Cytosolic Carboxypeptidase 5 maintains mammalian ependymal multicilia to ensure proper homeostasis and functions of the brain

Ependymal multicilia position at one-side on the cell surface and beat synchronously across tissue to propel the flow of cerebrospinal fluid. Loss of ependymal cilia often causes hydrocephalus. However, molecules contributing to their maintenance remain yet fully revealed. Cytosolic carboxypeptidase (CCP) family are erasers of polyglutamylation, a conserved posttranslational modification of ciliary-axoneme microtubules. CCPs possess a unique domain (N-domain) N-terminal to their carboxypeptidase (CP) domain with unclear function. Here, we show that a novel mutant mouse of Agbl5 , the gene encoding CCP5, with deletion of its N-terminus and partial CP domain (designated Agbl5 ^M1/M1 ), developed lethal hydrocephalus due to degeneration of ependymal multicilia. Interestingly, multiciliogenesis was not impaired in Agbl5 ^M1/M1 ependyma. The initially formed multicilia beat at a normal frequency, but in intercellularly diverse directions, indicative of aberrant tissue-level coordination. Moreover, actin networks are severely disrupted and basal body patches are improperly displaced in mutant cells, suggesting impaired cell polarity. In contrast, Agbl5 mutants with disruption solely in the CP domain of CCP5 ( Agbl5 ^M2/M2 ) do not develop hydrocephalus despite increased glutamylation levels in ependymal cilia as similarly seen in Agbl5 ^M1/M1 . This study revealed an unappreciated role of CCP5, particularly its N-domain, in ependymal multicilia stability associated with their polarization and coordination.