Amphiphilic and hydrophilic molecular forms of acetylcholinesterase in membranes derived from sarcoplasmic reticulum of skeletal muscle

Native molecular forms of acetylcholinesterase (AChE) present in a microsomal fraction enriched in SR of rabbit skeletal muscle were characterized by sedimentation analysis in sucrose gradients and by digestion with phospholipases and proteinases. The hydrophobic properties of AChE forms were studied by phase-partition of Triton X-114 and Triton X-100-solubilized enzyme and by comparing their migration in sucrose gradient containing either Triton X-100 or Brij 96. We found that in the microsomal preparation two hydrophilic 13.5 S and 10.5 S forms and an amphiphilic 4.5 S form exist. The 13.5 S is an asymmetric molecule which by incubation with collagenase and trypsin is converted into a 'lytic' 10.5 S form. The hydrophobic 4.5 S form is the predominant one in extracts prepared with Triton X-100. Proteolytic digestion of the membranes with trypsin brought into solution a significant portion of the total activity. Incubation of the membranes with phospholipase C failed to solubilize the enzyme. The sedimentation coefficient of the amphiphilic 4.5 S form remained unchanged after partial reduction, thus confirming its monomeric structure. Conversion of the monomeric amphiphilic form into a monomeric hydrophilic molecule was performed by incubating the 4.5 S AChE with trypsin. This conversion was not produced by phospholipase treatment.     

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     

Molecular properties of acetylcholinesterase in mouse spleen

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

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.     

Glycosyl-phosphatidylinositol anchored acetylcholinesterase as substrate for phosphatidylinositol-specific phospholipase C from Bacillus cereus.

We investigated the enzymatic properties of phosphatidylinositol-specific phospholipase C (PI-PLC) from Bacillus cereus towards glycosyl-phosphatidylinositol anchored acetylcholinesterase (AChE) from bovine erythrocytes and Torpedo electric organ as substrate. The conversion of membrane from AChE to soluble AChE by PI-PLC depended on the presence of a detergent and of phosphatidylcholine. In presence of mixed micelles containing Triton X-100 (0.05%) and phosphatidylcholine (0.5 mg/ml) the rate of AChE conversion was about 3 times higher than in presence of Triton X-100 alone. Furthermore, inhibition of PI-PLC occurring at Triton X-100 concentrations higher than 0.01% could be prevented by addition of phosphatidylcholine. Ca2+, Mg2+ and sodium chloride had no effect on PI-PLC activity in presence of phosphatidylcholine and Triton X-100, whereas in presence of Triton X-100 alone sodium chloride largely increased the rate of AChE conversion. Determination of kinetic parameters with three different substrates gave Km-values of 7 microM, 17 microM and 2 mM and Vmax-values of 0.095 microM.min-1, 0.325 microM.min-1 and 56 microM.min-1 for Torpedo AChE, bovine erythrocyte AChE and phosphatidylinositol, respectively. The low Km-values for both forms of AChE indicated that PI-PLC not only recognized the phosphatidylinositol moiety of the anchor but also other components thereof.     

Amphiphilic forms of butyrylcholinesterase in mucosal cells of rat intestine.

The properties of a cholinesterase from mucosal cells of rat intestine have been characterized. The enzyme was identified as butyrylcholinesterase because it was more sensitive to iso-OMPA (IC50 = 1.0 x 10(-6) M) than to BW284C51 (IC50 = 5.5 x 10(-5) M) and was not inhibited by substrate excess. It displayed a higher affinity for acetylthiocholine than for butyrylthiocholine. A major molecular form was observed sedimenting at 5.9 S. Two other minor molecular forms were identified as a hydrophilic tetramer (G4, sedimenting at 10.5 S) and a monomer (G1, sedimenting at 4.3 S). The 5.9 S component was referred to as "G" form (G for globular) and not "G2" as usual dimers for the following reasons: (i) the G form was unaffected by the reducing agents, beta-mercaptoethanol and dithiothreitol, which converted disulfide-linked dimers of acetylcholinesterase into monomers, (ii) the G form was shifted from 5.9 to 3.4 S when the sucrose gradient contained Triton X-100. This value of 3.4 S (in Triton X-100) appeared too low for a typical G2 form. The shift in the S value was partly reversible: the 3.4 S form resedimented at 5.2 S in the absence of detergent. The behavior of the G form in sucrose gradients indicated that it was amphiphilic. This was confirmed in nondenaturing electrophoreses and also by quantitative binding of the G form to octyl-Sepharose. The hydrophobic domain of the G form was not a glycolipid, as shown by its insensitivity to Bacillus thuringiensis phosphatidylinositol-specific phospholipase C and its nonaggregating properties in the absence of nondenaturing detergent.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and properties of hydrophilic dimers of acetylcholinesterase from mouse erythrocytes

