Dynein-2 is tuned for the A-tubule of the ciliary doublet through tubulin tyrosination

Eukaryotic cilia and flagella are thin structures present on the surface of cells, playing vital roles in signaling and cellular motion. Cilia structures rely on intraflagellar transport (IFT), which involves dynein-2 for retrograde and kinesin-2 for anterograde movements along doublet microtubules. Unlike dynein-1, which works on singlet microtubules within the cytoplasm, dynein-2 specifically works on the doublet microtubules inside the cilia. Previous cryo-electron tomography studies have shown that retrograde IFT, driven by dynein-2, occurs on the A-tubule of the doublet, suggesting a specialized regulatory mechanism involving dynein-2. However, the molecular basis of this specificity remains unclear. Here, we investigated this mechanism using cryo-electron tomography (cryo-ET) with Volta Phase Plate (VPP), molecular dynamics (MD) simulations, and biochemical analysis. Our biochemical assay revealed that the microtubule-binding domain of dynein-2 exhibits a higher affinity for the ciliary doublet microtubule compared to dynein-1. Cryo-ET with VPP further visualized the preferential binding of dynein-2 to the A-tubule of the doublet microtubule. MD simulations suggest that the preferential binding of dynein-2 is attributed to the tyrosinated tubulin in the A-tubule. These findings uncover a tyrosination-dependent regulatory mechanism that governs the bidirectional transport of IFT on doublet microtubules, providing new insights into the spatial and functional specialization of ciliary transport systems.