C ongenital heart defects (CHD) are the most common congenital malformations with an incidence of 0.5% to 1% of live births.1 They also are the first cause of mortality during the first year of life of newborns in developed countries.2 Despite therapeutic advances, CHD are associated with a high proportion of long term morbidity. Among CHD, a large subset involves the outflow tract (OFT). This heterogeneous group of malformations represents 20% to 30% of the CHD diagnosed in newborns.3 Transposition of the great arteries (TGA) accounts for 5% to 7% of all CHD 4 and is one of the most common cyanotic disorder diagnosed in the neonatal period with a prevalence of 0.2 per 1000 live births. The most common form of TGA is the dextro-looped type, which consists in a discordant ventriculoarterial connection implying that the aorta incorrectly arises from the right ventricle in an anterior and right-sided position, whereas the pulmonary artery incorrectly arises from the left ventricle in a posterior and left-sided position. By contrast to the normal heart in which both OFTs and great vessels show a dextral (right handed) spiralization, the great vessels in TGA present with a parallel course lacking normal spiralization. Coarctation Background-Congenital heart defects are the most frequent malformations among newborns and a frequent cause of morbidity and mortality. Although genetic variation contributes to congenital heart defects, their precise molecular bases remain unknown in the majority of patients. Methods and Results-We analyzed, by high-resolution array comparative genomic hybridization, 316 children with sporadic, nonsyndromic congenital heart defects, including 76 coarctation of the aorta, 159 transposition of the great arteries, and 81 tetralogy of Fallot, as well as their unaffected parents. We identified by array comparative genomic hybridization, and validated by quantitative real-time polymerase chain reaction, 71 rare de novo (n=8) or inherited (n=63) copy-number variants (CNVs; 50 duplications and 21 deletions) in patients. We identified 113 candidate genes for congenital heart defects within these CNVs, including BTRC, CHRNB3, CSRP2BP, ERBB2, ERMARD, GLIS3, PLN, PTPRJ, RLN3, and TCTE3. No de novo CNVs were identified in patients with transposition of the great arteries in contrast to coarctation of the aorta and tetralogy of Fallot (P=0.002; Fisher exact test). A search for transcription factor binding sites showed that 93% of the rare CNVs identified in patients with coarctation of the aorta contained at least 1 gene with FOXC1-binding sites. This significant enrichment (P<0.0001; permutation test) was not observed for the CNVs identified in patients with transposition of the great arteries and tetralogy of Fallot. We hypothesize that these CNVs may alter the expression of genes regulated by FOXC1. Foxc1 belongs to the forkhead transcription factors family, which plays a critical role in cardiovascular development in mice. Conclusions-These data suggest that deregulation of FOXC1 or its downstream ge...
Heterozygous loss-of-function coding-sequence mutations of the transcription factor SOX9 cause campomelic dysplasia, a rare skeletal dysplasia with congenital bowing of long bones (campomelia), hypoplastic scapulae, a missing pair of ribs, pelvic, and vertebral malformations, clubbed feet, Pierre Robin sequence (PRS), facial dysmorphia, and disorders of sex development. We report here two unrelated families that include patients with isolated PRS, isolated congenital heart defect (CHD), or both anomalies. Patients from both families carried a very similar ∼1 Mb deletion upstream of SOX9. Analysis of ChIP-Seq from mouse cardiac tissue for H3K27ac, a marker of active regulatory elements, led us to identify several putative cardiac enhancers within the deleted region. One of these elements is known to interact with Nkx2.5 and Gata4, two transcription factors responsible for CHDs. Altogether, these data suggest that disruption of cardiac enhancers located upstream of SOX9 may be responsible for CHDs in humans.
The HoxD cluster is critical for vertebrate limb development. Enhancers located in both the telomeric and centromeric gene deserts flanking the cluster regulate the transcription of HoxD genes. In rare patients, duplications, balanced translocations or inversions misregulating HOXD genes are responsible for mesomelic dysplasia of the upper and lower limbs. By aCGH, whole-genome mate-pair sequencing, long-range PCR and fiber fluorescent in situ hybridization, we studied patients from two families displaying mesomelic dysplasia limited to the upper limbs. We identified microduplications including the HOXD cluster and showed that microduplications were in an inverted orientation and inserted between the HOXD cluster and the telomeric enhancers. Our results highlight the existence of an autosomal dominant condition consisting of isolated ulnar dysplasia caused by microduplications inserted between the HOXD cluster and the telomeric enhancers. The duplications likely disconnect the HOXD9 to HOXD11 genes from their regulatory sequences. This presumptive loss-offunction may have contributed to the phenotype. In both cases, however, these rearrangements brought HOXD13 closer to telomeric enhancers, suggesting that the alterations derive from the dominant-negative effect of this digit-specific protein when ectopically expressed during the early development of forearms, through the disruption of topologically associating domain structure at the HOXD locus.
Congenital heart defect (CHD) is the leading malformation among newborns. However, its genetic basis remains mostly unknown. We report a child with transposition of the great arteries, ventricular septal defect, and coarctation of the aorta. By array comparative genomic hybridization, we identified a duplication of the 5' half of semaphorin3D (SEMA3D). Breakpoint sequencing and fiber fluorescent in situ hybridization showed tandem duplication. Expression studies showed a higher level of SEMA3D mRNA in patient's lymphoblasts versus controls. Moreover, we demonstrated the presence of a truncated SEMA3D poly-A tailed mRNA, resulting from an abnormal transcription of SEMA3D partial duplication. Sema3D is an axon guidance protein essential for the correct migration of cardiac neural crest cells (CNCC) into the outflow tract. Sema3D(-/-) mice present with CHD but its role in humans remains unclear. Our results suggest that truncated SEMA3D may have hampered the migration of CNCC during heart development, contributing to patient's CHD.
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