Molecular characterization of 22 novel UDP-N-acetylglucosamine-1-phosphate transferase alpha- and beta-subunit (GNPTAB) gene mutations causing mucolipidosis types IIalpha/beta and IIIalpha/beta in 46 patients.

Mutational analysis of the GNPTAB gene was performed in 46 apparently unrelated patients with mucolipidosis IIalpha/beta or IIIalpha/beta, characterized by the mistargeting of multiple lysosomal enzymes as a consequence of a UDP-GlcNAc-1-phosphotransferase defect. The GNPTAB mutational spectrum comprised 25 distinct mutant alleles, 22 of which were novel, including 3 nonsense mutations (p.Q314X, p.R375X, p.Q507X), 5 missense mutations (p.I403T, p.C442Y, p.C461G, p.Q926P, p.L1001P), 6 microduplications (c.749dupA, c.857dupA, c.1191_1194dupGCTG, c.1206dupT, c.1331dupG, c.2220_2221dupGA) and 8 microdeletions (c.755_759delCCTCT, c.1399delG, c.1959_1962delTAGT, c.1965delC, c.2550_2554delGAAAA, c.3443_3446delTTTG, c.3487_3490delACAG, c.3523_3529delATGTTCC). All micro-duplications/deletions were predicted to result in the premature termination of translation. A novel exonic SNP (c.303G>A; E101E) was identified which is predicted to create an SFRS1 (SF2/ASF) binding site that may be of potential functional/clinical relevance. This study of mutations in the GNPTAB gene, the largest yet reported, extends our knowledge of the mutational heterogeneity evident in MLIIalpha/beta/MLIIIalpha/beta.

A new method for analysis of mitochondrial DNA point mutations and assess levels of heteroplasmy.

Determination of mitochondrial DNA (mtDNA) heteroplasmy for the diagnosis of patients with mitochondrial disorders is a difficult task due to the coexistence of wild-type and mutant genomes. We have developed a new method for genotyping and quantification of heteroplasmic point mutations in mtDNA based on the SNaPshot technology. We compared the data of this method with the widely used "last hot-cycle" PCR-RFLP method by studying 15 patients carrying mtDNA mutations. We showed that SNaPshot is an accurate, reproducible, and sensitive technique for the determination of heteroplasmic mtDNA mutations in different tissues from patients, and it is a promising system to be used in prenatal and postnatal diagnosis of mtDNA-associated disorders.

Novel GNE mutations in Italian families with autosomal recessive hereditary inclusion-body myopathy.

The most common form of autosomal recessive (AR) hereditary inclusion-body myopathy (HIBM), originally described in Persian-Jewish families, is characterized by onset in early adult life with weakness and atrophy of distal lower limb muscles, which progress proximally and relatively spare the quadriceps. AR HIBM is associated with mutations in the UDP-N-acetylglucosamine 2-epimerase/N-acetylmannosamine kinase gene (GNE) on chromosome 9p12-13. In the present study we have identified seven novel GNE mutations in patients from five unrelated Italian families with clinical and pathologic features indicative of AR HIBM. Four were missense mutations (c.1556A>G [p.N519S], c.79C>T [p.P27S], c.1798G>A [p.A600T] and c.616G>A [p.G206S]), two consisted in a single-base deletion (c.616delG [p.G206fsX4] and c.1130delT [p.I377fsX16]) and one in an intronic single-base insertion (c.1070+2dupT). These latter findings further extend the type of GNE mutations associated with HIBM. Furthermore, in one patient we also identified the c.737G>A [p.R246Q] missense mutation that corresponds to the one previously reported in a family from the Bahamas. Interestingly, in two of our families distinct mutations affected nucleotide c.616 in exon 3 (c.616delG and c.616G>A). The possibility of specific portions of the gene being more prone to mutations remains to be elucidated.

Progressive exercise intolerance associated with a new muscle-restricted nonsense mutation (G142X) in the mitochondrial cytochrome b gene.

We report a novel nonsense mitochondrial cytochrome b mutation (G15170A) in a 40-year-old woman with progressive exercise intolerance and lactic acidosis. Muscle biopsy showed several cytochrome c oxidase-positive ragged-red fibers, and reduced activities of respiratory chain complexes I and III. This mutation, resulting in the loss of 228 amino acids of the protein, was very abundant in the patient's muscle, but undetectable in lymphocytes and fibroblasts. Clinical and laboratory data indicate that this defect is the primary cause of the disease, thus adding a new mutation in the cytochrome b gene among the growing number of patients with exercise intolerance and lactic acidosis.

Mitochondrial myopathy and respiratory failure associated with a new mutation in the mitochondrial transfer ribonucleic acid glutamic acid gene.

We report a novel T14687C mutation in the mitochondrial transfer ribonucleic acid glutamic acid gene in a 16-year-old boy with myopathy and lactic acidosis, retinopathy, and progressive respiratory failure leading to death. A muscle biopsy showed cytochrome c oxidase-negative ragged-red fibers, and biochemical analysis of the respiratory chain enzymes in muscle homogenate revealed complex I and complex IV deficiencies. The mutation, which affects the trinucleotide (TpsiC) loop, was nearly homoplasmic in the muscle DNA of the proband, but it was absent in his blood and in the blood from the asymptomatic mother, suggesting that it may have been a spontaneous somatic mutation in muscle.