Regulation and evolution of the single alpha‐tubulin gene of the ciliate Tetrahymena thermophila

Abstract

The single alpha‐tubulin gene of Tetrahymena thermophila was isolated from a genomic library and shown to encode a single protein. Comparisons of the rates of evolution of this gene with other alpha‐tubulin sequences revealed that it belongs to a group of more evolutionarily constrained alpha‐tubulin proteins in animals, plants, and protozoans versus the group of more rapidly evolving fungal and variant animal alpha‐tubulins. The single alpha‐tubulin of Tetrahymena must be used in a variety of microtubule structures, and we suggest that equivalently conserved alpha‐tubulins in other organisms are evolutionarily constrained because they, too, are multifunctional. Reduced constraints on fungal tubulins are consistent with their simpler microtubule systems. The animal variant alpha‐tubulins may also have diverged because of fewer functional requirements or they could be examples of specialized tubulins. To analyze the role of tubulin gene expression in regulation of the complex microtubule system of Tetrahymena, alpha‐tubulin mRNA amounts were examined in a number of cell states. Message levels increased in growing versus starved cells and also during early stages of conjugation. These changes were correlated with increases in transcription rates. Additionally, alpha‐tubulin mRNA levels oscillate in a cell cycle dependent fashion caused by changes in both transcription and decay rates. Therefore, as in other organisms, Tetrahymena adjusts alpha‐tubulin message amounts via message decay. However the complex control of alpha‐tubulin mRNA during the Tetrahymena life cycle involves regulation of both decay and transcription rates.