6个线粒体脑肌病伴高乳酸血症和卒中样发作综合征(MELAS)家系先证者线粒体基因全序列比较分析

线粒体脑肌病伴高乳酸血症和卒中样发作综合征(Mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes, MELAS)是一种异质性很强的遗传代谢性疾病,而位于tRNA ^Leu(UUR)基因的A3243G突变是该疾病最常见的致病位点。文章对6个汉族MELAS家系的先证者进行了临床病理、分子遗传学特征分析,探讨了线粒体基因多态性对MELAS病人表型可能产生的影响。线粒体基因检测结果显示,4例先证者为A3243G阳性,其异质性比例介于29%~59%之间,临床症状的严重性和异质性程度大致呈正相关;2例MELAS/Leigh叠加综合征先证者为A3243G阴性,复发次数和严重程度重于其他4例先证者,其中1例先证者的血液和肌肉组织中发现ND5基因T13094C突变,该位点已报道与MELAS/Leigh叠加综合征、小脑共济失调相关。另外,线粒体基因全序列测序结果显示：除主要致病突变外,还存在多个与耳聋、癫痫、糖尿病、心肌病、Leigh综合征相关的线粒体基因多态位点,临床症状严重的患者其多态位点也更多。这表明MELAS综合征的复杂表型不仅受致病突变位点的直接影响,也可能受到其他与疾病相关的多态性位点的修饰作用。     

The MELAS mutation m.3243A>G promotes reactivation of fetal cardiac genes and an epithelial-mesenchymal transition-like program via dysregulation of miRNAs

The pathomechanisms underlying oxidative phosphorylation (OXPHOS) diseases are not well-understood, but they involve maladaptive changes in mitochondria-nucleus communication. Many studies on the mitochondria-nucleus cross-talk triggered by mitochondrial dysfunction have focused on the role played by regulatory proteins, while the participation of miRNAs remains poorly explored. MELAS (mitochondrial encephalomyopathy, lactic acidosis, and stroke-like episodes) is mostly caused by mutation m.3243A>G in mitochondrial tRNA^Leu(UUR) gene. Adverse cardiac and neurological events are the commonest causes of early death in m.3243A>G patients. Notably, the incidence of major clinical features associated with this mutation has been correlated to the level of m.3243A>G mutant mitochondrial DNA (heteroplasmy) in skeletal muscle. In this work, we used a transmitochondrial cybrid model of MELAS (100% m.3243A>G mutant mitochondrial DNA) to investigate the participation of miRNAs in the mitochondria-nucleus cross-talk associated with OXPHOS dysfunction. High-throughput analysis of small-RNA-Seq data indicated that expression of 246 miRNAs was significantly altered in MELAS cybrids. Validation of selected miRNAs, including miR-4775 and miR-218-5p, in patient muscle samples revealed miRNAs whose expression declined with high levels of mutant heteroplasmy. We show that miR-218-5p and miR-4775 are direct regulators of fetal cardiac genes such as NODAL, RHOA, ISL1 and RXRB, which are up-regulated in MELAS cybrids and in patient muscle samples with heteroplasmy above 60%. Our data clearly indicate that TGF-β superfamily signaling and an epithelial-mesenchymal transition-like program are activated in MELAS cybrids, and suggest that down-regulation of miRNAs regulating fetal cardiac genes is a risk marker of heart failure in patients with OXPHOS diseases.     

Mitochondrial ND5 gene variation associated with encephalomyopathy and mitochondrial ATP consumption

