without dithiothreitol and over a pH range of 6.0 to 8.5, resolved two phosphodiesterase activities (peaks I and II) from the soluble fraction of pig coronary arteries. The activity of peak I was increased by calmodulin (3-7-fold), whereas that of peak II was not. Chromatography of peak I on Biol-Gel A-0.5 m columns resolved two peaks of phosphodiesterase activity (peaks Ia and Ib). Peak Ia was eluted in the presence or absence of 0.1 M KCl and was relatively insensitive to calmodulin. Peak Ib was eluted only in the presence of KCl and was sensitive to calmodulin. The substrate specificity and kinetic behavior were the same for peaks I, Ia, and Ib. Repeated gel chromatography of either peak Ia or Ib, under appropriate conditions, yielded a mixture of peaks Ia and Ib. Peak Ia appears to be a reversible aggregate of peak Ib. Gel chromatography of peak II resolved only one phosphodiesterase activity, which was eluted without KCl, was highly specific for cyclic AMP, was not sensitive to calmodulin and migrated differently on the gel column than either peak Ia or Ib. Sucrose density gradient centrifugation of the soluble fraction from pig coronary arteries in the presence or absence of dithiothreitol resolved two peaks of phosphodiesterase activity (6.6 S and 3.6 S) which were similar to peaks I and II separated by DEAE-cellulose chromatography with regard to their substrate specificity and their sensitivity to calmodulin. Upon recentrifugation, each of the two peaks of phosphodiesterase activity gave a single peak of activity which migrated with the same S value as did its parent. These results indicate that the two major forms of phosphodiesterase of pig coronary arteries, which are representative of those found in many tissues, are not interconvertible in cell-free systems.     

Changes in the Levels and Forms of Cholinesterases in the Blood Plasma of Normal and Dystrophic Chickens

Abstract: Acetylcholinesterase (AChE) and pseudocholinesterase (°ChE) were analysed in the blood plasma of developing chickens, both normal and those with inherited muscular dystrophy. The amounts and the molecular forms of each were examined. °ChE concentration rises in the plasma of normal and dystrophic chicks at the end of embryonic development and is maintained after hatching at a constant, relatively high level, accounting for 90-95% of total cholinesterase activity in normal plasma. This level is maintained in normal and dystrophic chickens. In embryonic plasma of both normal and dystrophic chicks, on the other hand, the levels of AChE are higher than those of °ChE. Immediately after hatching the AChE level decreases rapidly in normal plasma, reaching a very low level by 2-3 weeks ex ovo. The AChE level in plasma from dystrophic birds, although less than normal from day 19 in ovo to 2 weeks ex ovo, subsequently increases to peak around 4 months at levels 15-20-fold of those in normal birds. There is virtually no enzyme of either type in the erythrocytes of normal or dystrophic chickens. The changes of AChE in plasma were correlated with the alterations of AChE in dystrophic fast-twitch muscles, suggesting that the latter pool is a precursor of the plasma AChE. Both the AChE and the °ChE in plasma exist in multiple molecular forms, which are similar to certain of those found previously in the muscles of these birds. The major form (60-80%) of both enzymes in the plasma is the M form (sedimentation coefficient ≥11 S) in all cases, but it is accompanied by certain other forms. In no case is there any of the heaviest form (H₂, 19-20 S) of AChE or of °ChE found in normal and dystrophic muscle, which is attached at the synapses in normal muscle. The pattern of forms of plasma °ChE is constant at all ages, and in normal and dystrophic chickens. The pattern of forms of AChE in the plasma, in contrast, varies with age and with dystrophy in a characteristic manner. The sedimentation coefficients and the amounts of the enzymes in fast-twitch muscle of dystrophic animals are compared with those of the plasma forms, and an interpretation is given of the characteristic patterns of AChE and of χE in their blood.     

Tissue-specific expression of the acetylcholinesterase gene in Drosophila melanogaster embryos

Summary Acetylcholinesterase activity is present in both particulate and soluble forms in wild-type Drosophila melanogaster embryos. The particulate form of the enzyme is localized in the CNS, while the soluble forms are non-CNS-specific. Deletion mapping studies show that all AChE activity is abolished if the cytological region between 87E1-2 and 87E4 is missing. An additional region mapping to the proximal part of the 87E4 band is needed for CNS-specific AChE activityAbbreviations AChE acetylcholinesterase (acetylcholine acetyl hydrolase, EC 3.1.1.7) - ChE pseudocholinesterase (acetylcholine acylhydrolase, EC 3.1.1.8) - BAP 1,5-bis(allyldimethylammoniumphenyl)-pentan-3-one dibromide - i-OMPA tetraisopropylpyrophosphoramide - CNS central nervous system     

