线粒体T12338C突变可能是与Leber遗传性视神经病变相关的突变位点

Leber遗传性视神经病变变(Leber’s hereditary optic neuropathy,LHON)是一种与线粒体DNA(Mito-chondrial DNA,mtDNA)突变相关的母系遗传性眼科疾病。文章报道了两例具有典型LHON临床、分子遗传特征的中国汉族家系。首先通过对家系先证者和其他成员进行眼科相关检查,发现两个家系成员中视力都仅有先证者一人损害严重,即外显率很低。经常规的方法对母系成员进行mtDNA测序及相关软件分析,结果发现携带ND4 G11696A和ND5 T12338C同质性突变位点,多态性变异位点均属于东亚单体型F2。线粒体DNA ND4 G11696A是一个已知的与LHON相关的突变位点,而T12338C位于线粒体氧化磷酸化复合体I亚基ND5的第2个碱基,该突变使起始密码子由蛋氨酸转变成苏氨酸,并且紧连tRNALeu(CUN)的3′末端。这可能影响tRNA Leu(CUN)空间结构和稳定性发生改变,以及起始密码子改变导致线粒体ND5蛋白合成功能受损和ATP障碍,最终导致需求能量高的视神经受损和视力损害。因此,线粒体ND4 G11696A和ND5 T12338C突变可能协同作用Leber遗传性视神经病变的发生,是与LHON相关的mtDNA突变位点,但外显率很低说明突变本身不足以造成LHON的表型表达,提示其他修饰因子(核修饰基因、环境等)可能对这两个家系发病起协同作用。     

中国人群携带m.14484T>C突变的Leber’s遗传性视神经病变线粒体单体型及多态位点分析

线粒体ND6基因(MT-ND6)上的m.14484TC突变是Leber’s遗传性视神经病变(Leber’s hereditary optic neuropathy,LHON)的一个原发性突变,但该突变自身不足以产生视力损伤。为研究线粒体单体型对携带该突变人群LHON发病的影响,文章对1 177例中国汉族LHON患者MT-ND6基因进行了全面系统的筛查,共筛查到67例患者携带m.14484TC同质性突变,在该研究群体中所占比例为5.7%。携带m.14484TC突变的51例家系LHON的外显率从5.6%~100.0%不等,平均外显率为21.5%。对家系中51例先证者线粒体全基因组进行分析,各表现为不同的多态性,分别属于18个东亚线粒体单体型。其中单体型A和单体型F在病例组频率均明显低于106例对照组。另外,单体型M10a在病例组中占9.8%,在对照组中未被发现,进一步发现该单体型家系LHON的平均外显率(46.13%)显著高于其他单体型家系的平均外显率,提示线粒体单体型M10a可能增加视力损伤的风险。     

Leber遗传性视神经病变研究进展和挑战

Leber遗传性视神经病变(Leber hereditary optic neuropathy, LHON; MIM535000)是最典型的线粒体遗传病之一, 主要由线粒体DNA (Mitochondrial DNA, mtDNA)3个原发突变(Primary mutation, m.11778G>A、m.3460G> A 和m.14484T>C)引起。患者表现为无痛性双侧视力下降或丧失, 主要易感人群为青壮年男性。不完全外显(Incomplete penetrance)和性别偏好(Gender bias)是该病亟待解决的两大难题, 目前尚无有效的预防及治疗措施。文章对近年来LHON 的分子发病机制、临床症状及特点、体外实验和动物模型研究、预防及治疗等方面的研究进展进行综述, 并集中介绍了我们近期对于我国LHON患者的研究结果。     

