The Koolen-de Vries syndrome (KdVS) is a multisystem syndrome with variable facial features caused by a 17q21.31 microdeletion or KANSL1 truncating variant. As the facial gestalt of KdVS has resemblan Show more
The Koolen-de Vries syndrome (KdVS) is a multisystem syndrome with variable facial features caused by a 17q21.31 microdeletion or KANSL1 truncating variant. As the facial gestalt of KdVS has resemblance with the gestalt of the 22q11.2 deletion syndrome (22q11.2DS), we assessed whether our previously described hybrid quantitative facial phenotyping algorithm could distinguish between these two syndromes, and whether there is a facial difference between the molecular KdVS subtypes. We applied our algorithm to 2D photographs of 97 patients with KdVS (78 microdeletions, 19 truncating variants (likely) causing KdVS) and 48 patients with 22q11.2DS as well as age, gender and ethnicity matched controls with intellectual disability (n = 145). The facial gestalts of KdVS and 22q11.2DS were both recognisable through significant clustering by the hybrid model, yet different from one another (p = 7.5 × 10 Show less
We show that haploinsufficiency of KANSL1 is sufficient to cause the 17q21.31 microdeletion syndrome, a multisystem disorder characterized by intellectual disability, hypotonia and distinctive facial Show more
We show that haploinsufficiency of KANSL1 is sufficient to cause the 17q21.31 microdeletion syndrome, a multisystem disorder characterized by intellectual disability, hypotonia and distinctive facial features. The KANSL1 protein is an evolutionarily conserved regulator of the chromatin modifier KAT8, which influences gene expression through histone H4 lysine 16 (H4K16) acetylation. RNA sequencing studies in cell lines derived from affected individuals and the presence of learning deficits in Drosophila melanogaster mutants suggest a role for KANSL1 in neuronal processes. Show less
Recurrent deletions have been associated with numerous diseases and genomic disorders. Few, however, have been resolved at the molecular level because their breakpoints often occur in highly copy-numb Show more
Recurrent deletions have been associated with numerous diseases and genomic disorders. Few, however, have been resolved at the molecular level because their breakpoints often occur in highly copy-number-polymorphic duplicated sequences. We present an approach that uses a combination of somatic cell hybrids, array comparative genomic hybridization, and the specificity of next-generation sequencing to determine breakpoints that occur within segmental duplications. Applying our technique to the 17q21.31 microdeletion syndrome, we used genome sequencing to determine copy-number-variant breakpoints in three deletion-bearing individuals with molecular resolution. For two cases, we observed breakpoints consistent with nonallelic homologous recombination involving only H2 chromosomal haplotypes, as expected. Molecular resolution revealed that the breakpoints occurred at different locations within a 145 kbp segment of >99% identity and disrupt KANSL1 (previously known as KANSL1). In the remaining case, we found that unequal crossover occurred interchromosomally between the H1 and H2 haplotypes and that this event was mediated by a homologous sequence that was once again missing from the human reference. Interestingly, the breakpoints mapped preferentially to gaps in the current reference genome assembly, which we resolved in this study. Our method provides a strategy for the identification of breakpoints within complex regions of the genome harboring high-identity and copy-number-polymorphic segmental duplication. The approach should become particularly useful as high-quality alternate reference sequences become available and genome sequencing of individuals' DNA becomes more routine. Show less
Amplification of 8q is frequently found in gastroesophageal junction (GEJ) cancer. It is usually detected in high-grade, high-stage GEJ adenocarcinomas. Moreover, it has been implicated in tumor progr Show more
Amplification of 8q is frequently found in gastroesophageal junction (GEJ) cancer. It is usually detected in high-grade, high-stage GEJ adenocarcinomas. Moreover, it has been implicated in tumor progression in other cancer types. In this study, a detailed genomic analysis of 8q was performed on a series of GEJ adenocarcinomas, including 22 primary adenocarcinomas, 13 cell lines and two xenografts, by array comparative genomic hybridization (aCGH) with a whole chromosome 8q contig array. Of the 37 specimens, 21 originated from the esophagus and 16 were derived from the gastric cardia. Commonly overrepresented regions were identified at distal 8q, i.e. 124-125 Mb (8q24.13), at 127-128 Mb (8q24.21), and at 141-142 Mb (8q24.3). From these regions six genes were selected with putative relevance to cancer: ANXA13, MTSS1, FAM84B (alias NSE2), MYC, C8orf17 (alias MOST-1) and PTK2 (alias FAK). In addition, the gene EXT1 was selected since it was found in a specific amplification in cell line SK-GT-5. Quantitative RT-PCR analysis of these seven genes was subsequently performed on a panel of 24 gastroesophageal samples, including 13 cell lines, two xenografts and nine normal stomach controls. Significant overexpression was found for MYC and EXT1 in GEJ adenocarcinoma cell lines and xenografts compared to normal controls. Expression of the genes MTSS1, FAM84B and C8orf17 was found to be significantly decreased in this set of cell lines and xenografts. We conclude that, firstly, there are other genes than MYC involved in the 8q amplification in GEJ cancer. Secondly, the differential expression of these genes contributes to unravel the biology of GEJ adenocarcinomas. Show less