Acquisition of the wobble modification in mitochondrial tRNALeu(CUN) bearing the G12300A mutation suppresses the MELAS molecular defect

The A3243G mutation in the mitochondrial gene for human mitochondrial (mt) tRNA(Leu(UUR)), responsible for decoding of UUR codons, is associated with mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS). We previously demonstrated that this mutation causes defects in 5-taurinomethyluridine (taum(5)U) modification at the anticodon first (wobble) position of the mutant mt tRNA(Leu(UUR)), leading to a UUG decoding deficiency and entraining severe respiratory defects. In addition, we previously identified a heteroplasmic mutation, G12300A, in the other mt leucine tRNA gene, mt tRNA(Leu(CUN)), which functions as a suppressor of the A3243G respiratory defect in cybrid cells containing A3243G mutant mtDNA. Although the G12300A mutation converts the anticodon sequence of mt tRNA(Leu(CUN)) from UAG to UAA, this tRNA carrying an unmodified wobble uridine still cannot decode the UUG codon. Mass spectrometric analysis of the suppressor mt tRNA(Leu(CUN)) carrying the G12300A mutation from the phenotypically revertant cells revealed that the wobble uridine acquires de novo taum(5)U modification. In vitro translation confirmed the functionality of the suppressor tRNA for decoding UUG codons. These results demonstrate that the acquisition of the wobble modification in another isoacceptor tRNA is critical for suppressing the MELAS mutation, and they highlight the primary role of the UUG decoding deficiency in the molecular pathogenesis of MELAS syndrome.     

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.     

Mitochondrial tRNALeu isoforms in lung carcinoma cybrid cells containing the np 3243 mtDNA mutation

We have investigated the representation of structural isoforms of the two mitochondrial leucyl tRNAs in lung carcinoma cybrid cell lines containing the np 3243 (MELAS) mtDNA mutation, alone or in combination with the np 12300 suppressor mutation. The mutant tRNALeu(UUR) is aminoacylated very poorly or not at all, whereas the suppressor tRNALeu(CUN) is efficiently aminoacylated. Deacylated mitochondrial tRNALeu(CUN) is present, in all human cells tested, in two structural isoforms that are separable on denaturing gels, indicating a difference in primary structure. The ratio of the two isoforms differs between cell types and is strongly biased towards one isoform in lung carcinoma cybrids containing high levels of the np 3243 mutation, compared with control cybrids. We propose that structural modification of tRNALeu(CUN) could be a natural suppression mechanism for the np 3243 and other mitochondrial tRNALeu(UUR) mutations and could underlie some of the phenotypic variability of np 3243 disease.      

Mitochondrial gene mutations in familial non-insulin-dependent diabetes mellitus in Taiwan

Mitochondrial gene mutations are found to cause certain forms of diabetes mellitus and related syndromes. To study the prevalence of mitochondrial gene mutations in subjects with non-insulin-dependent diabetes mellitus (NIDDM) in Taiwan, 23 pedigrees with multiple siblings affected with NIDDM were consecutively collected from patients living in northern Taiwan. The A-to-G mutation at position 3243 np in the tRNALeu gene and the mutation at position 8344 were screened by PCR-RFLP methods and confirmed by direct DNA sequence analysis. Among 23 NIDDM pedigrees, one pedigree was found to carry the 3243 np mutation. There was no 8344 np mutation in this series. Clinical features of this pedigree were consistent with mitochondrial disease in terms of maternal transmission, relatively early onset, non-obesity, insulin-requirement and association with hearing impairment. There was no correlation between the degree of heteroplasmy of mitochondrial gene mutation in leukocyte DNA and clinical severity. We conclude that a mitochondrial gene defect is an important genetic factor in familial cases with NIDDM in Taiwan.     

