Solubilization of 20S acetylcholinesterase from chick retina

A 20S form of acetylcholinesterase has been solubilized from young chick retinas by means of a buffered salt-detergent solution containing EDTA. The release of this fast-sedimenting form of the enzyme is selectively blocked by the presence of even small amounts of Ca⁺⁺ in the homogenization medium. The collagen-tailed nature of this molecular species of acetylcholinesterase has been ascertained by collagenase digestion. This finding suggests that the avian central nervous system contains asymmetric, collagen-tailed quaternary structural forms of acetylcholinesterase as is the case in skeletal muscle and cholinergic ganglia.     

Two classes of collagen-tailed,asymmetric molecular forms of acetylcholinesterase in skeletal muscle: differential effects of denervation

Skeletal muscles of different vertebrate species contain, as it is the case in other cholinergic tissues, two classes of collagen-tailed, asymmetric forms (A-forms) of acetylcholinesterase (AChE). Class I A-forms are readily brought into solution in the presence of high salt, while class II A-forms do additionally require a chelating agent, such as EDTA, for solubilization. All A-forms aggregate at low ionic strength but only class II A-forms are reaggregated by excess Ca⁺⁺, even in the presence of 1M NaCl. This Ca⁺⁺-mediated aggregability of class II A-forms is slowly lost upon exposure to detergents such as Triton X-100.Although these two classes of AChE tailed forms seem to be present in endplate and non-endplate areas, and in both the extra- and intracellular compartments, class II A-forms are predominantly extracellular and endplate-specific, at least in the rat diaphragm. On the other hand, well-characterized fast- and slow-twitch muscles show no preference for either class of asymmetric AChE species. Upon denervation, class I A-forms are degraded faster and disappear earlier than their class II counterparts, which are still easily detectable 17 days after nerve section.Class I and class II AChE molecular species exist in similar relative proportions in many vertebrate muscles. Thus, collagen-tailed forms may be altogether more abundant, in skeletal muscle, than it was hitherto realized.It is expected that this further example of AChE polymorphism will contribute to a better understanding of cholinergic transmission in skeletal muscle and, more specially, of nerve-muscle interactions.     

Collagen-tailed and globular forms of acetylcholinesterase in the developing chick visual system

We have carried out a comparative study of the developmental profiles of the enzyme acetylcholinesterase, and of its collagen-tailed and globular structural forms, solubilized in the presence of 1 M NaCl, 1% (w/v) sodium cholate and 2 mM EDTA, in the chick retina and optic lobes. The overall acetylcholinesterase activities, both per mg protein and per embryo or chick, are substantially higher in tectum than in retina, from embryonic day 16. The A₁₂ collagen-tailed form of the enzyme is present in similar amounts in the embryonic retina and optic tectum; however, while the A₁₂ activity increases significantly in retina after birth, both by percentage and in absolute terms, the tectal tailed enzyme follows a declining developmental profile, reaching a minimum after 6 months of life. On the other hand, the globular G₄ species shows developmental profiles, both in retina and tectum, rather similar to those obtained for the overall enzyme activity, while the G₂ and G₁ forms are present in comparable concentrations in both tissues. Besides, G₄ is the predominant globular form in the chick optic lobe after hatching, G₂ and G₁ being enriched in the embryonic tectum. In the case of retina, however, all the globular forms contribute more evenly to the total acetylcholinesterase activity, along the developmental period considered.The potential significance of some of the postnatal developmental profiles is discussed in terms of the progressive adjustment of retina and tectum to the requirements of visual function.     

Molecular forms of acetylcholinesterase in developing Torpedo embryos

We have studied the evolution of acetylcholinesterase molecular forms during the embryonic development of Torpedo marmorata, in the electric organs and in the electric lobes of the central nervous system. In the early stages of development (35 mm embryos, ‘myogenic phase’ of electric organ development), globular forms of acetylcholinesterase (G₄ and G₂) are abundant in both tissues and the collagen-tailed form A₁₂ is already present. In the electric organs, this form accumulates rapidly after the 55–60 mm stage (‘electrogenic phase’), when synapse formation first commences. Although the molecular characteristics of the collagen-tailed forms, and particularly their aggregation properties, do not appear to change during development, their solubilization requires higher concentrations of MgCl₂, as the electrocytes mature, suggesting that they become more tightly integrated in a better organized basal lamina. The smaller collagen-tailed form A₈ shows a transient increase which coincides approximately with the maximal accumulation of A₁₂, suggesting that it is an intermediate in its synthesis. The accumulation of the hydrophobic G₂, which eventually becomes predominent in the adult electric organs, lags behind that of A₁₂. The functional significance of this important fraction of acetylcholinesterase is therefore not that of a pool of precursor for the synthesis of A₁₂. In the electric lobes, the tetrameric form (G₄) is abundant during development, as well as G₂ and G₁ at certain stages, but the A₁₂ form is predominant in the adult.     

