Molecular characterization of the heterozygous loss of function mutations in the X-linked PCDH19 gene causing PCDH19-Cluster Epilepsy

PCDH19-Cluster Epilepsy (PCDH19-CE) is a rare neurological disorder caused by mutations in the PCDH19 (Protocadherin-19) gene and is characterized by early-onset seizures and cognitive impairment. In contrast to most X-linked disorders, PCDH19 mutations predominantly affect heterozygous females, while hemizygous males are largely spared. Although advances have been made to understand the pathological mechanism underlying PCDH19-CE, key downstream targets and compensatory pathways are yet to be elucidated. Using CRISPR/Cas9 technology, we generated both a mouse model of PCDH19-CE and a human embryonic stem cell (ESC) model. Transcriptomic analysis identified genes that were differentially expressed in the brains of heterozygous (Pcdh19WT/mut) female mice compared with wildtype (WT) and homozygous (Pcdh19mut/mut) female mice. Pathway analysis of these differentially expressed genes (DEGs) revealed enrichment in pathways involved in neuronal development, ion channel activity, synaptic development and neuronal signalling. Neurons differentiated from human ESCs carrying a PCDH19 mutation exhibited similar gene expression patterns, with heterozygous neurons displaying a distinct expression pattern compared to both WT and homozygous mutant neurons. In contrast to the molecular phenotype, neurons derived from homozygous mutant cells showed highly elongated neurites while neurons from heterozygous cells showed intermediate neurite elongation. This suggests that neurite morphology correlates directly with levels of WT PCDH19. Overall, our findings indicate that heterozygous PCDH19 mutations are associated with defects in the expression of genes involved in developmental, signalling, and neuronal pathways in both mouse and human disease models, while certain morphological phenotypes appear to depend on the levels of WT PCDH19.