Leber遗传性视神经病变家系的线粒体基因突变分析

为探讨Leber遗传性视神经病变（Leber′s hereditary optic neuropathy,LHON）家系线粒体DNA（mtDNA）常见致病原发突变的频谱,用聚合酶链反应（polymerase chain reaction,PCR）和单链构象多态性（single-stranded conformational polymorphism,SSCP）以及DNA测序的方法,对13个家系22位临床诊断为LHON的患者及其母系亲属21人的线粒体DNA进行检测,同时检测71例正常人作为对照。临床拟诊为LHON的13个家系中,11个家系存在mtDNA位点11778 G→A突变,另2个家系存在14484位点T→C突变。说明中国LHON病人存在线粒体DNA 11778或14484位点突变,其中14484位点突变在国内尚未见报道。 Abstract:The purpose of the study is to investigate the frequency of common pathogenic primary mitochondrial DNA mutations in pedigrees of Leber′s hereditary optic neuropathy (LHON).Mutations were determined by polymerase chain reaction (PCR),single-stranded conformational polymorphism (SSCP) and DNA sequencing.Twenty-two patients with suspicion of LHON and twenty-one their maternal relatives underwent molecular genetic evaluation.Seventy-one normal individuals underwent molecular genetic evaluation as control at the same time.Members from 13 families with suspicion of LHON,11 families had nucleotide position nt11778 G→A mutations.Another 2 families had nt14484 T→C mutations.It is concluded that the point mutations at nucleotides 11778 and 14484 are primary LHON mutations,but the point mutation of nt14484 is rare in Chinese.     

脑胶质瘤中P53基因突变及其与染色体17p杂合性丢失的比较

为进一步阐明P53基因突变和染色体17p杂合性丢失(LOH)的关系及两者与脑胶质瘤发生发展的相关性。应用PCR－SSCP、DNA序列测定及RFLP分析方法对55例脑胶质瘤中的P53基因突变及染色体17p的杂合性丢失进行了检测。发现P53基因在高级别星型细胞肿瘤(III－IV级)、低级别星型细胞肿瘤(I－II级)和非星型细胞肿瘤中的突变频率分别为：53％(9/17)、7％(1/15)和9％(2/23)。而55例肿瘤组织对应的淋巴细胞中未见P53突变。22％的胶质瘤丢失1个17p等位基因,这部分肿瘤中P53基因的突变频率为50％(6/12),而在43例持有2个17p等位基因的肿瘤中,P53基因的突变频率降为14％,两组相比差异显著(P<0?025)。结果提示P53基因突变是星型细胞肿瘤演变过程中的一个常见遗传事件,可能标志着肿瘤的恶性进展;散发性脑胶质瘤中的P53突变是体细胞型的突变;另外,丢失1个17p等位基因的肿瘤中有50％缺少P53基因突变,提示染色体17p上可能存在另一个参与了部分肿瘤恶性演变的肿瘤抑制基因。 Abstract：To further illustrate the roles of P53 gene and loss of heterozygosity (LOH) on chromosome 17p in the development of malignant gliomas,mutations in the P53 gene were analyzed in 55 gliomas of various malignant grades and histological types by the polymerase chain reaction-single-strand conformation polymorphism (PCR-SSCP) technique and were confirmed by sequencing.Loss of heterozygosity (LOH) for chromosome 17p was also assessed using restriction fragment length polymorphism (RFLP) analysis in same tumors.The mutations did not follow a random distribution among various different subtypes,but occurred in 9 of 17 high-grade astrocytomas (53％),in 1 of 15 low-grade astrocytomas (7％) and in 2of 23 (9％) non-astrocytic tumors.Most of the mutations were missense ones and 42％ (5/12) occurred at the sites of CpG dinucleotide.P53 mutations were not detected in any of the 55 leukocyte DNA samples from patients with brain tumors.These studies demonstrated that P53 inactivation is a common genetic event in astrocytoma progression that may signal the transition from benign to malignant tumor stages.P53 gene mutations in sporadic human brain tumors are somatic in origin (i.e.,nonprenatally determined).The majority of glomas (43/55) analyzed here retained both 17p alleles.The frequency of P53 mutations was 14％ in this group of tumors and increased to 50％ (6/12) in tumors with one 17p allele (P<0.025).Allelic loss for chromosome 17p occurred in 6 of 12 gliomas independently of mutations in the P53 gene.Absence of P53 mutations in 50％ of the tumors with one allele suggests that a tumor suppressor gene other than P53 may be located on chromosome 17p and involved in progression to malignancy of some gliomas.     

