Abstract
Microtubules participate in a large number of intracellular events including cell division, intracellular transport and secretion, axonal transport, and maintenance of cell morphology. They are composed of tubulin, a heterodimeric protein, consisting of two similar polypeptides alpha and beta. In mammalian cells, both alpha- and beta-tubulin occur as seven to eight different genetic variants, which also undergo numerous posttranslational modifications that include tyrosination-detyrosination and deglutamylation, phosphorylation, acetylation, polyglutamylation, and polyglycylation. Tyrosination-detyrosination is one of the major posttranslational modifications in which the C-terminal tyrosine residue in alpha-tubulin is added or removed reversibly. Although this modification does not alter the assembly activity of tubulin in vitro, these two forms of tubulin have been found to be distributed differently in vivo and are also correlated with microtubule stability (Gunderson, G. G., Kalnoski, M. H., and Bulinski, J. C. (1984) Cell 38, 779-789). Thus, the question arises as to whether these two forms of tubulin differ in any other modifications. In an effort to answer this question, the tyrosinated and the nontyrosinated forms of the alpha1/2 isoform have been purified from brain tubulin by immunoaffinity chromatography. matrix-assisted laser desorption/ionization-time of flight mass spectrometric analysis of the C-terminal peptide revealed that the tyrosinated form is polyglutamylated with one to four Glu residues, while the Delta2 tubulin is polyglycylated with one to three Gly residues. These results indicate that posttranslational modifications of tubulin are correlated with each other and that polyglutamylation and polyglycylation of tubulin may have important roles in regulating microtubule assembly, stability, and function in vivo.
Highlights
In addition to the existence of different genetic variations, ␣and -tubulin undergo a number of covalent modifications that include tyrosination-detyrosination (34 – 42) and deglutamylation of the ␣-tubulin C terminus or the formation of ⌬2 tubulin (␣-tubulin lacking both the Glu and the Tyr residues from the C terminus) [43] and acetylation at Lys40 [44, 45]; III-tubulin undergoes phosphorylation at a serine residue [46]; both ␣- and -tubulin undergo polyglutamylation and polyglycylation, in which glutamyl or glycyl units are attached as side chains through the ␥-carboxyl of a Glu residue near the C terminus (46 –56)
In an effort to study how different covalent modifications may contribute to the structure and function of a tubulin isoform, tubulin dimers were separated on an immunoaffinity column that contained a monoclonal antibody to tyrosinated ␣1/2 tubulin [56]
It was interesting to study the posttranslational modifications on these two fractions by MALDI-TOF analyses
Summary
1992.73 2121.78 2285.84 2056.81 2185.84 2348.89 results show that tyrosinated ␣1/2 is polyglutamylated with one to four Glu residues, the tetraglutamylated form being the predominant one. The ⌬2 form of ␣1/2 that assembles normally is polyglycylated with one to three glycyl units, the biglycylated form being the major one These results indicate that there is a correlation between tyrosination/detyrosination and deglutamylation of tubulin on one hand and polyglutamylation/polyglycylation on the other hand. Since tyrosination/detyrosination appears to play a role in microtubule stability, these results raise the possibility that polyglycylation and polyglutamylation may be involved in microtubule stability and function. These results indicate that polyglycylation is not restricted to tubulin destined to form axonemal microtubules
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