Mitochondrial encephalomyopathy and lactic acidosis with strokelike episodes (MELAS) is a severe young onset stroke disorder without effective treatment. We have identified a MELAS patient harboring a 13528A-->G mitochondrial DNA (mtDNA) mutation in the Complex I ND5 gene. This mutation was homoplasmic in mtDNA from patient muscle and nearly homoplasmic (99.9%) in blood. Fibroblasts from the patient exhibited decreased mitochondrial membrane potential (Deltapsim) and increased lactate production, consistent with impaired mitochondrial function. Transfer of patient mtDNA to a new nuclear background using transmitochondrial cybrid fusions confirmed the pathogenicity of the 13528A-->G mutation; Complex I-linked respiration and Deltapsim were both significantly reduced in patient mtDNA cybrids compared with controls. Inhibition of the adenine nucleotide translocase or the F1F0-ATPase with bongkrekic acid or oligomycin caused a loss of potential in patient mtDNA cybrid mitochondria, indicating a requirement for glycolytically generated ATP to maintain Deltapsim. This was confirmed by inhibition of glycolysis with 2-deoxy-D-glucose, which caused depletion of ATP and mitochondrial depolarization in patient mtDNA cybrids. These data suggest that in response to impaired respiration due to the mtDNA mutation, mitochondria consume ATP to maintain Deltapsim, representing a potential pathophysiological mechanism in human mitochondrial disease.     

Metabolically induced heteroplasmy shifting and l-arginine treatment reduce the energetic defect in a neuronal-like model of MELAS

The m.3243A>G variant in the mitochondrial tRNA(Leu(UUR)) gene is a common mitochondrial DNA (mtDNA) mutation. Phenotypic manifestations depend mainly on the heteroplasmy, i.e. the ratio of mutant to normal mtDNA copies. A high percentage of mutant mtDNA is associated with a severe, life-threatening neurological syndrome known as MELAS (mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episodes). MELAS is described as a neurovascular disorder primarily affecting the brain and blood vessels, but the pathophysiology of the disease is poorly understood. We developed a series of cybrid cell lines at two different mutant loads: 70% and 100% in the nuclear background of a neuroblastoma cell line (SH-SY5Y). We investigated the impact of the mutation on the metabolism and mitochondrial respiratory chain activity of the cybrids. The m.3243A>G mitochondrial mutation induced a metabolic switch towards glycolysis in the neuronal cells and produced severe defects in respiratory chain assembly and activity. We used two strategies to compensate for the biochemical defects in the mutant cells: one consisted of lowering the glucose content in the culture medium, and the other involved the addition of l-arginine. The reduction of glucose significantly shifted the 100% mutant cells towards the wild-type, reaching a 90% mutant level and restoring respiratory chain complex assembly. The addition of l-arginine, a nitric oxide (NO) donor, improved complex I activity in the mutant cells in which the defective NO metabolism had led to a relative shortage of NO. Thus, metabolically induced heteroplasmy shifting and l-arginine therapy may constitute promising therapeutic strategies against MELAS.     

Mitochondrial DNA haplogroups do not play a role in the variable phenotypic presentation of the A3243G mutation

Thirty-five mitochondrial (mt) DNAs from Spain that harbor the mutation A3243G in association with either MELAS (mitochondrial myopathy, encephalopathy, lactic acidosis, and strokelike episodes) syndrome or a wide array of disease phenotypes (ranging from diabetes and deafness to a mixture of chronic progressive external ophthalmoplegic symptoms and strokelike episodes) were studied by use of high-resolution restriction fragment length polymorphism analysis and control-region sequencing. A total of 34 different haplotypes were found, indicating that all instances of the A3243G mutation are probably due to independent mutational events. Haplotypes were distributed into 13 haplogroups whose frequencies were close to those of the general Spanish population. Moreover, there was no statistically significant difference in haplogroup distribution between patients with MELAS and those with disease phenotypes other than MELAS. Overall, these data indicate that the A3243G mutation harbors all the evolutionary features expected from a severely deleterious mtDNA mutation under strong negative selection, and they reveal that European mtDNA backgrounds do not play a substantial role in modulating the mutation's phenotypic expression.     