Pathogenic mutations of nuclear genes associated with mitochondrial disorders

Mitochondrial disorders are clinical phenotypes associated with mitochondrial dysfunction, which can be caused by mutations in mitochondrial DNA （mtDNA） or nuclear genes. In this review, we summarized the pathogenic mutations of nuclear genes associated with mitochondrial disorders. These nuclear genes encode, components of mitochondrial translational machinery and structural subunits and assembly factors of the oxidative phosphorylation, that complex. The molecular mechanisms, that nuclear modifier genes modulate the phenotypic expression of mtDNA mutations, are discussed in detail.     

线粒体DNA缺失与神经肌肉性疾病的研究

应用PCR技术对13例神经肌肉疾病患者的线粒体DNA缺失进行了研究。结果表明,其中二例肢带型肌营养不良症患者骨骼肌组织和一例帕金森氏病患者的血细胞线粒体DNA中存在至少526bp的缺失。提示线粒体突变在一些神经肌肉性疾病的发生中起一定的作用。 Abstract: Using PCR technique,we analysed the skeletal muscle and blood of 13 patients with neuromuscular disaeases.The results show that a mutant mitochondrial DNA with at least 526bp deletion exits in the skeletal muscles of 2 patients with Erb muscular dystrophy and in the blood of a patients with Parkinson’s disease.From our results,mitochondrial DNA mutations could be an important contributory factor to neuromuscular diseases.     

线粒体基因突变与NIDDM发生的关系

采用PCR-SSCP、PCR-RFLP及PCR产物直接测序等技术对90例NIDDM(即非胰岛素依赖型糖尿病)及80例正常对照个体的血细胞线粒体DNA进行了突变分析。结果在2例患者中发现线粒体DNA(mitochondrial DNA,mtDNA) ND1 (NaDH Dehydrogenase subunitⅠ)基因上3316位点存在G→A的点突变,导致丙氨酸错义突变成苏氨酸,而在80例正常对照个体中均不存在此位点突变。国内外已证实的和1.5%NIDDM发生有关的mtDNA tRNA Leu^(UUR)|基因上3243位点A→G的突变在本实验中并未发现。由此推断,3316位点G→A的突变可能与NIDDM的发生在关,3243位点A→G的突变率确实很低,可见糖尿病的发生在线粒体遗传上具有广泛的异质性。 Abstract:Using PCR-SSCP,PCR-RFLP and PCR product direct sequencing techniques,we analysed the mitochondrial DNAs(mtDNAs)of 90 patients with NIDDM (Non Insulin-Dependent Diabetes Mellitus)and those of 80 normal controls.The results showed that a G to A mutation which leads alanine’s missence mutaton to threonine in the mitochondrial ND1(NaDH Dehydrogenase subunit I) gene at nucleotide pair 3316 occurred in the blood cells of 2 patients.We have not however,indentified with the A to G mutation at nucleotide pair 3243 of the mitochondrial tRNA Leu(UUR) gene,which has been reported to associate with NIDDM in about 1.5% of the diabetic population.We infer that the mutation at position 3316 is perhaps associated with the development of NIDDM,the occurance of the mutation at position 3243 is actually rare,and NIDDM has an intensive mitochondrial genetic heterogenous background.     

