Differentiation-dependent changes of nicotinic synapse-associated proteins

The role of thiols in nucleotide uptake into synaptic vesicles from Torpedo marmorata

We have employed sulfhydryl group reagents in an attempt to determine the mechanism by which the transport of nucleotides into synaptic vesicles is controlled. Transport proved to be sensitive to N-ethylmaleimide; radiolabelled N-ethylmaleimide was used to locate the sulfhydryl group to the translocase-associated molecule previously identified as a polypeptide of Mr 34,000 [Lee and Witzemann (1983) Biochemistry 22, 6123-6130]. The nucleotide uptake was 75% inhibited by the mercurials rho-hydroxymercuribenzoate and rho-chloromercuriphenylsulfonate. Uptake was also sensitive to the reagents phenylarsine oxide and iodosobenzoic acid, which are specific for dithiols. These results indicate that a readily accessible dithiol is critical for nucleotide transport. Using the lipophilic oxidants iodosobenzoic acid and plumbagin, we demonstrated that nucleotide uptake was inhibited upon oxidation of the dithiol but that this did not involve an alteration in the affinity of the translocase for its substrate.

Creatine kinase isoenzymes in Torpedo californica: absence of the major brain isoenzyme from nicotinic acetylcholine receptor membranes

Creatine kinase, actin, and nu 1 are three proteins of Mr 43 000 associated with membranes from electric organ highly enriched in nicotinic acetylcholine receptor. High levels of creatine kinase are required to maintain adequate ATP levels, while actin may play a role in maintaining the synaptic cytoskeleton. Previous investigations have prompted the conclusion that postsynaptic specializations at the receptor-enriched membrane domains in electroplax contain the brain form of creatine kinase rather than the form of creatine kinase predominantly found in muscle. We have examined this conclusion by purifying Torpedo brain creatine kinase to virtual homogeneity in order to examine its immunochemical, molecular, and electrophoretic properties. On the basis of immunological cross-reactivity and isozyme analysis, the receptor-associated creatine kinase is identified to be of the muscle type. When the molecular characteristics of Torpedo brain and muscle creatine kinase are compared, the brain enzyme is positioned at a more basic pH during chromatofocusing and on two-dimensional gel electrophoresis (pI = 7.5-7.9). Furthermore, electrophoretic mobilities of the brain and muscle forms of creatine kinase differ in sodium dodecyl sulfate electrophoresis: the brain isozyme of creatine kinase has lower apparent molecular weight (Mr 41 000) when compared with the muscle enzyme (Mr 43 000). On the basis of the results of our current investigations, the hypothesis that the brain isozyme of creatine kinase is a component of the postsynaptic specializations of the Torpedo californica electroplax must be abandoned. Recent sequence data have established close homology between Torpedo and mammalian muscle creatine kinases. On the basis of electrophoretic criteria, our results indicate that a lower degree of homology exists between the brain isozymes.

Creatine phosphokinase: isoenzymes in Torpedo marmorata

Creatine phosphokinase (ATP: creatine N-phosphotransferase, EC 2.7.3.2) is the major constituent of the "low-salt-soluble" proteins of the electric organ from Torpedo marmorata. The denatured subunits of the enzyme have an apparent Mr of 43 000 and isoelectric points ranging between pH 6.2 and pH 6.5. Identical properties are found for the creatine phosphokinase from Torpedo muscle tissue. Anti-(electric organ creatine phosphokinase) antibodies are specific for the muscle-type enzyme and do not cross-react with enzymes present in Torpedo brain and electric lobe tissue. Biochemical and immunochemical properties of the enzyme associated with acetylcholine-receptor-enriched membranes show that this enzyme is as the "low-salt-soluble" electric organ enzyme of the muscle-specific type. In vitro translation of electric organ poly(A)-rich mRNA in a reticulocyte lysate reveals the abundance of mRNA specific for muscle creatine phosphokinase. During embryonic development of the electrocyte a continuous increase of translatable amounts of this mRNA is observed. No brain-type polypeptides are synthesized. The subunits of the brain-specific enzyme differ in molecular mass (Mr approximately equal to 42000) and isoelectric properties (pI approximately equal to 7.0-7.2). The unexpected finding that the brain forms are more basic than the muscle-specific enzyme is supported by agarose and cellulose acetate electrophoresis and ion-exchange chromatography properties.

Limited proteolysis of human erythrocyte Ca2+-ATPase in membrane-bound form. Identification of calmodulin-binding fragments

Water-soluble and membrane-bound calmodulin-binding polypeptides formed upon limited proteolysis of erythrocyte ghosts were isolated by means of affinity chromatography. Immune blotting revealed that all isolated fragments originated from Ca2+-ATPase. Among the fragments obtained those having formed an acylphosphate intermediate were identified. The N-terminal residue of purified intact Ca2+-ATPase was shown to be blocked (probably acylated).

The 43-K protein, v1, associated with acetylcholine receptor containing membrane fragments is an actin-binding protein

Acetylcholine receptor enriched membrane fragments were obtained from the electric organs of Torpedo marmorata. The purified membrane fragments contained several proteins in addition to the acetylcholine receptor subunits. One of these was shown to be actin by means of immune blotting with a monoclonal antibody. Brief treatment of the membranes with pH 11.0 buffer removed actin and the other non-receptor proteins including the receptor-associated 43 000 mol. wt. polypeptide. This polypeptide was shown to bind actin after transferring the proteins from one- and two-dimensional polyacrylamide gels to nitrocellulose paper and incubating the nitrocellulose blots with actin. Specifically bound actin was demonstrated using the monoclonal antibodies to actin. No calcium or calmodulin dependency of binding was observed. The findings suggest that the 43 000 mol. wt. polypeptide is a link between the membrane-bound acetylcholine receptor and the cytoskeleton.

[Application of the technics of molecular genetics in neurochemistry]

Research in molecular neurobiology has recently entered a new phase of rapid development as a result of the application of the techniques of molecular genetics. This is illustrated by recent work on the electric ray (Torpedo marmorata and T. californica), whose electric organ is a rich source of cholinergic synapses. Other examples from recent literature of the application of the recombinant DNA technique to the mammalian central nervous system are given and possible future developments are discussed.