A novel mutation in the mitochondrial tRNAAla gene (m.5636T>C) in a patient with progressive external ophthalmoplegia

We report a heteroplasmic novel mutation m.5636T>C in the mt-tRNA^Ala in a patient with bilateral ptosis and ophthalmoparesis in whom a muscle biopsy showed cytochrome c oxdidase (COX) negative and ragged red fibers. Using laser capture microdissection we have isolated COX negative fibers and COX positive fibers from the muscle of the patient and determined that the mutation load was clearly increased in COX negative muscle fibers. Additionally, the mutated m.5636T nucleotide is conserved in all the mammal and non-mammal species analyzed and might be structurally relevant as it is located in a position involved in the formation of tertiary structure of canonical mitochondrial tRNAs.     

Impairment of mitochondrial tRNAIle processing by a novel mutation associated with chronic progressive external ophthalmoplegia

We report a sporadic case of chronic progressive external ophthalmoplegia associated with ragged red fibers. The patient presented with enlarged mitochondria with deranged internal architecture and crystalline inclusions. Biochemical studies showed reduced activities of complex I, III and IV in skeletal muscle. Molecular genetic analysis of all mitochondrial tRNAs revealed a G to A transition at nt 4308; the G is a highly conserved nucleotide that participates in a GC base-pair in the T-stem of mammalian mitochondrial tRNA(Ile). The mutation was detected at a high level (approx. 50%) in muscle but not in blood. The mutation co-segregated with the phenotype, as the mutation was absent from blood and muscle in the patient's healthy mother. Functional characterization of the mutation revealed a six-fold reduced rate of tRNA(Ile) precursor 3' end maturation in vitro by tRNAse Z. Furthermore, the mutated tRNA(Ile) displays local structural differences from wild-type. These results suggest that structural perturbations reduce efficiency of tRNA(Ile) precursor 3' end processing and contribute to the molecular pathomechanism of this mutation.     

Compound mutations of PEO1 and TYMP in a progressive external ophthalmoplegia patient with incomplete mitochondrial neurogastrointestinal encephalomyopathy phenotype

The Mendelian inherited progressive external ophthalmoplegia (PEO) and mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) are genetically heterogeneous mitochondrial diseases caused by nuclear-mitochondrial intergenomic defects. The PEO1 and TYMP nuclear genes are closely related in the machinery of the mitochondrial DNA (mtDNA) replication. Mutations in PEO1 and TYMP genes usually cause autosomal dominant PEO, and autosomal recessive MNGIE. We identified a PEO family of Korean origin with additional phenotype of incomplete MNGIE symptom (Family ID: MT16). The entire mitochondrial genome and all coding exons of PEO1, TYMP, ANT1, POLG1, POLG2, DGUOK, and TK2 nuclear genes were sequenced. Clinical information was obtained through history taking, physical examinations, clinical observations, and electrophysiological investigations. Muscle biopsy of left biceps brachii and shoulder magnetic resonance imaging (MRI) were undertaken. We found two heterozygous mutations, Arg374Gln in PEO1 and Glu106Gln in TYMP from the proband who showed complex phenotypes of a typical PEO and late-onset incomplete MNGIE. The PEO1 Arg374Gln has been reported in several PEO patients, but TYMP Glu106Gln has not been reported. Neither large deletion nor causative point mutations were observed in the mtDNA. We suggest that the heterozygous TYMP mutation might affect complex phenotypes as a secondary genetic cause in the co-presence of PEO1 mutation.     

16q subtelomeric deletion in proband with congenital malformations and mental retardation

We present a female child with mild mental retardation and congenital malformations. After fluorescence in situ hybridization (FISH) we found only abnormal karyotype in all cells. We used rapid FISH and original DNA probes--PAC62.10.1 and PAC20.19.N, specific for segments of chromosome 16q24. Karyotype of proband 46,XX.ish del(16)(q24.2:) (PAC20.19.N,PAC62.10.1-). Parent karyotypes are normal. This case may suggest the presence of clinical picture 16q- with defined clinical polymorphism at small telomeric loss, and also its necessary of the use of molecular-cytogenetic techniques in genetic departments.     

Mutations in mitochondrial tRNA genes: non-linkage with syndromes of Wolfram and chronic progressive external ophthalmoplegia.

We have recently identified a point mutation in the mitochondrially encoded tRNA(Leu(UUR)) gene which associates with a combination of type II diabetes mellitus and sensorineural hearing loss in a large pedigree. To extend this finding to other syndromes which exhibit a combination of diabetes mellitus and hearing loss we have sequenced all mitochondrial tRNA genes from two patients with the Wolfram syndrome, a rare congenital disease characterized by diabetes mellitus, deafness, diabetes insipidus and optic atrophy. In each patient, a single different mutation was identified. One is an A to G transition mutation at np 12,308 in tRNA(Leu(CUN)) gene in a region which is highly conserved between species during evolution. This mutation has been described by Lauber et al. (1) as associating with chronic progressive external ophthalmoplegia (CPEO). The other is a C to T transition mutation at np 15,904 in tRNA(Thr) gene. Both mutations are also present in the general population (frequency tRNA(Leu(CUN)) mutation 0.16, tRNA(Thr) mutation 0.015). These findings suggest that evolutionarily conserved regions in mitochondrial tRNA genes can exhibit a significant polymorphism in humans, and that the mutation at np 12,308 in the tRNA(Leu(CUN)) gene is unlikely to be associated with CPEO and Wolfram syndrome.     