7例携带线粒体tRNAAlaC5601T突变的Leber遗传性视神经病变家系的相关研究

文章收集了7例携带线粒体tRNAAl。C5601T突变的中国Leber遗传性视神经病变(Leber’s hereditary opticneuropathy,LHON)的家系,通过眼科检查和遗传学分析,发现7个家系的外显率很低,分别为9.5%、14.3%、4.5%、8.3%、10.0%、22.2%和25.0%。用24对有部分重叠的引物对7个先证者线粒体DNA(Mitochondrial DNA,mtDNA)全序列进行扩增,并进行相关的分子生物学分析,结果发现这些家系均未携带G11778A、G3460A和T14484C这3个常见的原发突变位点,而在tRNAAla上发现了C5601T同质性突变,多态性位点分析分别属于东亚线粒体单体型G2、G2a1、G2a1、G2、G2b、G2a1、G2。C5601T突变位于线粒体tRNAAla的高度保守区(通用位点为59位),可能引起tRNA空间结构和稳定性发生改变,继而影响tRNA的代谢,导致线粒体蛋白和ATP合成障碍,最终导致视力损害。因此,tRNAAlaC5601T突变可能是与LHON相关的线粒体突变位点。同时低外显率提示其他因素(包括核修饰基因、环境因素)可能影响这7个中国C5601T突变家系的表型表达。     

线粒体tRNAGlu A14693G可能是与Leber遗传性视神经病变相关的基因突变

收集了3个具有典型临床特征的中国汉族Leber遗传性视神经病变(Leber's hereditary optic neuropathy, LHON)家系。通过对先证者和家系其他成员进行眼科临床(如视力损害程度和发病年龄)检查, 发现这些家系成员中视力损害的外显率很低, 经mtDNA测序分析, 在tRNA^Glu 上发现了A14693G同质性突变位点, 多态性位点分别属于东亚单体型Y1b、Y1和Y1, 没有发现其他高度保守和有功能意义的突变位点。A14693G突变位于线粒体tRNAGlu高度保守区(通用位点为54位), 可能导致tRNA空间结构和稳定性发生改变, 继而影响tRNA的代谢, 导致线粒体蛋白合成功能受损和ATP障碍, 最终导致视力损害。所以, tRNAGlu A14693G突变可能是与视神经病变相关的致病性线粒体突变位点。     

在两个X连锁显性腓骨肌萎缩症家系中发现同一GJB1基因突变Glu208Lys

在两个X连锁显性腓骨肌萎缩症(Charcot-Marie-Tooth disease, CMT) 家系中进行了GJB1基因的突变分析。提取基因组DNA, PCR(polymerase chain reaction)反应扩增GJB1基因编码序列, 进行单链构象多态性(single strand conformational polymorphism, SSCP)分析, 对有差异SSCP带型的PCR产物进行测序, 结果在两家系中发现同一GJB1基因c.622G→A (Glu208Lys)突变。所发现的突变位点在国内尚未报道。     

散发性Leber遗传性视神经病的基因诊断

为了探讨散发性Leber遗传性视神经病(LHON)的诊断方法,对无家族史原因不明视神经萎缩病例,应用PCR扩增线粒体DNA片段,限制性内切酶SfaNI、MaeⅢ双重鉴定np11 778 G→A突变及BsaH I检测np3 460 G→A突变的有无。结果二例呈现np11 778点突变阳性,np3 460点突变阴性,明确诊断为LHON。上述点突变的检测,是目前诊断散发性LHON的首选有效方法。     

一个氨基糖苷类抗生素致聋家系线粒体DNA突变研究

应用PCR、PCR－SSCP和DNA序列分析等分子生物学技术,对一个有明确氨基糖苷类抗生素应用史的母系遗传耳聋家系共8人(包括聋人和听力正常者) 的线粒体DNA进行研究,结果显示,家系中有4份样品存在线粒体DNA 12S rRNA 1 555位点A→G的突变。提示线粒体DNA点突变是导致该家系致聋的主要因素之一。 Abstract:Blood samples were obtained from a pedigree with aminoglycoside antibiotic induced deafness.DNA was extracted from the isolated leukocytes.The mitochondrial DNA fragments were detected by PCR－SSCP and DNA sequencing.It was found that four individuals from the pedigree carried 1 555 A→G mutation.From our results,mitochondrial DNA mutation may be one of major factors in aminoglycoside antibiotic induced deafness.     

