Gln‐41 is intermolecularly cross‐linked to Lys‐113 in F‐actin by N‐(4‐azidobenzoyl)‐putrescine

Abstract

The bifunctional reagent N‐(4‐azidobenzoyl)‐putrescine was synthesized and covalently bound to rabbit skeletal muscle actin. The incorporation was mediated by guinea pig liver transglutaminase under conditions similar to those described by Takashi (1988, Biochemistry 27, 938–943); up to 0.5 M/M were incorporated into G‐actin, whereas F‐actin was refractory to incorporation. Peptide fractionation showed that at least 90% of the label was bound to Gln‐41. The labeled G‐actin was polymerized, and irradiation of the F‐actin led to covalent intermo‐lecular cross‐linking. A cross‐linked peptide complex was isolated from a tryptic digest of the cross‐linked actin in which digestion was limited to arginine; sequence analysis as well as mass spectrometry indicated that the linked peptides contained residues 40–62 and residues 96–116, and that the actual cross‐link was between Gln‐41 and Lys‐113. Thus the γ‐carboxyl group of Gln‐41 must be within 10.7 Å of the side chain (probably the amino group) of Lys‐113 in an adjacent actin monomer. In the atomic model for F‐actin proposed by Holmes et al. (1990, Nature 347, 44–49), the α‐carbons of these residues in adjacent monomers along the two‐start helices are sufficiently close to permit cross‐linking of their side chains, and, pending atomic resolution of the side chains, the results presented here seem to support the proposed model.