Effects of deletion and duplication in a patient with a 46,XX,der(7)t(7;17)(q36;p13)mat karyotype

Exact breakpoint determination by DNA-array has dramatically improved the analysis of genotype-phenotype correlations in chromosome aberrations. It allows a more exact definition of the most relevant genes and particularly their isolated or combined impact on the phenotype in an unbalanced state. Here, we report on a 21-year-old female with severe growth retardation, severe intellectual disability, hypoplasia of the corpus callosum, unilateral sacral hypoplasia, tethered cord, various minor facial dysmorphisms, and a telomeric deletion of about 4.4 Mb in 7q36.2->qter combined with a telomeric duplication of about 8 Mb in 17pter->p13.1. Fine mapping was achieved with the Illumina® Infinium HumanOmni1-Quad v1.0 BeadChip. Most of the major clinical features correspond to the well-known effects of haploinsufficiency of the MNX1 and SHH genes. In addition, review of the literature suggests an association of the 17p duplication with specific facial dysmorphic features and skeletal anomalies, but also an aggravating effect of the duplication-deletion for severe growth retardation as well as sacral and corpus callosum hypoplasia by one or more genes located on the proximal half of the segmental 17p duplication could be elaborated by comparison with other patients from the literature carrying either the deletion or the duplication found in our patient

Intronic mutations in the L1CAM gene may cause X-linked hydrocephalus by aberrant splicing

L1 disease is a clinically heterogeneous X-chromosomal neurodevelopmental disorder that is frequently associated with mental retardation and congenital hydrocephalus in males. It is caused by mutations in L1CAM that encodes a multifunctional transmembrane neuronal cell adhesion molecule. We report our findings on 6 novel intronic L1CAM sequence variants (c.523+5G>A, c.1123+1G>A, c.1547-13delC, c.3323-17dupG, c.3457+3A>T, and c.3457+18C>T), and a recurrent one (c.523+12C>T). While the pathogenic potential of nucleotide changes within the evolutionarily well-conserved splice consensus sequence (c.523+5G>A, c.1123+1G>A, and c.3457+3A>T) is widely accepted, it is not always straight forward to assess the disease relevance of intronic mutations, if they lie outside the consensus. The c.523+12C>T variant co-segregated with X-linked hydrocephalus in two unrelated families. In the mutated allele, a preferentially used novel splice donor site is generated that results in a frame shift due to insertion of the first 10 bp of intron 5 in the mature mRNA, a largely truncated protein, and most likely a functional null allele. The c.1547-13delC mutation creates a new acceptor site resulting in the insertion of 4 additional amino acids at the end of the immunoglobulin like domain 5. In contrast, c.3323-17dupG and c.3457+18C>T seem to be non-pathogenic L1CAM variants

Subtelomere FISH in 50 children with mental retardation and minor anomalies, identified by a checklist, detects 10 rearrangements including a de novo balanced translocation of chromosomes 17p13.3 and 20q13.33

Submicroscopic or subtle aneusomies at the chromosome ends, typically diagnosed by subtelomere fluorescence in situ hybridization (FISH), are a significant cause of idiopathic mental retardation (MR). Some 20 subtelomere studies, including more than 2,500 subjects, have been reported. The studies are not directly comparable because different techniques and patient ascertainment criteria were used, but an analysis of 14 studies showed that aberrations were detected in 97 out of 1,718 patients (5.8%, range 2-29%; 95% confidence interval (CI) 4.60-6.84%). We performed a subtelomere FISH study of 50 unrelated children ascertained by a checklist that evaluates MR or developmental delay, dysmorphism, growth defect, and abnormal pedigree and found 10 bona fide causal rearrangements (detection rate 20%, 95% CI 10-33.7%). The findings included five unbalanced familial translocations or inversions, two unbalanced de novo translocations, and two de novo deletions. Patient 5 showed multiple anomalies (large head, vision defect, omphalocele, heart defect, enlarged kidneys, moderate MR, speech defect, mild transient homocysteinemia) and a de novo balanced translocation of chromosomes 17p13.3 and 20q13.33. The report of a subtelomeric balanced rearrangement associated with a disease phenotype is a novel one. FISH mapping using panels of overlapping BAC clones identified a number of candidate genes at or near his breakpoints, including ASPA, TRPV3, TRPV1, and CTNS at 17p13.3, and three genes of unknown function at 20q13.33. Only the homocysteinemia could be speculatively linked to one of these genes (CTNS, the gene for cystinosis). Three within the subset of 16 children (18.8%) with mild (IQ, 50-69) or unspecified degree of MR tested positive, suggesting that the checklist approach could be especially useful within this group of patients

Pre- and postnatal findings in trisomy 17 mosaicism

Trisomy 17 mosaicism is one of the rarest autosomal trisomies in humans. Thus far, only 23 cases have been described, most of them detected prenatally. In only five instances has mosaicism been demonstrated in lymphocytes and/or fibroblasts postnatally, and only in these have multiple congenital anomalies (MCA), facial dysmorphisms, and mental retardation been reported. Patients with trisomy 17 mosaicism at amniocentesis and a normal karyotype in blood and fibroblasts (n = 17) were always healthy. Here, we report on pre- and postnatal clinical, cytogenetic, molecular-cytogenetic, and molecular findings in four patients with trisomy 17 mosaicism. The first case was detected in cultured but not in short-term chorionic villi and amniocytes. Due to MCA on prenatal ultrasound examination the pregnancy was terminated. The second patient is a 13-month-old healthy boy, in whom low level trisomy 17 mosaicism was detected in cultured chorionic villi only. The third patient is a 2-year-old girl with growth retardation, developmental delay, MCA, and trisomy 17 mosaicism in amniocytes, fibroblasts, and placenta, but not in blood and buccal smear. The fourth patient is a 9-year-old boy with growth and mental retardation, sensoneurinal hearing loss, and MCA. Cytogenetic analyses showed trisomy 17 mosaicism in amniocytes, skin fibroblasts, and urinary sediment cells, whereas in blood and buccal smear a 46,XY karyotype was found. Molecular investigations in all four cases indicated biparental inheritance of chromosome 17. Formation of trisomy was most likely due to a maternal meiosis I error in Patient 1 and a postzygotic non-disjunction of the paternal chromosome 17 in Patient 4. Cerebellar malformations, reported in two cases from the literature and in two reported here may be a specific feature of trisomy 17 mosaicism. Since the aberration has rarely been reported in lymphocytes, chordocentesis is not indicated in prenatal diagnosis. Prenatal genetic counseling for trisomy 17 mosaicism in chorionic villi or amniocytes should consider that the clinical significance remains uncertain