Immunochemical studies of mammalian brain acetylcholinesterase

Production and characterization of separate monoclonal antibodies to human brain and erythrocyte acetylcholinesterases

Four murine monoclonal antibodies (MAbs) of the IgM class were raised against human acetylcholinesterase (AChE; Ec 3.1.1.7). The MAbs BMS-3E4, BMS-7G10, and BMS-9F4 all recognized human erythrocyte AChE, while BMS-6D6 bound specifically to human soluble brain AChE, on the basis of immunobinding assays. Dose-response studies gave an ELISA ED50 titer of 4.5 x 10(-4) M for BMS-6D6, while BMS-3E4 gave the best titer at 8.8 x 10(-4) M. Sucrose density gradients demonstrated sedimentation of antigen-antibody complexes, consistent with earlier findings (i.e., BMS-6D6 bound with brain AChE while BMS-3E4 preferred erythrocyte (AChE). No cross-reactivity between the two MAbs against the two antigens was noted.

Acetylcholinesterase from Schistosoma mansoni: immunological characterization

The enzyme acetylcholinesterase (AChE) is present in the trematode Schistosoma mansoni, which infects humans and causes a severe disease called schistosomiasis or Bilharzia. We have purified this enzyme and raised polyclonal antibodies against it. The specificity of these antibodies against the schistosome enzyme was demonstrated by their capacity to precipitate exclusively AChE activity from cercariae extract and to recognize the 8S molecular form of the parasite's AChE. On the other hand, they did not cross-react at all with AChE from human erythrocytes. By employing immunogold electron microscopy, AChE was located on the surface, in the membranal bodies of the tegument and in the muscles of schistosomula. The antibodies raised against the purified AChE of S. mansoni are of protective value, as they led to efficient complement-mediated killing of schistosomula in vitro. It was also demonstrated that antibodies specific towards S. mansoni AChE are present in the sera of mice and of human patients infected with the parasite, suggesting that this enzyme partakes in the immune response towards the parasite during infection. These cumulative data, particularly the schistosomicidal activity of the antibodies and their lack of cross-reactivity with human AChE, are of significance in the consideration of the S. mansoni AChE for vaccination purposes.

A comparison of the localization of acetylcholinesterase in the rat brain as demonstrated by enzyme histochemistry and immunohistochemistry

The localization of acetylcholinesterase (AChE) as revealed either by enzyme-histochemical or by immunohistochemical methods was compared in distinct regions of the rat brain. In general, the localization of AChE observed was nearly the same, whether revealed by histochemical demonstration of its catalytic activity or by immunohistochemical detection of the enzyme molecule itself, in all regions investigated. Penetration problems of the antibodies, however, arose on strong myelin sheaths of the facial nerve, for instance, where no immunohistochemical staining was found though there was a relatively strong histochemical reaction. These problems could be partly solved by increasing the normal concentration of Triton X-100 added to the immunohistochemical solutions (0.1%) to 2.5%. Furthermore, it seems that sites containing low amounts of AChE could be better detected by the enzyme-histochemical method, whereas the depiction of structures (particularly of nerve fibres) was somewhat sharper with the immunohistochemical method.

Secretory acetylcholinesterases from Brugia malayi adult and microfilarial parasites

Brugia malayi, a lymphatic filarial parasite, secretes acetylcholinesterase during in vitro cultivation. A significant amount of enzyme activity was detected both in culture media and somatic extracts of adult and microfilarial stages of the parasite. The microfilarial stage produces three times more enzyme than adult parasites as a proportion of total protein. The enzyme has true acetylcholinesterase (AChE) activity as hydrolysis of acetylthiocholine is three times faster than butyrylthiocholine and is inhibited by eserine, a specific inhibitor of AChE. Secretory enzyme from adult female parasite excretory-secretory material (ES) was enriched 23 fold using copper chelating and concanavalin A (Con A) affinity chromatography. The Con A eluate showed a major protein band of 100 kDa and a minor 200 kDa component. The ES enzyme is antigenic and cross reacts with antibodies raised in mice against AChE from electric eel by enzyme-linked immunosorbent assay and immunoprecipitation. Immunoprecipitation of 125I-labelled microfilarial ES and adult ES with anti-electric eel AChE antibodies revealed three proteins of 30, 40 and 200 kDa in microfilariae and two proteins of 100 and 200 kDa in adult female ES. It appears that filarial secretory AChE exists in multiple molecular forms.

