Prevalence and Phenotypic Impact of Robertsonian Translocations.

Robertsonian translocations (RTs) result from fusion of 2 acrocentric chromosomes (e.g., 13, 14, 15, 21, 22) and consequential losses of segments of the p arms containing 47S rDNA clusters and transcription factor binding sites. Depending on the position of the breakpoints, the size of these losses vary considerably between types of RTs. The prevalence of RTs in the general population is estimated to be around 1 per 800 individuals, making RTs the most common chromosomal rearrangement in healthy individuals. Based on their prevalence, RTs are classified as "common," rob(13;14) and rob(14;21), or "rare" (the 8 remaining nonhomologous combinations). Carriers of RTs are at an increased risk for offspring with chromosomal imbalances or with uniparental disomy. RTs are generally regarded as phenotypically neutral, although, due to RTs formation, 2 of the 10 ribosomal rDNA gene clusters, several long noncoding RNAs, and in the case of RTs involving chromosome 21, several mRNA encoding genes are lost. Nevertheless, recent evidence indicates that RTs may have a significant phenotypic impact. In particular, rob(13;14) carriers have a significantly elevated risk for breast cancer. While RTs are easily spotted by routine karyotyping, they may go unnoticed if only array-CGH and NextGen sequencing methods are applied. This review first discusses possible molecular mechanisms underlying the particularly high rates of RT formation and their incidence in the general population, and second, likely causes for the elevated cancer risk of some RTs will be examined.

Genomic and functional overlap between somatic and germline chromosomal rearrangements.

Genomic rearrangements are a common cause of human congenital abnormalities. However, their origin and consequences are poorly understood. We performed molecular analysis of two patients with congenital disease who carried de novo genomic rearrangements. We found that the rearrangements in both patients hit genes that are recurrently rearranged in cancer (ETV1, FOXP1, and microRNA cluster C19MC) and drive formation of fusion genes similar to those described in cancer. Subsequent analysis of a large set of 552 de novo germline genomic rearrangements underlying congenital disorders revealed enrichment for genes rearranged in cancer and overlap with somatic cancer breakpoints. Breakpoints of common (inherited) germline structural variations also overlap with cancer breakpoints but are depleted for cancer genes. We propose that the same genomic positions are prone to genomic rearrangements in germline and soma but that timing and context of breakage determines whether developmental defects or cancer are promoted.

Constitutional chromothripsis rearrangements involve clustered double-stranded DNA breaks and nonhomologous repair mechanisms.

Chromothripsis represents a novel phenomenon in the structural variation landscape of cancer genomes. Here, we analyze the genomes of ten patients with congenital disease who were preselected to carry complex chromosomal rearrangements with more than two breakpoints. The rearrangements displayed unanticipated complexity resembling chromothripsis. We find that eight of them contain hallmarks of multiple clustered double-stranded DNA breaks (DSBs) on one or more chromosomes. In addition, nucleotide resolution analysis of 98 breakpoint junctions indicates that break repair involves nonhomologous or microhomology-mediated end joining. We observed that these eight rearrangements are balanced or contain sporadic deletions ranging in size between a few hundred base pairs and several megabases. The two remaining complex rearrangements did not display signs of DSBs and contain duplications, indicative of rearrangement processes involving template switching. Our work provides detailed insight into the characteristics of chromothripsis and supports a role for clustered DSBs driving some constitutional chromothripsis rearrangements.

Chromosomal abnormalities resembling Joubert syndrome: two cases illustrating the diagnostic pitfalls.

We describe two patients with severe developmental delay, hypotonia and breathing abnormalities initially diagnosed with the autosomal recessive Joubert syndrome (JBS) who at a later stage appeared to carry chromosomal abnormalities. One case was due to a 4.8 Mb terminal 1q44 deletion, and the other due to a 15.5 Mb duplication of Xq27.2-qter containing the MECP2 gene. Critical evaluation of the clinical data showed that, retrospectively, the cases did not fulfil the diagnostic criteria for JBS, and that the diagnosis of JBS was incorrectly made. We discuss the diagnostic pitfalls and recommend adhering strictly to the JBS diagnostic criteria in the case of a negative molecular diagnosis. Critical assessment of the MRI findings by a specialized neuroradiologist is imperative. As chromosomal abnormalities may give rise to symptoms resembling JBS, we recommend array-based screening for segmental aneuploidies as an initial genetic test in all cases with a JBS-like phenotype.