线粒体DNA 3243、3316点突变与2型糖尿病

目的研究2型糖尿病患者中线粒体tRNA^Leu(UUR)基因3243A／G突变和NADH脱氢酶亚单位1基因(ND1)基因3316G／A突变的发生频率及其与2型糖尿病的相关性。方法应用聚合酶链反应及限制性片段长度多态性技术检测225例中国云南2型糖尿病患者和195名无糖尿病家族史的健康对照者有无3243A／G突变和3316G／A突变，并经DNA直接测序确证。结果2型糖尿病患者中3316G／A突变者5例(2．22％)，195例对照者中突变者2例(1．03％)，突变发生率在两组间差异无统计学意义(P=0．4576)；两组中无线粒体3243A／G突变。结论线粒体tRNA^Leu(UUR)基因3243A／G突变在中国云南2型糖尿病人群中发生频率低，可能不是云南人群中2型糖尿病的常见病因。线粒体ND1基因3316G／A突变可能仅为人群中线粒体基因组的正常多态。其他的遗传、环境及子宫内因素需要进一步研究。     

Prevalence of A-to-G mutation at nucleotide 3243 of the mitochondrial tRNALeu(UUR) gene in Japanese patients with diabetes mellitus and end stage renal disease

The A-to-G mutation at nucleotide 3243 of the mitochondrial tRNA ^Leu(UUR) gene (mt.3243A>G) is associated with both diabetes mellitus and myopathy, encephalopathy, lactic acidosis, and stroke-like episodes (MELAS). Recently, this mutation was found in three diabetic subjects with progressive kidney disease, suggesting that it may be a contributing factor in the development of kidney disease in patients with diabetes. The aim of this study was to evaluate the contribution of this mutation to the development of end stage renal disease (ESRD) in patients with diabetes. The study group consisted of 135 patients with diabetes and ESRD. The control group consisted of 92 non-diabetic subjects with ESRD who were receiving hemodialysis. The mt.3243A>G mutation was detected by polymerase chain reaction-restriction frag-ment length polymorphism (PCR-RFLP). We found the mt.3243A>G mutation in eight patients (8/135; 5.9%), all of whom were initially diagnosed with type II diabetes. Five of the eight patients were subsequently also diagnosed with MELAS. We did not find the mutation in any of the 92 non-diabetic subjects with ESRD. The prevalence of this mutation was 6.5-fold higher in patients with diabetes and ESRD than in those with diabetes alone (8/135 vs 5/550, respectively; χ² = 13.704; P = 0.0002). The mt.3243A>G mutation may be a contributing genetic factor in the development of ESRD in Japanese patients with diabetes. Received: November 29, 2000 / Accepted: February 27, 2001     

Can mitochondrial DNA mutations cause sperm dysfunction?

Very low levels of somatic mitochondrial (mt)DNA deletions have been identified in the semen of infertile men. It has been suggested that these mutations cause infertility through an effect on sperm motility, but there has been no direct evidence to show that mutant mtDNA can affect sperm function. We have carried out semen analysis on a male harbouring the A3243G mtDNA mutation and show that high levels of mutant mtDNA strongly correlate with low sperm motility.     

Combination of mtDNA mutations in a patient with a mitochondrial multisystem syndrome

We report a patient who manifested a heterogeneous clinical presentation, including hypertrophic cardiomyopathy and hypothyroidism, with initially limited central nervous system involvement, and who harbored the mitochondrial (mt)DNA A3243G mutation. MtDNA analyses also revealed deleted genomes in muscle and blood. This atypical molecular combination may have influenced the clinical phenotype. Received: August 5, 1999 / Accepted: October 5, 1999     

The np 3243 MELAS mutation: damned if you aminoacylate, damned if you don't

The np 3243 MELAS mtDNA mutation in tRNA(leu(UUR))has been variously proposed as a loss-of-function or as a gain-of-function mutation, based on apparently contradictory studies in cultured cell lines. A new report describing the molecular effects of the mutation in vivo now mirrors this variability. This should prompt a more systematic re-investigation of cells carrying the mutation, in order to separate primary from secondary and pathogenic from compensatory effects, all of which may contribute to disease phenotype. Nuclear genetic and developmental background, mitochondrial haplotype, and epigenetic effects may all influence the pathological outcome. Defects in both base-modification and aminoacylation of the mutant tRNA could play critical roles.     

