Microtubule deacetylation drives kinesin-1 mediated mitochondrial transport accelerating breast cancer cell migration

Mitochondrial trafficking is reprogrammed in metastatic breast cancer cells to sustain their migratory and invasive behavior. Mitochondria repositioning to sites of high energy demand is governed by a balance between opposing dynein and kinesin-1 (KIF5B) molecular motors whose regulation remains incompletely understood. Here, we identify the SYBU gene as a candidate prognostic marker downregulated in metastatic disease. SYBU encodes syntabulin, a mitochondria outer membrane protein that interacts with dynein to counterbalance KIF5B-dependent anterograde transport to the cell cortex. Loss of SYBU disrupts the balance, causing excessive KIF5B-driven mitochondria movement, microtubule damage and deacetylation. In turn, microtubule deacetylation reinforces KIF5B-mediated transport, creating a positive feedback loop that drives mitochondria distribution close to the cell periphery and enhances cancer cell migration. Pharmacological inhibition of the tubulin deacetylase HDAC6 restores mitochondrial positioning and reduces cell migration in SYBU -deficient cells. Our findings identify SYBU as a key regulator of mitochondrial trafficking and pave the way to personalized therapeutic approaches for metastatic breast tumors with low SYBU expression.