The toxicity of N-methyldithiocarbamate may be mediated through decomposition to more biologically active compounds. Two principal products, CS2 and methyl isothiocyanate, have the potential to interact covalently with macromolecules in biological systems. In this investigation the ability of N-methyldithiocarbamate to generate methyl isothiocyanate and CS2 under physiological conditions resulting in acylation and covalent cross-linking of proteins was examined using 13C NMR and GC/MS. Two N-methyldithiocarbamate esters, S-methyl N-methyldithiocarbamate and (N-acetyl-S-methylthiocarbamoyl)cysteine, were also investigated to evaluate the acylating ability of sulfhydryl conjugates of N-methyldithiocarbamate. The predominant and most stable adduct produced by the free dithiocarbamate and its S-substituted esters was methylthiourea on epsilon-lysyl and N-terminal alpha-amino groups. Derivatization on N-terminal amino groups progressed more rapidly for the dithiocarbamate than for its mercapturate. Methylurea protein adducts were also produced by the dithiocarbamate and its esters, suggesting production of methyl isocyanate in the decomposition of N-methyldithiocarbamate. Covalent cross-linking of beta-lactoglobulin by N-methyldithiocarbamate resulting from its decomposition to CS2 was observed using denaturing polyacrylamide gel electrophoresis. These results demonstrate the ability of a monoalkyldithiocarbamate to acylate protein amino groups and effect covalent cross-linking. These processes represent molecular mechanisms that may contribute to the toxicity of this class of compounds.