Differences in the glycosylation of acetylcholinesterase (AChE) subunits which form the dimers of mouse erythrocyte and a suitable procedure to purify the enzyme by affinity chromatography in edrophonium-Sepharose are described. AChE was extracted ( approximately 80%) from erythrocytes with Triton X-100 and sedimentation analyses showed the existence of amphiphilic AChE dimers in the extract. The AChE dimers were converted into monomers by reducing the disulfide bond which links the enzyme subunits. Lectin interaction studies revealed that most of the dimers were bound by concanavalin A (Con A) (90-95%), Lens culinaris agglutinin (LCA) (90-95%), and wheat germ (Triticum vulgaris) agglutinin (WGA) (70-75%), and a small fraction by Ricinus communis agglutinin (RCA(120)) (25-30%). The lower level of binding of the AChE monomers with WGA (55-60%), and especially with RCA (10-15%), with respect to the dimers, reflected heterogeneity in the sugar composition of the glycans linked to each AChE subunit in dimers. Forty per cent of the amphiphilic AChE dimers lost the glycosylphosphatidylinositol (GPI) and, therefore, were converted into hydrophilic forms, by incubation with phosphatidylinositol-specific phospholipase C (PIPLC), which permitted their separation from the amphiphilic variants in octyl-Sepharose. Only the hydrophilic dimers, either isolated or mixed with the amphiphilic forms, were bound by edrophonium-Sepharose, which allowed their purification (4800-fold) with a specific activity of 7700 U/mg protein. The identification of a single protein band of 66 kDa in gel electrophoresis demonstrates that the procedure can be used for the purification of GPI-anchored AChE, providing that the attached glycolipid domain is susceptible to PIPLC.     

Amphiphilic and Nonamphiphilic Forms of Torpedo Cholinesterases: I. Solubility and Aggregation Properties

We report an analysis of the solubility and hydrophobic properties of the globular forms of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) from various Torpedo tissues. We distinguish globular nonamphiphilic forms (Gna) from globular amphiphilic forms (Ga). The Ga forms bind micelles of detergent, as indicated by the following properties. They are converted by mild proteolysis into nonamphiphilic derivatives. Their Stokes radius in the presence of Triton X-100 is approximately 2 nm greater than that of their lytic derivatives. The G2a forms fall in two classes. Class I contains molecules that aggregate in the absence of detergent, when mixed with an AChE-depleted Triton X-100 extract from electric organ. AChE G2a forms from electric organs, nerves, skeletal muscle, and erythrocyte membranes correspond to this type, which is also detectable in detergent-soluble (DS) extracts of electric lobes and spinal cord. Class II forms never aggregate but only present a slight shift in sedimentation coefficient, in the presence or absence of detergent. This class contains the AChE G2a forms of plasma and of the low-salt-soluble (LSS) fractions from spinal cord and electric lobes. The heart possesses a BuChE G2a form of class II in LSS extracts, as well as a similar G1a form. G4a forms of AChE, which are solubilized only in the presence of detergent and aggregate in the absence of detergent, represent a large proportion of cholinesterase in DS extracts of nerves and spinal cord, together with a smaller component of G4a BuChE. These forms may be converted to nonamphiphilic derivatives by Pronase. Nonaggregating G4a forms exist at low levels in the plasma (BuChE) and in LSS extracts of nerves (BuChE) and spinal cord (AChE).     

Acetylcholinesterase is orientated facing the cytoplasmic side in membranes derived from sarcoplasmic reticulum

