The 2p15-p16.1 microdeletion syndrome is a novel, rare disorder characterized by developmental delay, intellectual disability, microcephaly, growth retardation, facial abnormalities, and other medical problems. We report here on an 11-year-old female showing clinical features consistent with the syndrome and carrying a de novo 0.45 Mb long deletion of the paternally derived 2p16.1 allele. The deleted region contains only three protein-coding RefSeq genes, BCL11A, PAPOLG, and REL, and one long non-coding RNA gene FLJ16341. Based on close phenotypic similarities with six reported patients showing typical clinical features of the syndrome, we propose that the critical region can be narrowed down further, and that these brain expressed genes can be considered candidates for the features seen in this microdeletion syndrome.
Kabuki syndrome (KS) is a dominantly inherited disorder mainly due to de novo pathogenic variation in KMT2D or KDM6A genes. Initially, a representative cohort of 14 Czech cases with clinical features suggestive of KS was analyzed by experienced clinical geneticists in collaboration with other specialties, and observed disease features were evaluated according to the 'MLL2-Kabuki score' defined by Makrythanasis et al. Subsequently, the aforementioned genes were Sanger sequenced and copy number variation analysis was performed by MLPA, followed by genome-wide array CGH testing. Pathogenic variants in KMT2D resulting in protein truncation in 43% (6/14; of which 3 are novel) of all cases were detected, while analysis of KDM6A was negative. MLPA analysis was negative in all instances. One female patient bears a 6.6 Mb duplication of the Xp21.2-Xp21.3 region that is probably disease causing. Subjective KS phenotyping identified predictive clinical features associated with the presence of a pathogenic variant in KMT2D. We provide additional evidence that this scoring approach fosters prioritization of patients prior to KMT2D sequencing. We conclude that KMT2D sequencing followed by array CGH is a diagnostic strategy with the highest diagnostic yield.
Analyses at nucleotide resolution reveal unexpected complexity of seemingly simple and balanced chromosomal rearrangements. Chromothripsis is a rare complex aberration involving local shattering of one or more chromosomes and reassembly of the resulting DNA segments. This can influence gene expression and cause abnormal phenotypes. We studied the structure and mechanism of a seemingly balanced de novo complex rearrangement of four chromosomes in a boy with developmental and growth delay. Microarray analysis revealed two paternal de novo deletions of 0.7 and 2.5 Mb at two of the breakpoints in 1q24.3 and 6q24.1-q24.2, respectively, which could explain most symptoms of the patient. Subsequent whole-genome mate-pair sequencing confirmed the chromothriptic nature of the rearrangement. The four participating chromosomes were broken into 29 segments longer than 1 kb. Sanger sequencing of all breakpoint junctions revealed additional complexity compatible with the involvement of different repair pathways. We observed translocation of a 33 bp long DNA fragment, which may have implications for the definition of the lower size limit of structural variants. Our observations and literature review indicate that even very small fragments from shattered chromosomes can be detected and handled by the repair machinery during germline chromothriptic chromosome reassembly.
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