The awakening of an advanced malignant cancer: an insult to the mitochondrial genome.

BACKGROUND: In only months-to-years a primary cancer can progress to an advanced phenotype that is metastatic and resistant to clinical treatments. As early as the 1900s, it was discovered that the progression of a cancer to the advanced phenotype is often associated with a shift in the metabolic profile of the disease from a state of respiration to anaerobic fermentation - a phenomenon denoted as the Warburg Effect. SCOPE OF REVIEW: Reports in the literature strongly suggest that the Warburg Effect is generated as a response to a loss in the integrity of the sequence and/or copy number of the mitochondrial genome content within a cancer. MAJOR CONCLUSIONS: Multiple studies regarding the progression of cancer indicate that mutation, and/or, a flux in the copy number, of the mitochondrial genome content can support the early development of a cancer, until; the mutational load and/or the reduction-to-depletion of the copy number of the mitochondrial genome content induces the progression of the disease to an advanced phenotype. GENERAL SIGNIFICANCE: Collectively, evidence has revealed that the human cell has incorporated the mitochondrial genome content into a cellular mechanism that, when pathologically actuated, can de(un)differentiate a cancer from the parental tissue of origin into an autonomous disease that disrupts the hierarchical structure-and-function of the human body. This article is part of a Special Issue entitled: Biochemistry of Mitochondria.

Progressive tumor features accompany epithelial-mesenchymal transition induced in mitochondrial DNA-depleted cells.

The growth of LNCaP, a human prostate adenocarcinoma cell line, and MCF-7, a human breast adenocarcinoma cell line, is initially hormone dependent. We previously demonstrated that LNrho0-8 and MCFrho0, derived from LNCaP and MCF-7 by depleting mitochondrial DNA (mtDNA), exhibited hormone-independent growth that led to progressed phenotypes. Here, we demonstrate that LNrho0-8 and MCFrho0 have invasive characters as evaluated by the ability of invasion through the extracellular matrix (ECM) in vitro. In addition, the induction of vimentin and the repression of E-cadherin expression in rho0 cells indicate that they are mesenchymal cells. Since LNrho0-8 and MCFrho0 were derived from epithelial cancer cell lines, LNCaP and MCF-7 must have lost epithelial features and gained the mesenchymal phenotype by epithelial-mesenchymal transition (EMT) during the mtDNA depletion. In the rho0 cell lines, the Raf/MAPK signaling cascade was highly activated together with the expressions of transforming growth factor-beta (TGF-beta) and type I TGF-beta receptor (TGF-betaRI). EMT requires cooperation of TGF-beta signaling with activation of the Raf/MAPK cascade, suggesting that EMT was induced in mtDNA depleted cells resulting in the acquisition of progressive tumor features, such as higher invasiveness and loss of hormone dependent growth. Our results indicate that decreasing mtDNA content induces EMT, enabling the progressive phenotypes observed in cancer.

Are oxidative mechanisms primary in ethanol induced Purkinje neuron death of the neonatal rat?

Rat cerebellar Purkinje neurons are vulnerable to ethanol exposure during the brain growth spurt, especially during early postnatal exposure. A prominent hypothesis is that ethanol induces oxidative types of alterations that result in the neurodegeneration. The purpose of this study was to test this hypothesis in two ways. One was to determine if the reactive oxidative species, nitrotyrosine (NT), was produced in the cerebellum following ethanol exposure. Second, was to determine if co-administration of the clinically useful antioxidant N-acetylcysteine (NAC) afforded any protection from Purkinje neuron loss. Rat pups were treated on postnatal day 4 with a single ethanol (6.0 g/kg) or isocaloric intragastric intubation. The cerebelli were analyzed for NT with ELISA assays at 2, 4, 6, or 8 h following the single exposure. No evidence of NT was found at any of these time points. Another group of animals received ethanol exposure on PN4, or ethanol exposure plus NAC. Control groups included isocaloric intubated controls (IC), IC plus NAC, and mother reared controls. Twenty-four hours following the exposures, the pups were perfused and the cerebellum processed for cell counting. Ethanol exposure reduced the number of Purkinje neurons in the cerebellum. Concurrent treatment with antioxidant did not protect the Purkinje neurons from ethanol-related cell loss. These in vivo analyses do not support a robust oxidative mechanism involving the production of reactive nitrogen species as a significant means of Purkinje cell neurodegeneration.