Increased oxidative phosphorylation in response to acute and chronic DNA damage

Accumulation of DNA damage is intricately linked to aging, aging-related diseases and progeroid syndromes such as Cockayne syndrome (CS). Free radicals from endogenous oxidative energy metabolism can damage DNA, however the potential of acute or chronic DNA damage to modulate cellular and/or organismal energy metabolism remains largely unexplored. We modeled chronic endogenous genotoxic stress using a DNA repair-deficient Csa−/−|Xpa−/− mouse model of CS. Exogenous genotoxic stress was modeled in mice in vivo and primary cells in vitro treated with different genotoxins giving rise to diverse spectrums of lesions, including ultraviolet radiation, intrastrand crosslinking agents and ionizing radiation. Both chronic endogenous and acute exogenous genotoxic stress increased mitochondrial fatty acid oxidation (FAO) on the organismal level, manifested by increased oxygen consumption, reduced respiratory exchange ratio, progressive adipose loss and increased FAO in tissues ex vivo. In multiple primary cell types, the metabolic response to different genotoxins manifested as a cell-autonomous increase in oxidative phosphorylation (OXPHOS) subsequent to a transient decline in steady-state NAD+ and ATP levels, and required the DNA damage sensor PARP-1 and energy-sensing kinase AMPK. We conclude that increased FAO/OXPHOS is a general, beneficial, adaptive response to DNA damage on cellular and organismal levels, illustrating a fundamental link between genotoxic stress and energy metabolism driven by the energetic cost of DNA damage. Our study points to therapeutic opportunities to mitigate detrimental effects of DNA damage on primary cells in the context of radio/chemotherapy or progeroid syndromes.

[1]  W. V. van IJcken,et al.  Short‐term dietary restriction and fasting precondition against ischemia reperfusion injury in mice , 2010, Aging cell.

[2]  J. Hoeijmakers,et al.  Aging and Genome Maintenance: Lessons from the Mouse? , 2003, Science.

[3]  L. Brace,et al.  Defective Mitophagy in XPA via PARP-1 Hyperactivation and NAD+/SIRT1 Reduction , 2014, Cell.

[4]  Vasant R. Marur,et al.  Lipidomics profiling by high-resolution LC-MS and high-energy collisional dissociation fragmentation: focus on characterization of mitochondrial cardiolipins and monolysocardiolipins. , 2011, Analytical chemistry.

[5]  A. Stewart,et al.  Dysregulation of gene expression as a cause of Cockayne syndrome neurological disease , 2014, Proceedings of the National Academy of Sciences.

[6]  E. Rapizzi,et al.  Poly(ADP-ribose) Catabolism Triggers AMP-dependent Mitochondrial Energy Failure* , 2009, The Journal of Biological Chemistry.

[7]  H. H. Evans,et al.  Poly(ADP-ribose) and the response of cells to ionizing radiation. , 1985, Radiation research.

[8]  Vito Pistoia,et al.  Fasting Cycles Retard Growth of Tumors and Sensitize a Range of Cancer Cell Types to Chemotherapy , 2012, Science Translational Medicine.

[9]  N. Berger Poly(ADP-ribose) in the cellular response to DNA damage. , 1985, Radiation research.

[10]  Pedro Mejia,et al.  Surgical Stress Resistance Induced by Single Amino Acid Deprivation Requires Gcn2 in Mice , 2012, Science Translational Medicine.

[11]  Robert W Sobol,et al.  ARTD1/PARP1 negatively regulates glycolysis by inhibiting hexokinase 1 independent of NAD+ depletion. , 2014, Cell reports.

[12]  E. Jung,et al.  AMP-activated protein kinase-α1 as an activating kinase of TGF-β-activated kinase 1 has a key role in inflammatory signals , 2012, Cell Death and Disease.

[13]  Craig B. Thompson,et al.  Fuel feeds function: energy metabolism and the T-cell response , 2005, Nature Reviews Immunology.

[14]  Dong-Ho Han,et al.  High-fat diets cause insulin resistance despite an increase in muscle mitochondria , 2008, Proceedings of the National Academy of Sciences.

[15]  Tong Xu,et al.  MDM2 restrains estrogen-mediated AKT activation by promoting TBK1-dependent HPIP degradation , 2014, Cell Death and Differentiation.

[16]  Vasant R. Marur,et al.  Serum lipidomics profiling using LC-MS and high-energy collisional dissociation fragmentation: focus on triglyceride detection and characterization. , 2011, Analytical chemistry.

[17]  M. I. Davies,et al.  Stimulation of poly(ADP-ribose) polymerase activity by the anti-tumour antibiotic, streptozotocin. , 1975, Biochemical and biophysical research communications.

[18]  J. Campisi,et al.  Persistent DNA damage signaling triggers senescence-associated inflammatory cytokine secretion , 2009, Nature Cell Biology.

