Abstract
Latrunculin A is used extensively as an agent to sequester monomeric actin in living cells. We hypothesize that additional activities of latrunculin A may be important for its biological activity. Our data are consistent with the formation of a 1:1 stoichiometric complex with an equilibrium dissociation constant of 0.2 to 0.4 micrometer and provide no evidence that the actin-latrunculin A complex participates in the elongation of actin filaments. Profilin and latrunculin A bind independently to actin, whereas binding of thymosin beta(4) to actin is inhibited by latrunculin A. Potential implications of this differential effect on actin-binding proteins are discussed. From a structural perspective, if latrunculin A binds to actin at a site that sterically influences binding by thymosin beta(4), then the observation that latrunculin A inhibits nucleotide exchange on actin implies an allosteric effect on the nucleotide binding cleft. Alternatively, if, as previously postulated, latrunculin A binds in the nucleotide cleft of actin, then its ability to inhibit binding by thymosin beta(4) is a surprising result that suggests that significant allosteric changes affect the thymosin beta(4) binding site. We show that latrunculin A and actin form a crystalline structure with orthorhombic space group P2(1)2(1)2(1) and diffraction to 3.10 A. A high resolution structure with optimized crystallization conditions should provide insight regarding these remarkable allosteric properties.
Highlights
Latrunculin A is used extensively as an agent to sequester monomeric actin in living cells
If latrunculin A binds to actin at a site that sterically influences binding by thymosin 4, the observation that latrunculin A inhibits nucleotide exchange on actin implies an allosteric effect on the nucleotide binding cleft
The Initial Rate of Polymerization in a Seeded Polymerization Assay Fit a Model in Which the Latrunculin A-Actin Complex Did Not Participate in Elongation—Unlike the actin-monomer-binding protein, profilin, elongation data for actin in the presence of latrunculin A can be explained by monomer sequestration alone with KdL of 0.22 Ϯ 0.06 M (Fig. 2)
Summary
Latrunculin A is used extensively as an agent to sequester monomeric actin in living cells. If latrunculin A binds to actin at a site that sterically influences binding by thymosin 4, the observation that latrunculin A inhibits nucleotide exchange on actin implies an allosteric effect on the nucleotide binding cleft. The observation that latrunculin affects nucleotide exchange has been offered as support of this conclusion (3) These data, are inconclusive in light of the fact that many actin-binding proteins with binding sites that are spatially distant from the nucleotide cleft are able to affect nucleotide exchange (5) and that actin demonstrates several additional allosteric properties that serve as a precedent for the transmission of structural alterations to distant sites (6 – 8). Our results illustrate a novel mechanism by which pharmacological agents that bind actin could be used to modulate the function of actin-binding proteins
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
