Reaction of cardiac myosin with a purine disulfide analog of adenosine triphosphate. II. Stoichiometry and subunit location of labeling

Abstract

The reaction of bovine cardiac myosin with the site-specific purine disulfide analog of ATP, 6,6'-dithiobis (inosinyl imidodiphosphate), was studied to determine the stoichiometry of labeling and subunit location of the reactive cysteines. The analog inactivates myosin by forming a mixed disulfide between the thiopurine nucleotide and certain key cysteines. The thiopurine nucleotide was displaced quantitatively by 14CN to form the more stable thiocyanato-enzyme derivatives. In cardiac myosin, the reactive cysteines could be categorized into three classes, nonessential, critical, and noncritical. The modification of the critical cysteines (two per myosin) inactivated the EDTA and Ca2+ ATPase activities, the latter to a lesser extent. The nonessential cysteines (two to three per myosin) and the noncritical cysteines (two per myosin), differentiated by their rates of reaction, had no effect on the ATPase activities after modification. Thiocyanato-modified myosin was analyzed by sodium dodecyl sulfate gel electrophoresis to determine the distribution of 14CN in the subunits. The critical cysteines were found on the 21,000-dalton light chain (LC1) and the noncritical cysteines on the heavy chains. More specifically, the critical cysteine modified in cardiac LC1 (determined from the products after cyclization and chain cleavage at the thiocyanatoalanyl residues) was shown to be the thiol residue whose surrounding amino acid sequence is homologous to that of the single cysteine of the skeletal myosin alkali light chains, confirming the likely similar structure and function of these light chains in the two different muscle types.