(1) Microsomal membranes from white rabbit muscle enriched in sarcoplasmic reticulum (SR) were used to investigate the preferential localization of acetylcholinesterase (AChE) in these membranes. (2) Integrity and orientation of the vesicles was assessed by measuring the inulin-inaccessible space of the vesicles and its calcium-loading capacity. (3) Treatment of the membranes with diisopropyl phosphorofluoridate (DFP), an irreversible inhibitor which is free soluble in lipid, produced an almost complete inactivation of AChE. The inhibition was prevented in assays performed with the non-permeant reversible inhibitor BW 284c51 (BW). (4) Similar results were obtained if echothiophate iodide (ECHO), an irreversible and poorly permeant inhibitor, instead of DFP was used. (5) Sedimentation profiles of enzyme solubilized with Triton X-100 from membranes inhibited by DFP after protection with BW showed a minor reduction in the relative proportion of a 4.5 S (G1) form. (6) Treatment of intact or saponin-permeabilized membranes with concanavalin A (ConA) produced enzyme-lectin complexes. In both cases, most of the enzyme was recovered in the sedimented complexes after centrifugation of the Triton-solubilized membranes. (7) Incubation of intact membranes with the antibody AE1 led to the formation of immuno complexes. Sedimentation analyses of the molecular forms of AChE revealed a shift in the sedimentation coefficients, whether the antibody was added before or after solubilization of the enzyme. (8) These results firmly establish an external localization of AChE in SR, most of the protein backbone facing the cytoplasmic side of the membrane.     

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

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

Differential effects of ethanol on membrane-bound and soluble acetylcholinesterase from sarcoplasmic reticulum membranes

The action of ethanol on the activity of membrane-bound and soluble acetylcholinesterase (AChE) in sarcoplasmic reticulum of skeletal muscle has been studied. Treatment of membranes with 2.5–12.5% v/v ethanol produced a slight stimulation of the AChE activity and inhibition at higher concentration. The enzyme remained associated with the membranes after these treatments. The enzyme solubilized with Triton X-100 was inhibited by ethanol in a time-independent manner. Isolated 16 S (A₁₂), 10.5 S (G₄) and 4.5 S (G₁) forms of AChE were inhibited by ethanol to a similar extent. Samples were reversibly inhibited by ethanol, up to 12.5% v/v, and irreversibly at higher concentrations. Kinetic studies performed with isolated forms in the presence of 5–12.5% v/v ethanol showed that the solvent behaved as a competitive inhibitor of the asymmetric form but as a mixed inhibitor of the tetrameric and monomeric forms. The results show that the solvent interacts with active and/or regulatory sites of AChE from muscle microsomes.     

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. The results suggest that the monomeric form of AChE (4.8S), the most abundant species in muscle microsomes, has a Stokes radius of 3.3 nm and a molecular weight in the range of 70,000.     

Proteolytic stimulation and solubilization of membrane-bound acetylcholinesterase from muscle sarcotubular system

Incubation of membranes derived from sarcotubular system of rabbit skeletal muscle with increasing concentrations of Triton X-100 produced both stimulation of the AChE activity and solubilization of this enzyme. Mild proteolytic treatment of microsomal membranes produced a several fold activation of the still membrane-bound acetylcholinesterase (AChE) activity. Attempts were made to solubilize AChE from microsomal membranes by proteolytic treatment. About 30–40% of the total enzyme activity could be solubilized by means of trypsin or papain. Short trypsin treatment of the microsomal membranes produced first an activation of the membrane-bound enzyme followed by solubilization. Incubation of muscle microsomes for a short time with papain yielded a significant portion of soluble enzyme. Membrane-bound enzyme activation was measured after a prolonged incubation period. These results are compared with those of solubilization obtained by treatment of membranes with progressive concentrations of Triton X-100. The occurrence of molecular forms in protease-solubilized AChE was investigated by means of centrifugation analysis and slab gel electrophoresis. Centrifugation on sucrose gradients revealed two main components of 4.4S and 10–11S in either trypsin or papain-solubilized AChE. These components behaved as hydrophilic species whereas the Triton solubilized AChE showed an amphipatic character. Application of slab gel electrophoresis showed the occurrence of forms with molecular weights of 350,000; 175,000; 165,000; 85,000 and 76,000. The stimulation of membrane-bound AChE by detergents or proteases would indicate that most of the enzyme molecules or their active sites are sequestered into the lipid bilayer through lipid-protein or protein-protein interactions and these are broken by proteolytic digestion of the muscle microsomes.     

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.     

