First reported case of interstitial 15 q15.3-q21.3 deletion diagnosed prenatally and characterized with array CGH in a fetus with an isolated short femur.

We report on a fetus with an isolated short femur detected by ultrasound and a de novo interstitial deletion of chromosome 15. The deletion was diagnosed prenatally by karyotype and further mapped by fluorescence in situ hybridization (FISH) and array comparative genomic hybridization (array-CGH) to bands 15q15.3 to 15q21.3 with a size of 11.11 Mb. Fetal autopsy showed characteristic minor anomalies, urinary abnormalities, and delayed bone maturation, but neither craniosynostosis, nor congenital heart defects as observed in previously reported cases. Despite the existence of ultrasound abnormalities, all five cases reported so far were diagnosed after birth. This is the first case of an interstitial deletion involving chromosomal band 15q15.3-q21.3 diagnosed prenatally and characterized at the molecular level. Our observation suggests the absence of imprinted genes in the area of 15q15-q22 and strengthens the hypothesis that a critical region for craniosynostosis may be mapped outside the deleted region in the present patient.

Mitochondrial DNA depletion is a prevalent cause of multiple respiratory chain deficiency in childhood.

OBJECTIVE: To determine the actual incidence of mitochondrial DNA (mtDNA) depletion syndrome in multiple respiratory chain deficiency. STUDY DESIGN: We carried out a real-time polymerase chain reaction quantification of mtDNA in liver or muscle tissue of 100 children with unexplained multiple oxidative phosphorylation enzyme deficiency. RESULTS: A reduction of mtDNA copy number to <35% of control values was found in liver and/or muscle in half of the children (50/100). Most of these patients (32/50; 64%) presented with severe neonatal onset liver involvement; 7 (14%) had Alpers syndrome, and 11 (22%) exhibited various forms of neurologic involvement. Deoxyguanosine kinase or polymerase gamma (POLG) mutations could be identified in 11 of 32 patients with liver involvement, and POLG mutations were consistently found in all 7 patients with Alpers syndrome. Homozygous thymidine kinase 2 and MPV17 gene mutations were found in 2 patients. CONCLUSIONS: Our findings show that mtDNA depletion is a prevalent cause of multiple respiratory chain deficiency in infancy.

A novel mutation of the NDUFS7 gene leads to activation of a cryptic exon and impaired assembly of mitochondrial complex I in a patient with Leigh syndrome.

Complex I deficiency is a frequent cause of mitochondrial disease as it accounts for one third of these disorders. By genotyping several putative disease loci using microsatellite markers we were able to describe a new NDUFS7 mutation in a consanguineous family with Leigh syndrome and isolated complex I deficiency. This mutation lies in the first intron of the NDUFS7 gene (c.17-1167 C>G) and creates a strong donor splice site resulting in the generation of a cryptic exon. This mutation is predicted to result in a shortened mutant protein of 41 instead of 213 amino acids containing only the first five amino acids of the normal protein. Analysis of the assembly state of the respiratory chain complexes under native condition revealed a marked decrease of fully assembled complex I while the quantity of the other complexes was not altered. These results report the first intronic NDUFS7 gene mutation and demonstrate the crucial role of NDUFS7 in the biogenesis of complex I.