Limiting Role of Protein Disulfide Isomerase in the Expression of Collagen-tailed Acetylcholinesterase Forms in Muscle

The expression of acetylcholinesterase (AChE) in skeletal muscle is regulated by muscle activity; however, the underlying molecular mechanisms are incompletely understood. We show here that the expression of the synaptic collagen-tailed AChE form (ColQ-AChE) in quail muscle cultures can be regulated by muscle activity post-translationally. Inhibition of thiol oxidoreductase activity decreases expression of all active AChE forms. Likewise, primary quail myotubes transfected with protein disulfide isomerase (PDI) short hairpin RNAs showed a significant decrease of both the intracellular pool of all collagen-tailed AChE forms and cell surface AChE clusters. Conversely, overexpression of PDI, endoplasmic reticulum protein 72, or calnexin in muscle cells enhanced expression of all collagen-tailed AChE forms. Overexpression of PDI had the most dramatic effect with a 100% increase in the intracellular ColQ-AChE pool and cell surface enzyme activity. Moreover, the levels of PDI are regulated by muscle activity and correlate with the levels of ColQ-AChE and AChE tetramers. Finally, we demonstrate that PDI interacts directly with AChE intracellularly. These results show that collagen-tailed AChE form levels induced by muscle activity can be regulated by molecular chaperones and suggest that newly synthesized exportable proteins may compete for chaperone assistance during the folding process.     

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.     

Transplantation of Quail Collagen-tailed Acetylcholinesterase Molecules Onto the Frog Neuromuscular Synapse

The highly organized pattern of acetylcholinesterase (AChE) molecules attached to the basal lamina of the neuromuscular junction (NMJ) suggests the existence of specific binding sites for their precise localization. To test this hypothesis we immunoaffinity purified quail globular and collagen-tailed AChE forms and determined their ability to attach to frog NMJs which had been pretreated with high-salt detergent buffers. The NMJs were visualized by labeling acetylcholine receptors (AChRs) with TRITC-α-bungarotoxin and AChE by indirect immunofluorescence; there was excellent correspondence (>97%) between the distribution of frog AChRs and AChE. Binding of the exogenous quail AChE was determined using a speciesspecific monoclonal antibody. When frog neuromuscular junctions were incubated with the globular G₄/G₂ quail AChE forms, there was no detectable binding above background levels, whereas when similar preparations were incubated with the collagen-tailed A₁₂ AChE form >80% of the frog synaptic sites were also immunolabeled for quail AChE attached. Binding of the A₁₂ quail AChE was blocked by heparin, yet could not be removed with high salt buffer containing detergent once attached. Similar results were obtained using empty myofiber basal lamina sheaths produced by mechanical or freeze-thaw damage. These experiments show that specific binding sites exist for collagen-tailed AChE molecules on the synaptic basal lamina of the vertebrate NMJ and suggest that these binding sites comprise a “molecular parking lot” in which the AChE molecules can be released, retained, and turned over.     

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.     