Screening of common mitochondrial mutations in Chinese patients with mitochondrial encephalomyopathies

To investigate the spectrum of common mitochondrial mutations in Northern China during the years of 2000-2005, 552 patients of mitochondrial encephalomyopathies clinically diagnosed as MELAS, MERRF or Leigh's syndrome, 14 cases of LHON and 46 cases of aminoglycoside induced deafness along with their family members, accepted routine point mutation tests at nucleotide positions 3243, 8344, 8993, 11778 or 1555 in mitochondrial genome. PCR-RFLP analysis, site-specific PCR and PCR-sequencing methods were used to identify the mutations. Fifty-seven cases with A3243G mutation, 4 cases with A8344G, 2 cases with T8993C and 1 case with T8993G were identified from the 552 encephalomyopathy patients. In addition, one case with G11778A was found from the 14 cases of LHON, and 5 cases with A1555G from the 46 cases of aminoglycoside ototoxicity patients. Additional screening for T8356G and T3271C merely had limited significance for the diagnosis of MERRF and MELAS. Differential diagnosis among mitochondrial encephalomyopathies was often complicated due to many similar clinical manifestations. For A3243G mutation, the proportion of mutant mtDNA was not related to severity of the disease but to the age of onset.     

De novo mutation in the mitochondrial ATP synthase subunit 6 gene (T8993G) with rapid segregation resulting in Leigh syndrome in the offspring

The mutation in the mitochondrial ATP synthase subunit 6 gene (ATP6 T8993G) was identified in a male infant who died at age 15 months of Leigh syndrome. He had 94% mutated mitochondrial DNA (mtDNA) in muscle and 92% in lymphocytes. His mother was healthy but had 37% mutated mtDNA in muscle and 38% in lymphocytes. The proband's brother, who was also healthy, had 44% mutated mtDNA in lymphocytes. No mutated mtDNA was detected in muscle and lymphocytes from the maternal grandmother of the proband or in lymphocytes from 15 other maternal relatives, showing that the first carrier of the ATP6 T8993G mutation in this family was the mother of the proband. This study shows that this point mutation may occur at substantial levels in a carrier of a de novo mutation and rapid segregation with high levels of mutated mtDNA causing neurodegenerative disease may occur in the second generation.     

A specific point mutation in the mitochondrial genome of Caucasians with MELAS

Summary The mitochondrial DNA (mtDNA) of Japanese patients suffering from the syndrome of mitochondrial myopathy, encephalopathy, lactic acidosis and strokelike episodes (MELAS) exhibits a specific heteroplasmic AG transition in the tRNA^Leu at position 3243. In this study, we investigated mtDNA from skeletal muscle, cardiac muscle, brain, liver, diaphragm, fibroblasts and blood cells of four Caucasians with MELAS, one younger healthy sister of two MELAS patients, and eleven controls. We found that 1) the mutation was present in all investigated tissues of Caucasians with MELAS but not in controls, 2) within a single patient, the tissue-specific variation of the copy number of mutated mtDNA covered the same range as in the skeletal muscle of different patients, 3) the mutation was also present in the blood cells of the healthy sister of two MELAS siblings.     

Clinical phenotype, prognosis and mitochondrial DNA mutation load in mitochondrial encephalomyopathies

We studied 42 individuals, including 8 patients with either complete or partial syndrome of mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS), 8 patients with either complete or partial syndrome of myoclonic epilepsy with ragged-red fibers (MERRF) and 26 maternal family members who carried either the A3243G or A8344G mutation of mitochondrial DNA (mtDNA). Clinical manifestations and prognosis were followed up in the patients harboring the A3243G or A8344G mutation. The relationship between clinical features and proportions of mutant mtDNAs in muscle biopsies, blood cells and/or hair follicles was studied. In the 8 regularly followed patients with the A3243G mutation, 4 died within 1 month to 7 years due to status epilepticus and/or recurrent stroke-like episodes. Two patients developed marked mental deterioration and 2 remained stationary. All of the patients harboring the A8344G mutation were stable or deteriorated slightly, except for 1 patient who died due to brain herniation after putaminal hemorrhage. The A3243G and A8344G mtDNA mutations were heteroplasmic in the muscle biopsies, blood cells and hair follicles of both the probands and their maternal family members. The mean proportion of A3243G mutant mtDNA in the muscle biopsies of the patients with MELAS syndrome (68.5 ± 21.3%, range 33–92%) was significantly higher than that of the asymptomatic family members (37.1 ± 12.6%, range 0–51%). The average proportions of A8344G mutant mtDNA in the muscle biopsies (90.1 ± 3.9%, range 89–95%) and hair follicles (93.9 ± 6.4%, range 84–99%) of the patients with MERRF syndrome were also significantly higher than those of the asymptomatic family members (muscle: 40.3 ± 39.5%, range 1–80%; hair follicles: 51.0 ± 44.5%, range 0.1–82%). We concluded that measurement of the proportion of mutant mtDNA in muscle biopsies may provide useful information in the identification of symptomatic patients with mitochondrial encephalomyopathies. For patients with the A3243G mutation, the prognosis was related to status epilepticus and the number of recurrent stroke-like episodes and was much worse than for patients with the A8344G mutation of mtDNA, who had stable or slowly deteriorating clinical courses.     

