Identification of a DLG3 stop mutation in the MRX20 family.

Here, we identified the causal mutation in the MRX20 family, one of the larger X-linked pedigrees that have been described in which no gene had been identified up till now. In 1995, the putative disease gene had been mapped to the pericentromeric region on the X chromosome, but no follow-up studies were performed. Here, whole exome sequencing (WES) on two affected and one unaffected family member revealed the c.195del/p.(Thr66ProfsTer55) mutation in the DLG3 gene (NM_021120.4) that segregated with the affected individuals in the family. DLG3 mutations have been consequently associated with intellectual disability and are a plausible explanation for the clinical abnormalities observed in this family. In addition, we identified two other variants co-segregating with the phenotype: a stop gain mutation in SSX1 (c.358G>T/p.(Glu120Ter)) (NM_001278691.2) and a nonsynonymous SNV in USP27X (c.56 A>G/p.(Gln19Arg)) (NM_001145073.3). RNA sequencing revealed 14 differentially expressed genes (p value < 0.1) in 7 affected males compared to 4 unaffected males of the family, including four genes known to be associated with neurological disorders. Thus, in this paper we identified the c.195del/p.(Thr66ProfsTer55) mutation in the DLG3 gene (NM_021120.4) as likely responsible for the phenotype observed in the MRX20 family.

Mutations in ADNP affect expression and subcellular localization of the protein.

Truncating de novo mutations in ADNP have been identified in patients with the Helsmoortel-Van der Aa syndrome. However correlations between the distinct mutations and their impact on the protein have not been studied before. Here we report the effect of mutations in ADNP by examining the expression and subcellular localization of GFP-tagged mutant transcripts in transfected HEK293T cells. ADNP encloses a bipartite nuclear localization signal and we found mutations therein to stall the mutant protein within the cytoplasm. Using immunocytochemistry, we could demonstrate colocalization of wild-type ADNP with heterochromatin. We found mutations presenting a pattern based on the genetic position. For certain mutant proteins enrichment at pericentromeric heterochromatin seems partially lost. Finally, N-terminal truncated ADNP mutants are routed towards cytosolic proteasomal degradation and rescued with the proteasome inhibitor MG132. Our results suggest a correlation between the position of the mutations across the protein, its stability and subcellular localization.