Phosphoinositide lipids have bidirectional and spatially distinct roles in filopodial dynamics

Neural circuits are assembled by filopodia, dynamic actin-rich protrusions that connect environment sensing with structural changes. Using rapid timelapse imaging and acute pharmacological perturbation in Xenopus laevis retinal ganglion cells, we reveal that phosphoinositide lipid conversions impose spatially distinct control over filopodial dynamics. The class I phosphoinositide 3-kinase (PI3K) inhibitor alpelisib and Oculocerebrorenal syndrome of Lowe protein/Inositol polyphosphate 5-phosphatase inhibitor YU142670 markedly reduced filopodial tip motility. Class II PI3K inhibitor PITCOIN4 and YU142670 curtailed base dynamics, indicating location-specific lipid requirements. Despite no detectable change in PI(4,5)P ₂ , both alpelisib and YU142670 depleted PI(3,4)P ₂ at filopodial tips. Their co-application was non-additive, with partial alleviation of YU142670-induced stalling by alpelisib, consistent with networked control of lipid conversion and actin remodelling. Live imaging with a TAPP1-3xcPH probe combined with quantitative cross-correlation and Granger causality analysis showed that PI(3,4)P ₂ at filopodial tips both generates tip extension and responds to forward filopodial movement. Disrupting actin polymerisation rapidly erased tip PI(3,4)P ₂ prior to filopodial stalling. These findings define a vulnerable node with implications for neurodevelopmental miswiring.