A case of a de novo A3243G mutation in mitochondrial DNA in a patient with diabetes and deafness

A female individual with symptoms of the Maternally Inherited Diabetes and Deafness syndrome (MIDD) was diagnosed positive for the A3243G mutation in her mitochondrial DNA. Heteroplasmy levels were 18% in DNA from leucocytes and 55% in oral mucosa DNA. This finding corroborates the diagnosis of MIDD. Normally, this mutation is present in all the individuals within the maternal lineage of the pedigree. In this particular pedigree the mutation was undetectable in the mother of the proband and her three brothers. Paternity testing using polymorphic chromosomal DNA markers supported the assumed family relationship. We conclude that we are dealing in this proband with the de novo appearance of the A3243G mutation that has reached high heteroplasmy values in at least two tissues within one generation. This observation supports the hypothesis that during embryogenesis mitochondrial DNA goes through a genetic bottleneck with a limited number of segregating units.     

Sequence and functional analyses of mtDNA in a maternally inherited family with bipolar disorder and depression

Recent studies suggest that mutations/polymorphisms of mitochondrial DNA (mtDNA) are associated with neuropsychiatric diseases. We identified a patient with major depression and epilepsy. Some family members in the pedigree of the proband had bipolar disorder, depression, suicide, or psychotic disorder not otherwise specified. The mode of inheritance was compatible with maternal inheritance with low penetration. We assumed that the mental disorder in this family might be associated with maternally inherited mitochondrial DNA (mtDNA) mutation. We sequenced the entire mtDNA of the proband. Among the 34 base substitutions detected in the proband, two homoplasmic, nonsynonymous single substitutions of mtDNA, T3394C in MT-ND1 and A9115G in MT-ATP6, were suspected to cause functional impairment, because the former was reported to be disease-related and the latter is vary rare. To study the functional outcome of these substitutions, we examined mitochondrial membrane potential and the activity of mitochondrial ATP synthesis in the transmitochondrial cybrids, but no significant impairment was detected. The data did not support our hypothesis that these disorders in this family are caused by mtDNA mutation(s).     

Mitochondrial DNA mutations in mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episodes (MELAS)

The total sequences of mitochondrial DNA were determined in two patients with juvenile-onset mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episodes (MELAS) due to Complex I deficiency. Patients 1 and 2 had three and two unique point mutations, respectively, causing replacement of phylogenically conserved amino acids. A transition from G to A was found at nucleotide position 5601 in the alanine tRNA gene of Patient 2, and a transition from A to G was found at 3243 in the leucine (UUR) tRNA gene of both patients. The latter mutation located at the phylogenically conserved 5' end of the dihydrouridine loop of the tRNA molecule, and was present in two patients with adult-onset MELAS and absent in controls. These results indicate that a mass of mtDNA mutations including the A-to-G transition in the tRNA(Leu) gene is a genetic cause of MELAS.     

