CHD2 Dosage Ties Autolysosomal Pathway to Cortical Maturation in Disease and Evolution

The relatively slow pace of cortical development in humans has long been a topic of investigation. Studies seeking to understand the underlying mechanisms have mostly focused on neurogenetic comparisons with extant species. Here we ask if developmental tempo differences may have also existed between us and our extinct relatives for whom genomes are available. To do so, we nominate a sapiens -specific derived allele, virtually fixed in contemporary populations, which resides in an enhancer region active during early cortical development. The single nucleotide variant is predicted to significantly affect CHD2 expression, a chromatin remodeler known to play an important role in neural development and for which haploinsufficiency is associated with epilepsy and autism. We leverage patient induced pluripotent stem lines (iPSC) and engineered iPSCs in which we reintroduced the ancestral allele and generated heterozygous loss-of-function mutations. We reveal that CHD2 deficiency impairs lysosomal acidification and autophagosome flux. In contrast, ancestralized lines, which we find express higher levels of CHD2, exhibit enhanced lysosomal function and consequently accelerated autophagosome flux, consistent with our observations in chimpanzee and bonobo lines. This set of findings demonstrates that CHD2 dosage critically regulates the autolysosomal pathway. Through deep phenotyping of cortical organoid and neuron cultures, we show that the CHD2-modulated autolysosomal pathway impacts the timing of developmental programs, acquisition of neuronal functional properties and circuit maturation. Finally, we validate an estrogen-dependent rewiring of CHD2 regulation in the evolution of our lineage, providing a mechanistic understanding of how a single nucleotide variant in a regulatory region contributed to the modern pace of neuronal development and maturation. Together, our findings establish CHD2 as a regulator in setting neurodevelopmental tempo via the autolysosomal pathway.