Another observation with VATER association and a complex IV respiratory chain deficiency

The VATER association of vertebral anomalies (V), anal atresia (A), esophageal atresia and/or tracheo-esophageal fistula (TE), radial and renal anomalies (R) is a common congenital association of unknown origin with probably heterogeneous causes. Here, we report on a girl presenting with pre- and postnatal growth retardation, esophageal atresia, vertebral and costal anomalies and a unilateral radial defect, consistent with the diagnosis of VATER association. In the first month of life, she presented with failure to thrive, severe episodes of hypoglycemia, liver dysfunction and high levels of lactate, which prompted us to perform metabolic screening. A complex IV respiratory chain deficiency (RCD) was diagnosed on a liver biopsy. The respiratory chain defect was not observed in skin fibroblasts. No mtDNA point mutation or deletion was identified. The girl is now 9 years old and has a normal mental development but persistent feeding difficulties and moderate hyperlactatemia. To our knowledge, this is the second report of VATER association with mitochondrial disorder. In a previous report, a VACTERL association was observed in a girl with the mitochondrial A3243G point mutation. The association of VATER phenotype with a mitochondrial disorder may be coincidental but could also suggest that the presence of multiple malformations is the result of the antenatal expression of RCD.     

Higher proportion of mitochondrial A3243G mutation in blood than in skeletal muscle in a patient with cardiomyopathy and hearing loss

Phenotypes of individuals with the mitochondrial A3243G mutation and amount of mutant DNA in different tissues can be very variable, but the proportion of mutant DNA was consistantly lower in blood than muscle in previously studied patients. We detected the A3243G mutation in a 54-year-old patient with cardiomyopathy and hearing loss, where the amount of mutant DNA was higher in blood (19%) than in muscle (6%). This shows that the level of A3243G mutation is not always lower in rapidly dividing tissues such as blood than in muscle, as has been presumed until now.     

The pathogenic A4269G mutation in human mitochondrial tRNA(Ile) alters the T-stem structure and decreases the binding affinity for elongation factor Tu

The A4269G mutation in the human mitochondrial (mt) tRNA(Ile) gene is associated with fatal cardiomyopathy. This mutation completely inhibits protein synthesis in mitochondria, thereby significantly reducing their respiratory activity. The steady-state amount of tRNA(Ile) in cells bearing the A4269G mutation is almost half that of control cells. We previously reported that this mutation causes tRNA(Ile) to be unstable both in vivo and in vitro. To investigate whether the instability of the mutant tRNA(Ile) is due to structural alterations, a nuclease-probing experiment was performed with a mitochondrial enzymatic extract, which showed that the A4269G mutation destabilizes the T-stem of the mutant tRNA(Ile). In addition, measurements of the binding affinity of the aminoacylated mutant tRNA(Ile) for mt elongation factor Tu (EF-Tu) showed that the mutant tRNA(Ile) binds mt EF-Tu less efficiently than the wild-type does. This observation provides insight into the molecular pathology associated with tRNA dysfunction caused by this pathogenic point mutation.     

Nonrandom tissue distribution of mutant mtDNA.

Heteroplasmic mitochondrial DNA (mtDNA) defects are an important cause of inherited human disease. On a cellular level, the percentage of mutant mtDNA is the principal factor behind the expression of the genetic defect. Marked variation in the level of mutant mtDNA among tissues is thought to be responsible for the diverse clinical phenotypes associated with the same pathogenic mtDNA mutation. This study was designed to determine whether the percentage level of a pathogenic mtDNA molecule is determined by a purely random process. The tissue distribution of the A3243G MELAS point mutation was analyzed in five individuals who were members of a family with maternally inherited diabetes and deafness. The level of mutant mtDNA was measured in four tissues in three individuals and three tissues in two individuals. The highest level of mutant mtDNA occurred in skeletal muscle, followed by hair follicles, and then buccal mucosa, with the lowest levels in blood (leucocyte/platelet fraction). The probability of observing any strict hierarchy in family is 4.82 x 10(-5). These results indicate that the distribution of the A3243G mutation is not solely determined by random processes.     

