Tubulin Monoglutamylation is Sufficient to Rescue the Ciliary Motility Defects in a Chlamydomonas Polyglutamylation Deficient Mutant

The axonemes of eukaryotic cilia and flagella display high tubulin glutamylation heterogeneity, yet the functional significance of this variation remains elusive. We previously showed that long-chain polyglutamylation is crucial for ciliary motility in Chlamydomonas. However, the respective contributions of long-chain polyglutamylation versus short-chain species to motility remain unclear, as existing mutants did not allow for a clear functional dissection of these two modification states. Here, we generated mutants deficient in deglutamylases, cytosolic carboxypeptidases (CCPs) 1, 2, and 5. Importantly, CCP5 is known to remove the branch-point glutamate residue, the final step in deglutamylation. While axonemal polyglutamylation levels remained largely unaffected in these mutants, abundance of short-chain glutamylation was significantly increased in both the axonemal and cytoplasmic microtubules of ccp5-1, consistent with CCP5s role as a branch-point deglutamylase. Although each single mutant exhibited slightly reduced swimming velocity, the loss of CCP5 in the tpg1 background lacking long polyglutamate side chains resulted in a significant restoration of motility. These findings indicate that the abundance of short-chain species, regulated by CCP5, plays a distinct role in modulating ciliary motility, particularly in the absence of long polyglutamate side chains. This suggests that even minimal glutamylation can functionally support dynein-driven microtubule sliding.