Isolation and characterization of acetylcholinesterase from Drosophila

The purification and characterization of acetylcholinesterase from heads of the fruit fly Drosophila are described. Sequential extraction procedures indicated that approximately 40% of the activity was soluble and 60% membrane-bound and that virtually none (less than 4%) corresponded to collagen-tailed forms. The membrane-bound enzyme was extracted with Triton X-100 and purified over 4000-fold by affinity chromatography on acridinium resin. Hydrodynamic analysis by both sucrose gradient centrifugation and chromatography on Sepharose CL-4B revealed an Mr of 165,000 similar to that observed for dimeric (G2) forms of the enzyme in mammalian tissues. In contrast, the purified enzyme gave predominant bands of about 100 kDa prior to disulfied reduction and 55 kDa after reduction on polyacrylamide gel electrophoresis in sodium dodecyl sulfate, values that are significantly lower than those reported for purified G2 enzymes from other species. However, the presence of a faint band at 70 kDa which could be labeled by [3H]diisopropyl fluorophosphate prior to denaturation suggested that the 55-kDa band as well as a 16-kDa species arose from proteolysis. This was confirmed by reductive radiomethylation and amine analysis of the 70-, 55-, and 16-kDa bands. All three contained ethanolamine and glucosamine residues that are characteristic of a C-terminal glycolipid anchor in other G2 acetylcholinesterases. The catalytic properties of the enzyme were examined by titration with a fluorogenic reagent which revealed a turnover number for acetylthiocholine that was 6-fold lower than eel and 3-fold lower than human erythrocyte acetylcholinesterase. Furthermore, the Drosophila enzyme hydrolyzed butyrylthiocholine much more efficiently than these eel or human enzymes, an indication that the fly head enzyme has a substrate specificity intermediate between mammalian acetylcholinesterases and butyrylcholinesterases.     

Mutation in the human acetylcholinesterase-associated collagen gene,COLQ, is responsible for congenital myasthenic syndrome with end-plate acetylcholinesterase deficiency (Type Ic).

Congenital myasthenic syndrome (CMS) with end-plate acetylcholinesterase (AChE) deficiency is a rare autosomal recessive disease, recently classified as CMS type Ic (CMS-Ic). It is characterized by onset in childhood, generalized weakness increased by exertion, refractoriness to anticholinesterase drugs, and morphological abnormalities of the neuromuscular junctions (NMJs). The collagen-tailed form of AChE, which is normally concentrated at NMJs, is composed of catalytic tetramers associated with a specific collagen, COLQ. In CMS-Ic patients, these collagen-tailed forms are often absent. We studied a large family comprising 11 siblings, 6 of whom are affected by a mild form of CMS-Ic. The muscles of the patients contained collagen-tailed AChE. We first excluded the ACHE gene (7q22) as potential culprit, by linkage analysis; then we mapped COLQ to chromosome 3p24.2. By analyzing 3p24.2 markers located close to the gene, we found that the six affected patients were homozygous for an interval of 14 cM between D3S1597 and D3S2338. We determined the COLQ coding sequence and found that the patients present a homozygous missense mutation, Y431S, in the conserved C-terminal domain of COLQ. This mutation is thought to disturb the attachment of collagen-tailed AChE to the NMJ, thus constituting the first genetic defect causing CMS-Ic.     

Active-site determinations on forms of mammalian brain and eel acetylcholinesterase.

Three forms of brain acetylcholinesterase were purified from bovine caudate-nucleus tissue and determined by calibrated gel filtration to have mol.wts. of approx. 120 000 (C), 230 000 (B) and 330 000 (A). [3H]Di-isopropyl phosphorofluoridate (isopropyl moiety labelled) was purified from commercial preparations and its concentration estimated by an enzyme-titration procedure. Brain acetylcholinesterase preparations and enzyme from eel electric tissue were allowed to react with [3H]di-isopropyl phosphorofluridate in phosphate buffer until enzyme activity was inhibited by 98%. Excess of [3H]di-isopropyl phosphorofluoridate that had not reacted was separated from the labelled enzyme protein by gel filtration, or by vacuum filtration or by extensive dialysis. The specificity of active-site labelling was confirmed by use of the enzyme reactivator, pyridine 2-aldoxime. The forms of brain acetylcholinesterase were calculted to contain approximately two (C) four (B) and six (A) active sites per molecule respectively. Acetylcholinesterase (mol.wt. 250 000) from electric-eel tissue was estimated to contain two active sites per molecule. Gradient-gel electrophoresis was used to confirm the estimation of molecular weights of brain acetylcholinesterase forms made by gel filtration. Under the conditions of electrophoresis acetylcholinesterase form A was stable, but form B was converted into a species of approx. 120 000 mol. wt. Similarly, form C of the brain enzyme was converted into a 60 000-mol.wt. form during electrophoresis. These results are in general accord with the suggestion that the multiple forms of brain acetylcholinesterase may be related to the aggregation of a single low-molecular-weight species.     

