Mitochondrial DNA Polymerase γ Mutations and Their Implications in mtDNA Alterations in Colorectal Cancer

Mitochondrial DNA was found to be highly mutated in colorectal cancer cells. One of the key molecules involved in the maintenance of the mitochondrial genome is the nuclear‐encoded polymerase gamma. The aim of our study was to determine if there is a link between polymorphisms within the polymerase gamma gene (POLG) and somatic mutations within the mitochondrial genome in cancer cells. We investigated POLG sequence variability in 50 colorectal cancer patients whose complete mitochondrial genome sequences were determined. Relative mtDNA copy number was also determined. We identified 251 sequence variants in the POLG gene. Most of them were germline‐specific (～92%). Twenty‐one somatic changes in POLG were found in 10 colorectal cancer patients. We have found no association between the occurrence of mtDNA somatic mutations and the somatically occurring variants in POLG. MtDNA content was reduced in patients carrying somatic variants in POLG or germline nucleotide variants located in the region encoding the POLG polymerase domain, but the difference did not reach statistical significance. Our findings suggest that somatic mtDNA mutations occurring in colorectal cancer are not a consequence of somatic mutations in POLG. Nevertheless, POLG nucleotide variants may lead to a decrease in mtDNA content, and consequently result in mitochondrial dysfunction.     

Novel heteroplasmic frameshift and missense somatic mitochondrial DNA mutations in oral cancer of betel quid chewers

Mitochondrial DNA (mtDNA) has been proposed to be involved in carcinogenesis because of its high susceptibility to oxidative DNA damage and limited repair mechanisms. For investigation of the potential role of somatic mtDNA mutations in the tumorigenesis of oral cancer, we screened the occurrence of mtDNA mutations by the temporal temperature gradient gel electrophoresis method. We amplified the entire mitochondrial genome by use of 32 pairs of overlapping primers, and to identify the mutations, we sequenced DNA fragments showing different banding patterns between normal and tumor mtDNA. Fourteen of eighteen (77.8%) oral carcinomas displayed somatic mtDNA mutations, with a total of 26 mutations. Among them, six were in the mRNA coding region. Three were missense mutations (C14F, H186R, T173P) in NADH dehydrogenase subunit 2, and one was a frameshift mutation, 9485delC, in cytochrome c oxidase subunit III. Eight (44%) tumors had insertion or deletion mutations in the nucleotide position 303-309 poly C region of the D-loop. Multiple large deletions were also observed. Our results demonstrate that somatic mtDNA mutations occur in oral cancer. Some missense and frameshift mutations may play an important role in the tumorigenesis of this carcinoma. More extensive biochemical and molecular studies will be necessary for determining the pathologic effect of these somatic mutations.     

Role of mitochondrial mutations in cancer

A role for mitochondria in cancer causation has been implicated through identification of mutations in the mitochondrial DNA (mtDNA) and in nuclear-encoded mitochondrial genes. Although many mtDNA mutations were detected in common tumors, an unequivocal causal link between heritable mitochondrial abnormalities and cancer is provided only by the germ line mutations in the nuclear-encoded genes for succinate dehydrogenase (mitochondrial complex II) and fumarate hydratase (fumarase). The absence of evidence for highly penetrant tumors caused by inherited mtDNA mutations contrasts with the frequent occurrence of mtDNA mutations in many different tumor types. Thus, either the majority of diverse mtDNA mutations observed in tumors are not important for the process of carcinogenesis or that they play a common oncogenic role.     

