Single‐fiber PCR in MELAS3243 patients: Correlations between intratissue distribution and phenotypic expression of the mtDNAA3243G genotype

We performed morphological, biochemical, and genetic studies, including single‐fiber PCR (sf PCR), on muscle biopsies obtained from a mother and daughter with MELAS syndrome due to the A3243G transition of mitochondrial DNA (mtDNA). The severity of muscle involvement appeared quite distinct, in spite of the fact that both patients segregated similar mutant mtDNA levels on total muscle DNA. The daughter did not show any clinical muscle involvement: muscle biopsy revealed many ragged red fibers (RRFs) mostly positive for cytochrome‐c oxidase (COX) activity. In contrast, her mother had developed a generalized myopathy without progressive external ophthalmoplegia (PEO), morphologically characterized by many COX‐negative RRFs. Single‐muscle fiber PCR demonstrated in both patients significantly higher percentages of wild‐type mtDNA in normal fibers (daughter: 23.25 ± 15.22; mother: 43.13 ± 26.11) than in COX‐positive RRFs (daughter: 11.25 ± 5.22, P < 0.005; mother: 9.12 ± 5.9, P < 0.001) and in COX‐negative RRFs (daughter: 8.9 ± 4.2, P < 0.001 mother: 4.8 ± 2.8, P < 0.001). Wild‐type mtDNA levels resulted higher also in COX‐positive vs. COX‐negative RRFs (daughter: P < 0.05; mother: P < 0.001). Our data confirm a direct correlation between A3243G levels and impairment of COX function at the single‐muscle fiber level. Moreover, the evidence of a clinical myopathy in the patient with higher amounts of COX‐negative RRFs bolsters the concept that a differential distribution of mutant mtDNAs at the cellular level may have effects on the clinical involvement of individual tissues. However, the occurrence of a similar morphological and biochemical muscle phenotype also in PEO³²⁴³ patients suggests that other genetic factors involved in the interaction between mitochondrial and nuclear DNA, rather than the stochastic distribution of mtDNA genomes during embryogenesis, are primarily implicated in determining the various clinical expressions of the A3243G of mtDNA. Am. J. Med. Genet. 94:201–206, 2000. © 2000 Wiley‐Liss, Inc.     

Extremely high levels of mutant mtDNAs co-localize with cytocohrome c oxidase-negative ragged-red fibers in patients harboring a point mutation at nt 3243

A single mtDNA point mutation at nt 3243 has been associatedwith two different clinical phenotypes: mitochondrial encephalomyopathy,lactic acldosis, and stroke-like episodes (‘MELAS³²⁴³’)and progressive external ophthalmoplegia (‘PEO³²⁴³’).It has been shown that there Is a much higher proportion ofragged-red fibers (RRF) with cytochrome c oxldase (COX) deficiencyIn PEO³²⁴³ than in MELAS³²⁴³. Using PCR/RFLP analysis of isolatedindividual skeletal muscle fibers from patients with both syndromes,we found a direct correlation between the localized concentrationof the nt 3243 mutation and Impairment of COX function at thesingle muscle fiber level: we found relatively low levels ofmutant mtDNAs (56±21%) in ‘normal’ fibers;high levels (90±6%) In COX-positive RRF; and an almostcomplete segregation of mutant mtDNAs (95 ±3%) In COX-negativeRRF. Thus, the differential distribution of fibers with extremelyhigh concentrations of mutant mtDNAs characterizes, and probablydistinguishes, the skeletal muscle of PEO and MELAS patientsharboring the same nt-3243 mutations.     

Noninvasive diagnosis of the 3243A > G mitochondrial DNA mutation using urinary epithelial cells

The 3243A > G mutation is one of the most frequently observed mutations of mitochondrial DNA (mtDNA), and is associated with numerous clinical presentations including mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS), progressive external ophthalmoplegia (PEO) and diabetes and deafness. The routine diagnosis of the 3243A > G mutation in blood is difficult as mutation levels are known to decrease in this tissue over time, while in some patients it may be absent. We have directly compared the levels of the 3243A > G mutation in skeletal muscle, blood and urinary epithelial cells in 18 patients and observed a striking correlation between the mutation load in postmitotic muscle and urinary epithelium, a mitotic tissue. These data strongly support the use of urinary epithelial cells as the tissue of choice in the noninvasive diagnosis of the 3243A > G mutation.     

