Regulation of acetylcholinesterase forms in quail and chicken muscle cultures.

High molecular forms of acetylcholinesterase (AChE) have been difficult to obtain in primary cultures of muscle from mammals and birds. This research used pectoral muscle cultures from Japanese quail and chick embryos grown in medium containing embryo extract and horse serum to study the growth and extraction conditions necessary for study of high molecular weight 20S AChE forms found in these birds. The results confirmed the presence of a 20S AChE form in quail muscle cultures and showed that its extraction from the cells was considerably improved by using a Mg-cholate extraction buffer rather than the more commonly used NaCl-Triton X buffer. A striking finding was that removal of serum from the medium for 1-2 days caused the preferential increase in a 20S form in the quail and the resolution of one from background activity in chick muscle cultures. Removal of embryo extract had no effect on levels of the AChE forms. The results suggest that serum factors inhibit the formation of the high molecular weight, motor end plate associated form of AChE in aneural cultures of avian muscle, and that effects of factors such as neural extracts and nerves on AChE forms in cultured muscle should be examined using a defined basal media.

Allosteric interactions between the membrane-bound acetylcholine receptor and chemical mediators. Kinetic studies.

The kinetics of the specific irreversible reaction of a snake neurotoxin, alpha-bungarotoxin, with the acetylcholine receptor of electroplax membrane preparations have been investigated. The effects of activators (decamethonium, carbamylcholine) and inhibitors (alpha-bungarotoxin, d-tubocurarine) of neural transmission on this reaction have been measured and the following new information obtained. (1) The irreversible reaction is preceded by the reversible formation of toxin-receptor complexes. (2) Two types of receptor binding site exist. d-Tubocurarine directly competes with the toxin for one type of binding site. Decamethonium and carbamylcholine are noncompetitive inhibitors of the toxin reaction. (3) The data are inconsistent with binding sites on separate and distinct molecules or with preexisting nonequivalent binding sites. A simple model is proposed to explain both the kinetic data and equilibrium measurements which indicated that activators and inhibitors of neural transmission compete for only one-half of the receptor sites available to them. The model proposes that for the compounds investigated the binding sites of activators do not overlap with those of inhibitors and the ligand-induced conformational changes of the receptor result in changes in the affinities of the binding sites. The model is simple and is based on mechanisms which have been found to be valid for many well-characterized regulatory enzymes.