一个母系遗传非综合征耳聋大家系mtDNA序列分析

通过分析本家系mtDNA序列,探讨淮阴一非综合征耳聋大家系患病的分子遗传学机制.采用聚合酶链反应(PCR)扩增mtDNA与非综合征耳聋相关位点nt1555、nt7445的区域和人类种群研究的D-loop区、PCR-异源双链分析、PCR-RFLP、PCR产物克隆序列测定等技术对该家系进行了系统的研究.发现该家系中全部母系亲属有mtDNAA1555G突变,而家系中非母系个体、对照组(100例正常个体)的mtDNA1555位点均为A.该家系mtDNA7445位点无突变;该家系属于II型线粒体;发现家系D-loop区存在未见报道的碱基插入.提示mtDNAA1555G位点突变可能是导致该家系患者致聋的主要因素之一.遗传背景可能对家系疾病的表型存在一定程度的影响。 Abstract:We find an extensive nonsyndromic sensorineural deafness family in Huaiyin,and investigate the possible molecular genetic mechanism of matrilineal nonsyndromic sensorineural deafness.We use PCR,combined with PCR-heteroduplex analysis,PCR-RFLP and sequencing techniques to examine part of 12S rRNA,tRNAser(UCN),and D-loop region of this pedigree.1)We found an A to G transition at position 1555(A1555G) of the mitochondrial 12S rRNA from all the patients and four matrilineal.2)An new nucleotide insertion was indentified in D-Loop region.3)According to the polymorphism of D-loop,this pedigree belong to mitochondrial type II.The study showed that the A1555G mutation may be one of major factors in progressive inherited deafness of this family and genetic background should be investigated in the future.     

线粒体ND1基因T3866C突变可能是Leber’s遗传性视神经病和四肢畸形跛行相关的突变

线粒体DNA(Mitochondrial DNA,mtDNA)突变与人类许多疾病的发病机制相关。现报道1个具有典型母系遗传特征的中国人Leber’s遗传性视神经病和四肢畸形跛行的家系。该家系共5代60人,共27名母系成员,其中4人只有Leber’s遗传性视神经病症状,1人呈现四肢畸形跛行症状,4人同时具有上述两种临床症状,而其他成员无临床症状。对先证者的mtDNA全序列进行分析,发现ND1基因T3866C突变位点和43个多态位点,经系统进化树分析属于东亚单体型D4a3。MtDNAND13866位点T-C碱基的改变使ND1亚基第187位进化高度保守的异亮氨酸转变为苏氨酸,从而改变该蛋白的结构,进而影响其功能。在135名正常对照中未发现该突变。因此,线粒体ND1T3866C可能是与Leber’s遗传性视神经病和四肢畸形跛行相关的线粒体基因突变。     

Leber's hereditary optic neuroretinopathy (LHON) associated with mitochondrial DNA point mutation G11778A in two Croatian families

Leber's hereditary optic neuroretinopathy (LHON) is manifested as a bilateral acute or subacute loss of central vision due to optic atrophy. It is linked to point mutations of mitochondrial DNA, which is inherited maternally. The most common mitochondrial DNA point mutations associated with LHON are G3460A, G11778A and T14484C. These mutations are linked with the defects of subunits of the complex I (NADH-dehydrogenase-ubiquinone reductase) in mitochondria. The G11778A mitochondrial DNA point mutation is manifested by a severe visual impairment. In this paper two Croatian families with the LHON G11778A mutation are presented. Three LHON patients from two families were younger males which had the visual acuity of 0.1 or below, the ophthalmoscopy revealed telangiectatic microangiopathy and papilloedema, while Goldmann kinetic perimetry showed a central scotoma. The mothers and female relatives were LHON mutants without symptoms, whereas their sons suffered from a severe visual impairment. Molecular diagnosis helps to explain the cause of LHON disease.     

Clustering of Caucasian Leber hereditary optic neuropathy patients containing the 11778 or 14484 mutations on an mtDNA lineage.