Histochemical and molecular genetic study of MELAS and MERRF in Korean patients

Mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episode (MELAS) and myoclonic epilepsy and ragged-red fibers (MERRF) are rare disorders caused by point mutation of the tRNA gene of the mitochondrial genome. To understand the pathogenetic mechanism of MELAS and MERRF, we studied four patients. Serially sectioned frozen muscle specimens with a battery of histochemical stains were reviewed under light microscope and ultrastructural changes were observed under electron microscope. The polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) analysis was performed and the tRNA genes were sequenced to confirm mutations. In two patients with MELAS, strongly succinyl dehydrogenase positive blood vessels (SSVs) and many cytochrome oxidase (COX) positive ragged-red fibers (RRFs) were observed, and A3243G mutations were found from the muscle samples. In two patients with MERRF, neither SSV nor COX positive RRFs were seen and A8344G mutations were found from both muscle and blood samples. In the two MERRF families, the identical mutation was observed among family members. The failure to detect the mutation in blood samples of the MELAS suggests a low mutant load in blood cells. The histochemical methods including COX stain are useful for the confirmation and differentiation of mitochondrial diseases. Also, molecular biological study using muscle sample seems essential for the confirmation of the mtDNA mutation.     

Low frequency of mtDNA point mutations in patients with PEO associated with POLG1 mutations

Mitochondrial myopathy in progressive external ophthalmoplegia (PEO) has been associated with POLG1 mutations. POLG1 encodes the catalytic alpha subunit of polymerase gamma and is the only polymerase known to be involved in mtDNA replication. It has two functionally different domains, one polymerase domain and one exonuclease domain with proofreading activity. In this study we have investigated whether mtDNA point mutations are involved, directly or indirectly, in the pathogenesis of PEO. Muscle biopsy specimens from patients with POLG1 mutations, affecting either the exonuclease or the polymerase domain, were investigated. Single cytochrome c oxidase (COX)-deficient muscle fibers were dissected and screened for clonally expanded mtDNA point mutations using a sensitive denaturing gradient gel electrophoresis analysis, in which three different regions of mtDNA, including five different tRNA genes, were investigated. To screen for randomly distributed mtDNA point mutations in muscle, two regions of mtDNA including deletion breakpoints were investigated by high-fidelity PCR, followed by cloning and sequencing. Long-range PCR revealed multiple mtDNA deletions in all the patients but not the controls. No point mutations were identified in single COX-deficient muscle fibers. Cloning and sequencing of muscle homogenate identified randomly distributed point mutations at very low frequency in patients and controls (<1:50 000). We conclude that mtDNA point mutations do not appear to be directly or indirectly involved in the pathogenesis of mitochondrial disease in patients with different POLG1 mutations.     

Presence of mitochondrial tRNA(Leu(UUR)) A to G 3243 mutation in DNA extracted from serum and plasma of patients with type 2 diabetes mellitus

AIMS/BACKGROUND: An A to G substitution at base pair 3243 in the mitochondrial tRNA(Leu(UUR)) gene (mt3243) is commonly associated with maternally inherited diabetes and deafness, and other diseases. It is possible that cell free mitochondrial DNA exists in serum and plasma from these patients, and these samples might be a source of material for the detection of such mutations. METHODS: Sixteen patients with type 2 diabetes mellitus and 25 healthy subjects were tested for the 3243 mutation by polymerase chain reaction restriction fragment length polymorphism (PCR-RFLP) analysis. Plasma and serum from the 41 subjects were tested blind, without knowledge of the final diagnosis. RESULTS: PCR amplification of the mtRNA(Leu(UUR)) region in mitochondrial DNA (mtDNA) in serum samples revealed the presence of mtDNA in all samples. After ApaI digestion of the amplified DNA fragments, mt3243 was detected in the serum and plasma samples of the seven patients with diabetes who had previously been found to have this mutation in their leucocyte DNA. None of the serum/plasma samples from the healthy subjects or those patients negative for mt3243 in their leucocytes had this mutation (p < 0.001). In addition, the degree of heteroplasmy of mt3243 appeared to be higher in serum and plasma samples than in leucocytes among mt3243 carriers (p < 0.05). CONCLUSIONS: Therefore, mtDNA and associated mutations are present and detectable in serum and plasma. Plasma and serum might be alternative sources for the molecular diagnosis of mt3243 associated diabetes mellitus, as well as other mitochondrial mediated diseases.     