Generation of monoclonal antibodies to characterize antigens of the nematode Nippostrongylus brasiliensis

Hybridomas secreting monoclonal antibodies to Nippostrongylus brasiliensis antigens were generated by fusion of NSI mouse myeloma cells with spleen cells from Balb/c mice which had been immunized either with killed third stage larvae or killed adult worms of N. brasiliensis. Enzyme-linked immunosorbent assays with worm or larvae fragments as antigens revealed that thirteen hybrids produced parasite-specific antibodies. The antibodies reacted with either both worms and larvae or exclusively recognized worm antigens. No antibody was found which solely reacted with larval antigens. Immunofluorescence studies demonstrated that most antibodies homogeneously stained the cuticle of 80-90% of the adult worms and 10-20% of the third stage larvae. The antibodies were further characterized by enzyme-linked immunosorbent assays specific for worm or larvae homogenates and secretions or for acetylcholinesterase from electric eel and bovine erythrocytes. Investigations of the epitope specificity by the inhibition of binding to worm fragments in the presence of various glycosides, N-acetylneuraminic acid and phosphorylcholine revealed that six antibodies reacted with N-acetylneuraminic acid. All antibodies displayed a low affinity to phosphorylcholine.

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

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

Monoclonal antibodies to rabbit brain acetylcholinesterase: selective enzyme inhibition, differential affinity for enzyme forms, and cross-reactivity with other mammalian cholinesterases

Eleven unique monoclonal IgG antibodies were raised against rabbit brain acetylcholinesterase (AChE, EC 3.1.1.7), purified to electrophoretic homogeneity by a two-step procedure involving immunoaffinity chromatography. The apparent dissociation constants of these antibodies for rabbit AChE ranged from about 10 nM to more than 100 nM (assuming one binding site per catalytic subunit). Species cross-reactivity was investigated with crude brain extracts from rabbit, rat, mouse cat, guinea pig, and human. One antibody bound rabbit AChE exclusively; most bound AChE from three or four species; two bound enzyme from all species tested. Identical, moderate affinity for rat and mouse brain AChE was displayed by two antibodies; two others were able to distinguish between these similar antigens. Nine of the antibodies had lowered affinity for AChE in the presence of 1 M NaCl, but two were salt resistant. Analysis of mutual interferences in AChE binding suggested that certain of the antibodies were competing for nearby epitopes on the AChE surface. One antibody was a potent AChE inhibitor (IC50 = 10(-8) M), blocking up to 90% of the enzyme activity. Most of the antibodies were less able to bind the readily soluble AChE of detergent-free brain extracts than the AChE which required detergent for solubilization. The extreme case, an antibody that was unable to recognize nearly half of the "soluble" AChE, was suspected of lacking affinity for the hydrophilic enzyme form.

Localization and axonal transport of immunoreactive cholinergic organelles in rat motor neurons--an immunofluorescent study