Somatic mitochondrial DNA mutations in Chinese patients with osteosarcoma

Somatic mutations in mitochondrial DNA (mtDNA) have been long proposed to drive the pathogenesis and progression of human malignancies. Previous investigations have revealed a high frequency of somatic mutations in the D‐loop control region of mtDNA in osteosarcoma. However, little is known with regard to whether or not somatic mutations also occur in the coding regions of mtDNA in osteosarcoma. To test this possibility, in the present study we screened somatic mutations over the full‐length mitochondrial genome of 31 osteosarcoma tumour tissue samples, and corresponding peripheral blood samples from the same cohort of patients. We detected a sum of 11 somatic mutations in the mtDNA coding regions in our series. Nine of them were missense or frameshift mutations that have the potential to hamper mitochondrial respiratory function. In combination with our earlier observations on the D‐loop fragment, 71.0% (22/31) of patients with osteosarcoma carried at least one somatic mtDNA mutation, and a total of 40 somatic mutations were identified. Amongst them, 29 (72.5%) were located in the D‐loop region, two (5%) were in the sequences of the tRNA genes, two (5%) were in the mitochondrial ATP synthase subunit 6 gene and seven (17.5%) occurred in genes encoding components of the mitochondrial respiratory complexes. In addition, somatic mtDNA mutation was not closely associated with the clinicopathological characteristics of osteosarcoma. Together, these findings suggest that somatic mutations are highly prevalent events in both coding and non‐coding regions of mtDNA in osteosarcoma. Some missense and frameshift mutations are putatively harmful to proper mitochondrial activity and might play vital roles in osteosarcoma carcinogenesis.     

Mitochondrial DNA,nuclear context,and the risk for carcinogenesis

The inheritance of mitochondrial DNA (mtDNA) from mother to child is complicated by differences in the stability of the mitochondrial genome. Although the germ line mtDNA is protected through the minimization of replication between generations, sequence variation can occur either through mutation or due to changes in the ratio between distinct genomes that are present in the mother (known as heteroplasmy). Thus, the unpredictability in transgenerational inheritance of mtDNA may cause the emergence of pathogenic mitochondrial and cellular phenotypes in offspring. Studies of the role of mitochondrial metabolism in cancer have a long and rich history, but recent evidence strongly suggests that changes in mitochondrial genotype and phenotype play a significant role in the initiation, progression and treatment of cancer. At the intersection of these two fields lies the potential for emerging mtDNA mutations to drive carcinogenesis in the offspring. In this review, we suggest that this facet of transgenerational carcinogenesis remains underexplored and is a potentially important contributor to cancer. Environ. Mol. Mutagen. 60:455–462, 2019. © 2018 Wiley Periodicals, Inc.     

Improving upon nature’s somatic mitochondrial DNA therapies

Mitochondrial DNA (mtDNA) directs key metabolic functions in eukaryotic cells. While a number of mtDNA mutations are known causes of human diseases and age-related dysfunctions, some mtDNA haplotypes are associated with extreme longevity. Despite the mutagenic mitochondrial environment naturally enhancing somatic mtDNA mutation rates, mtDNA remains grossly stable along generations of plant and animal species including man. This relative stability can be accounted for by the purging of deleterious mutations by natural selection operating on growing cells, tissues, organisms and populations, as observed in gametogenesis, embryogenesis, oncogenesis and cladogenesis. In the adult multicellular organism, however, mtDNA mutations accumulate in slowly dividing cells, and, to a much higher degree, in postmitotic cells and tissues. Dynamic mitochondrial fusion and fission, by redistributing polymorphic mtDNA molecules; mitophagy, by clearing defective mitochondria and mutated mtDNA; compensatory mutations and mtDNA repair can compensate for the accumulation of mtDNA mutations only to a certain extent, thereby creating a dysfunctional threshold. Here we hypothesize that this threshold is naturally up-regulated by both vertical and horizontal transfers of mtDNA from stem cells or cell types which retain the capacity of purging deleterious mtDNA through cell division and natural selection in the adult organism. When these natural cell and tissue mtDNA reserves are exhausted, artificial mtDNA therapy may provide for additional threshold up-regulation. Replacement of mtDNA has been already successfully accomplished in early stage embryos and stem cells in a number of species including primates. It is thus simply a matter of refinement of technique that somatic mtDNA therapy, i.e., therapy of pathological conditions based on the transfer of mtDNA to somatic eukaryotic cells and tissues, becomes a medical reality.     

