Iron(III)-mediated photolysis of outer arm dynein ATPase from sea urchin sperm flagella.

Irradiation of outer arm dynein ATPase from sea urchin sperm tail flagella at 365-410 nm in the presence of Fe(III)-gluconate complex and ATP produces photolytic cleavage at two distinct sites on the beta heavy chain, located approximately 250 and approximately 230 kDa from its amino terminus. The former cut is close to or identical with the V1 site of the vanadate-mediated photocleavage (Gibbons, I.R., Lee-Eiford, A., Mocz, G., Phillipson, C. A., Tang, W.-J.Y., and Gibbons, B.H. (1987) J. Biol. Chem. 262, 2780-2786. The rate of photolysis shows a hyperbolic dependence on Fe(III)-gluconate concentration with half-maximal rate occurring at 23 microM at pH 6.3. In the presence of 0.1-0.5 mM Fe(III)-gluconate-ATP, approximately 58% of the beta chain becomes cleaved with a half-time of about 34 s; the remainder of the beta chain and almost all of the alpha chain are resistant to cleavage. This photolytic cleavage of the beta chain is accompanied by an approximately parallel loss of the dynein latent ATPase activity, whereas the Triton-activated ATPase is lost to a somewhat greater extent. Mg2+ concentrations above approximately 3 mM inhibit photolysis. Substitution of ADP for ATP changes the pattern of cleavage so that both the alpha and beta heavy chain undergo scission but at the 250-kDa site only. AMP, adenyl-5'-yl imidodiphosphate and Fe(II) do not support cleavage at either site. Trivalent rhodium-ATP complexes, as models of MgATP, can also catalyze photolysis of the beta chain at the 250-kDa site. These results suggest that photolysis results from the activation of an Fe(III)-ATP complex bound to the hydrolytic ATP binding site of the beta chain and that both Fe(III) cleavage sites are located close to the nucleotide binding site in the tertiary folding of the beta heavy chain. The cleavage reaction possibly involves initial photoreduction of Fe(III) bound at the Mg2+ binding site in the dynein.Fe.ATP complex, followed by covalent modification of an amino acid side chain that leads to eventual peptide scission.