The primordial growth disorder 3-M syndrome connects ubiquitination to the cytoskeletal adaptor OBSL1.

3-M syndrome is an autosomal-recessive primordial growth disorder characterized by significant intrauterine and postnatal growth restriction. Mutations in the CUL7 gene are known to cause 3-M syndrome. In 3-M syndrome patients that do not carry CUL7 mutations, we performed high-density genome-wide SNP mapping to identify a second locus at 2q35-q36.1. Further haplotype analysis revealed a 1.29 Mb interval in which the underlying gene is located and we subsequently discovered seven distinct null mutations from 10 families within the gene OBSL1. OBSL1 is a putative cytoskeletal adaptor protein that localizes to the nuclear envelope. We were also able to demonstrate that loss of OBSL1 leads to downregulation of CUL7, implying a role for OBSL1 in the maintenance of CUL7 protein levels and suggesting that both proteins are involved within the same molecular pathway.

Disruption of CNTNAP2 and additional structural genome changes in a boy with speech delay and autism spectrum disorder.

Patients with autism spectrum disorder (ASD) frequently harbour chromosome rearrangements and segmental aneuploidies, which allow us to identify candidate genes. In a boy with mild facial dysmorphisms, speech delay and ASD, we reconstructed by karyotyping, FISH and SNP array-based segmental aneuploidy profiling a highly complex chromosomal rearrangement involving at least three breaks in chromosome 1 and seven breaks in chromosome 7. Chromosome banding revealed an inversion of region 7q32.1-7q35 on the derivative chromosome 7. FISH with region-specific BACs mapped both inversion breakpoints and revealed additional breaks and structural changes in the CNTNAP2 gene. Two gene segments were transposed and inserted into the 1q31.2 region, while the CNTNAP2 segment between the two transposed parts as well as intron 13 to the 5-UTR were retained on the der(7). SNP array analysis revealed an additional de novo deletion encompassing the distal part of intron1 and exon 2 of CNTNAP2, which contains FOXP2 binding sites. Second, we found another de novo deletion on chromosome 1q41, containing 15 annotated genes, including KCTD3 and USH2A. Disruptions of the CNTNAP2 gene have been associated with ASD and with Gilles de la Tourette syndrome (GTS). Comparison of disruptions of CNTNAP2 in patients with GTS and ASD suggests that large proximal disruptions result in either GTS or ASD, while relatively small distal disruptions may be phenotypically neutral. For full-blown ASD to develop, a proximal disruption of CNTNAP2 may have to occur concomitantly with additional genome mutations such as hemizygous deletions of the KCTD3 and USH2A genes.

Mutations in NOTCH2 cause Hajdu-Cheney syndrome, a disorder of severe and progressive bone loss.

We used an exome-sequencing strategy and identified an allelic series of NOTCH2 mutations in Hajdu-Cheney syndrome, an autosomal dominant multisystem disorder characterized by severe and progressive bone loss. The Hajdu-Cheney syndrome mutations are predicted to lead to the premature truncation of NOTCH2 with either disruption or loss of the C-terminal proline-glutamate-serine-threonine-rich proteolytic recognition sequence, the absence of which has previously been shown to increase Notch signaling.