The study of mitochondrial A3243G mutation in different samples

Mitochondrial encephalopathy, lactic acidosis and stroke-like episodes syndrome (MELAS) is the most frequent syndromic manifestation of A3243G mutation in mitochondrial DNA. Detection of A3243G mutation in blood is less helpful for the diagnosis of MELAS and the carriers, and the mutation ratio in blood correlates only in a limited extent with the severity of the disease. Here we compared the ratio of A3243G mutation in four easily available samples (blood, urine, hair follicle and saliva) in patients with MELAS carrying A3243G mutation as well as their maternal relatives from 32 families, to find out the samples appropriate for the detection of the patients and carriers and useful for the evaluation of clinical severity from their mutation ratio. In MELAS patients and the carriers with minor symptoms or normal phenotype, A3243G mutation ratio was significantly higher in urine than in blood. A close correlation between A3243G mutation ratio in blood and that in urine, hair follicles and saliva was found in the probands and their relatives. Clinical features closely correlated with the mutation ratio in urine. Measurement of A3243G mutation ratio in urine is a non-invasive, convenient and rapid method with its diagnostic meaning superior to blood testing.     

Respiration-deficient cells are caused by a single point mutation in the mitochondrial tRNA-Leu (UUR) gene in mitochondrial myopathy, encephalopathy, lactic acidosis, and strokelike episodes (MELAS).

MELAS (mitochondrial myopathy, encephalopathy, lactic acidosis, and strokelike episodes) is a major subgroup of heterogeneous mitochondrial diseases. For identifying a mutation in the mitochondrial gene, we isolated, from the same muscle tissue from a patient with MELAS, cell lines with distinctly different phenotypes: one was respiration-deficient, and the other was apparently normal. Compared with the normal cells, only one A-to-G nucleotide transition at nucleotide 3243 in the tRNA-Leu (UUR) gene was found in whole mtDNA of the respiration-deficient cells. This mutation was also found in eight patients, from unrelated families, who had MELAS in a heteroplasmic manner but was not found in control individuals. Therefore, the single point mutation causes the functional abnormality in the respiratory chain of mitochondria.     

Accurate detection and quantitation of heteroplasmic mitochondrial point mutations by pyrosequencing

Disease-causing mutations in mitochondrial DNA (mtDNA) are typically heteroplasmic and therefore interpretation of genetic tests for mitochondrial disorders can be problematic. Detection of low level heteroplasmy is technically demanding and it is often difficult to discriminate between the absence of a mutation or the failure of a technique to detect the mutation in a particular tissue. The reliable measurement of heteroplasmy in different tissues may help identify individuals who are at risk of developing specific complications and allow improved prognostic advice for patients and family members. We have evaluated Pyrosequencing technology for the detection and estimation of heteroplasmy for six mitochondrial point mutations associated with the following diseases: Leber's hereditary optical neuropathy (LHON), G3460A, G11778A, and T14484C; mitochondrial encephalopathy with lactic acidosis and stroke-like episodes (MELAS), A3243G; myoclonus epilepsy with ragged red fibers (MERRF), A8344G, and neurogenic muscle weakness, ataxia, and retinitis pigmentosa (NARP)/Leighs: T8993G/C. Results obtained from the Pyrosequencing assays for 50 patients with presumptive mitochondrial disease were compared to those obtained using the commonly used diagnostic technique of polymerase chain reaction (PCR) and restriction enzyme digestion. The Pyrosequencing assays provided accurate genotyping and quantitative determination of mutational load with a sensitivity and specificity of 100%. The MELAS A3243G mutation was detected reliably at a level of 1% heteroplasmy. We conclude that Pyrosequencing is a rapid and robust method for detecting heteroplasmic mitochondrial point mutations.     

The impact of mitochondrial tRNA mutations on the amount of ATP synthase differs in the brain compared to other tissues

The impact of point mutations in mitochondrial tRNA genes on the amount and stability of respiratory chain complexes and ATP synthase (OXPHOS) has been broadly characterized in cultured skin fibroblasts, skeletal muscle samples, and mitochondrial cybrids. However, less is known about how these mutations affect other tissues, especially the brain. We have compared OXPHOS protein deficiency patterns in skeletal muscle mitochondria of patients with Leigh (8363G>A), MERRF (8344A>G), and MELAS (3243A>G) syndromes. Both mutations that affect mt-tRNA(Lys) (8363G>A, 8344A>G) resulted in severe combined deficiency of complexes I and IV, compared to an isolated severe defect of complex I in the 3243A>G sample (mt-tRNA(LeuUUR). Furthermore, we compared obtained patterns with those found in the heart, frontal cortex, and liver of 8363G>A and 3243A>G patients. In the frontal cortex mitochondria of both patients, the patterns of OXPHOS deficiencies differed substantially from those observed in other tissues, and this difference was particularly striking for ATP synthase. Surprisingly, in the frontal cortex of the 3243A>G patient, whose ATP synthase level was below the detection limit, the assembly of complex IV, as inferred from 2D-PAGE immunoblotting, appeared to be hindered by some factor other than the availability of mtDNA-encoded subunits.     