The mitochondrial DNA G13513A MELAS mutation in the NADH dehydrogenase 5 gene is a frequent cause of Leigh-like syndrome with isolated complex I deficiency

Leigh syndrome is a subacute necrotising encephalomyopathy frequently ascribed to mitochondrial respiratory chain deficiency. This condition is genetically heterogeneous, as mutations in both mitochondrial (mt) and nuclear genes have been reported. Here, we report the G13513A transition in the ND5 mtDNA gene in three unrelated children with complex I deficiency and a peculiar MRI aspect distinct from typical Leigh syndrome. Brain MRI consistently showed a specific involvement of the substantia nigra and medulla oblongata sparing the basal ganglia. Variable degrees of heteroplasmy were found in all tissues tested and a high percentage of mutant mtDNA was observed in muscle. The asymptomatic mothers presented low levels of mutant mtDNA in blood leucocytes. This mutation, which affects an evolutionary conserved amino acid (D393N), has been previously reported in adult patients with MELAS or LHON/MELAS syndromes, emphasising the clinical heterogeneity of mitochondrial DNA mutations. Since the G13513A mutation was found in 21% of our patients with Leigh syndrome and complex I deficiency (3/14), it appears that this mutation represents a frequent cause of Leigh-like syndrome, which should be systematically tested for molecular diagnosis in affected children and for genetic counselling in their maternal relatives.     

线粒体脑肌病伴乳酸血症和卒中样发作综合征的临床特征及遗传学研究

目的探讨线粒体脑肌病伴乳酸血症和卒中样发作（MELAS）综合征临床与分子遗传学特征,寻找MELAS线粒体DNA（mtDNA）A3243G点突变比例与临床特征的关联性。方法对2001年1月至2008年1月在首都医科大学附属北京儿童医院神经内科住院和门诊临床疑似线粒体脑肌病的患儿,行外周血白细胞mtDNA A3243G点突变筛查、血乳酸检测和神经影像学等检查。A3243G点突变阳性病例中选取符合MELAS临床疑似诊断标准的患儿（突变阳性组）,对其家系进行调查,采集家族成员血进行mtDNA A3243G点突变筛查;A3243G点突变阴性病例中选取符合MELAS临床疑似诊断标准的患儿行肌肉病理活检和肌肉A3243G点突变筛查（突变阴性组）。分析比较两组的临床资料及MELAS遗传学特征。结果研究期间共有272例疑似线粒体脑肌病的患儿进行了外周血白细胞A3243G点突变的筛查。A3243G点突变的20例阳性标本中,突变均为异胞质性（heteroplasmy）,18例符合MELAS的临床疑似诊断标准。血细胞中突变型mtDNA的比例为9.0%-50.0%,其中4例同时在肌肉组织检测到相同突变,突变比例为42.4%-64.8%。临床症状以惊厥、乏力、智力进行性倒退、发热、呕吐、视力障碍和失语为主,身材矮小和体毛增多为主要体征,13例合并癫,血乳酸均升高,头颅CT/MRI显示双侧对称性苍白球钙化和脑梗死信号。A3243G点突变筛查阴性标本中有4例临床符合MELAS临床疑似诊断标准,肌肉病理可见破碎红边纤维,肌肉A3243G点突变筛查阴性。14个家庭中的37名家庭成员采集了外周血进行mtDNA A3243G点突变筛查,突变阳性组中患儿母亲5名检测到A3243G点突变,突变比例分别为3.0%,5.0%,11.8%,21.3%和26.9%,同胞兄弟4名检测到A3243G突变,突变比例分别为19.3%、33.3%,37.5%和41.5%,均无临床症状,其他成员未检测到突变。本研究A3243G点突变比例与发病年龄和就诊年龄呈负相关趋势,与病程未?     

