KLHL13 functional defects cause neurodevelopmental disorder in humans that can be rescued via inhibition of AURKB in cellular and animal models.

Abstract

PURPOSE: Neurodevelopmental disorders (NDDs) are characterized by limitations in brain development. This study aims to determine the genetic causes of NDD in humans. METHODS: Exome sequencing was used to detect genetic variants of KLHL13, which encodes Kelch like protein 13 (KLHL13), in four families segregating in an X-linked pattern. In silico protein modeling and overexpression in heterologous cells were used to determine the variant's impact. klhl13 loss of function was modeled in zebrafish, followed by rescue studies using human KLHL13 messenger RNA (mRNA) and an Aurora Kinase B (AURKB) inhibitor. RESULTS: We found one frameshift and three missense hemizygous variants of KLHL13 in individuals exhibiting NDD characteristics, such as intellectual disability (ID) and macrocephaly. Three-dimensional protein modeling simulation predicted the alteration of the KLHL13 protein folding for missense variants. Overexpression of NDD-associated variants in HEK293T cells revealed a significant impact on KLHL13-mediated cell-cycle regulation during mitosis, leading to genomic instability. Knocking down klhl13 in zebrafish resulted in developmental deficits, which were rescued by coinjection of human KLHL13messenger RNA but not by transcript encoding NDD variants. Treatment with AURKB selective inhibitor AZD1152-HQPA rescued genomic stability in heterologous cells and neurobehavioral deficits in zebrafish. CONCLUSION: Our results implicate KLHL13-mediated AURKB regulation as a significant contributor to NDD in humans. Inhibiting AURKB activity could serve as a potential therapeutic approach to improve brain development and cognitive function.