Amphiphilic and Nonamphiphilic Forms of Torpedo Cholinesterases: II. Electrophoretic Variants and Phosphatidylinositol Phospholipase C-Sensitive and -Insensitive Forms

We report an electrophoretic analysis of the hydrophobic properties of the globular forms of acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) from various Torpedo tissues. In charge-shift electrophoresis, the rate of electrophoretic migration of globular amphiphilic forms (Ga) is increased at least twofold when the anionic detergent deoxycholate is added to Triton X-100, whereas that of globular nonamphiphilic forms (Gna) is not modified. The G2a forms of the first class, as defined by their aggregation properties, are converted to nonamphiphilic derivatives by phosphatidylinositol phospholipase C (PI-PLC) and human serum phospholipase D (PLD). AChE G2a forms from electric organs, nerves, skeletal muscle, and erythrocyte membranes correspond to this type, which also exists in very small quantities in detergent-solubilized extracts of electric lobes and spinal cord. They present different electrophoretic mobilities, so that each of these tissues contains a distinct "electromorph," or two in the case of electric organs. The G2a forms of the second class (AChE in plasma, BuChE in heart), as well as G4a forms of AChE and BuChE, are insensitive to PI-PLC and PLD but may be converted to nonamphiphilic derivatives by Pronase.     

Acetylcholinesterases of the nematode Steinernema carpocapsae. Characterization of two types of amphiphilic forms differing in their mode of membrane association.

We analyzed the molecular forms of acetylcholinesterase (AChE) in the nematode Steinernema carpocapsae. Two major AChEs are involved in acetylcholine hydrolysis. The first class of AChE is highly sensitive to eserine (IC50 = 0.05 microM). The corresponding molecular forms are: an amphiphilic 14S form converted into a hydrophilic 14.5S form by mild proteolysis and two hydrophilic 12S and 7S forms. Reduction of the amphiphilic 14S form with 10 mM dithiothreitol produces hydrophilic 7S and 4S forms, indicating that it is an oligomer of hydrophilic catalytic subunits linked by disulfide bond(s) to a hydrophobic structural element that confers the amphiphilicity to the complex. Sedimentation coefficients suggest that 4S, 7S, 12S forms correspond to hydrophilic monomer, dimer, tetramer and that the 14S form is also a tetramer linked to one structural element. The second class of AChE is less sensitive to eserine (IC50 = 0.1 mM). Corresponding molecular forms are hydrophilic and amphiphilic 4S forms (monomers) and a major amphiphilic 7S form converted into a hydrophilic dimer by Bacillus thuringiensis phosphatidylinositol-specific phospholipase C. This amphiphilic 7S form thus possesses a glycolipid anchor. It appears that Steinernema (a very primitive invertebrate) presents AChEs with two types of membrane association that closely resemble those described for amphiphilic G2 and G4 forms of AChE in more evolved animals.     

Absence of substrate inhibition and freezing-inactivation of the mosquito acetylcholinesterase are caused by alterations of hydrophobic interactions

Membrane-bound acetylcholinesterase (AChE) from mosquito showed the characteristic substrate inhibition of this enzyme, but 105,000 x g supernatants of freshly extracted enzyme did not. Addition of chaotropic anions, a freeze-thaw cycle and autolysis of the amphiphilic acetylcholinesterase to its non-amphiphilic derivatives resulted in return of the substrate inhibition feature along with an apparent increment in the enzyme activity. These results suggested that the lipidic environment of the mosquito AChE is temporarily perturbed when extracted. The enzyme is probably trapped in non-sedimenting mixtures composed of endogenous amphiphilic molecules. The occurrence of this phenomenon was not affected by the presence of Triton X-100 and other detergents, either alone or in combination with sodium chloride. Freezing in the presence of strong chaotropic anions (perchlorate, iodide and thiocyanate) caused the irreversible inactivation of the mosquito AChE. Crude and incomplete purified fractions of the enzyme were more sensitive than a more purified preparation. With both the purified AChE and the non-purified AChE, amphiphilic AChE was more freeze labile. Freezing at -10 degrees C enhanced inactivation of non-purified fractions. At this temperature, even weak chaotropic anions (fluoride, chloride and nitrate), while in combination with non-ionic detergents that solubilized mosquito AChE efficiently, reduced the enzyme activity of these fractions. In this case, recovery of the enzyme activity by incubation at 25 degrees C was inversely correlated with the effectiveness of the chaotropic anion. Gel filtration failed to show any change in the hydrodynamic radius of the freezing-inactivated AChE. Therefore, this phenomenon is explained as different degrees of denaturation of the enzyme in direct association with the chaotropic strength. Thus, antichaotropic anions, such as sulfate, should improve the stability of the mosquito acetylcholinesterase during extraction, purification and storage.     