The mitochondrial A3243G mutation presenting as severe cardiomyopathy.

A 6 year old Portuguese boy with dilated cardiomyopathy had abundant ragged red fibres in muscle (20% of total) and severe lactic acidosis. Molecular genetic analysis showed the A to G transition in the mitochondrial transfer RNALeu(UUR) gene at nt 3243 ("MELAS mutation"), which accounted for 88% and 68% of the total mtDNA in his muscle and blood, respectively. Molecular studies in blood from 16 maternal relatives identified lower percentages of the mutation only in the oligo-symptomatic mother and brother. This case reinforces the notion that cardiomyopathy can be the presenting and predominant clinical expression of the A3243G mutation.     

The A3243G tRNALeu(UUR) mutation induces mitochondrial dysfunction and variable disease expression without dominant negative acting translational defects in complex IV subunits at UUR codons

Mutations in the mitochondrial tRNA(Leu(UUR)) gene are associated with a large variety of human diseases through a largely undisclosed mechanism. The A3243G tRNA(Leu(UUR)) mutation leads to reduction of mitochondrial DNA (mtDNA)-encoded proteins and oxidative phosphorylation activity even when the cells are competent in mitochondrial translation. These two aspects led to the suggestion that a dominant negative factor may underlie the diversity of disease expression. Here we test the hypothesis that A3243G tRNA(Leu(UUR)) generates such a dominant negative gain-of-function defect through misincorporation of amino acids at UUR codons of mtDNA-encoded proteins. Using an anti-complex IV immunocapture technique and mass spectrometry, we show that the mtDNA-encoded cytochrome c oxidase I (COX I) and COX II exist exclusively with the correct amino acid sequences in A3243G cells in a misassembled complex IV. A dominant negative component therefore cannot account for disease phenotype, leaving tissue-specific accumulation by mtDNA segregation as the most likely cause of variable mitochondrial disease expression.     

Evidence of apoptosis in chronic alcoholic skeletal myopathy

Apoptosis is a common mechanism of programmed cell death that has been implicated in the pathogenesis of alcohol-induced organ damage. Experimental studies have suggested alcohol-mediated apoptosis in cardiac muscle. The relationship between skeletal and cardiac muscle damage in alcoholism led us to consider the possible role of apoptosis in the pathogenesis of skeletal myopathy. We prospectively evaluated apoptosis in skeletal muscle biopsies of 30 consecutively selected male high-dose well-nourished chronic alcohol consumers and 12 nonalcoholic controls. Alcohol consumption, evaluation of muscle strength by myometry, and deltoid muscle biopsy with immunohistochemical and morphometric analysis were performed. Apoptosis was assessed by TUNEL, BAX, and BCL-2 immunohistochemical assays. Chronic alcoholics compared with controls showed a significantly higher apoptotic index in TUNEL (2.35% +/- 0.25% versus 0.18% +/- 0.03%, P < 0.001), BAX (9.16% +/- 2.00% versus 0.66% +/- 0.22%, P < 0.001), and BCL-2 muscle assays (8.08% +/- 0.20% versus 0.83% +/- 0.20%, P = 0.001), respectively. In addition, these apoptotic indexes were higher in alcoholics with skeletal myopathy compared with in those without skeletal myopathy (3.04% +/- 0.36% versus 1.65% +/- 0.26%, P = 0.004 for TUNEL; 17.00% +/- 2.78% versus 1.33% +/- 0.22%, P < 0.001 for BAX; and 15.13% +/- 3.2% versus 1.03% +/- 0.33%, P < 0.001 for BCL-2 assays, respectively). We conclude that apoptosis is present in the skeletal muscle of high-dose alcohol consumers, mainly in those affected by myopathy. However, the specific pathogenic mechanism of apoptosis in chronic skeletal myopathy in alcoholics remains to be elucidated.     