Molecular forms of acetylcholinesterase present in the white and grey matter of pig brain

Extraction of the white matter of pig brain with EDTA, lysolecithin or Triton X-100 gave poor yields of soluble acetylcholinesterase although these agents had proved effective at solubilizing the enzyme in the grey matter. This finding, together with the observation that the strong detergent sodium deoxycholate, was needed to solubilize the enzyme, shows that it is more difficult to remove acetylcholinesterase from the white matter of brain than from the grey. This could mean that the enzyme in the white matter is more firmly bound to the membrane than the enzyme in the grey matter.The difference in binding of the enzyme from the two regions of the brain is also reflected in the affinity chromatography experiments which showed a lower recovery for the acetylcholinesterase of white matter compared with the enzyme from grey matter.Starch-block electrophoresis of acetylcholinesterase showed a single negatively charged peak of activity for both the naturally soluble and the deoxycholate solubilized preparations. The presence of only one form on electrophoresis suggests that the molecular species of acetylcholinesterase do not arise from differences in charge.Sucrose density gradient centrifugation of the two preparations from white matter gave a single peak of activity with a sedimentation constant of about 10 S. This corresponds closely to the major species of molecular weight 260,000 detected by gradient gel electrophoresis. Other forms detected in both enzyme preparations by gradient gel electrophoresis were species with molecular weights of 660,000, 180,000, 130,000 and 115,000. The significance of these species in terms of the formation of oligomers is discussed.A comparison was made with the corresponding preparations of acetylcholinesterase from the grey matter and the results showed that acetylcholinesterase from the white and grey matter of pig brain were very similar. The exception to this was the species with a molecular weight of 68,000 which was present in the grey but not the white matter of pig brain.     

Solubilization of Collagen-Tailed Acetylcholinesterase from Chick Retina: Effect of Different Extraction Procedures

We have extracted acetylcholinesterase from young chick retinas by homogenization in different solutions combining high salt concentration, ionic and nonionic detergents, and EDTA, looking for an optimum procedure for the solubilization of collagen-tailed, asymmetric structural forms of the enzyme. High salt and EDTA seem to be the only necessary requirements for the solubilization of acetylcholinesterase as the A12 form (20S), and the presence of detergent in the homogenization medium does not significantly improve the yield of tailed enzyme. Extraction in the absence of detergent has the potential advantage of a threefold enrichment of tailed enzyme, because only about one-third of the total retinal acetylcholinesterase activity is solubilized. Divalent cations, especially Ca2+, seem to be involved in the attachment of the tailed enzyme to the retinal membranes, at the tail level. High salt-EDTA-extracted 20S acetylcholinesterase (without detergent) aggregates in the presence of exogenous Ca2+ and becomes "insoluble." However, the aggregated 20S acetylcholinesterase can be completely recovered and brought back into solution by further addition of EDTA. Besides, the aggregation can be prevented by the inclusion of Triton X-100 in the homogenization buffer or by adding the detergent concurrently with Ca2+. It is postulated that the acetylcholinesterase collagenous tail is coated by acidic lipid molecules hydrophobically bound to the tail protein so that Ca2+ ionic bridges would actually link these lipid molecules (and consequently the tail) to the membrane matrix. Removal of the lipid coat (e.g., by Triton X-100) produces tailed acetylcholinesterase molecules that no longer aggregate in the presence of Ca2+ and are fully accessible to collagenase digestion.     

Anchorage of collagen-tailed acetylcholinesterase to the extracellular matrix is mediated by heparan sulfate proteoglycans

Heparan sulfate and heparin, two sulfated glycosaminoglycans (GAGs), extracted collagen-tailed acetylcholinesterase (AChE) from the extracellular matrix (ECM) of the electric organ of Discopyge tschudii. The effect of heparan sulfate and heparin was abolished by protamine; other GAGs could not extract the esterase. The solubilization of the asymmetric AChE apparently occurs through the formation of a soluble AChE-GAG complex of 30S. Heparitinase treatment but not chondroitinase ABC treatment of the ECM released asymmetric AChE forms. This provides direct evidence for the vivo interaction between asymmetric AChE and heparan sulfate residues of the ECM. Biochemical analysis of the electric organ ECM showed that sulfated GAGs bound to proteoglycans account for 5% of the total basal lamina. Approximately 20% of the total GAGs were susceptible to heparitinase or nitrous acid oxidation which degrades specifically heparan sulfates, and approximately 80% were susceptible to digestion with chondroitinase ABC, which degrades chondroitin-4 and -6 sulfates and dermatan sulfate. Our experiments provide evidence that asymmetric AChE and carbohydrate components of proteoglycans are associated in the ECM; they also indicate that a heparan sulfate proteoglycan is involved in the anchorage of the collagen-tailed AChE to the synaptic basal lamina.     