Somatic mutations of the mitochondrial genome in human breast cancers

Somatic mutations in mitochondrial DNA (mtDNA) have been identified in various tumors, including breast cancer. However, their clinicopathological impact on breast cancer still remains unclear. In this study, we re-sequenced the entire mtDNA from breast cancer samples together with paired non-tumorous breast tissues from 58 Taiwanese patients. We identified 19 somatic mutations in the mtDNA coding region of 16 breast cancers. Out of these mutations, 12 of the 19 mutations (63%) are missense or frame-shift mutations that have the potential to cause mitochondrial dysfunction. In combination with our previously study on the D-loop region of mtDNA, we found that 47% (27/58) of the breast cancers harbored somatic mtDNA mutations. Among a total of 40 somatic mutations, 53% (21/40) were located in the D-loop region of the mtDNA, 5% (2/40) were in the ribosomal RNA genes, 5% (2/40) were in the tRNA genes, and 38% (15/40) occurred in mRNA genes. The occurrence of these somatic mtDNA mutations is associated with an older onset age (≥ 50-year old, P = 0.039), a higher TNM stage (P = 0.027), and a higher histological grade (P = 0.012). Multiple logistic regression analysis revealed that an older onset age (P = 0.029) and a higher histological grade (P = 0.006) are significantly correlated with patients having somatic mutations in the mtDNA in their breast cancer sample. In conclusion, our results suggest that somatic mtDNA mutations may play a critical role in the progression of breast cancer.     

Age-dependent accumulation of mtDNA mutations in murine hematopoietic stem cells is modulated by the nuclear genetic background

Alterations in mitochondrial DNA (mtDNA) and consequent loss of mitochondrial function underlie the mitochondrial theory of aging. In this study, we systematically analyzed the mtDNA control region somatic mutation pattern in 2864 single hematopoietic stem cells (HSCs) and progenitors, isolated by flow cytometry sorting on Lin(-)Kit(+)CD34(-) parameters from young and old C57BL/6 (B6) and BALB/cBy (BALB) mice, to test the hypothesis that the accumulated mtDNA mutations in HSCs were strain-correlated and associated with HSC functional senescence during aging. An increased level of mtDNA mutations in single HSCs was observed in old B6 when compared with young B6 mice (P=0.003); in contrast, no significant age-dependent accumulation of mutations was observed in BALB mice (old versus young, P=0.202) and the level of mutations in both young and old BALB mice was close to that of old B6 mice (P>0.280). Cellular reactive oxygen species (ROS) in mouse HSCs could not be correlated with the level of mtDNA mutations in these cells, although B6 mice had a higher proportion of ROS(-) cells when compared with the BALB mice. Propagation assays of single HSCs showed B6 cells form larger colonies compared with cells from BALB mice, irrespective of age and mtDNA mutation load. We infer from our data that age-related mtDNA somatic mutation accumulation in mouse HSCs is influenced by the nuclear genetic background and that these mutations may not obviously correlate to either cellular ROS content or HSC senescence.     

Mitochondrial genotype associated with longevity and its inhibitory effect on mutagenesis

Mitochondria are not only the major site of ATP production in cells but also an important source of reactive oxygen species (ROS) under certain pathological conditions. Because mitochondrial DNA (mtDNA) in the mitochondrial matrix is exposed to ROS that leak from the respiratory chain, this extranuclear genome is prone to mutations. Therefore, the mitochondrial genome is a rich source of single nucleotide polymorphisms (SNPs) and the functional significance of SNPs in the mitochondrial genome is comparable to that of SNPs in the entire nuclear genome. To demonstrate the contribution of mitochondrial SNPs to the susceptibility to adult-onset diseases, we analyzed the mtDNA from Japanese centenarians and identified a longevity-associated mitochondrial genotype, Mt5178A. Because this genotype was demonstrated to suppress the occurrence of mtDNA mutations in the oocytes, it also would seem to decelerate the accumulation of mtDNA mutations in the somatic cells with increasing age. This genotype is likely to confer resistance to adult-onset diseases by suppressing obesity and atherosclerosis.     