The giant panda (Ailuropoda melanoleuca) somatic nucleus can dedifferentiate in rabbit ooplasm and support early development of the reconstructed egg

The giant panda skeletal muscle cells, uterus epithelial cells and mammary gland cells from an adult individual were cultured and used as nucleus donor for the construction of interspecies embryos by transferring them into enucleated rabbit eggs. All the three kinds of somatic cells were able to reprogram in rabbit ooplasm and support early embryo development, of which mammary gland cells were proven to be the best, followed by uterus epithelial cells and skeletal muscle cells. The experiments showed that direct injection of mammary gland cell into enucleated rabbit ooplasm, combined with in vivo development in ligated rabbit oviduct, achieved higher blastoeyst development than in vitro culture after the somatic cell was injected into the perivitelline space and fused with the enucleated egg by electrical stimulation. The chromosome analysis demonstrated that the genetic materials in reconstructed blastocyst cells were the same as that in panda somatic cells. In addition, giant panda mitochondrial DNA (     

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.     

Very Low-Level Heteroplasmy mtDNA Variations Are Inherited in Humans

Little is known about the inheritance of very low heteroplasmy mitochondria DNA （mtDNA） variations. Even with the development of new next-generation sequencing methods, the practical lower limit of measured heteroplasmy is still about 1% due to the inherent noise level of the sequencing. In this study, we sequenced the mitochondrial genome of 44 individuals using Illumina high-throughput sequencing technology and obtained high-coverage mitochondria sequencing data. Our study population contains many mother-offspring pairs. This unique study design allows us to bypass the usual heteroplasmy limitation by analyzing the correlation of mutation levels at each position in the mtDNA sequence between maternally related pairs and non-related pairs. The study showed that very low heteroplasmy variants, down to almost 0.1%, are inherited maternally and that this inheritance begins to decrease at about 0.5%, cor- resnondin to abottleneck of about 200 mtDNA.     

The dichotomy of p53 regulation by noncoding RNAs

The p53 tumor suppressor gene is the most frequently mutated gene in cancer. Significant progress has been made to discern the im- portance of p53 in coordinating cellular responses to DNA damage, oncogene activation, and other stresses. Noncoding RNAs are RNA molecules functioning without being translated into proteins. In this work, we discuss the dichotomy of p53 regulation by noncoding RNAs with four unconventional questions. First, is overexpression of microRNAs responsible for p53 inactivation in the absence of p53 mutation？ Second, are there somatic mutations in the noncoding regions of the p53 gene？ Third, is there a germline mutant in the non- coding regions of the p53 gene that predisposes carriers to cancer？ Fourth, can p53 activation mediated by a noncoding RNA mutation cause cancer？ This work highUghts the prominence of noncoding RNAs in p53 dysregutation and tumorigenesis.     

Interpretation, Stratification and Evidence for Sequence Variants Affecting mRNA Splicing in Complete Human Genome Sequences

Information theory-based methods have been shown to be sensitive and specific for predicting and quantifying the effects of non-coding mutations in Mendelian diseases. We present the Shannon pipeline software for genome-scale mutation analysis and provide evidence that the software predicts variants affecting mRNA splicing. Individual information contents (in bits) of reference and variant splice sites are compared and significant differences are annotated and prioritized. The software has been implemented for CLC-Bio Genomics platform. Annotation indicates the context of novel mutations as well as common and rare SNPs with splicing effects. Potential natural and cryptic mRNA splicing variants are identified, and null mutations are distinguished from leaky mutations. Mutations and rare SNPs were predicted in genomes of three cancer cell lines (U2OS, U251 and A431), which were supported by expression analyses. After filtering, tractable numbers of potentially deleterious variants are predicted by the software, suitable for further laboratory investigation. In these cell lines, novel functional variants comprised 6-17 inactivating mutations, 1-5 leaky mutations and 6-13 cryptic splicing mutations. Predicted effects were validated by RNA-seq analysis of the three aforementioned cancer cell lines, and expression microarray analysis of SNPs in HapMap cell lines.     

