In-frame deletion of SPECC1L microtubule binding domain results in embryonic tissue movement and fusion defects

Embryonic morphogenesis of the neural tube, palate, ventral body wall and optic fissure require precise sequence of tissue movement and fusion, which if incomplete, leads to anencephaly/exencephaly, cleft palate, omphalocele and coloboma, respectively. These are genetically heterogeneous birth defects, so there is a continued need to identify etiologic genes. Patients with autosomal dominant SPECC1L mutations show syndromic malformations, including hypertelorism, cleft palate and omphalocele. These SPECC1L mutations cluster in the second coiled-coil domain (CCD2), which facilitates association with microtubules. To study SPECC1L function in mice, we first generated a null allele ( Specc1lΔEx4 ) lacking the entire SPECC1L protein. Homozygous mutants for these truncations died perinatally without cleft palate or exencephaly. Given the clustering of human mutations in CCD2, we hypothesized that targeted perturbation of CCD2 may be required. Indeed, homozygotes for in-frame deletions involving CCD2 ( Specc1lΔCCD2 ) resulted in ~50% exencephaly and ~50% cleft palate. Interestingly, these two phenotypes are never observed in the same embryo. Examination of embryos with and without exencephaly revealed that the oral cavity was narrower in exencephalic embryos, which allowed palatal shelves to elevate despite their defect. In contrast to an evenly distributed subcellular expression pattern, mutant SPECC1L-ΔCCD2 protein showed abnormal subcellular localization, decreased overlap with microtubules, increased actin bundles, and dislocated non-muscle myosin II to the cell cortex. Thus, we show that perturbations of CCD2 in the context of full SPECC1L protein affects tissue fusion dynamics, indicating that human SPECC1L CCD2 mutations are gain-of-function. Improper SPECC1L subcellular localization appears to disrupt connections between actomyosin and microtubule networks, which in turn may affect cell alignment and coordinate movement during tissue morphogenesis. ### Competing Interest Statement The authors have declared no competing interest.