Antisera produced in rabbits against pure fractions of cholinergic vesicles from Narcine brasiliensis were used to study cholinergic organelles in rat motor neurons. The indirect immunofluorescence method was used on perfusion-fixed material. The rats were surgically sympathectomized to remove sympathetic adrenergic and cholinergic nerves from the sciatic nerve. In the intact animal immunoreactive material, likely to represent cholinergic vesicles, was observed in motor endplates, identified by labelling with rhodamine-conjugated alpha-bungarotoxin or with subsequent acetylcholinesterase staining. The motor perikarya contained very little immunoreactive material. Non-terminal axons were virtually devoid of immunofluorescence in the intact animal. After crushing the sciatic nerve, immunoreactive material (likely to represent axonal cholinergic organelles) accumulated rapidly on both sides of the crush, indicating a rapid bidirectional transport. The transport was sensitive to local application of mitotic inhibitors. The axons which accumulated immunoreactive organelles were motor axons, as demonstrated by various procedures: Cutting of ventral roots prevented accumulation of immunoreactive material in the nerve. Deafferentation did not notably influence accumulations of immunoreactive material. Ligated axons with immunoreactive material were acetylcholinesterase positive when identification was made on the same section; the intra-axonal distribution of immunoreactive material and acetylcholinesterase was not identical, however, and the Narcine antisera did not cross-react with bovine acetylcholinesterase in a solid phase immunoassay. Most axons in ventral roots, but not in dorsal roots, accumulated strongly fluorescent immunoreactive material, while axons in dorsal roots contained weakly fluorescent material. On the other hand, substance P-like immune reactivity was present in many dorsal root axons, but only very rarely in ventral roots. It is suggested that the antisera against Narcine cholinergic vesicles can be used as a marker for cholinergic organelles in the motor neuron, and may be an important tool for studying the axonal cholinergic vesicles. It cannot, however, be used to identify cholinergic structures in unknown locations because it recognizes common antigenic determinants in transmitter organelles of other nerves, e.g. adrenergic nerves. The axonal cholinergic organelles may carry important molecules, other than acetylcholine to the nerve endings.

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

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

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

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

Acetylcholinesterase of Schistosoma mansoni: antigenic cross-reactivity with Electrophorus electricus and its functional implications

Acetylcholinesterase (AChE) of the parasite Schistosoma mansoni cross-reacts with rabbit antibodies against AChE from the electric eel. Cross-reactivity was demonstrated by radioimmunoassay with sonicate, as well as soluble, preparations from various stages of the parasite life cycle. On sucrose density gradient, the parasite enzyme migrates as an 7.5 S form, whereas an 9.5 S peak is observed with the enzyme-antibody complex. Immunofluorescence microscopy shows specific staining of intact schistosomula as well as of adult worms. Moreover, the interaction of these antibodies resulted in a marked complement-dependent cytotoxicity towards intact schistosomula, indicating that AChE is an antigen of significance on the surface of the parasite.

Cholinesterase activities in the autonomic nervous system of rabbits with experimental allergic neuritis: a biochemical study

Utilizing a colorimetric method with acetylthiocholine iodide (AThCh) as substrate and eserine and ethopropazine as inhibitors, the activities of AThCh-splitting enzymes, acetylcholinesterase (AChE) and non-specific esterase (psi ChE) were determined in different structures of the autonomic nervous system (ANS) from the left and from the right sides of rabbits with experimental allergic neuritis (EAN) and controls. The total activity of AThCh-splitting enzymes showed a highly significant decrease in the ganglion nodosum and in the ganglia of the thoracal and abdominal paravertebral sympathetic chain in rabbits with clinical symptoms of ANS-involvement. Lesser but still significant changes were found in EAN-rabbits with motor symptoms but without ANS symptoms. No definite changes could be found in the superior cervical ganglia, the cervical sympathetic trunk or the interganglionic portions of the abdominal and thoracal paravertebral sympathetic chains. In samples with decreased total enzyme activities, both AChE and psi ChE appeared to decrease to approximately the same extent. This study demonstrates that the activities of AThCh-splitting enzymes are decreased in EAN in parts of ANS innervating the heart, abdominal and pelvic organs, and suggests that enzyme activities not derived from the myelin sheath may be involved in the pathogenesis of this demyelinating disease.