Analysis of heteroplasmy in the major noncoding region of mitochondrial DNA in the blood and atherosclerotic plaques of carotid arteries

For identification of somatic mitochondrial DNA (mtDNA) mutations, the mtDNA major noncoding region (D-loop) sequence in blood samples and carotid atherosclerosis plaques from patients with atherosclerosis was analyzed. Five point heteroplasmic positions were observed in 4 of 23 individuals (17%). Only in two cases could heteroplasmy have resulted from somatic mutation, whereas three heteroplasmic positions were found in both vascular tissue and blood. In addition, length heteroplasmy in a polycytosine stretches was registered at nucleotide positions 303–315 in 16 individuals, and also in the 16184–16193 region in four patients. The results suggest that somatic mtDNA mutations can occur during atherosclerosis, but some heteroplasmic mutations may appear in all tissues, possibly being inherited.     

Haplotype-matched controls as a tool to discriminate polymorphisms from pathogenic mutations in mtDNA

We have studied the pathogenic role of 10044A-->G, a heteroplasmic mitochondrial DNA (mtDNA) mutation that has been suggested to be pathogenic in one family with severe pediatric morbidity. We found the mutation at an average frequency of 1.9% among 259 individuals including healthy controls. The mutation appeared to be heteroplasmic by restriction fragment analysis but analysis of subcloned polymerase chain reaction fragments confirmed homoplasmy. The polymorphic nature of 10044A-->G was verified by demonstrating exclusive association with a rare mtDNA haplotype within haplogroup H. We suggest that the evaluation of putatively pathogenic mutations in mtDNA should include the analysis of a sufficient number of haplotype-matched control samples and that the heteroplasmy should be verified by cloning.     

Human aging and somatic point mutations in mtDNA: A comparative study of generational differences (grandparents and grandchildren)

The accumulation of somatic mutations in mtDNA is correlated with aging. In this work, we sought to identify somatic mutations in the HVS-1 region (D-loop) of mtDNA that might be associated with aging. For this, we compared 31 grandmothers (mean age: 63 ± 2.3 years) and their 62 grandchildren (mean age: 15 ± 4.1 years), the offspring of their daughters. Direct DNA sequencing showed that mutations absent in the grandchildren were detected in a presumably homoplasmic state in three grandmothers and in a heteroplasmic state in an additional 13 grandmothers; no mutations were detected in the remaining 15 grandmothers. However, cloning followed by DNA sequencing in 12 grandmothers confirmed homoplasia in only one of the three mutations previously considered to be homoplasmic and did not confirm heteroplasmy in three out of nine grandmothers found to be heteroplasmic by direct sequencing. Thus, of 12 grandmothers in whom mtDNA was analyzed by cloning, eight were heteroplasmic for mutations not detected in their grandchildren. In this study, the use of genetically related subjects allowed us to demonstrate the occurrence of age-related (> 60 years old) mutations (homoplasia and heteroplasmy). It is possible that both of these situations (homoplasia and heteroplasmy) were a long-term consequence of mitochondrial oxidative phosphorylation that can lead to the accumulation of mtDNA mutations throughout life.     

Validation of Next-Generation Sequencing of Entire Mitochondrial Genomes and the Diversity of Mitochondrial DNA Mutations in Oral Squamous Cell Carcinoma

Background

Oral squamous cell carcinoma (OSCC) is mainly caused by smoking and alcohol abuse and shows a five-year survival rate of ~50%. We aimed to explore the variation of somatic mitochondrial DNA (mtDNA) mutations in primary oral tumors, recurrences and metastases.

Methods

We performed an in-depth validation of mtDNA next-generation sequencing (NGS) on an Illumina HiSeq 2500 platform for its application to cancer tissues, with the goal to detect low-level heteroplasmies and to avoid artifacts. Therefore we genotyped the mitochondrial genome (16.6 kb) from 85 tissue samples (tumors, recurrences, resection edges, metastases and blood) collected from 28 prospectively recruited OSCC patients applying both Sanger sequencing and high-coverage NGS (~35,000 reads per base).

Results

We observed a strong correlation between Sanger sequencing and NGS in estimating the mixture ratio of heteroplasmies (r = 0.99; p<0.001). Non-synonymous heteroplasmic variants were enriched among cancerous tissues. The proportions of somatic and inherited variants in a given gene region were strongly correlated (r = 0.85; p<0.001). Half of the patients shared mutations between benign and cancerous tissue samples. Low level heteroplasmies (<10%) were more frequent in benign samples compared to tumor samples, where heteroplasmies >10% were predominant. Four out of six patients who developed a local tumor recurrence showed mutations in the recurrence that had also been observed in the primary tumor. Three out of five patients, who had tumor metastases in the lymph nodes of their necks, shared mtDNA mutations between primary tumors and lymph node metastases. The percentage of mutation heteroplasmy increased from the primary tumor to lymph node metastases.