Clinical features of MELAS and its relation with A3243G gene point mutation

Mitochondrial encephalopathy with lactic acidosis and stroke-like episodes (MELAS) mostly occur in children. The point mutation A3243G of mitochondrial DNA (mtDNA) may work as a specific bio-marker for mitochondrial disorders. The related clinical features, however, may vary among individuals. This study therefore investigated the relation between MELAS clinical features and point mutation A3243G of mtDNA, in an attempt to provide further evidences for genetic diagnosis of MELAS. Children with MELAS-like syndromes were tested for both blood lactate level and point mutation A3243G of mtDNA. Further family study was performed by mtDNA mutation screening at the same loci for those who had positive gene mutation at A3243G loci. Those who were negative for A3243G point mutation were examined by muscle biopsy and genetic screening. Both clinical and genetic features were analyzed. In all 40 cases with positive A3243G mutation, 36 children fitted clinical diagnosis of MELAS. In other 484 cases with negative mutation, only 8 children were clinically diagnosed with MELAS. Blood lactate levels in both groups were all elevated (P>0.05). In a further genetic screening of 28 families, 10 biological mothers and 8 silbings of MELAS children had positive A3243G point mutations but without any clinical symptoms. Certain difference existed in the clinical manifestations between children who were positive and negative for A3243G mutation of mtDNA but without statistical significance. MELAS showed maternal inheritance under most circumstances.     

Comparison of the relative levels of the 3243 (A-->G) mtDNA mutation in heteroplasmic adult and fetal tissues.

In this report, levels of the 3243 A to G mtDNA mutation associated with the mitochondrial encephalopathy, lactic acidosis, and stroke-like episodes (MELAS) syndrome were measured in different heteroplasmic tissues of subjects in a kindred including adults with variable clinical phenotypes and a fetus. The relative proportions of mutant mtDNA varied widely (0.03 to 0.67) between identical tissues of the six different subjects and between different tissues of the same subjects. In the one adult for whom sufficient data were available there was an apparent correlation between the distribution of mutant mtDNA and clinical presentation. A woman without neurological symptoms who died prematurely with a cardiomyopathy and lactic acidosis had higher proportions of mutant in heart (0.49, SD 0.02), skeletal muscle (0.56, SD 0.01), and liver (0.55, SD 0.12) than in other tissues studied (for example, kidney, 0.03, SD 0.01). A strikingly different result was found in a 24 week old fetus in whom there was little variation in heteroplasmy in different tissues (average proportion of mutant mtDNA in six tissues, 0.53, SD 0.02). These observations add cardiomyopathy to the growing list of presenting features of the 3243 mtDNA mutation. The unique results from the fetus suggest also that selection pressures acting on either wild type or 3243 mutant mtDNA (rather than variation from replicative segregation of the heteroplasmic mtDNA) may be responsible primarily for the variable levels of 3243 mutant mtDNA in different heteroplasmic tissues of adults.     

Contrasting phenotypes in three patients with novel mutations in mitochondrial tRNA genes

We studied three patients, each harboring a novel mutation at a highly conserved position in a different mitochondrial tRNA gene. The mutation in patient 1 (T5543C) was associated with isolated mitochondrial myopathy, and occurred in the anticodon loop of tRNA(Trp). In patient 2, with mitochondrial myopathy and marked retinopathy, the mutation (G14710A) resulted in an anticodon swap (Glu to Lys) in tRNA(Glu). Patient 3, who manifested mitochondrial encephalomyopathy and moderate retinal dysfunction, harbored a mutation (C3287A) in the TpsiC loop of tRNA(Leu(UUR)). The mutations were heteroplasmic in muscle in all cases, and sporadic in two cases. PCR-RFLP analysis in all patients showed much higher amounts of mutated mtDNA in affected tissue (muscle) than unaffected tissue (blood), and significantly higher levels of mutated mtDNA in cytochrome c oxidase (COX)-negative muscle fibers than in COX-positive fibers, confirming the pathogenicity of these mutations. The mutation was also detected in single hair roots from all three patients, indicating that each mutation must have arisen early in embryonic development or in maternal germ cells. This suggests that individual hair root analyses may reflect a wider tissue distribution of mutated mtDNA than is clinically apparent, and might be useful in predicting prognosis and, perhaps, the risk of transmitting the mutation to offspring. Our data suggest a correlation between clinical phenotype and distribution of mutated mtDNA in muscle versus hair roots. Furthermore, the high threshold for phenotypic expression in single muscle fibers (92-96%) suggests that therapies may only need to increase the percentage of wild-type mtDNA by a small amount to be beneficial.     

