Detection of genomic imbalances by array based comparative genomic hybridisation in fetuses with multiple malformations.

BACKGROUND: Malformations are a major cause of morbidity and mortality in full term infants and genomic imbalances are a significant component of their aetiology. However, the causes of defects in many patients with multiple congenital malformations remain unexplained despite thorough clinical examination and laboratory investigations. METHODS: We used a commercially available array based comparative genomic hybridisation method (array CGH), able to screen all subtelomeric regions, main microdeletion syndromes, and 201 other regions covering the genome, to detect submicroscopic chromosomal imbalances in 49 fetuses with three or more significant anomalies and normal karyotype. RESULTS: Array CGH identified eight genomic rearrangements (16.3%), all confirmed by quantitative multiplex PCR of short fluorescent fragments. Subtelomeric and interstitial deletions, submicroscopic duplications, and a complex genomic imbalance were identified. In four de novo cases (15qtel deletion, 16q23.1-q23.3 deletion, 22q11.2 deletion, and mosaicism for a rearranged chromosome 18), the genomic imbalance identified clearly underlay the pathological phenotype. In one case, the relationship between the genotype and phenotype was unclear, since a subtelomeric 6q deletion was detected in a mother and her two fetuses bearing multiple malformations. In three cases, a subtelomeric 10q duplication, probably a genomic polymorphism, was identified. CONCLUSIONS: The detection of 5/49 causative chromosomal imbalances (or 4/49 if the 6qtel deletion is not considered as causative) suggests wide genome screening when standard chromosome analysis is normal and confirms that array CGH will have a major impact on pre and postnatal diagnosis as well as providing information for more accurate genetic counselling.

Prenatal diagnosis of a cleidocranial dysplasia-like phenotype associated with a de novo balanced t(2q;6q)(q36;q16) translocation.

Cleidocranial dysplasia (CCD) is a congenital disorder of bone development characterized by persistently open or delayed closure of cranial sutures and wormian bones, hypoplastic and/or aplastic clavicles, wide pubic symphysis, dental anomalies and short stature. The condition is inherited as an autosomal-dominant trait and the human CBFA1 gene has been identified as the CCD gene. We describe a prenatal form of the skeletal disorder that included clavicular hypoplasia, absence of ossification of the cranial parietal bones and very poor ossification of the frontal and pubic bones. Growth restriction affecting only the long bones was also noted. The fetal karyotype revealed an apparently de novo balanced t(2q;6q)(q36;q16) translocation. This particular form of skeletal disorder associated with the absence of family history and an apparently de novo balanced translocation led the parents to opt for termination of the pregnancy.

Prenatal diagnosis of sacrococcygeal teratoma with constitutional partial monosomy 7q/trisomy 2p.

We report the prenatal diagnosis of a fetus with sacrococcygeal teratoma and facial dysmorphism attributed to a constitutional terminal deletion of chromosome 7q and partial trisomy of chromosome 2p likely resulting from a de novo balanced translocation. The cytogenetic abnormality was diagnosed prenatally after sonographic detection of teratoma and confirmed on peripheral blood cells at birth. The newborn died of post-operative complications at seven days of age. FISH analysis demonstrated haploinsufficiency of HLXB9, a gene identified in the triad of a presacral mass (teratoma or anterior meningocele), sacral agenesis, and anorectal malformation, which constitutes the Currarino syndrome. Despite the absence of other features of the triad, the teratoma observed in the fetus we describe might represent a partial form of Currarino syndrome.

Prenatal diagnosis of a small supernumerary, XIST-negative, mosaic ring X chromosome identified by fluorescence in situ hybridization in an abnormal male fetus.

Marker or ring X [r(X)] chromosomes of varying size are often found in patients with Turner syndrome. Patients with very small r(X) chromosomes that did not include the X-inactivation locus (XIST) have been described with a more severe phenotype. Small r(X) chromosomes are rare in males and there are only five previous reports of such cases. We report the identification of a small supernumerary X chromosome in an abnormal male fetus. Cytogenetic analysis from chorionic villus sampling was performed because of fetal nuchal translucency thickness and it showed mosaicism 46,XY/47,XY,+r(X)/48,XY,+r(X),+r(X). Fluorescence in situ hybridizations (FISH) showed the marker to be of X-chromosome origin and not to contain the XIST locus. Additional specific probes showed that the r(X) included a euchromatic region in proximal Xq. At 20 weeks gestation, a second ultrasound examination revealed cerebral abnormalities. After genetic counselling, the pregnancy was terminated. The fetus we describe is the first male with a mosaic XIST-negative r(X) chromosome identified at prenatal diagnosis. The phenotype we observed was probably the result of functional disomy of the genes in the r(X) chromosome, secondary to loss of the XIST locus.

French multi-centric study of 2000 amniotic fluid interphase FISH analyses from high-risk pregnancies and review of the literature.

This prospective and multi-centric study confirms the accuracy and the limitations of interphase FISH and shows that any cytogenetics laboratory can perform this technique. With regard to the technical approach, we think that slides must be examined by two investigators, because the scoring may be subjective. The main problem with the AneuVysion kit concerns the alpha satellite probes, and especially the chromosome 18 probe, which is sometimes very difficult to interpret because of the high variability of the size of the spots, and this may lead to false negative and uninformative cases. The best solution would be to replace these probes by locus-specific probes. Concerning clinical management, we offer interphase FISH only in very high-risk pregnancies or/and at late gestational age because of the cost of the test. We think that an aberrant FISH result can be used for a clinical decision when it is associated with a corresponding abnormal ultrasound scan. In other cases, most of the time, we prefer to wait for the standard karyotype.

Familial congenital pulmonary lymphangectasia, non-immune hydrops fetalis, facial and lower limb lymphedema: confirmation of Njolstad's report.

We report on four cases, three familial and one sporadic, with congenital pulmonary lymphangectasia and facial and lower limb lymphedema. Hydrops fetalis was observed in three cases and death occurred in one of those. This is the third report describing inherited pulmonary lymphangectasia with a clinical phenotype very similar to that described by Njolstad et al. [1998: Eur J Pediatr 157: 498-501], who reported three sibs with non-immune hydrops fetalis (NIHF), chylothorax, pulmonary lymphangectasia, distal lymphedema, and swelling of the face. We think that the present report and that of Njolstad et al. describe a new condition very similar to Hennekam syndrome, which is characterized by autosomal recessive inheritance, intestinal lymphangiectasia, lymphedema of the lower limbs and facial anomalies (flat face, hypertelorism, flat, broad nasal bridge, lymphedema, tooth anomalies, and ear defects). Similarity with our cases and Hennekam syndrome will be discussed.

Characterization of two add(4qter) chromosomes by comparative genomic hybridization.

We describe the combined use of comparative genomic hybridization (CGH) and fluorecence in situ hybridization (FISH) to identify the origin of de novo unbalanced translocations in a fetus with abnormalities on ultrasound examination and in a newborn with multiple congenital abnormalities. RHG banding of amniocytes and lymphocytes respectively showed a unbalanced karyotype: 46,XX,add(4)(q34), with normal parental karyotypes in both cases. CGH revealed a gain of material from distal 15q (q23qter) in the fetus and a gain of distal 7q (q31qter) in the newborn. CGH results were confirmed using FISH with painting probes in both cases. These cases demonstrate the efficiency of CGH in identifying the chromosomal origin of extramaterial in unbalanced de novo translocations.