Mitochondrial DNA mutations and mitochondrial DNA depletion in gastric cancer

Gastric carcinoma is one of the most common types of cancer in Taiwan. Somatic mitochondrial DNA (mtDNA) alteration in gastric carcinoma and its association with clinicopathologic features remain unclear. When we used polymerase chain reaction (PCR) and direct sequencing, 15 of the 31 (48%) gastric carcinomas displayed somatic mutations in the D-loop region, a hot spot for mutations in mtDNA of human cancers. Ten (67%) cancers with the somatic mutations in the D-loop had insertion or deletion mutations in nucleotide position (np) 303-309 in the mononucleotide repeat region. One carcinoma carried tandem duplication and triplication flanked by mononucleotide repeats starting at np 311 and 568, respectively, in the D-loop. We also detected the common 4,977-bp deletion in 17 (55%) of the noncancerous tissue samples, but only in three (9%) carcinomas. Moreover, we quantified the mtDNA content using a competitive PCR technique and found that mtDNA depletion occurred in 17 (55%) of the gastric carcinomas. Although no significant association was found between clinicopathologic features and the mtDNA mutations in the D-loop, mtDNA depletion was observed significantly in the ulcerated, infiltrating (Borrmann's type III) and diffusely thick (Borrmann's type IV) types of gastric carcinomas (P = 0.018). Our results suggest that somatic mtDNA mutations and mtDNA depletion occur in gastric cancer and that mtDNA depletion is involved in carcinogenesis and/or cancer progression of gastric carcinoma.     

Capture of Somatic mtDNA Point Mutations with Severe Effects on Oxidative Phosphorylation in Synaptosome Cybrid Clones from Human Brain

Mitochondrial DNA (mtDNA) is replicated throughout life in postmitotic cells, resulting in higher levels of somatic mutation than in nuclear genes. However, controversy remains as to the importance of low‐level mtDNA somatic mutants in cancerous and normal human tissues. To capture somatic mtDNA mutations for functional analysis, we generated synaptosome cybrids from synaptic endings isolated from fresh hippocampus and cortex brain biopsies. We analyzed the whole mtDNA genome from 120 cybrid clones derived from four individual donors by chemical cleavage of mismatch and Sanger sequencing, scanning around two million base pairs. Seventeen different somatic point mutations were identified, including eight coding region mutations, four of which result in frameshifts. Examination of one cybrid clone with a novel m.2949_2953delCTATT mutation in MT‐RNR2 (which encodes mitochondrial 16S rRNA) revealed a severe disruption of mtDNA‐encoded protein translation. We also performed functional studies on a homoplasmic nonsense mutation in MT‐ND1, previously reported in oncocytomas, and show that both ATP generation and the stability of oxidative phosphorylation complex I are disrupted. As the mtDNA remains locked against direct genetic manipulation, we demonstrate that the synaptosome cybrid approach can capture biologically relevant mtDNA mutants in vitro to study effects on mitochondrial respiratory chain function.     

Chromosomal non-disjunction in human oocytes: is there a mitochondrial connection?

The frequency of chromosome abnormalities due to non-disjunction of maternal chromosomes during meiosis is a function of age, with a sharp increase in the slope of the trisomy-age curve between the ages of 30 and 40 years. The basis of this increase, which is a major cause of birth defects, is unknown at present. In recent years, mutations in mitochondrial (mt) DNA have been associated with a growing number of disorders, including those associated with spontaneous deletions of mtDNA (deltamt DNAs). Intriguingly, these pathogenic deltamtDNAs, which are present at extremely high levels in certain patients, are also present at extremely low levels (detectable only by polymerase chain reaction) in normal individuals. The proportion of such deltamtDNAs in normal muscle is a function of age; the shape of this curve is exponential, with the accelerating part of the curve beginning at approximately 30-40 years. We postulate that, as well as muscle and brain, a similar time-dependent accumulation of deltamtDNAs also occurs in normal oocytes. Since deltamtDNAs are functionally inactive, an accumulation of such aberrant genomes could eventually compromise ATP-dependent energy-utilization in these cells. Furthermore, these deficiencies would also affect the function of the somatic follicular cells that surround, and secrete important paracrine factors to, the oocyte. If there is indeed an age-associated relationship between deltamtDNAs and oocyte age, perhaps errors in meiosis (which is almost certainly an energy, and ATP, dependent process) are related to mutations in mtDNA (primarily deletions, but perhaps point mutations as well) in oocytes and/or the surrounding somatic cells, which result in deficiencies in both mitochondrial function in general and oxidative energy metabolism in particular. This hypothesis would explain many of the non-Mendelian features associated with maternal age-related trisomies, e.g. Down's syndrome.     

