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Nucleotide Effects on the Structure and Dynamics of Actin

Center for Computational Biology and Department of Biomedical Engineering, Washington University, St. Louis, Missouri 63130

Correspondence: Address reprint requests to David Sept, Biomedical Engineering, Campus Box 1097, Washington University, St. Louis, MO 63130-4899. Tel.: 314-935-8837; Fax: 314-935-7448; E-mail: dsept{at}biomed.wustl.edu.

Adenosine 5'-triphosphate or ATP is the primary energy source within the cell, releasing its energy via hydrolysis into adenosine 5'-diphosphate or ADP. Actin is an important ATPase involved in many aspects of cellular function, and the binding and hydrolysis of ATP regulates its polymerization into actin filaments as well as its interaction with a host of actin-associated proteins. Here we study the dynamics of monomeric actin in ATP, ADP-P_i, and ADP states via molecular dynamics simulations. As observed in some crystal structures we see that the DNase-I loop is an -helix in the ADP state but forms an unstructured coil domain in the ADP-P_i and ATP states. We also find that this secondary structure change is reversible, and by mimicking nucleotide exchange we can observe the transition between the helical and coil states. Apart from the DNase-I loop, we also see several key structural differences in the nucleotide binding cleft as well as in the hydrophobic cleft between subdomains 1 and 3 where WH2-containing proteins have been shown to interact. These differences provide a structural basis for understanding the observed differences between the various nucleotide states of actin and provide some insight into how ATP regulates the interaction of actin with itself and other proteins.

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