Complex I deficiency is associated with 3243G:C mitochondrial DNA in osteosarcoma cell cybrids

143B.206 rho degrees cells were repopulated with mitochondria from a MELAS patient harbouring a mixture of 3243G:C and 3243A:T mitochondrial DNA. A number of biochemical assays were performed on selected cybrids with various proportions of the two types of mitochondrial DNA. These assays revealed a marked decrease in oxygen consumption with pyruvate, a complex I substrate, in cybrids containing 60% to 90% 3243G:C mitochondrial DNA. Moreover, these cybrids showed decreased synthesis of a number of polypeptides in a mitochondrial in vitro translation assay. A cybrid line with a very high level of 3243G:C mitochondrial DNA (95%) had additional deficiencies in complexes III and IV and there was a marked generalised decrease in mitochondrial translation in this cybrid. The observation of complex I deficiency is consistent with previously reported enzymatic measurements of muscle homogenates from MELAS patients with the 3243G:C mutation.      

线粒体tRNALeu(UUR)基因nt3243A→G突变糖尿病临床特点分析

目的 了解线粒体tRNALeu(UUR)基因nt3243A→G突变在上海及江浙地区家族性糖尿病人群中的发生率及其临床特点.方法 应用聚合酶链反应-限制性片段长度多态结合直接测序方法对随机抽取的无亲缘关系的770个糖尿病家系的先证者进行线粒体tRNA<'Leu(UUR)>基因nt3243A→G突变的筛查,并进一步对阳性先证者家系进行家系遗传学及临床特点分析.结果 在770个糖尿病先证者中发现13例(1.69%)nt3243A→G突变.13个先证者家系的一级亲属中共检出32例3243突变携带者,其中24例为糖尿病,8例糖耐量正常,17例伴不同程度听力减退.24例糖尿病患者多呈消瘦体型,有18例呈典型母系遗传,13例伴胰岛素抵抗,15例伴听力障碍,14例应用胰岛素治疗.结论 上海及江浙地区家族性糖尿病人群线粒体3243点突变检出率是1.69%,线粒体糖尿病患者的临床特点是:(1)多数呈母系遗传,少数可为散发;(2)多于45岁以前发病;(3)体型多偏瘦;(4)胰岛β细胞分泌功能明显降低,部分患者同时伴有胰岛素抵抗;(5)多数患者伴神经性听力障碍或神经性耳聋.     

Varying loads of the mitochondrial DNA A3243G mutation in different tissues: implications for diagnosis

Testing for common mutations in mitochondrial DNA (mtDNA), including the A3243G MELAS (mitochondrial encephalomyopathy, lactic acidosis, and strokelike episodes) mutation, is routinely done in DNA isolated from blood. Since the blood level of the A3243G mutation may be low in probands and even lower in asymptomatic or oligosymptomatic maternal relatives, we assessed the proportion of A3243G mutant genomes in other accessible tissues. We studied five tissues (leukocytes, skin fibroblasts, hair roots, urinary sediment, and cheek mucosa) in 61 individuals from 22 families harboring the A3243G mutation. Although mutational loads varied widely among these tissues, as a rule DNA from urinary sediment had the highest and blood the lowest proportion of mutant genomes; individual hair roots differed markedly from one another; fibroblasts and cheek mucosa tended to have higher mutation loads than blood but lower than urinary sediment. In all individuals in whom the mutation was detectable in blood, it was also detected in other tissues. Conversely, in some individuals the mutation was undetectable in blood but clearly present in other tissues. We conclude that urinary sediment and cheek mucosa are tissues of choice for the diagnosis of mtDNA mutations, as they are easy to obtain and the mutation load is almost always greater than in blood.     

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.