Pathogenic mitochondrial mt-tRNAAla variants are uniquely associated with isolated myopathy

Pathogenic mitochondrial DNA (mtDNA) point mutations are associated with a wide range of clinical phenotypes, often involving multiple organ systems. We report two patients with isolated myopathy owing to novel mt-tRNA^Ala variants. Muscle biopsy revealed extensive histopathological findings including cytochrome c oxidase (COX)-deficient fibres. Pyrosequencing confirmed mtDNA heteroplasmy for both mutations (m.5631G>A and m.5610G>A) whilst single-muscle fibre segregation studies (revealing statistically significant higher mutation loads in COX-deficient fibres than in COX-positive fibres), hierarchical mutation segregation within patient tissues and decreased steady-state mt-tRNA^Ala levels all provide compelling evidence of pathogenicity. Interestingly, both patients showed very high-mutation levels in all tissues, inferring that the threshold for impairment of oxidative phosphorylation, as evidenced by COX deficiency, appears to be extremely high for these mt-tRNA^Ala variants. Previously described mt-tRNA^Ala mutations are also associated with a pure myopathic phenotype and demonstrate very high mtDNA heteroplasmy thresholds, inferring at least some genotype:phenotype correlation for mutations within this particular mt-tRNA gene.     

Tissue specific distribution of the 3243A->G mtDNA mutation

Background

The 3243A→G is a common pathogenic mitochondrial DNA (mtDNA) point mutation causing a variety of different phenotypes. Segregation of this mutation to different tissues during embryonic life and postnatally is still enigmatic.

Objective

To investigate the tissue distribution of this mutation.

Methods

In 65 individuals from nine families segregating the 3243A→G mutation, the mutation load (% mutated mtDNA) was determined in various tissues. Mutation load was measured in two to four cell types—blood leucocytes, buccal cells, skeletal muscle cells, and urine epithelial cells (UEC)—derived from all three embryogenic germ layers.

Results

There was a significant correlation among mutation loads in the four tissues (r = 0.80–0.89, p<0.0001). With blood serving as reference, the mutation load was increased by 16% in buccal mucosa, by 31% in UEC, and by 37% in muscle. There were significant differences between the mitotic tissues blood, buccal mucosa, and UEC (p<0.0001), but no difference between UEC and muscle. Using the present data as a cross sectional investigation, a negative correlation of age with the mutation load was found in blood, while the mutation load in muscle did not change with time; 75% of the children presented with higher mutation loads than their mothers in mitotic tissues but not in the post‐mitotic muscle.

Conclusions

There appears to be a uniform distribution of mutant mtDNA throughout the three germ layers in embryogenesis. The significant differences between mutation loads of the individual tissue types indicate tissue specific segregation of the 3243A→G mtDNA later in embryogenesis.     