Acetylcholinesterase from the invertebrate Ciona intestinalis is capable of assembling into asymmetric forms when co-expressed with vertebrate collagenic tail peptide

To learn more about the evolution of the cholinesterases (ChEs), acetylcholinesterase (AChE) and butyrylcholinesterase in the vertebrates, we investigated the AChE activity of a deuterostome invertebrate, the urochordate Ciona intestinalis, by expressing in vitro a synthetic recombinant cDNA for the enzyme in COS-7 cells. Evidence from kinetics, pharmacology, molecular biology, and molecular modeling confirms that the enzyme is AChE. Sequence analysis and molecular modeling also indicate that the cDNA codes for the AChE(T) subunit, which should be able to produce all three globular forms of AChE: monomers (G(1)), dimers (G(2)), and tetramers (G(4)), and assemble into asymmetric forms in association with the collagenic subunit collagen Q. Using velocity sedimentation on sucrose gradients, we found that all three of the globular forms are either expressed in cells or secreted into the medium. In cell extracts, amphiphilic monomers (G(1)(a)) and non-amphiphilic tetramers (G(4)(na)) are found. Amphiphilic dimers (G(2)(a)) and non-amphiphilic tetramers (G(4)(na)) are secreted into the medium. Co-expression of the catalytic subunit with Rattus norvegicus collagen Q produces the asymmetric A(12) form of the enzyme. Collagenase digestion of the A(12) AChE produces a lytic G(4) form. Notably, only globular forms are present in vivo. This is the first demonstration that an invertebrate AChE is capable of assembling into asymmetric forms. We also performed a phylogenetic analysis of the sequence. We discuss the relevance of our results with respect to the evolution of the ChEs in general, in deuterostome invertebrates, and in chordates including vertebrates.     

Developmental changes and acetylcholinesterase activity in the metamorphosing brain of Tenebrio molitor: Correlation to ecdysteroid titers

The brain of Tenebrio molitor exhibited marked fluctuations in acetylcholinesterase (AChE) activity throughout metamorphosis. This was true AChE activity, since it was inhibited by high substrate concentrations and by 10 μM of the specific AChE inhibitor BW284C51 [(1,5-bis'4-allyldimethylammoniumphenyl)-pentan-3-one dibromide] but not by iso-OMPA (tetraisopropylpyrophosphoramide), a cholinesterase (but not AChE) inhibitor. The histochemical AChE activity was localized in the neuropile and the nuclear envelope of neurons and glial cells. The enzyme extracted from brains with 1% Triton X-100 and 1 M NaCl sedimented as a single peak in a sucrose density gradient, with a sedimentation coefficient of 5.4S. This single AChE sedimentation peak was mainly due to an amphiphilic dimeric form. AChE activity per brain increased in newly ecdysed pupa. AChE activity per milligram of protein exhibited a peak in the mid-pupa which could be correlated to the increase in ecdysteroid titers. © 1994 Wiley-Liss, Inc.     

Multiple molecular forms of purified human erythrocyte acetylcholinesterase.

1. Human erythrocyte acetylcholinesterase was solubilized by Triton X-100 and purified by affinity chromatography to a specific activity of 3800 IU/mg of protein. The yield of the purified enzyme was 25--45%. 2. Gel filtration on Sepharose 4-B in the presence of Triton X-100 revealed one peak of enzyme activity with a Stokes' radius of 8.7 nm. Density gradient centrifugation in 0.1% Triton X-100 showed one peak of enzyme activity with an S4 value of 6.3S. 3. Isoelectric focusing in Triton X-100 resolved the enzyme into five molecular forms with isoelectric points of 4.55, 4.68, 4.81, 4.98 and 5.18. Upon incubation with neuraminidase the enzyme activity in the first four forms was decreased with a concommitant increase in activity in the form with the higher isoelectric point. 4. After removal of excess Triton X-100 on Bio-Gel HTP, polyacrylamide gel electrophoresis showed seven bands of protein and corresponding bands of enzyme activity. Density gradient centrifugation of the detergent-depleted enzyme at high ionic strength revealed five multiple molecular forms with S4 values of 6.3 S, 10.2 S, 12.2 S, 14.2 S and 16.3 S. At low ionic strength, higher aggregates were observed in addition to the other forms. Dodecylsulfate-polyacrylamide gel electrophoresis gave one subunit only with an apparent molecular weight of 80 000. 5. These results suggest that human erythrocyte acetylcholinesterase, solubilized by Triton X-100, exists in various forms differing in net charge but of apparently similar molecular dimensions. After removal of the detergent, forms with different molecular sizes are observed.