Tubulin post-translational modifications generate microtubule heterogeneity and modulate microtubule function, and are catalyzed by tubulin tyrosine ligase-like (TTLL) proteins. Using antibodies specific to monoglycylated, polyglycylated, and glutamylated tubulin in whole mount immunostaining of zebrafish embryos, we observed distinct, tissue-specific patterns of tubulin modifications. Tubulin modification patterns in cilia correlated with the expression of ttll3 and ttll6 in ciliated cells. Expression screening of all zebrafish tubulin tyrosine ligase-like genes revealed additional tissue-specific expression of ttll1 in brain neurons, ttll4 in muscle, and ttll7 in otic placodes. Knockdown of ttll3 eliminated cilia tubulin glycylation but had surprisingly mild effects on cilia structure and motility. Similarly, knockdown of ttll6 strongly reduced cilia tubulin glutamylation but only partially affected cilia structure and motility. Combined loss of function of ttll3 and ttll6 caused near complete loss of cilia motility and induced a variety of axonemal ultrastructural defects similar to defects previously observed in zebrafish fleer mutants, which were shown to lack tubulin glutamylation. Consistently, we find that fleer mutants also lack tubulin glycylation. These results indicate that tubulin glycylation and glutamylation have overlapping functions in maintaining cilia structure and motility and that the fleer/ dyf-1 TPR protein is required for both types of tubulin posttranslational modification.Glycylation and glutamylation are post-translational modifications of tubulin subunits within stable microtubules of cilia, centrioles, neuronal axons, and mitotic spindles (1-3). Variable lengths of added glycyl or glutamyl side chains generate diverse tubulin subtypes and contribute to heterogeneity of tubulin function by modulating microtubule-protein interactions (2, 4, 5). For instance, glutamyl side chain length has been shown to differentially affect recruitment of the microtubule-associated proteins MAP1A and MAP2 (6), and to selectively enhance KIF1A-dependent vesicle transport in hippocampal neurons (7). In vertebrates, glutamylated tubulin is associated with cilia and neuronal axons, whereas glycylated tubulin is primarily localized to cilia (8 -11). Both modifications occur on an overlapping set of glutamates near the tubulin C terminus (3, 12, 13). Deletion of the -tubulin C terminus is lethal in Tetrahymena and generates non-motile, short cilia lacking a portion of the microtubule doublet B-subfiber (14 -16). Drosophila mutants lacking the -tubulin C terminus fail to assemble sperm axonemes, whereas cytoplasmic microtubules are not affected (17, 18). Axonemal B-subfiber defects and reduced cilia beat amplitude are also observed in the zebrafish fleer mutant, which lacks a TPR protein required for cilia polyglutamylation (19), as well as in Tetrahymena overexpressing the tubulin glutamylase, TTLL6Ap (20,21). Evidence for a role for tubulin glycylation in cilia elongation in zebrafish has recently been re...