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

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

Laminin, fibronectin, and collagen in synaptic and extrasynaptic portions of muscle fiber basement membrane

Light and electron microscope immunohistochemical methods were used to study the distribution of several proteins in rat skeletal muscle. The aims were to identify components of muscle fiber basement membrane and to compare the small fraction (0.1%) of the basement membrane that extends through the synaptic cleft at the neuromuscular junction with the remaining, extrasynaptic portion. Synaptic basement membrane is functionally specialized and plays important roles in neuromuscular function and regeneration. Laminin, fibronectin, collagen IV, collagen V, and a collagenous protein (high-salt-soluble protein [HSP]) are all present in muscle fiber basement membrane. Laminin and collagen IV are concentrated in basal lamina (the feltlike, inner layer of the basement membrane) and are shared by synaptic and extrasynaptic regions. Fibronectin, also present synaptically and extrasynaptically, is present in basal lamina and in the overlying reticular lamina. Collagen V and HSP are present throughout extrasynaptic basement membrane but are absent from synaptic sites; HSP is concentrated in the reticular lamina and on the outer surface of the basal lamina. These results, together with experiments reported previously (Sanes and Hall, 1979. J. Cell Biol: 83:357--370), provide examples of three classes of components in muscle fiber basement membrane--synaptic, extrasynaptic, and shared.

Major component of acetylcholinesterase in Torpedo electroplax is not basal lamina associated

Electroplax tissue from Torpedo californica contains two major structural forms of the enzyme acetylcholinesterase. One form, composed of tetrameric protomers which are further aggregated by interactions among associated collagenous "tail fibers", has been well characterized previously. This form is associated in situ with the basal lamina. The other form is described and characterized herein. This latter form accounts for at least 50% of the acetylcholinesterase activity of the tissue. This enzyme associated with the tissue phospholipids. It aggregates in aqueous solution but readily dissociates to dimers in 1% sodium cholate solution, a solvent in which it is both soluble and catalytically fully active. The same dimer is obtained in sodium dodecyl sulfate solution where the enzyme is denatured. Denaturation in the presence of the reductant dithiothreitol results in the formation of a single 80000-dalton subunit. The purified enzyme contains no collagenous component. It is not derivable from the collagenous "tailed-enzyme" form in the tissue homogenate. However, the two enzymes have similar molecular weight catalytic subunits and the same substrate-dependent turnover numbers (per active site) for a variety of choline esters which are generally utilized to distinguish specific esterase function. In the tissue homogenate each form of the enzyme is associated with a characteristic structural component (phospholipid or collagen). By implication, acetylcholinesterase function is localized in situ in the phospholipid membrane as well as at the basal lamina.

Antibodies to synaptic vesicles purified from Narcine electric organ bind a subclass of mammalian nerve terminals

Antibodies were raised in rabbits to synaptic vesicles purified to homogeneity from the electric organ of Narcine brasiliensis, a marine electric ray. These antibodies were shown by indirect immunofluorescence techniques to bind a wide variety of nerve terminals in the mammalian nervous system, both peripheral and central. The shared antigenic determinants are found in cholinergic terminals, including the neuromuscular junction, sympathetic ganglionic and parasympathetic postganglionic terminals, and in those synaptic areas of the hippocampus and cerebellum that stain with acetylcholinesterase. They are also found in some noncholinergic regions, including adrenergic sympathetic postganglionic terminals, the peptidergic terminals in the posterior pituitary, and adrenal chromaffin cells. They are, however, not found in many noncholinergic synapse-rich regions. Such regions include the molecular layer of the cerebellum and those laminae of the dentate gyrus that receive hippocampal associational and commissural input. We conclude that one or more of the relatively small number of antigenic determinants in pure electric fish synaptic vesicles have been conserved during evolution, and are found in some but not all nerve terminals of the mammalian nervous system. The pattern of antibody binding in the central nervous system suggests unexpected biochemical similarities between nerve terminals heretofore regarded as unrelated.