Leber hereditary optic neuropathy (LHON) is a type of blindness caused by mtDNA mutations. Three LHON mtDNA mutations at nucleotide positions 3460, 11778, and 14484 are specific for LHON and account for 90% of worldwide cases and are thus designated as "primary" LHON mutations. Fifteen other "secondary" LHON mtDNA mutations have been identified, but their pathogenicity is unclear. mtDNA haplotype and phylogenetic analysis of the primary LHON mutations in North American Caucasian patients and controls has shown that, unlike the 3460 and 11778 mutations, which are distributed throughout the European-derived (Caucasian) mtDNA phylogeny, patients containing the 14484 mutation tended to be associated with European mtDNA haplotype J. To investigate this apparent clustering, we performed chi2-based statistical analyses to compare the distribution of LHON patients on the Caucasian phylogenetic tree. Our results indicate that, unlike the 3460 and 11778 mutations, the 14484 mutation was not distributed on the phylogeny in proportion to the frequencies of the major Caucasian mtDNA haplogroups found in North America. The 14484 mutation was next shown to occur on the haplogroup J background more frequently that expected, consistent with the observation that approximately 75% of worldwide 14484-positive LHON patients occur in association with haplogroup J. The 11778 mutation also exhibited a moderate clustering on haplogroup J. These observations were supported by statistical analysis using all available mutation frequencies reported in the literature. This paper thus illustrates the potential importance of genetic background in certain mtDNA-based diseases, speculates on a pathogenic role for a subset of LHON secondary mutations and their interaction with primary mutations, and provides support for a polygenic model for LHON expression in some cases.     

Leber's hereditary optic neuropathy: no significant evidence for primary or secondary pathogenicity of the 15257 mutation

Leber's hereditary optic neuropathy (LHON) is a maternally inherited disease of the optic nerves associated with various mitochondrial DNA (mtDNA) mutations. Four of these mutations, at nucleotide positions (np) 3460, 11778, 14484 and 15257, have been postulated to be of primary pathogenetical importance. Previously, we described the molecular and clinical findings in patients with the 11778 and 14484 mutations. Here we describe the molecular and clinical findings of patients in eight pedigrees with the 3460 mutation and in three pedigrees with the 15 257 mutation. In all three 15257 positive pedigrees the 3460, the 11778 or the 14484 mutation was also found. The first combination has not been reported before. We compared the clinical findings in these pedigrees with those of the 3460, 11778 and 14484 positive pedigrees that lack the 15257 mutation. No significant differences were found with respect to the age of onset, visual outcome or the probability of developing LHON. We conclude that there is no evidence that the 15257 mutation, which has been reported in normal controls, has primary causal significance, because it may coincide with the 3460, 11778 and 14484 mutations. We presume that the 15257 mutation has no secondary pathogenic importance, since it has no clear contribution to the degree or the probability of phenotypic expression.     

Clinical expression of Leber hereditary optic neuropathy is affected by the mitochondrial DNA-haplogroup background

Leber hereditary optic neuropathy (LHON) is due primarily to one of three common point mutations of mitochondrial DNA (mtDNA), but the incomplete penetrance implicates additional genetic or environmental factors in the pathophysiology of the disorder. Both the 11778G-->A and 14484T-->C LHON mutations are preferentially found on a specific mtDNA genetic background, but 3460G-->A is not. However, there is no clear evidence that any background influences clinical penetrance in any of these mutations. By studying 3,613 subjects from 159 LHON-affected pedigrees, we show that the risk of visual failure is greater when the 11778G-->A or 14484T-->C mutations are present in specific subgroups of haplogroup J (J2 for 11778G-->A and J1 for 14484T-->C) and when the 3460G-->A mutation is present in haplogroup K. By contrast, the risk of visual failure is significantly less when 11778G-->A occurs in haplogroup H. Substitutions on MTCYB provide an explanation for these findings, which demonstrate that common genetic variants have a marked effect on the expression of an ostensibly monogenic mtDNA disorder.     

Pitfalls in the molecular genetic diagnosis of Leber hereditary optic neuropathy (LHON).

