Microcephaly-Associated Genes asp and Sas4 Control Chromatin Organization and Nuclear Lamina Structure in Drosophila melanogaster

Autosomal recessive primary microcephaly (MCPH) is a neurodevelopmental disorder characterized by reduced brain size and non-progressive intellectual disability. Mutations in over 30 genes have been linked to MCPH. Nearly a half of the genes identified by these mutations encode proteins involved in centrosome biogenesis or microtubule (MT) dynamics, suggesting a central role for mitotic spindle organization and division plane orientation in disease aetiology. However, it has been suggested that disruptions in spindle positioning alone are not sufficient to lead to microcephaly. Here, we investigate the contribution of the Drosophila orthologs of ASPM / MCPH5 ( asp ) and CENPJ/MCPH6 ( Sas4 ) to nuclear architecture, chromatin organization, and genome stability. We show that loss of either Sas4 or Asp leads to aberrant microtubule architecture, mislocalization of the LINC complex, and deformation of the nuclear lamina. These defects are accompanied by reduced levels of both lamin and HP1α and impaired centromere clustering in interphase cells. Sas4 and asp mutants also exhibit a global reduction in heterochromatin-associated histone marks (H3K9me2/3 and H3K27me3) and increased levels of the euchromatin-associated mark H3K4me3. Remarkably, treatment with Methylstat, a demethylase inhibitor, reduced nuclear invaginations by partially restoring H3K9me3 levels. Additionally, Sas4 or Asp depletion leads to DNA damage, increased sensitivity to genotoxic stress, and delayed DNA repair.

Together, these findings reveal a previously underappreciated role for Asp and Sas4 in preserving nuclear architecture and chromatin integrity, offering new insight into the pathogenesis of MCPH.