Chromothripsis as a mechanism driving complex de novo structural rearrangements in the germline.

A variety of mutational mechanisms shape the dynamic architecture of human genomes and occasionally result in congenital defects and disease. Here, we used genome-wide long mate-pair sequencing to systematically screen for inherited and de novo structural variation in a trio including a child with severe congenital abnormalities. We identified 4321 inherited structural variants and 17 de novo rearrangements. We characterized the de novo structural changes to the base-pair level revealing a complex series of balanced inter- and intra-chromosomal rearrangements consisting of 12 breakpoints involving chromosomes 1, 4 and 10. Detailed inspection of breakpoint regions indicated that a series of simultaneous double-stranded DNA breaks caused local shattering of chromosomes. Fusion of the resulting chromosomal fragments involved non-homologous end joining, since junction points displayed limited or no homology and small insertions and deletions. The pattern of random joining of chromosomal fragments that we observe here strongly resembles the somatic rearrangement patterns--termed chromothripsis--that have recently been described in deranged cancer cells. We conclude that a similar mechanism may also drive the formation of de novo structural variation in the germline.

Recombinant vitronectin is a functionally defined substrate that supports human embryonic stem cell self-renewal via alphavbeta5 integrin.

Defined growth conditions are essential for many applications of human embryonic stem cells (hESC). Most defined media are presently used in combination with Matrigel, a partially defined extracellular matrix (ECM) extract from mouse sarcoma. Here, we defined ECM requirements of hESC by analyzing integrin expression and ECM production and determined integrin function using blocking antibodies. hESC expressed all major ECM proteins and corresponding integrins. We then systematically replaced Matrigel with defined medium supplements and ECM proteins. Cells attached efficiently to natural human vitronectin, fibronectin, and Matrigel but poorly to laminin + entactin and collagen IV. Integrin-blocking antibodies demonstrated that alphaVbeta5 integrins mediated adhesion to vitronectin, alpha5beta1 mediated adhesion to fibronectin, and alpha6beta1 mediated adhesion to laminin + entactin. Fibronectin in feeder cell-conditioned medium partially supported growth on all natural matrices, but in defined, nonconditioned medium only Matrigel or (natural and recombinant) vitronectin was effective. Recombinant vitronectin was the only defined functional alternative to Matrigel, supporting sustained self-renewal and pluripotency in three independent hESC lines.

Dandy-Walker complex in a boy with a 5 Mb deletion of region 1q44 due to a paternal t(1;20)(q44;q13.33).

A 10-year-old boy with vermis hypoplasia, dilatation of the fourth ventricle, enlarged cisterna magna and aplasia of the corpus callosum, consistent with the Dandy-Walker complex (DWC), and slight facial dysmorphisms, severe motor and mental retardation is presented. By combining data obtained by karyotyping, array-CGH, FISH, and multiplex ligation-mediated probe amplification (MLPA) we identified a 5 Mb deletion of the 1q44 --> qter region resulting from a paternal t(1;20)(q44;q13.33). This smallest 1q44 deletion reported so far, enabled us to significantly narrow down the number of candidate genes for the DWC in this region. Since the ZNF124 transcription factor is strongly expressed in the fetal brain it may represent a candidate gene for the DWC at 1q44.

A familial inverted duplication 2q33-q34 identified and delineated by multiple cytogenetic techniques.

We describe a unique family with two children having a delay in psychomotor development. In both children we identified an interstitial duplication dup(2)(q34q33) using multiple, complementary molecular cytogenetic techniques. Comparative genomic hybridisation (CGH) and array-CGH were used to determine the size and the location of the duplicated region, the orientation of the duplicated region was identified with fluorescence in situ hybridisation (FISH). Both parents demonstrated a normal karyotype and normal CGH and array-CGH-profiles. However, FISH on peripheral blood cells from the mother showed the inv dup(2) in 9% of metaphases and 19% of interphase nuclei. To our knowledge this is the first report of a mosaic carrier of duplication in the long arm of chromosome 2. The finding of chromosomal mosaicism of at least 19% in the mother increases the recurrence risk. The exact characterisation of the inv dup(2) with FISH probes enabled us to offer a reliable prenatal FISH test. Comparison of the clinical features of the two children with those of previously described cases supports the hypothesis that the characteristic facial phenotype is linked to the distal part of the 2q33-q37 region. This report illustrates that in case of two sibs with an identical structural chromosomal abnormality the possibility of parental chromosomal mosaicism must be thoroughly investigated.