Clonal expansion of mutated mitochondrial DNA is associated with tumor formation and complex I deficiency in the benign renal oncocytoma

Mutations in mitochondrial DNA (mtDNA) are frequent in cancers but it is not yet clearly established whether they are modifier events involved in cancer progression or whether they are a consequence of tumorigenesis. Here we show a benign tumor type in which mtDNA mutations that lead to complex I (CI) enzyme deficiency are found in all tumors and are the only genetic alteration detected. Actually renal oncocytomas are homogeneous tumors characterized by dense accumulation of mitochondria and we had found that they are deficient in electron transport chain complex I (CI, NADH-ubiquinone oxidoreductase). In this work total sequencing of mtDNA showed that 9/9 tumors harbored point mutations in mtDNA, seven in CI genes, one in complex III, and one in the control region. 7/8 mutations were somatic. All tumors were somatically deficient for CI. The clonal amplification of mutated mtDNA in 8/9 tumors demonstrates that these alterations are selected and therefore favor or trigger growth. No nuclear DNA rearrangement was detected beside mtDNA defects. We hypothesize that functional deficiency of the oxidative phosphorylation CI could create a loop of amplification of mitochondria during cell division, impair substrates oxidation and increase intermediary metabolites availability.     

Organismal effects of mitochondrial dysfunction

Mitochondrial disease can lead to clinical abnormalities in any organ system. Both inherited and spontaneous disorders are known. The spontaneous forms can occur as a mitochondrial DNA (mtDNA) mutation early in embryogenesis or, later in life, as somatic mutations that accumulate with age. The inherited forms may arise from any of >100 characterized mutations in mtDNA or from >200 nuclear gene defects that affect proteins required for mitochondrial function. Most dividing cells survive and interact normally despite their mitochondrial defects. Thus post-mitotic, terminally differentiated cells are preferentially affected in mitochondrial disease. This review emphasizes cellular metabolic co-operation and the structural and biochemical diversity of mitochondria as the framework for understanding the clinical spectrum of mitochondrial disease. The principles of the mitochondrial clinical assessment scale I (MCAS-I) are presented to assist in the development of diagnostic spectra of mitochondrial disease.     

Enhanced ROS production and antioxidant defenses in cybrids harbouring mutations in mtDNA

It has been suggested that mutations in mitochondrial DNA (mtDNA) can produce an increase in reactive oxygen species (ROS) and that this can play a major role in the pathogenic mechanisms of mitochondrial encephalomyopathies. Many studies exist using electron transport chain (ETC) inhibitors, however there are only a few studies that examine ROS production associated with mutations in the mtDNA. To investigate this issue, we have studied ROS production, antioxidant defences and oxidative damage to lipids and proteins in transmitochondrial cybrids carrying different mtDNA mutations. Here, we report that two different mutant cell lines carrying mutations in their mitochondrial tRNA genes (A3243G in tRNA LeuUUR and A8344G in tRNA Lys) showed an increased ROS production with a parallel increase in the antioxidant enzyme activities, which may protect cells from oxidative damage in our experimental conditions (no overt oxidative damage to lipids and proteins has been observed). In contrast, cytochrome c oxidase (COX) mutant cybrids (carrying the stop-codon mutation G6930A in the COXI gene) showed neither an increase in ROS production nor elevation of antioxidant enzyme activities or oxidative damage. These results suggest that the specific location of mutations in mtDNA has a strong influence on the phenotype of the antioxidant response. Therefore, this issue should be carefully considered when antioxidant therapies are investigated in patients with mitochondrial disorders.     

