Understanding Mitochondrial Polymorphisms in Cancer

Bussard, Karen M.; Siracusa, Linda D.

doi:10.1158/0008-5472.can-17-1939

Cited by 38 publications

(31 citation statements)

References 66 publications

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“…Therefore, review of mtDNA haplogroup association below is not complete, but rather provides examples of compelling mtDNA polymorphism correlations with cancer susceptibility. For a more thorough analysis of the strengths and weaknesses of animal models studying mtDNA polymorphisms in cancer risk association, please refer to a recent review from Bussard and Siracusa [97]. Following a brief discussion of the population-based studies, we will briefly summarize some of the newer experimental approaches to dissect the contributions of mitochondrial DNA in cancer progression and metastasis.…”

Section: Mitochondrial Haplogroups and Cancermentioning

confidence: 99%

Roles of the mitochondrial genetics in cancer metastasis: not to be ignored any longer

Beadnell

Scheid

Vivian

et al. 2018

Cancer Metastasis Rev

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Mitochondrial DNA (mtDNA) encodes for only a fraction of the proteins that are encoded within the nucleus, and therefore has typically been regarded as a lesser player in cancer biology and metastasis. Accumulating evidence, however, supports an increased role for mtDNA impacting tumor progression and metastatic susceptibility. Unfortunately, due to this delay, there is a dearth of data defining the relative contributions of specific mtDNA polymorphisms (SNP), which leads to an inability to effectively use these polymorphisms to guide and enhance therapeutic strategies and diagnosis. In addition, evidence also suggests that differences in mtDNA impact not only the cancer cells, but also the cells within the surrounding tumor microenvironment, suggesting a broad encompassing role for mtDNA polymorphisms in regulating the disease progression. mtDNA may have profound implications in the regulation of cancer biology and metastasis. However, there are still great lengths to go to understand fully its contributions. Thus, herein we discuss the recent advances in our understanding of mtDNA in cancer and metastasis, providing a framework for future functional validation and discovery.

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Section: Mitochondrial Haplogroups and Cancermentioning

confidence: 99%

Roles of the mitochondrial genetics in cancer metastasis: not to be ignored any longer

Beadnell

Scheid

Vivian

et al. 2018

Cancer Metastasis Rev

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“…However, the role of mtDNA mutations or copy number variations as potential causative agents in cancer development have not been fully established due to the technological difficulties of manipulating the mtDNA genome. Studies in mice that have mtDNA from one strain and nuclear DNA from another strain (i.e., mice generated by mitochondrial-nuclear exchange) show effects in cancer progression models including changes in tumor size and metastatic burden [49] , suggesting that the mtDNA can affect cancer progression.…”

Section: Mitochondria Heterogeneity In Cancermentioning

confidence: 99%

Genomic heterogeneity meets cellular energetics: crosstalk between the mitochondria and the cell cycle

Herrera¹,

Azzam²,

Berger³

et al. 2018

JCMT

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Changes in cellular energetics and genomic instability are two characteristics of cancers that have been studied independently. Evidence of cross-talk between mitochondria function and nuclear function has started to emerge, suggesting that these pathways can influence one another. Here we review recent evidence that links the mitochondria and the cell cycle. This evidence indicates bidirectional cross-talk where mitochondria function can regulate the cell cycle and induce genomic instability, and conversely, the cell cycle machinery regulates mitochondria function. Implications for this cross-talk in the development of cancer are discussed.

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“…For example, C3H/HeN mice do not contain a mutation in the toll-like receptor 4 (TLR4); whereas, C3H/HeJ mice do. Such differences are also manifest during the generation of conplastic strains, which allows comparison between strains with similar or identical nuclear genomes but differing in their mitochondrial genome, thus providing evidence that the mitochondrial genome influences phenotypes [52,53]. …”

Section: Introductionmentioning

confidence: 99%

“…Although several strategies have been used to assess the contributions of mtDNA to disease, strengths and limitations exist for each (reviewed in [53,36]). In order to avoid use of mutagens, off-target effects of drugs and nDNA crossover complications to studying mitochondrial genetic contributions, we developed Mitochondrial-Nuclear Exchange (MNX) mice [37,59,39,15].…”

Section: Introductionmentioning

confidence: 99%

Mitochondrial polymorphisms contribute to aging phenotypes in MNX mouse models

Vivian

Hagedorn

Jensen

et al. 2018

Cancer Metastasis Rev

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Many inbred strains of mice develop spontaneous tumors as they age. Recent awareness of the impacts of mitochondrial DNA (mtDNA) on cancer and aging have inspired developing a Mitochondrial-Nuclear Exchange (MNX) mouse model in which nuclear DNA is paired with mitochondrial genomes from other strains of mouse. MNX mice exhibit mtDNA influences on tumorigenicity and metastasis upon mating with transgenic mice. However, we also wanted to investigate spontaneous tumor phenotypes as MNX mice age. Utilizing FVB/NJ, C57BL/6J, C3H/HeN, and BALB/cJ wild-type inbred strains, previously documented phenotypes were observed as expected in MNX mice with the same nuclear background. However, aging nuclear matched MNX mice exhibited decreased occurrence of mammary tumors in C3H/HeN mice containing C57BL/6J mitochondria compared to wild-type C3H/HeN mice. Although aging tumor phenotypes appear to be driven by nuclear genes, evidence suggesting that some differences are modified by the mitochondrial genome is presented.

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Understanding Mitochondrial Polymorphisms in Cancer

Cited by 38 publications

References 66 publications

Roles of the mitochondrial genetics in cancer metastasis: not to be ignored any longer

Roles of the mitochondrial genetics in cancer metastasis: not to be ignored any longer

Genomic heterogeneity meets cellular energetics: crosstalk between the mitochondria and the cell cycle

Mitochondrial polymorphisms contribute to aging phenotypes in MNX mouse models

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