MELAS syndrome, cardiomyopathy, rhabdomyolysis, and autism associated with the A3260G mitochondrial DNA mutation

The A to G transition mutation at position 3260 of the mitochondrial genome is usually associated with cardiomyopathy and myopathy. One Japanese kindred reported the phenotype of mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS syndrome) in association with the A3260G mtDNA mutation. We describe the first Caucasian cases of MELAS syndrome associated with the A3260G mutation. Furthermore, this mutation was associated with exercise-induced rhabdomyolysis, hearing loss, seizures, cardiomyopathy, and autism in the large kindred. We conclude that the A3260G mtDNA mutation is associated with wide phenotypic heterogeneity with MELAS and other “classical” mitochondrial phenotypes being manifestations.     

Intracellular heteroplasmy for disease-associated point mutations in mtDNA: implications for disease expression and evidence for mitotic segregation of heteroplasmic units of mtDNA

Studies in vitro have shown that a respiratorydeficient phenotype is expressed by cells when the proportion of mtDNA with a disease-associated mutation exceeds a threshold level, but analysis of tissues from patients with mitochondrial encephalomyopathy, lactic acidosis, and strokelike episodes (MELAS) have failed to show a consistent relationship between the degree of heteroplasmy and biochemical expression of the defect. One possible explanation for this phenomenon is that there is variation of heteroplasmy between individual cells that is not adequately reflected by the mean heteroplasmy for a tissue. We have confirmed this by study of fibroblast clones from subjects heteroplasmic for the MELAS 3243 (A G) mtDNA mutation. Similar observations were made with fibroblast clones derived from two subjects heteroplasmic for the 11778 (GA) mtDNA mutation of Leber's hereditary optic neuropathy. For the MELAS 3243 mutation, the distribution of mutant mtDNA between different cells was not randomly distributed about the mean, suggesting that selection against cells with high proportions of mutant mtDNA had occurred. To explore the way in which heteroplasmic mtDNA segregates in mitosis we followed the distribution of heteroplasmy between clones over approximately 15 generations. There was either no change or a decrease in the variance of intercellular heteroplasmy for the MELAS 3243 mutation, which is most consistent with segregation of heteroplasmic units of multiple mtDNA molecules in mitosis. After mitochondria from one of the MELAS 3243 fibroblast cultures were transferred to a mitochondrial DNA-free (⁰) cell line derived from osteosarcoma cells by cytoplast fusion, the mean level and intercellular distribution of heteroplasmy was unchanged. We interpret this as evidence that somatic segregation (rather than nuclear background or cell differentiation state) is the primary determinant of the level of heteroplasmy.     

Identification of mtDNA mutation in a pedigree with gestational diabetes, deafness, Wolff-Parkinson-White syndrome and placenta accreta

Mitochondrial DNA (mtDNA) defects are associated with a number of human disorders. Although many occur sporadically, maternal transmission is the hallmark of diseases due to mtDNA point mutations. The same mutation may manifest strikingly different phenotypes; for example, the A to G substitution at np 3243 was first reported in patients with mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (the MELAS syndrome), but is also found in patients with diabetes and deafness. Here we present a case of gestational diabetes, deafness, premature greying, placenta accreta and Wolff-Parkinson-White (WPW) syndrome associated with a mtDNA mutation. Although this is the first report of such an association, study of 27 other patients with WPW syndrome failed to confirm that this mtDNA mutation is a common cause of such pre-excitation disorders.