A Tunisian patient with Pearson syndrome harboring the 4.977kb common deletion associated to two novel large-scale mitochondrial deletions

Pearson syndrome (PS) is a multisystem disease including refractory anemia, vacuolization of marrow precursors and pancreatic fibrosis. The disease starts during infancy and affects various tissues and organs, and most affected children die before the age of 3 years. Pearson syndrome is caused by de novo large-scale deletions or, more rarely, duplications in the mitochondrial genome. In the present report, we described a Pearson syndrome patient harboring multiple mitochondrial deletions which is, in our knowledge, the first case described and studied in Tunisia. In fact, we reported the common 4.977 kb deletion and two novel heteroplasmic deletions (5.030 and 5.234 kb) of the mtDNA. These deletions affect several protein-coding and tRNAs genes and could strongly lead to defects in mitochondrial polypeptides synthesis, and impair oxidative phosphorylation and energy metabolism in the respiratory chain in the studied patient.     

Congenital heart defect and mental retardation in a patient with a 13q33.1-34 deletion

13q deletion syndrome is a rare genetic disorder caused by deletions of the long arm of chromosome 13. Patients with 13q deletion display a variety of phenotypic features. We describe a one-year-old female patient with congenital heart defects (CHD), facial anomalies, development and mental retardation. We identified a 12.75Mb deletion in chromosome region 13q33.1-34 with high resolution SNP Array (Human660W-Quad, Illumina, USA). This chromosome region contains about 55 genes, including EFNB2, ERCC5, VGCNL1, F7, and F10. Comparing our findings with previously reported 13q deletion patients with congenital heart defects, we propose that the 13q33.1-34 deletion region might contain key gene(s) associated with cardiac development. Our study also identified a subclinical deficiency of Factors VII and X in our patient with Group 3 of 13q deletion syndrome.     

Chromosome studies in patients with congenital malformations and mental retardation.

16 (41%) out of 39 individuals referred by physicians because of sexual anomalies showed abnormal karyotypes; the corresponding figure for those investigated due to suspected autosomal aberrations was 37 out of 104 (36%). A special survey was also conducted among 51 mentally defective children with at least 3 malformations; 5 individuals (10%) were observed with chromosome abnormalities plus 3(6%) with rare variants. These results were compared with those presented in 26 other surveys reported in the literature.     

A novel heteroplasmic tRNA(Leu(CUN)) mtDNA point mutation associated with chronic progressive external ophthalmoplegia

We have sequenced all mitochondrial tRNA genes from a patient with chronic progressive external ophthalmoplegia (CPEO) and mitochondrial myopathy, who had no detectable large mtDNA deletions. Direct sequencing failed to detect previously reported mutations and showed a heteroplasmic mutation at nucleotide 12,276 in the tRNA(Leu(CUN)) gene, in the dihydrouridine stem, which is highly conserved through the species during evolution. RFLP analyses confirmed that 18% of muscle mtDNA harbored the mutation, while it was absent from DNA of fibroblasts and lymphocytes of the proband and in 110 patients with other encephalomyopathies. To date, besides large and single nucleotide deletions, several point mutations on mitochondrial tRNA genes have been reported in CPEO patients, but only three were in the gene coding for tRNA(Leu(CUN)).     

Pearson syndrome and mitochondrial encephalomyopathy in a patient with a deletion of mtDNA.

A patient is described who has features of Pearson syndrome and who presented in the neonatal period with a hypoplastic anemia. He later developed hepatic, renal, and exocrine pancreatic dysfunction. At the age of 5 years he developed visual impairment, tremor, ataxia, proximal muscle weakness, external ophthalmoplegia, and a pigmentary retinopathy (Kearns-Sayre syndrome). Muscle biopsy confirmed the diagnosis of mitochondrial myopathy. Analysis of mtDNA from leukocytes and muscle showed mtDNA heteroplasmy in both tissues, with one population of mtDNA deleted by 4.9 kb. The deleted region was bridged by a 13-nucleotide sequence occurring as a direct repeat in normal mtDNA. Both Pearson syndrome and Kearns-Sayre syndrome have been noted to be associated with deletions of mtDNA; they have not previously been described in the same patient. These observations indicate that the two disorders have the same molecular basis; the different phenotypes are probably determined by the initial proportion of deleted mtDNAs and modified by selection against them in different tissues.     

Prenatal diagnosis of X-linked choroideremia with mental retardation,associated with a cytologically detectable X-chromosome deletion

Summary We describe a family in which an X-chromosome deletion is segregating with choroideremia, an X-linked recessive condition. The DNA sequences DXYS1 and DXS3, defined by the probes pDP34 and 19.2 respectively, are absent in the affected male (who is also mentally retarded), and hemizygous in his mother and in his carrier sister, who presented early in pregnancy. Analysis of chorionic villus DNA formed the basis of prenatal exclusion of choroideremia in her male fetus. In three female relatives, studied with late-labelling techniques, the deleted X was preferentially inactivated in 86–100% of cells studied. This family confirms the localisation of the choroideremia locus to within Xq1321, and places the loci for anhidrotic ectodermal dysplasia and the X-linked immunodeficiencies outside this region.     

A new form of X-linked mental retardation with growth retardation, deafness, and microgenitalism.

The proband and two maternal uncles were similarly affected by a unique constellation of mental retardation and physical abnormalities. There were severe retardation, growth less than the third percentile, and significantly delayed bone age. They manifested deafness, a flat nasal bridge, several ocular abnormalities, and a rudimentary scrotum with cryptorchidism, and one had a small penis. The proband also had onychodystrophy of his fingers and toes. Their birth weights and lengths were less than expected. No chromosomal or biochemical abnormality was detected. Both uncles died, but the proband is healthy at 4 years. Their phenotype is distinguished from other forms of X-linked mental retardation and appears to be a new syndrome.