Differential age-related changes in mitochondrial DNA repair activities in mouse brain regions

Aging in the brain is characterized by increased susceptibility to neuronal loss and functional decline, and mitochondrial DNA (mtDNA) mutations are thought to play an important role in these processes. Due to the proximity of mtDNA to the main sites of mitochondrial free radical generation, oxidative stress is a major source of DNA mutations in mitochondria. The base excision repair (BER) pathway removes oxidative lesions from mtDNA, thereby constituting an important mechanism to avoid accumulation of mtDNA mutations. The complexity of the brain implies that exposure and defence against oxidative stress varies among brain regions and hence some regions may be particularly prone to accumulation of mtDNA damages. In the current study we investigated the efficiency of the BER pathway throughout the murine lifespan in mitochondria from cortex and hippocampus, regions that are central in mammalian cognition, and which are severely affected during aging and in neurodegenerative diseases. A regional specific regulation of mitochondrial DNA repair activities was observed with aging. In cortical mitochondria, DNA glycosylase activities peaked at middle-age followed by a significant drop at old age. However, only minor changes were observed in hippocampal mitochondria during the whole lifespan of the animals. Furthermore, DNA glycosylase activities were lower in hippocampal than in cortical mitochondria. Mitochondrial AP endonuclease activity increased in old animals in both brain regions. Our data suggest an important regional specific regulation of mitochondrial BER during aging.     

Somatic mitochondrial DNA mutations in cortex and substantia nigra in aging and Parkinson's disease

Oxidative damage to mitochondrial DNA (mtDNA) increases with age in the brain and can induce G:C to T:A and T:A to G:C point mutations. Though rare at any particular site, multiple somatic mtDNA mutations induced by oxidative damage or by other mechanisms may accumulate with age in the brain and thus could play a role in aging and neurodegenerative diseases. However, no prior study has quantified the total burden of mtDNA point mutation subtypes in the brain. Using a highly sensitive cloning and sequencing strategy, we find that the aggregate levels of G:C to T:A and T:A to G:C transversions and of all point mutations increase with age in the frontal cortex (FCtx). In the substantia nigra (SN), the aggregate levels of point mutations in young controls are similar to the levels in the SN or FCtx of elderly subjects. Extrapolation from our data suggests an average of 2.7 (FCtx) to 3.2 (SN) somatic point mutations per mitochondrial genome in elderly subjects. There were no significant differences between Parkinson's disease (PD) patients and age-matched controls in somatic mutation levels. These results indicate that individually rare mtDNA point mutations reach a high aggregate burden in FCtx and SN of elderly subjects.     

Genetic pathways in colorectal cancer

The model of colorectal tumorigenesis put forward by Fearon and Vogelstein has had great influence on molecular oncology. They proposed that a series of mutations occur in the progression from normal cells to colorectal cancer and that these mutations are associated with the histological features of such tumours. Several postulates of the model appear to be correct, particularly its emphasis on the stepwise accumulation of genetic changes and the inclusion of mutations at the adenomatous polyposis coli ( APC ) and TP53 loci. Since the publication of the original model, however, mutations at other loci have been identified which may be alternatives or additions. There is also evidence to suggest that some colorectal cancers develop along a different genetic pathway. In this review, we discuss how tumour development can occur as Darwinian evolution through selection of advantageous somatic mutations. The non-random nature of mutation selection gives rise to genetic pathways of tumorigenesis. In addition, we consider the Fearon and Vogelstein model, its shortcomings and possible additions to it. The evidence suggests that not all colorectal cancers follow the same genetic pathway during carcinogenesis.