Existence of two membrane-bound acetylcholinesterases in the honey bee head

Two acetylcholinesterase (EC 3.1.1.7) membrane forms AChE(m1) and AChE(m2), have been characterised in the honey bee head. They can be differentiated by their ionic properties: AChE(m1) is eluted at 220 mM NaCl whereas AChE(m2) is eluted at 350 mM NaCl in anion exchange chromatography. They also present different thermal stabilities. Previous processing such as sedimentation, phase separation, and extraction procedures do not affect the presence of the two forms. Unlike AChE(m1), AChE(m2) presents reversible chromatographic elution properties, with a shift between 350 to 220 mM NaCl, depending on detergent conditions. Purification by affinity chromatography does not abolish the shift of the AChE(m2) elution. The similar chromatographic behaviour of soluble AChE strongly suggests that the occurrence of the two membrane forms is not due to the membrane anchor. The two forms have similar sensitivities to eserine and BW284C51. They exhibit similar electrophoretic mobilities and present molecular masses of 66 kDa in SDS-PAGE and a sensitivity to phosphatidylinositol-specific phospholipase C in non-denaturing conditions, thus revealing the presence of a glycosyl-phosphatidylinositol anchor. We assume that bee AChE occurs in two distinct conformational states whose AChE(m2) apparent state is reversibly modulated by the Triton X-100 detergent into AChE(m1).     

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.     

Purification and Properties of Prostaglandin H-E Isomerase from the Cytosol of Human Brain: Identification as Anionic Forms of Glutathione S-Transferase

Abstract: Prostaglandin H-E isomerase (EC 5.3.99.3) was purified from human brain cytosol. Purification was by ammonium sulfate fractionation, diethylaminoethyl-Sephar-ose chromatography, gel filtration on a BioGel P-100 column, GSH-agarose chromatography, and MonoQ chromatography. The activity was eluted in two peaks from the MonoQ column, which were designated peaks 1 and 2. The molecular weights of peaks 1 and 2, determined by gel filtration, were 42,000 and 44,000, respectively. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, peak 1 showed two bands at the molecular weights of 24,500 and 25,000, and peak 2 showed a single band at the molecular weight of 25,000, results suggesting that both were dimeric proteins. The pI values of both enzymes were ∼5.4. The enzymes catalyzed selective conversion of prostaglandin H₂ to prostaglandin E₂. The K _m values for prostaglandin H₂ of peaks 1 and 2 were 147 and 308 μ M , respectively, and the V _max values were 380 and 720 nmol/min/mg of protein, respectively. GSH was required for the catalysis of both enzymes, and no other sulfhydryl compounds could support the reaction. A part of glutathione S -transferase (EC 2.5.1.18) was copurified with peaks 1 and 2 of prostaglandin H-E isomerase. Prostaglandin H-E isomerase activity of peak 2 enzyme was competitively inhibited by 1-chloro-2,4-dinitrobenzene, a substrate of glutathione S -transferase. These results suggested that prostaglandin H-E isomerases in human brain cytosol were identical with anionic forms of glutathione S -transferase.     

On the homogeneity of 11-S acetylcholinesterase

11-S acetylcholinesterase (acetylcholine hydrolase, EC 3.1.1.7) purified by affinity chromatography of trypsin-digested homogenates was shown to be contaminated with three other active forms of enzyme. The initial purification used an affinity column of the inhibitor, N-methylacridinium ion. Chromatography of the "affinity-pure" sample on hydroxyapatite resulted in two peaks of acetylcholinesterase activity. One peak contained only a form sedimenting at 11-S (approx. 85% of the recovered activity). The other peak consisted of a 9.5-S form, in addition to 14-S and 18-S forms. The 9.5-S form (approx. 7% of the activity) co-electrophoresed with 11-S in 6% polyacrylamide gels and co-sedimented with the same form in sucrose density gradients containing 0.1 M NaCl. The purified 11-S enzyme was shown to be homogeneous by sucrose density gradient centrifugation and electrophoresis. These results indicate that 11-S acetylcholinesterase may be unsuitable for some characterization studies due to undetected contamination by the 9.5-S form.     