POLG mutations in sporadic mitochondrial disorders with multiple mtDNA deletions

The accumulation of multiple mitochondrial DNA (mtDNA) deletions in stable tissues is a distinctive feature of several autosomal disorders, characterized by Progressive External Ophthalmoplegia (PEO), ptosis, and proximal myopathy. At least three nuclear genes are responsible for these disorders: ANT1 and C10orf2 cause autosomal dominant PEO, while mutations of DNA polymerase gammaA (POLG1 or POLG) gene on chromosome 15q25 causes both autosomal dominant and recessive forms of PEO. To investigate the contribution of these genes to the sporadic cases of PEO with multiple mtDNA deletions, we studied 31 mitochondrial myopathy patients without any family history for the disorder: 23 had PEO with myopathy, with or without the additional features of pigmentary retinopathy, ataxia, neurosensorial hypoacusia and diabetes mellitus, 7 presented isolated myopathy and one a peripheral neuropathy with ptosis. In all patients Southern blot of muscle DNA showed multiple mtDNA deletions; screening for ANT1 and C10ORF2 genes was negative. POLG analysis revealed mutations in eight patients; in six of them the mutations were allelic, while two patients were heterozygous. Five mutations were new, namely one stop codon (c.2407C>T/p.R709X) and four missense mutations (c.1085G>C/p.G268A; c.1967G>A/p.R562Q; c.2702G>C/p.R807P; c.3076C>T/p.H932W). A high degree of conservation was observed for all the new missense mutations. Only patients presenting PEO as part of their clinical phenotype had POLG mutations, in seven of them together with myopathic signs and in one with a sensori-motor peripheral neuropathy.     

Depletion of mitochondrial DNA in leucocytes harbouring the 3243A->G mtDNA mutation

Background

The 3243A→G MTTL1 mutation is the most common heteroplasmic mitochondrial DNA (mtDNA) mutation associated with disease. Previous studies have shown that the percentage of mutated mtDNA decreases in blood as patients get older, but the mechanisms behind this remain unclear.

Objectives and method

To understand the dynamics of the process and the underlying mechanisms, an accurate fluorescent assay was established for 3243A→G heteroplasmy and the amount of mtDNA in blood with real‐time polymerase chain reaction was determined. The amount of mutated and wild‐type mtDNA was measured at two time points in 11 subjects.

Results

The percentage of mutated mtDNA decreases exponentially during life, and peripheral blood leucocytes in patients harbouring 3243A→G are profoundly depleted of mtDNA.

Conclusions

A similar decrease in mtDNA has been seen in other mitochondrial disorders, and in 3243A→G cell lines in culture, indicating that depletion of mtDNA may be a common secondary phenomenon in several mitochondrial diseases. Depletion of mtDNA is not always due to mutation of a nuclear gene involved in mtDNA maintenance.The 3243A→G MTTL1 gene mutation of mitochondrial DNA (mtDNA) is the most common heteroplasmic pathogenic mtDNA mutation and is found in approximately 1 in 6000 of the general population.¹ Although first described in mitochondrial encephalomyopathy with lactic acidosis and stroke‐like episodes (MELAS), the phenotypic spectrum is extremely diverse, including isolated diabetes and deafness, hypertrophic cardiomyopathy and retinitis pigmentosa.² The clinical variability can be explained partly by tissue‐specific differences in the percentage of mutated mtDNA.^3,4Intriguingly, the percentage of mutated mtDNA is consistently lower in peripheral blood than in post‐mitotic tissues such as skeletal muscle and brain.^3,5 Serial measurements in the same subject have shown that the percentage of the 3243A→G mutation in blood decreases over time,^6,7 but the reasons for this are not clear. One possibility is that vegetative segregation in rapidly proliferating leucocyte precursors leads to high percentages of mutated mtDNA in some cells. This causes a biochemical defect of the respiratory chain, which either impairs the further proliferation of that cell lineage or leads to cell death.⁷ This would ultimately lead to a decrease in the percentage of mutated mtDNA in the daughter cells present in the peripheral blood. However, it is currently not known whether the biochemical defect is primarily because of high amounts of mutated mtDNA,⁸ low amounts of wild‐type mtDNA⁹ or a combination of both.To advance our understanding of this process, we developed and validated a highly sensitive fluorescent assay to measure the changes in heteroplasmy over time, and also measured the absolute amount of mutated and wild‐type mtDNA in 11 subjects known to harbour 3243A→G.     