A comparative study of the composition of the microsomal membranes of the liver, brain and skeletal muscles in vertebrates]

Phospholipid and cholesterol amounts, intrinsic protein/lipid ratios in liver, brain and skeletal muscle microsomal membranes of 14 species of vertebrate animals have been studied. No significant differences between phospholipid amounts in tissues as well as vertebrate classes have been discovered. The highest cholesterol amount has been found in brain microsomes, the smallest one in sarcoplasmic reticulum membranes. In reptile brain and muscle microsomes a higher amount of cholesterol compared to that in species of other vertebrate classes has been found. In brain membranes intrinsic protein and lipid amounts are approximately equal, while in liver and muscle microsomes a protein component predominates. Phospholipid/protein ratio is larger in brain membranes than in liver and muscle ones. Cholesterol/protein ratio reaches the highest values in microsomal membranes of reptile tissues. Brain membranes of vertebrate animals are characterized by a greater stability of protein-lipid composition than liver and muscle ones.     

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.     

Cellular and Secreted Forms of Acetylcholinesterase in Mouse Muscle Cultures

When grown in primary cell culture in the absence of neurons, muscle cells from a variety of species synthesize several forms of acetylcholinesterase (AChE), including the collagen-tailed A12 form. A12 AChE has been the subject of much study because it is thought to be a major functional enzyme form normally found in the basal lamina at the neuromuscular junction. In this paper, we show that muscle fibers derived from mouse embryos and neonates are also able to synthesize substantial percentages of their AChE as the A12 form when grown in vitro. This synthesis is modulated by a process associated with spontaneous muscle contractile activity since both total enzyme levels and the proportion of A12 AChE expressed on the cell surface are decreased when the cells are grown in the sodium channel blocker tetrodotoxin, which blocks muscle contraction. On the other hand, when the cells are treated with veratridine, which opens sodium channels, thereby mimicking one aspect of muscle contraction, their AChE levels are comparable to those of untreated cells. Although smaller in magnitude, these changes are similar to those seen in rat muscle cultures. A novel feature of mouse muscle cultures, not seen in those from rat and chick, is the presence of a secreted enzyme form that sediments in the same position as the cellular A12 form (when separated on sucrose density gradients containing high salt) and is also collagenase sensitive.     

Polymorphism of Pseudocholinesterase in Torpedo marmorata Tissues: Comparative Study of the Catalytic and Molecular Properties of this Enzyme with Acetylcholinesterase

We report the existence, in Torpedo marmorata tissues, of a cholinesterase species (sensitive to 10(-5) M eserine) that differs from acetylcholinesterase (AChE, EC 3.1.1.7) in several respects: (a) The enzyme hydrolyzes butyrylthiocholine (BuSCh) at about 30% of the rate at which it hydrolyzes acetylthiocholine (AcSCh), whereas Torpedo AChE does not show any activity on BuSCh. (b) It is not inhibited by 10(-5) M BW 284C51, but rapidly inactivated by 10(-8) M diisopropylfluorophosphonate. (c) It does not exhibit inhibition by excess substrate up to 5 X 10(-3) M AcSCh. (d) It does not cross-react with anti-AChE antibodies raised against purified Torpedo AChE. This enzyme is obviously homologous to the "nonspecific" or pseudocholinesterase (pseudo-ChE, EC 3.1.1.8) that exists in other species, although it is closer to "true" AChE than classic pseudo-ChE in several respects. Thus, it shows the highest Vmax with acetyl-, and not propionyl- or butyrylthiocholine, and it is not specifically sensitive to ethopropazine. Pseudo-ChE is apparently absent from the electric organs, but represents the only cholinesterase species in the heart ventricle. Pseudo-ChE and AChE coexist in the spinal cord and in blood plasma, where they contribute to AcSCh hydrolysis in comparable proportions. Pseudo-ChE exists in several molecular forms, including collagen-tailed forms, which can be considered as homologous to those of AChE. In the heart the major component of pseudo-ChE appears to be a soluble monomeric form (G1). This form is inactivated by Triton X-100 within days.(ABSTRACT TRUNCATED AT 250 WORDS)