Abstract
All but 11 of the 323 known actin sequences have Tyr at position 53, and the 11 exceptions have the conservative substitution Phe, which raises the following questions. What is the critical role(s) of Tyr-53, and, if it can be replaced by Phe, why has this happened so infrequently? We compared the properties of purified endogenous Dictyostelium actin and mutant constructs with Tyr-53 replaced by Phe, Ala, Glu, Trp, and Leu. The Y53F mutant did not differ significantly from endogenous actin in any of the properties assayed, but the Y53A and Y53E mutants differed substantially; affinity for DNase I was reduced, the rate of nucleotide exchange was increased, the critical concentration for polymerization was increased, filament elongation was inhibited, and polymerized actin was in the form of small oligomers and imperfect filaments. Growth and/or development of cells expressing these actin mutants were also inhibited. The Trp and Leu mutations had lesser but still significant effects on cell phenotype and the biochemical properties of the purified actins. We conclude that either Tyr or Phe is required to maintain the functional conformations of the DNase I-binding loop (D-loop) in both G- and F-actin, and that the conformation of the D-loop affects not only the properties that directly involve the D-loop (binding to DNase I and polymerization) but also allosterically modifies the conformation of the nucleotide-binding cleft, thus increasing the rate of nucleotide exchange. The apparent evolutionary "preference" for Tyr at position 53 may be the result of Tyr allowing dynamic modification of the D-loop conformation by phosphorylation (Baek, K., Liu, X., Ferron, F., Shu, S., Korn, E. D., and Dominguez, R. (2008) Proc. Natl. Acad. Sci. U.S.A. 105, 11748-11753) with effects similar, but not identical, to those of the Ala and Glu mutations.
Highlights
Actin is one of the most highly conserved proteins, with all actins having the same amino acid in at least 7% of the 375 positions [1] and about 95% of actins having the same amino acid in about 66% of the positions
It may be relevant that Tyr-53 is dynamically phosphorylated when Dictyostelium amoebae are subjected to stress [3,4,5,6] and during the developmental cycle, accounting for 50% of the actin in spores [7,8,9,10], and rapidly dephosphorylated prior to spore germination
In the research reported in this paper, we initially studied the biochemical and biophysical properties of Dictyostelium actin with Tyr-53 replaced by either Phe, to mimic Tyr; Glu, to mimic the negative charge of phospho-Tyr; Ala, to remove the bulky side chain; or Leu and Trp, to determine whether any hydrophobic amino acid could replace Tyr-53 or if an aromatic amino acid were required
Summary
Actin is one of the most highly conserved proteins, with all actins having the same amino acid in at least 7% of the 375 positions [1] and about 95% of actins having the same amino acid in about 66% of the positions. In this and similar situations, what is the critical role of the amino acid (Tyr in this example) that leads to its strong conservation throughout evolution, and why is it, very occasionally, replaced by one, and only one, other amino acid (Phe in this example). The critical concentration is increased, the rates of nucleation and pointed end elongation are reduced, polymerization and ATP hydrolysis are partially uncoupled, and filaments of pY53-actin are unstable such that polymerized pY53-actin is predominantly in the form of very short oligomers. Mutation of Actin Tyr-53 whether the effects of Tyr-53 phosphorylation are due to the “loss” of tyrosine or the addition of phosphate
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