Mitochondrial DNA mutations in renal cell carcinomas revealed no general impact on energy metabolism

Meierhofer, David; Mayr, Johannes A.; Fink, Klaus; Schmeller, N.; Kofler, Barbara; Sperl, Wolfgang

doi:10.1038/sj.bjc.6602929

Cited by 54 publications

(34 citation statements)

References 41 publications

(51 reference statements)

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“…These include renal adenocarcinoma, colon cancer cells, head and neck tumours, astrocytic tumours, thyroid tumours, breast tumours, ovarian tumours, prostate and bladder cancer, neuroblastomas and oncocytomas 19–24 . Although technical and interpretive errors were common in early publications on mtDNA mutations in cancer 25–27 , the identification of clearly deleterious mtDNA mutations in cancer tissues — such as an intragenic deletion 8 or the common tRNA Leu(UUR) A3243G MELAS mutation 26 — validate the relevance of pathogenic mutations in neoplastic transformation. The importance of the mtDNA in cancer has been confirmed by the exchange of cancer cell mtDNA with pathogenic or normal mtDNA, resulting in alterations of cancer cell phenotypes 28–31 .…”

Section: Mutations That Affect the Expression Of Mtdnamentioning

confidence: 99%

Mitochondria and cancer

2012

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Contrary to conventional wisdom, functional mitochondria are essential for the cancer cell. Although mutations in mitochondrial genes are common in cancer cells, they do not inactivate mitochondrial energy metabolism but rather alter the mitochondrial bioenergetic and biosynthetic state. These states communicate with the nucleus through mitochondrial ‘retrograde signalling’ to modulate signal transduction pathways, transcriptional circuits and chromatin structure to meet the perceived mitochondrial and nuclear requirements of the cancer cell. Cancer cells then reprogramme adjacent stromal cells to optimize the cancer cell environment. These alterations activate out-of-context programmes that are important in development, stress response, wound healing and nutritional status.

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Section: Mutations That Affect the Expression Of Mtdnamentioning

confidence: 99%

Mitochondria and cancer

2012

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“…The A3243G mutation might be sporadically associated with other tumor types because it was also detected in a colon cancer sample (28) and a renal cell carcinoma (24).…”

Section: Discussionmentioning

confidence: 99%

“…Determination of mutational load of the A3243G mutation. The percentage of mutational load was quantified by densitometry of ethidium bromide -stained agarose gels, as described previously (24).…”

Section: Methodsmentioning

confidence: 99%

93 Loss of complex I due to mitochondrial DNA mutations in renal oncocytoma

et al. 2007

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Purpose: Many solid tumors exhibit abnormal aerobic metabolism characterized by increased glycolytic capacity and decreased cellular respiration. Recently, mutations in the nuclear encoded mitochondrial enzymes fumarate hydratase and succinate dehydrogenase have been identified in certain tumor types, thus demonstrating a direct link between mitochondrial energy metabolism and tumorigenesis. Although mutations in the mitochondrial genome (mitochondrial DNA, mtDNA) also can affect aerobic metabolism and mtDNA alterations are frequently observed in tumor cells, evidence linking respiratory chain deficiency in a specific tumor type to a specific mtDNA mutation has been lacking. Experimental Design: To identify mitochondrial alterations in oncocytomas, we investigated the activities of respiratory chain enzymes and sequenced mtDNA in 15 renal oncocytoma tissues.Results: Here, we show that loss of respiratory chain complex I (NADH/ubiquinone oxidoreductase) is associated with renal oncocytoma. Enzymatic activity of complex I was undetectable or greatly reduced in the tumor samples (n = 15). Blue Native gel electrophoresis of the multisubunit enzyme complex revealed a lack of assembled complex I. Mutation analysis of the mtDNA showed frame-shift mutations in the genes of either subunit ND1, ND4, or ND5 of complex I in 9 of the 15 tumors. Conclusion: Our data indicate that isolated loss of complex I is a specific feature of renal oncocytoma and that this deficiency is frequently caused by somatic mtDNA mutations.

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“…The identification of clearly deleterious mtDNA mutations in cancer tissues - such as an intragenic deletion [21] or the common tRNALeu (UUR) A3243G MELAS mutation, or, even more so, very rare clearly pathogenic mutations in complex I [22] (for a review see [19, 23]) - underline the relevance of pathogenic mtDNA mutations in neoplastic transformation. In recent years a high number of point mutations, either germline or somatic, insertions and deletions in mtDNA have been identified in multiple cancers [24–28].…”

Section: Introductionmentioning

confidence: 99%

A comprehensive characterization of rare mitochondrial DNA variants in neuroblastoma

et al. 2016

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BackgroundNeuroblastoma, a tumor of the developing sympathetic nervous system, is a common childhood neoplasm that is often lethal. Mitochondrial DNA (mtDNA) mutations have been found in most tumors including neuroblastoma. We extracted mtDNA data from a cohort of neuroblastoma samples that had undergone Whole Exome Sequencing (WES) and also used snap-frozen samples in which mtDNA was entirely sequenced by Sanger technology. We next undertook the challenge of determining those mutations that are relevant to, or arisen during tumor development. The bioinformatics pipeline used to extract mitochondrial variants from matched tumor/blood samples was enriched by a set of filters inclusive of heteroplasmic fraction, nucleotide variability, and in silico prediction of pathogenicity.ResultsOur in silico multistep workflow applied both on WES and Sanger-sequenced neuroblastoma samples, allowed us to identify a limited burden of somatic and germline mitochondrial mutations with a potential pathogenic impact.ConclusionsThe few singleton germline and somatic mitochondrial mutations emerged, according to our in silico analysis, do not appear to impact on the development of neuroblastoma. Our findings are consistent with the hypothesis that most mitochondrial somatic mutations can be considered as ‘passengers’ and consequently have no discernible effect in this type of cancer.

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Mitochondrial DNA mutations in renal cell carcinomas revealed no general impact on energy metabolism

Cited by 54 publications

References 41 publications

Mitochondria and cancer

Mitochondria and cancer

93 Loss of complex I due to mitochondrial DNA mutations in renal oncocytoma

A comprehensive characterization of rare mitochondrial DNA variants in neuroblastoma

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