Conclusions

We conclude that Sanger sequencing is valid for heteroplasmy quantification for heteroplasmies ≥10% and that NGS is capable of reliably detecting and quantifying heteroplasmies down to the 1%-level. The finding of shared mutations between primary tumors, recurrences and metastasis indicates a clonal origin of malignant cells in oral cancer.     

Mitochondrial DNA somatic mutation burden and heteroplasmy are associated with chronological age,smoking, and HIV infection

The gradual accumulation of mitochondrial DNA (mtDNA) mutations is implicated in aging and may contribute to the accelerated aging phenotype seen with tobacco smoking and HIV infection. mtDNA mutations are thought to arise from oxidative damage; however, recent reports implicate polymerase γ errors during mtDNA replication. Investigations of somatic mtDNA mutations have been hampered by technical challenges in measuring low‐frequency mutations. We use primer ID‐based next‐generation sequencing to quantify both somatic and heteroplasmic blood mtDNA point mutations within the D‐loop, in 164 women and girls aged 2–72 years, of whom 35% were smokers and 56% were HIV‐positive. Somatic mutations and the occurrence of heteroplasmic mutations increased with age. While transitions are theorized to result from polymerase γ errors, transversions are believed to arise from DNA oxidative damage. In our study, both transition and transversion mutations were associated with age. However, transition somatic mutations were more prevalent than transversions, and no heteroplasmic transversions were observed. We also measured elevated somatic mutations, but not heteroplasmy, in association with high peak HIV viremia. Conversely, heteroplasmy was higher among smokers, but somatic mutations were not, suggesting that smoking promotes the expansion of preexisting mutations rather than de novo mutations. Taken together, our results are consistent with blood mtDNA mutations increasing with age, inferring a greater contribution of polymerase γ errors in mtDNA mutagenesis. We further suggest that smoking and HIV infection both contribute to the accumulation of mtDNA mutations, though in different ways.     

Rapid segregation of heteroplasmic bovine mitochondria.

By following the transmission of a heteroplasmic mitochondrial DNA mutation through four generations of Holstein cows, we have documented that substantial shifts in the levels of heteroplasmy can occur between single mammalian generations, that neutral mitochondrial genotypes can segregate in different directions in offspring of the same female, and that a return to homoplasmy may occur in only two or three generations. This apparently rapid rate of mitochondrial DNA segregation in mammals contrasts to the much slower rates observed previously in insects and suggest fundamental differences between taxa regarding the mechanisms of mitochondrial gene transmission.     

The epidemiology of Leber hereditary optic neuropathy in the North East of England

We performed the first population-based clinical and molecular genetic study of Leber hereditary optic neuropathy (LHON) in a population of 2,173,800 individuals in the North East of England. We identified 16 genealogically unrelated families who harbor one of the three primary mitochondrial DNA (mtDNA) mutations that cause LHON. Two of these families were found to be linked genetically to a common maternal founder. A de novo mtDNA mutation (G3460A) was identified in one family. The minimum point prevalence of visual failure due to LHON within this population was 3.22 per 100,000 (95% CI 2.47-3.97 per 100,000), and the minimum point prevalence for mtDNA LHON mutations was 11.82 per 100,000 (95% CI 10.38-13.27 per 100,000). These results indicate that LHON is not rare but has a population prevalence similar to autosomally inherited neurological disorders. The majority of individuals harbored only mutant mtDNA (homoplasmy), but heteroplasmy was detected in approximately 12% of individuals. Overall, however, approximately 33% of families with LHON had at least one heteroplasmic individual. The high incidence of heteroplasmy in pedigrees with LHON raises the possibility that a closely related maternal relative of an index case may not harbor the mtDNA mutation, highlighting the importance of molecular genetic testing for each maternal family member seeking advice about their risks of visual failure.     

