The regulatory role and environmental sensitivity of DNA methylation in neurodevelopment

Abstract

The emerging field of epigenetics is expanding our understanding of how biological diversity is generated in the face of genetic limitations. One epigenetic mechanism in particular, DNA methylation, has demonstrated a dynamic range during neural development. Here, we provide evidence that DNA methylation occurs as a cell unique program aiding in the regulation of neurodevelopmental gene expression. DNA methylation has demonstrated sensitivity to external inputs ranging from stress to chemical exposure and dietary factors. To explore DNA methylation as a means of communicating early-life stress to the brain, we utilized a mouse model of fetal alcohol spectrum disorders (FASD). FASD presents a range of neurodevelopmental deficits and is a leading cause of neurodevelopmental disabilities in the United States. Predicated on the knowledge of alcohol's teratogenic role in brain development, we describe that the normal pattern of cortical DNA methylation and epigenetic correlates is similarly impacted by prenatal alcohol exposure. Due to the biochemical interaction of alcohol metabolism and the pathways regulating DNA methylation synthesis, we further investigated whether dietary manipulation could normalize the cortical DNA methylation program and aid in the protection of FASD characteristics. We found that the alcohol sensitive DNA methylation landscape is dually capable of registering dietary intervention, demonstrating normalization of disease-related patterns in the cortex and improved neurodevelopmental gene expression and morphology. Finally, we investigated the DNA methylation landscape in a crucial corticodevelopmental gene to more accurately define the breadth and scope of the environmental impacts at the nucleotide level. We found that alcohol and dietary supplementation are selective for regions associated with transcriptional control. Collectively, the evidence supports that DNA methylation plays a regulatory role in development and that its sensitivity to external inputs is dynamic and detectable at the smallest genomic level. Importantly, DNA methylation landscapes are adaptable and thus bear diagnostic and therapeutic potential.