Metformin targets histone acetylation in cancer-prone epithelial cells

Cuyàs, Elisabet; Fernández-Arroyo, Salvador; Joven, Jorge; Menendez, Javier A.

doi:10.1080/15384101.2016.1249547

Cited by 17 publications

(12 citation statements)

References 66 publications

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“…Germline BRCA1 mutation reprograms breast epithelial cell metabolism towards mitochondrial-dependent biosynthesis and increased risk of oncogenesis. Metformin studies in BRCA1 haploinsufficiency-driven oncogenesis support potential prevention approaches in BRCA1 carriers: inhibition of complex I and restriction of mitochondrial-dependent biosynthetic intermediates (123) may open a new avenue for “starvation” strategies; and regulating mitochondrial-nuclear communication and modulating the epigenetic landscape (targeting histone acetylation) in genomically unstable precancerous cells (124), might guide the development of new metabolomic-epigenetic strategies. As with nuclear GWAS, certain mtDNA alterations modify (lower) risks of breast cancer in germline BRCA2 mutations (125).…”

Section: Translating Inherited Cancer Risk Into Precision Preventionmentioning

confidence: 99%

Precancer Atlas to Drive Precision Prevention Trials

et al. 2017

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Cancer development is a complex process driven by inherited and acquired molecular and cellular alterations. Prevention is the holy grail of cancer elimination, but making this a reality will take a fundamental rethinking and deep understanding of premalignant biology. In this Perspective, we propose a national concerted effort to create a Precancer Atlas (PCA), integrating multi-omics and immunity - basic tenets of the neoplastic process. The biology of neoplasia caused by germline mutations has led to paradigm-changing precision prevention efforts, including: tumor testing for mismatch repair (MMR) deficiency in Lynch syndrome establishing a new paradigm, combinatorial chemoprevention efficacy in familial adenomatous polyposis (FAP), signal of benefit from imaging-based early detection research in high-germline risk for pancreatic neoplasia, elucidating early ontogeny in -mutation carriers leading to an international breast cancer prevention trial, and insights into the intricate germline-somatic-immunity interaction landscape. Emerging genetic and pharmacologic (metformin) disruption of mitochondrial (mt) respiration increased autophagy to prevent cancer in a Li-Fraumeni mouse model (biology reproduced in clinical pilot) and revealed profound influences of subtle changes in mt DNA background variation on obesity, aging, and cancer risk. The elaborate communication between the immune system and neoplasia includes an increasingly complex cellular microenvironment and dynamic interactions between host genetics, environmental factors, and microbes in shaping the immune response. Cancer vaccines are in early murine and clinical precancer studies, building on the recent successes of immunotherapy and HPV vaccine immune prevention. Molecular monitoring in Barrett's esophagus to avoid overdiagnosis/treatment highlights an important PCA theme. Next generation sequencing (NGS) discovered age-related clonal hematopoiesis of indeterminate potential (CHIP). Ultra-deep NGS reports over the past year have redefined the premalignant landscape remarkably identifying tiny clones in the blood of up to 95% of women in their 50s, suggesting that potentially premalignant clones are ubiquitous. Similar data from eyelid skin and peritoneal and uterine lavage fluid provide unprecedented opportunities to dissect the earliest phases of stem/progenitor clonal (and microenvironment) evolution/diversity with new single-cell and liquid biopsy technologies. Cancer mutational signatures reflect exogenous or endogenous processes imprinted over time in precursors. Accelerating the prevention of cancer will require a large-scale, longitudinal effort, leveraging diverse disciplines (from genetics, biochemistry, and immunology to mathematics, computational biology, and engineering), initiatives, technologies, and models in developing an integrated multi-omics and immunity PCA - an immense national resource to interrogate, target, and intercept events that drive oncogenesis..

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Section: Translating Inherited Cancer Risk Into Precision Preventionmentioning

confidence: 99%

Precancer Atlas to Drive Precision Prevention Trials

et al. 2017

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“…AMPK activated by metformin regulates histone acetylation in a metabolic state-dependent manner. For example, metformin reduces H3 acetylation by decreasing bioavailability of mitochondrial acetyl-CoA in breast cancer, bringing acetylation status to normal in promoters of cancer-specific genes [ 37 ].…”

Section: Histone Modificationmentioning

confidence: 99%

AMPK: An Epigenetic Landscape Modulator

Gongol

Sari

Bryant

et al. 2018

IJMS

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Activated by AMP-dependent and -independent mechanisms, AMP-activated protein kinase (AMPK) plays a central role in the regulation of cellular bioenergetics and cellular survival. AMPK regulates a diverse set of signaling networks that converge to epigenetically mediate transcriptional events. Reversible histone and DNA modifications, such as acetylation and methylation, result in structural chromatin alterations that influence transcriptional machinery access to genomic regulatory elements. The orchestration of these epigenetic events differentiates physiological from pathophysiological phenotypes. AMPK phosphorylation of histones, DNA methyltransferases and histone post-translational modifiers establish AMPK as a key player in epigenetic regulation. This review focuses on the role of AMPK as a mediator of cellular survival through its regulation of chromatin remodeling and the implications this has for health and disease.

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“…This mathematical approach predicted that regulating the stochastic translation of mitochondrial-driven metabolic inputs into resilient versus plastic cell states via epigenetics could promote the establishment of epigenomes refractory to (CSC-related) loss of cell fate and de-differentiation phenomena. In this context, apparently simple drugs such as the anti-diabetic biguanide metformin, which operates as a metabolo-epigenetic reprogrammer of the molecular conduits linking mitochondrial-driven synthesis of epigenetic metabolites with the structure and functioning of the epigenome [23][24][25][26], are now recognized as molecules that selectively target CSCs [27,28]. Metformin has been shown to potently and specifically suppress the undifferentiated stem cell compartment responsible for malignant carcinoma-like growth within tumor masses generated upon injection of induced pluripotent stem cells (iPSCs) into mice [29][30].…”

Section: Metabolic Symbiosis-related Mitonuclear Communicationmentioning

confidence: 99%

Mitostemness

et al. 2018

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Unraveling the key mechanisms governing the retention versus loss of the cancer stem cell (CSC) state would open new therapeutic avenues to eradicate cancer. Mitochondria are increasingly recognized key drivers in the origin and development of CSC functional traits. We here propose the new term "mitostemness" to designate the mitochondria-dependent signaling functions that, evolutionary rooted in the bacterial origin of mitochondria, regulate the maintenance of CSC self-renewal and resistance to differentiation. Mitostemness traits, namely mitonuclear communication, mitoproteome components, and mitochondrial fission/fusion dynamics, can be therapeutically exploited to target the CSC state. We briefly review the pre-clinical evidence of action of investigational compounds on mitostemness traits and discuss ongoing strategies to accelerate the clinical translation of new mitostemness drugs. The recognition that the bacterial origin of present-day mitochondria can drive decision-making signaling phenomena may open up a new therapeutic dimension against life-threatening CSCs. New therapeutics aimed to target mitochondria not only as biochemical but also as biophysical and morpho-physiological hallmarks of CSC might certainly guide improvements to cancer treatment.

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Metformin targets histone acetylation in cancer-prone epithelial cells

Cited by 17 publications

References 66 publications

Precancer Atlas to Drive Precision Prevention Trials

Precancer Atlas to Drive Precision Prevention Trials

AMPK: An Epigenetic Landscape Modulator

Mitostemness

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