Cofilin is an actin regulatory protein that binds to both monomeric and filamentous actin, and has filament severing activity. Although crystal structures for the monomeric forms of both G-actin and cofilin have been described, the structure of the binary cofilin-G-actin complex is not available. Synchrotron protein footprinting is used to identify specific side chain residues on the cofilin surface that are buried in the formation of the cofilin-G-actin binary complex. Exposure to synchrotron X-rays results in stable oxidative modifications of aromatic, aliphatic, and sulfur-containing side chains, with the rate of modification for a particular residue being dependent on its intrinsic reactivity and solvent accessibility. The rates of modification were monitored for a number of peptides generated by digestion of oxidized cofilin, both in isolation and in its binary complex with G-actin. After binding to G-actin takes place, a significant decrease in modification rates, indicating protection of side chain groups, is seen for cofilin peptides corresponding to residues 4-20, 10-17, 83-96, 91-105, and 106-117. A number of other peptides show no change in reactivity, and are presumed to represent regions distal to the binding site. Tandem mass spectrometry demonstrates that residues Leu 13, Pro 94, Met 99, and Leu 108 and 112 directly participate in the binding interface. These results are generally consistent with, and complementary to, the results of previous site-directed mutagenesis studies and extend our understanding of the G-actin binding surface of cofilin.
The solution structures of isolated monomeric actins in their Mg(2+)-ATP and Ca(2+)-ATP bound forms and in complexes with gelsolin segment-1 have been probed using hydroxyl radicals (*OH) generated by synchrotron X-ray radiolysis. Proteolysis and mass spectrometry analysis of 28 peptides containing 58 distinct reactive probe sites within actin were used to monitor conformational variations linked to divalent cation and gelsolin segment-1 binding. The solvent accessibilities of the probe sites, as measured by footprinting in solution for the Ca(2+)-G-actin and Mg(2+)-G-actin complexes with gelsolin segment-1, were consistent with available crystallographic data. This included a specific protection at the contact interface between the partners, as revealed by reduced reactivity of peptide 337-359 in the complex. Aside from the specific protection indicated previously, the oxidation rates for the reactive residues of the isolated Ca(2+)-G-actin were similar to those of the actin gelsolin segment-1 complexes; however, the reactivity of numerous residues in the isolated Mg(2+)-G-actin form was significantly reduced. Specifically, Mg(2+)-G-actin has a set of protected sites relative to Ca(2+)-G-actin that suggest a structural reorganization in subdomains 4 and 2 and a C-terminus more closely packed onto subdomain 1. These conformational variations for isolated Mg(2+)-G-actin provide a structural basis for its greater tendency to polymerize into filaments as compared to Ca(2+)-G-actin.
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