Comparison of the Molecular Forms of the Cholinesterases in Tissues of Normal and Dystrophic Chickens

Abstract: The levels and molecular forms of acetylcholinesterase (AChE, EC 3.1.1.7) and pseudocholinesterase (ΦChE, EC 3.1.1.8) were examined in various skeletal muscles, cardiac muscles, and neural tissues from normal and dystrophic chickens. The relative amount of the heavy (H_c) form of AChE in mixed-fibre-type twitch muscles varies in proportion to the percentage of glycolytic fast-twitch fibres. Conversely, muscles with higher levels of oxidative fibres (i.e., slow-tonic, oxidative-glycolytic fast-twitch, or oxidative slow-twitch) have higher proportions of the light (L) form of AChE. The effects of dystrophy on AChE and ΦChE are more severe in muscles richer in glycolytic fast-twitch fibres (e.g., pectoral or posterior latissimus dorsi, PLD); there is no alteration of AChE or ΦChE in a slow-tonic muscle. In the pectoral or PLD muscles from older dystrophic chickens, however, the AChE forms revert to a normal distribution while the ΦChE pattern remains abnormal. Muscle ΦChE is sensitive to collagenase in a similar way as is AChE, thus apparently having a similar tailed structure. Unlike skeletal muscle, cardiac muscle has very high levels of ΦChE, present mainly as the L form; AChE is present mainly as the medium (M) form, with smaller amounts of L and H_c. The latter pattern of AChE forms resembles that seen in several neural tissues examined. No alterations in AChE or ΦChE were found in cardiac or neural tissues from dystrophic chickens.     

Multiple forms of ACTH biological activity in the pars intermedia of the rat adenohypophysis.

Acid extracts of a) acutely dispersed rat pars intermedia (PI) cells, b) media after incubation of PI cells, c) whole nervosa-intermedia, and d) whole pars distalis, were chromatographed on Sephadex G-50 Fine in 1% acetic acid. Three peaks of ACTH biological activity were resolved in all four extracts. Peak I eluted in the void volume of the column, peak III co-eluted with synthetic ACTH^1–39, and peak II eluted in an intermediate position. The predominant ACTH activity derived from the PI tissue was peak I, amounting to over 70% of the total ACTH activity present in that lobe. The positions of PI peaks I and II remained unaltered after rechromatography as well as after treatment with and chromatography in 8 M urea. However, peak I of PI ACTH was further resolved into two separate peaks by chromatography on Sephadex G-100 SF. Thus pars intermedia ACTH activity appears to be composed of four separate entities, with the predominant forms being larger than ACTH^1–39.     

Age-dependent changes in plasma and brain cholinesterase activities of house wrens and European starlings

We determined age-dependent changes in plasma and brain cholinesterase (ChE) activity for two species of passerines: house wren (Troglodytes aedon) and European starling (Sturnus vulgaris, starling). In plasma from nestlings of both species, total ChE activity increased with age, acetycholinesterase (AChE, EC 3.1.1.7) activity declined rapidly immediately after hatching, and butyrylcholinesterase (BChE, EC 3.1.1.8) activity increased steadily. For both species, total ChE and BChE activities and the BChE:AChE ratio in plasma were significantly greater in adults than nestlings suggesting trends observed in nestlings continue post fledging. In older nestlings and adults, AChE activity in plasma was significantly greater and BChE:AChE ratio less in house wrens than starlings. For house wrens as compared with starlings, ChE activity in brain increased at a significantly greater rate with age in nestlings and was significantly greater in adults. However, ChE activity in brain was similar at fledging for both species suggesting that the increase in ChE in brain is more directly related to ontogeny than chronologic age in nestlings of passerines. For both species, ChE activity increased significantly with brain weight of nestlings but not adults. House wrens hold similar patterns of age-dependent change in ChE activity in common with starlings but also exhibit differences in AChE activity in plasma that should be considered as a factor potentially affecting their relative toxicologic response to ChE inhibitors.     

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.     

SUBCELLULAR ANALYSIS OF THE MOLECULAR FORMS OF ACETYLCHOLINESTERASE IN RAT SKELETAL MUSCLE

Acetylcholinesterase (AChE, EC 3.1.1.7) activity of rat gastrocnemius muscle homogenized in 1 M-NaCl and 0.5% Triton X-100 was separated by velocity sedimentation in sucrose gradients into three molecular forms with sedimentation coefficients of about 4S, 10S and 16S. The distribution of homogenate AChE activity among the three peaks was 53, 34 and 13% respectively. The different molecular forms were found to be heterogeneously distributed in subcellular fractions prepared from sucrose homogenates of muscle, as follows: Subfractions of the crude sarcolemmal fraction were prepared by discontinuous sucrose gradient centrifugation. AChE was recovered in the greatest yield and with the highest specific activity in a light density subfraction (0.6/0.8 M-sucrose interface). The AChE activity in this light density subfraction was mainly (81-88%) the 10S form of the enzyme. The velocity sedimentation profiles of the AChE activity in the more dense subfractions were markedly different in that 16S AChE was a major component.