A novel heteroplasmic point mutation in the mitochondrial tRNA(Lys) gene in a sporadic case of mitochondrial encephalomyopathy: de novo mutation and no transmission to the offspring

We have identified a new mutation in the tRNA(Lys) gene of mtDNA, in a 49-year-old patient with mitochondrial encephalomyopathy. The mutation is a heteroplasmic G-->A transition at position 8328, which affects the anticodon stem loop at a conserved site. The mutation was neither found in 100 controls nor in the maternal relatives of the patient. The level of mutated mtDNA was 57% in muscle, 13% in fibroblasts, and 10% in lymphocytes. Histochemistry of muscle tissue revealed cytochrome c oxidase-deficient fibers with abnormal accumulation of mitochondria. Biochemistry of muscle mitochondria showed slight cytochrome c oxidase deficiency. The mean ratio of mutant mtDNA to normal mtDNA in cytochrome c oxidase-positive muscle fibers was 59%, whereas a mean ratio of 95% was found in cytochrome c oxidase-negative fibers. The difference between cytochrome c oxidase-positive and cytochrome c oxidase-negative fibers was highly significant (P < 0.001). The mutation was not found in muscle or lymphocytes of the mother and daughter of the proband. This is the first report of a de novo point mutation in the tRNA(Lys) gene in an individual expressing disease and the first report of lack of transmission of the mutation to the offspring of a patient expressing a mitochondrial encephalomyopathy caused by a point mutation in mtDNA.     

A patient with two mitochondrial DNA mutations causing PEO and LHON

We report a 22-year-old man with PEO and optic atrophy. PEO developed before the onset of optic atrophy. The patient showed mitochondrial myopathy with cytochrome c oxidase deficient fibers.In skeletal muscle the patient was homoplasmic for the mtDNA G11778A Leber hereditary optic neuropathy (LHON) mutation and heteroplasmic for the mtDNA 5 kb “common” deletion mutation. In blood only the homoplasmic LHON mutation was identified.The occurrence of two pathogenic mtDNA mutations is exceedingly rare. The clinical findings in this patient indicate that the combination of the two mtDNA mutations resulted in the expected combined phenotype since the mtDNA deletion mutation accounted for the PEO and the mtDNA G11778A point mutation for the optic atrophy.     

Barth's syndrome-like disorder: a new phenotype with a maternally inherited A3243G substitution of mitochondrial DNA (MELAS mutation)

An Argentine male child died at 4.5 years of age of a lethal mitochondrial disease associated with a MELAS mutation and a Barth syndrome-like presentation. The child had severe failure to thrive from the early months and for approximately two years thereafter. In addition, the patient had severely delayed gross motor milestones, marked muscle weakness, and dilated cardiomyopathy that progressed to congestive heart failure. He also had persistently elevated urinary levels of 3-methylglutaconic and 2-ethylhydracrylic acids and low blood levels of cholesterol. Detailed histopathologic evaluation of the skeletal muscle biopsy showed high activity of succinate dehydrogenase, a generalized decrease of COX activity, and abundant ragged-red fibers. Electron microscopic studies revealed multiple mitochondrial abnormalities in lymphocytes and monocytes, in the striated muscle, and in the postmortem samples (muscle, heart, liver, and brain). Biochemical analysis showed a pronounced and constant lactic acidosis, and abnormal urinary organic acid excretion (unchanged in the fasting and postprandial states). In addition, in CSF there was a marked increase of lactate and beta-hydroxybutyrate (beta-HOB) and also a high systemic ratio beta-HOB/acetoacetate. Enzymatic assay of the respiratory chain in biopsied muscle showed 10% of complex I activity and 24% of complex IV activity compared with controls. Molecular studies of the mitochondrial genome revealed an A to G mutation at nucleotide pair 3243 in mitochondrial DNA, a well-known pathogenetic mutation (MELAS mutation) in all the patient's tissues and also in the blood specimens of the probands mother and sibs (4 of 5). The diagnosis of MELAS mutation was reinforced by the absence of an identifiable mutation in the X-linked G4.5 gene of the propositus. The present observation gives additional evidence of the variable clinical expression of mtDNA mutations in humans and demonstrates that all clinical variants deserve adequate investigation to establish a primary defect. It also suggests adding Barth-like syndrome to the list of phenotypes with the MELAS mutation.