Pathogenetic mutations in mtDNA are found in the majority of patients with Leber hereditary optic neuropathy (LHON), and molecular genetic techniques to detect them are important for the diagnosis. A false-positive molecular genetic error has adverse consequences for the diagnosis of this maternally inherited disease. We found a number of mtDNA polymorphisms that occur adjacent to known LHON-associated mutations and that confound their molecular genetic detection. These transition mutations occur at mtDNA nt 11779 (SfaNI site loss, 11778 mutation), nt 3459 (BsaHI site loss, 3460 mutation), nt 15258 (AccI site loss, 15257 mutation), nt 14485 (mismatch primer Sau3AI site loss, 14484 mutation), and nt 13707 (BstNI site loss, 13708 mutation). Molecular genetic detection of the most common pathogenetic mtDNA mutations in LHON, using a single restriction enzyme, may be confounded by adjacent polymorphisms that occur with a false-positive rate of 2%-7%.     

The spectrum of mitochondrial DNA mutations in families with Leber hereditary optic neuroretinopathy

The mitochondrial complex I genes were sequenced in seven Leber hereditary optic neuroretinopathy (LHON) families without the ND4/11778 and ND1/3460 mutations. Four replacement mutations restricted only to LHON families were found, one in the ND1 gene at nt 4025, and three in the ND5 gene at nt 12811, 13637, and 13967. The mutations did not change evolutionarily conserved amino acids suggesting that they are not primary LHON mutations in these families. They may be considered as secondary LHON mutations serving as exacerbating factors in an appropriate genetic background. A complex III mutation, cyt b/15257, has been suggested to be one of the primary mutations causing LHON. Its presence was determined for 23 Finnish LHON families, and it was detected in two families harboring the ND4/11778 mutation. Similarly, complex IV mutation COI/7444 was screened in Finnish LHON families, and it was found in one family carrying the ND1/3460 mutation.     

The role of mtDNA background in disease expression: a new primary LHON mutation associated with Western Eurasian haplogroup J

Leber's hereditary optic neuropathy (LHON) is a maternally transmitted form of blindness caused by mitochondrial DNA (mtDNA) mutations. Approximately 90% of LHON cases are caused by 3460A, 11778A, or 14484C mtDNA mutations. These are designated "primary" mutations because they impart a high risk for LHON expression. Although the 11778A and 14484C mutations unequivocally predispose carriers to LHON, they are preferentially associated with mtDNA haplogroup J, one of nine Western Eurasian mtDNA lineages, suggesting a synergistic and deleterious interaction between these LHON mutations and haplogroup J polymorphism(s). We report here the characterization of a new primary LHON mutation in the mtDNA ND4L gene at nucleotide pair 10663. The homoplasmic 10663C mutation has been found in three independent LHON patients who lack a known primary mutation and all of which belong to haplogroup J. This mutation has not been found in a large number of haplotype-matched or non-haplogroup-J control mtDNAs. Phylogenetic analysis with primarily complete mtDNA sequence data demonstrates that the 10663C mutation has arisen at least three independent times in haplogroup J, indicating that it is not a rare lineage-specific polymorphism. Analysis of complex I function in patient lymphoblasts and transmitochondrial cybrids has revealed a partial complex I defect similar in magnitude to the 14484C mutation. Thus, the 10663C mutation appears to be a new primary LHON mutation that is pathogenic when co-occurring with haplogroup J. These results strongly support a role for haplogroup J in the expression of certain LHON mutations.     

Mitochondrial DNA sequence variation and haplogroup distribution in Chinese patients with LHON and m.14484T>C

Background

Leber hereditary optic neuropathy (LHON, MIM 535000) is one of the most common mitochondrial genetic disorders caused by three primary mtDNA mutations (m.3460G>A, m.11778G>A and m. 14484T>C). The clinical expression of LHON is affected by many additional factors, e.g. mtDNA background, nuclear genes, and environmental factors. Hitherto, there is no comprehensive study of Chinese LHON patients with m.14484T>C.

