The I-BAR domain protein baiap2l1a is required for protrusion and lateral elongation of epithelial microridge structures

Microridges are laterally elongated membrane protrusions from the apical surface of epithelial cells. Microridges are arranged in striking maze-like patterns. They are found on various mucosal epithelia in many animals, including the skin of zebrafish, where they are required to maintain mucus on the skin surface. Recent studies have revealed molecular mechanisms of how microridiges formation involving actin and actin-regulatory proteins. However, the molecular mechanism that deforms epithelial membranes to create microridge protrusions remain unknown. We have found that one of the I-BAR domain proteins, baiap2l1a, which is known to regulate membrane curvature, is required for microridge morphogenesis. CRISPR/Cas9 knockdown showed that baiap2l1a mutant zebrafish had defects in microridge morphogenesis. Baiap2l1a mutant zebrafish had shorter and wider microridges than WT microridges. Baiap2l1a localized to microridges, and its localization proceeded microridge actin formation. Furthermore, the baiap2l1a I-BAR domain, which binds and curves membranes, was sufficient to localize to microridges in zebrafish skin cells. Structure/function experiments revealed that the I-BAR domain alone could partially rescued microridge length in baiap2l1a mutants. A 39 amino acid deletion in the I-BAR domain, which caused the loss of one -helix according to AlphaFold2 simulations, is sufficient to impair microridge localization and failed to rescue microridge elongation in baiap2l1a mutants. These results suggest that the I-BAR domain is required for baiap2l1a microridge localization and function. Eps8like1a, a member of the Eps8 family proteins known as an actin capping and bundling protein genetically interacted with baiap2l1a in microridge elongation. Together, we found that the membrane curvature protein baiap2l1a plays an important role in generating microridges in zebrafish epithelia.