272 Integrative Genomics Implicates Primary Impact on Cortical Development in Spina Bifida

Abstract

INTRODUCTION: Spina bifida is one of the most common malformation of the central nervous system that is associated with poor neurodevelopmental outcomes. Altered neurodevelopment in spina bifida has been attributed to venting of CSF through the neural tube defect. Despite correction of the spinal defect, some patients still develop hydrocephalus with poor neurodevelopmental outcomes, suggesting incomplete understanding of disease pathogenesis. Recent human genetic efforts have identified candidate genes that confer spina bifida risk, however, the mechanisms linking gene mutations to altered neurodevelopment remain poorly understood. METHODS: We curated a list of 439 genes that confer risk to spina bifida from a whole-genome sequencing study of 310 individuals. We then mapped the spatiotemporal and cell-type specific expression of these risk genes onto bulk and single-cell RNA sequencing data of normally developing human brains covering the entire lifespan of human development. RESULTS: We found that spina bifida risk genes are enriched at post-conception weeks 5-6 and 25-38 in the developing human brain. After birth, spina bifida risk genes are enriched at postnatal months 6-10 and then after 60 years of age. At the cell type level, spina bifida risk genes are enriched in proliferative neuroprogenitor cells and microglia in the prenatal human cortex. CONCLUSIONS: Our analyses show that spina bifida risk genes are expressed in the developing human brain, suggesting a primary impact on brain development that is independent from the open caudal end of the neural tube defect. The finding that spina bifida risk genes continue to be expressed postnatally suggests a window for therapeutic intervention to optimize neurodevelopmental outcomes after birth in at least a subset of patients.