Single-cell mtDNA heteroplasmy in colorectal cancer

Human mitochondria can be genetically distinct within the same individual, a phenomenon known as heteroplasmy. In cancer, this phenomenon seems exacerbated, and most mitochondrial mutations seem to be heteroplasmic. How this genetic variation is arranged within and among normal and tumor cells is not well understood. To address this question, here we sequenced single-cell mitochondrial genomes from multiple normal and tumoral locations in four colorectal cancer patients. Our results suggest that single cells, both normal and tumoral, can carry various mitochondrial haplotypes. Remarkably, this intra-cell heteroplasmy can arise before tumor development and be maintained afterward in specific tumoral cell subpopulations. At least in the colorectal patients studied here, the somatic mutations in the single-cells do not seem to have a prominent role in tumorigenesis.     

Mitochondrial activity in response to serum starvation in bovine (Bos taurus) cell culture

In nuclear transfer procedures, in addition to nuclei, donor cell mitochondria are routinely transferred into recipient oocytes, and mitochondrial heteroplasmy has been reported. However, various protocols have resulted in either homoplasmy for recipient oocyte mitochondria or varying heteroplasmic levels in cloned animals. In nuclear transfer protocols, donor cells are subjected to serum-starvation prior to electroporation. Therefore, the relationship between culture conditions and mitochondrial activity was explored. Fibroblast cell lines were propagated from bovine ear epithelium, skin, skeletal muscle, or cumulus cells. In vitro mitochondrial viability was assessed in proliferative and confluent cells, cultured under serum-starvation or supplemented conditions. Cells were stained with MitoTracker Red CMXRos and comparative fluorescence intensities were assessed. The mitochondrial activity per cell was highest under proliferation, significantly lower at confluency (p < 0.001), and remained depressed after serum starvation for within a week (p < 0.001). Serum starvation induced an increase in mitochondrial viability in confluent cells. These results demonstrate that mitochondrial viability is dramatically affected by cell culture conditions. Consequently, specific cell culture parameters provide one explanation for the varying incidence of heteroplasmy identified in cloned animals. Future research should reveal whether specific cell culture parameters represent one of the factors for the varying incidence of heteroplasmy identified in cloned animals.     

Somatic mutations in mitochondrial genome and their potential roles in the progression of human gastric cancer

Background

Somatic mutation in mitochondrial DNA (mtDNA) has been proposed to contribute to initiation and progression of human cancer. In our previous study, high frequency of somatic mutations was found in the D-loop region of mtDNA of gastric cancers. However, it is unclear whether somatic mutations occur in the coding region of mtDNA of gastric cancers.

Methods

Using DNA sequencing, we studied 31 gastric cancer specimens and corresponding non-cancerous stomach tissues. Moreover, a human gastric cancer SC-M1 cell line was treated with oligomycin to induce mitochondrial dysfunction. Cisplatin sensitivity and cell migration were analyzed.

Results

We identified eight somatic mutations in the coding region of mtDNAs of seven gastric cancer samples (7/31, 22.6%). Patients with somatic mutations in the entire mtDNA of gastric cancers did not show significant association with their clinicopathologic features. Among the eight somatic mutations, five point mutations (G3697A, G4996A, G9986A, C12405T and T13015C) are homoplasmic and three mutations (5895delC, 7472insC and 12418insA) are heteroplasmic. Four (4/8, 50%) of these somatic mutations result in amino acid substitutions in the highly conserved regions of mtDNA, which potentially lead to mitochondrial dysfunction. In addition, in vitro experiments in SC-M1 cells revealed that oligomycin-induced mitochondrial dysfunction promoted resistance to cisplatin and enhanced cell migration. N-acetyl cysteine was effective in the prevention of the oligomycin-enhanced migration, which suggests that reactive oxygen species generated by defective mitochondria may be involved in the enhanced migration of SC-M1 cells.

General Significance

Our results suggest that somatic mtDNA mutations and mitochondrial dysfunction may play an important role in the malignant progression of gastric cancer.