Methodology/Principal Findings

In this study, we analyzed the mtDNA sequence variations and haplogroup distribution pattern of the largest number of Chinese LHON patients with m.14484T>C to date. We first determined the complete mtDNA sequences in eleven LHON probands with m.14484T>C, to discern the potentially pathogenic mutations that co-segregate with m.14484T>C. We then dissected the matrilineal structure of 52 patients with m.14484T>C (including 14 from unrelated families and 38 sporadic cases) and compared it with the reported Han Chinese from general populations. Complete mtDNA sequencing showed that the eleven matrilines belonged to nine haplogroups including Y2, C4a, M8a, M10a1a, G1a1, G2a1, G2b2, D5a2a1, and D5c. We did not identify putatively pathogenic mutation that was co-segregated with m.14484T>C in these lineages based on the evolutionary analysis. Compared with the reported Han Chinese from general populations, the LHON patients with m.14484T>C had significantly higher frequency of haplogroups C, G, M10, and Y, but a lower frequency of haplogroup F. Intriguingly, we also observed a lower prevalence of F lineages in LHON subjects with m.11778G>A in our previous study, suggesting that this haplogroup may enact similar role during the onset of LHON in the presence of m.14484T>C or m.11778G>A.

Conclusions/Significance

Our current study provided a comprehensive profile regarding the mtDNA variation and background of Chinese patients with LHON and m.14484T>C. Matrilineal background might affect the expression of LHON in Chinese patients with m.14484T>C.     

Functional analysis of lymphoblast and cybrid mitochondria containing the 3460, 11778, or 14484 Leber's hereditary optic neuropathy mitochondrial DNA mutation

Leber's hereditary optic neuropathy (LHON) is a form of blindness caused by mitochondrial DNA (mtDNA) mutations in complex I genes. We report an extensive biochemical analysis of the mitochondrial defects in lymphoblasts and transmitochondrial cybrids harboring the three most common LHON mutations: 3460A, 11778A, and 14484C. Respiration studies revealed that the 3460A mutation reduced the maximal respiration rate 20-28%, the 11778A mutation 30-36%, and the 14484C mutation 10-15%. The respiration defects of the 3460A and 11778A mutations transferred in cybrid experiments linking these defects to the mtDNA. Complex I enzymatic assays revealed that the 3460A mutation resulted in a 79% reduction in specific activity and the 11778A mutation resulted in a 20% reduction, while the 14484C mutation did not affect the complex I activity. The enzyme defect of the 3460A mutation transferred with the mtDNA in cybrids. Overall, these data support the conclusion that the 3460A and 11778A mutants result in complex I defects and that the 14484C mutation causes a much milder biochemical defect. These studies represent the first direct comparison of oxidative phosphorylation defects among all of the primary LHON mtDNA mutations, thus permitting insight into the underlying pathophysiological mechanism of the disease.     

Sequence analysis of the mitochondrial genomes from Dutch pedigrees with Leber hereditary optic neuropathy

The complete mitochondrial DNA (mtDNA) sequences for 63 Dutch pedigrees with Leber hereditary optic neuropathy (LHON) were determined, 56 of which carried one of the classic LHON mutations at nucleotide (nt) 3460, 11778, or 14484. Analysis of these sequences indicated that there were several instances in which the mtDNAs were either identical or related by descent. The most striking example was a haplogroup J mtDNA that carried the 14484 LHON mutation. Four different but related mitochondrial genotypes were identified in seven of the Dutch pedigrees with LHON, including six of those described by van Senus. The control region of the founder sequence for these Dutch pedigrees with LHON matches the control-region sequence that Macmillan and colleagues identified in the founder mtDNA of French Canadian pedigrees with LHON. In addition, we obtained a perfect match between the Dutch 14484 founder sequence and the complete mtDNA sequences of two Canadian pedigrees with LHON. Those results indicate that these Dutch and French Canadian 14484 pedigrees with LHON share a common ancestor, that the single origin of the 14484 mutation in this megalineage occurred before the year 1600, and that there is a 14484/haplogroup J founder effect. We estimate that this lineage--including the 14484 LHON mutation--arose 900-1,800 years ago. Overall, the phylogenetic analyses of these mtDNA sequences conservatively indicate that a LHON mutation has arisen at least 42 times in the Dutch population. Finally, analysis of the mtDNA sequences from those pedigrees that did not carry classic LHON mutations suggested candidate pathogenic mutations at nts 9804, 13051, and 14325.