[19]  T. Hryniewiecki,et al.  The effect of brief food withdrawal on the level of free radicals and other parameters of oxidative status in the liver. , 2003, Medical science monitor : international medical journal of experimental and clinical research.

[20]  D. Hardie,et al.  AMPK: a nutrient and energy sensor that maintains energy homeostasis , 2012, Nature Reviews Molecular Cell Biology.

[21]  David Carling,et al.  Signaling Kinase AMPK Activates Stress-Promoted Transcription via Histone H2B Phosphorylation , 2010, Science.

[22]  Michael Karin,et al.  p53 Target Genes Sestrin1 and Sestrin2 Connect Genotoxic Stress and mTOR Signaling , 2009, Cell.

[23]  R. de Cabo,et al.  Cockayne syndrome group B protein prevents the accumulation of damaged mitochondria by promoting mitochondrial autophagy , 2012, The Journal of experimental medicine.

[24]  S. J. Berger,et al.  Poly(ADP-ribose) Polymerase inhibitors preserve nicotinamide adenine dinucleotide and adenosine 5'-triphosphate pools in DNA-damaged cells: mechanism of stimulation of unscheduled DNA synthesis. , 1983, Biochemistry.

[25]  P. Garnier,et al.  NAD+ Depletion Is Necessary and Sufficient forPoly(ADP-Ribose) Polymerase-1-Mediated Neuronal Death , 2010, The Journal of Neuroscience.

[26]  E. Jacobson,et al.  Poly(ADP-ribose) metabolism in ultraviolet irradiated human fibroblasts. , 1983, The Journal of biological chemistry.

[27]  Valerie A. I. Natale A comprehensive description of the severity groups in Cockayne syndrome , 2011, American journal of medical genetics. Part A.

[28]  Masayuki Yamamoto,et al.  Molecular mechanisms of the Keap1–Nrf2 pathway in stress response and cancer evolution , 2011, Genes to cells : devoted to molecular & cellular mechanisms.

[29]  C. I. Zeeuw,et al.  Adaptive Stress Response in Segmental Progeria Resembles Long-Lived Dwarfism and Calorie Restriction in Mice , 2006, PLoS genetics.

[30]  M. Smith-Wheelock,et al.  Methionine‐deficient diet extends mouse lifespan, slows immune and lens aging, alters glucose, T4, IGF‐I and insulin levels, and increases hepatocyte MIF levels and stress resistance , 2005, Aging cell.

[31]  A. Bhatt,et al.  Transient elevation of glycolysis confers radio-resistance by facilitating DNA repair in cells , 2015, BMC Cancer.

[32]  J. Dhahbi,et al.  Genomic profiling of short- and long-term caloric restriction effects in the liver of aging mice , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[33]  David M. Wilson,et al.  Repair of persistent strand breaks in the mitochondrial genome , 2012, Mechanisms of Ageing and Development.

[34]  Cyrus F. Khambatta,et al.  Calorie restriction increases fatty acid synthesis and whole body fat oxidation rates , 2010, American journal of physiology. Endocrinology and metabolism.

[35]  J. Hoeijmakers,et al.  Congenital DNA repair deficiency results in protection against renal ischemia reperfusion injury in mice , 2009, Aging cell.

[36]  Xiaoling Xu,et al.  SIRT4 has tumor-suppressive activity and regulates the cellular metabolic response to DNA damage by inhibiting mitochondrial glutamine metabolism. , 2013, Cancer cell.

[37]  Louis Hue,et al.  The Randle cycle revisited: a new head for an old hat. , 2009, American journal of physiology. Endocrinology and metabolism.

[38]  D. Houle,et al.  Pancreatic islet-specific expression of an insulin-like growth factor-I transgene compensates islet cell growth in growth hormone receptor gene-deficient mice. , 2005, Endocrinology.

[39]  N. Lenard,et al.  Dietary methionine restriction enhances metabolic flexibility and increases uncoupled respiration in both fed and fasted states. , 2010, American journal of physiology. Regulatory, integrative and comparative physiology.

[40]  M. Hulver,et al.  The pivotal role of pyruvate dehydrogenase kinases in metabolic flexibility , 2014, Nutrition & Metabolism.

[41]  N. Curtin,et al.  Differential effects of the poly (ADP-ribose) polymerase (PARP) inhibitor NU1025 on topoisomerase I and II inhibitor cytotoxicity in L1210 cells in vitro , 2001, British Journal of Cancer.

[42]  David M. Wilson,et al.  A high-fat diet and NAD(+) activate Sirt1 to rescue premature aging in cockayne syndrome. , 2014, Cell metabolism.

[43]  J. Hoeijmakers,et al.  Extended longevity mechanisms in short-lived progeroid mice: Identification of a preservative stress response associated with successful aging , 2007, Mechanisms of Ageing and Development.

[44]  L. Brace,et al.  Lifespan extension by dietary intervention in a mouse model of Cockayne Syndrome uncouples early postnatal development from segmental progeria , 2013, Aging cell.