Your search keyword '"Matthew D. Hirschey"' showing total 117 results

1. In vivo metabolic imaging identifies lipid vulnerability in a preclinical model of Her2+/Neu breast cancer residual disease and recurrence

Author

Megan C. Madonna, Joy E. Duer, Brock J. McKinney, Enakshi D. Sunassee, Brian T. Crouch, Olga Ilkayeva, Matthew D. Hirschey, James V. Alvarez, and Nirmala Ramanujam

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Recurrent cancer cells that evade therapy is a leading cause of death in breast cancer patients. This risk is high for women showing an overexpression of human epidermal growth factor receptor 2 (Her2). Cells that persist can rely on different substrates for energy production relative to their primary tumor counterpart. Here, we characterize metabolic reprogramming related to tumor dormancy and recurrence in a doxycycline-induced Her2+/Neu model of breast cancer with varying times to recurrence using longitudinal fluorescence microscopy. Glucose uptake (2-NBDG) and mitochondrial membrane potential (TMRE) imaging metabolically phenotype mammary tumors as they transition to regression, dormancy, and recurrence. “Fast-recurrence” tumors (time to recurrence ~55 days), transition from glycolysis to mitochondrial metabolism during regression and this persists upon recurrence. “Slow-recurrence” tumors (time to recurrence ~100 days) rely on both glycolysis and mitochondrial metabolism during recurrence. The increase in mitochondrial activity in fast-recurrence tumors is attributed to a switch from glucose to fatty acids as the primary energy source for mitochondrial metabolism. Consequently, when fast-recurrence tumors receive treatment with a fatty acid inhibitor, Etomoxir, tumors report an increase in glucose uptake and lipid synthesis during regression. Treatment with Etomoxir ultimately prolongs survival. We show that metabolic reprogramming reports on tumor recurrence characteristics, particularly at time points that are essential for actionable targets. The temporal characteristics of metabolic reprogramming will be critical in determining the use of an appropriate timing for potential therapies; namely, the notion that metabolic-targeted inhibition during regression reports long-term therapeutic benefit.

Published

2022

2. Statin therapy inhibits fatty acid synthase via dynamic protein modifications

Author

Alec G. Trub, Gregory R. Wagner, Kristin A. Anderson, Scott B. Crown, Guo-Fang Zhang, J. Will Thompson, Olga R. Ilkayeva, Robert D. Stevens, Paul A. Grimsrud, Rhushikesh A. Kulkarni, Donald S. Backos, Jordan L. Meier, and Matthew D. Hirschey

Subjects

Science

Abstract

Statin therapy is associated with numerous cellular effects. Here, the authors show that statin treatment increases post-translational modifications on fatty acid synthase in the active site, revealing communication between the cholesterol and lipid biosynthetic pathways.

Published

2022

3. Early-life mitochondrial DNA damage results in lifelong deficits in energy production mediated by redox signaling in Caenorhabditis elegans

Author

Kathleen A. Hershberger, John P. Rooney, Elena A. Turner, Lauren J. Donoghue, Rakesh Bodhicharla, Laura L. Maurer, Ian T. Ryde, Jina J. Kim, Rashmi Joglekar, Jonathan D. Hibshman, Latasha L. Smith, Dhaval P. Bhatt, Olga R. Ilkayeva, Matthew D. Hirschey, and Joel N. Meyer

Subjects

Mitochondrial DNA damage, Bioenergetics, Redox signaling, Mitochondrial function, Environmental toxicants, Developmental exposures, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

The consequences of damage to the mitochondrial genome (mtDNA) are poorly understood, although mtDNA is more susceptible to damage resulting from some genotoxicants than nuclear DNA (nucDNA), and many environmental toxicants target the mitochondria. Reports from the toxicological literature suggest that exposure to early-life mitochondrial damage could lead to deleterious consequences later in life (the “Developmental Origins of Health and Disease” paradigm), but reports from other fields often report beneficial (“mitohormetic”) responses to such damage. Here, we tested the effects of low (causing no change in lifespan) levels of ultraviolet C (UVC)-induced, irreparable mtDNA damage during early development in Caenorhabditis elegans. This exposure led to life-long reductions in mtDNA copy number and steady-state ATP levels, accompanied by increased oxygen consumption and altered metabolite profiles, suggesting inefficient mitochondrial function. Exposed nematodes were also developmentally delayed, reached smaller adult size, and were rendered more susceptible to subsequent exposure to chemical mitotoxicants. Metabolomic and genetic analysis of key signaling and metabolic pathways supported redox and mitochondrial stress-response signaling during early development as a mechanism for establishing these persistent alterations. Our results highlight the importance of early-life exposures to environmental pollutants, especially in the context of exposure to chemicals that target mitochondria.

Published

2021

4. Investigating RNA expression profiles altered by nicotinamide mononucleotide therapy in a chronic model of alcoholic liver disease

Author

Mohammed A. Assiri, Hadi R. Ali, John O. Marentette, Youngho Yun, Juan Liu, Matthew D. Hirschey, Laura M. Saba, Peter S. Harris, and Kristofer S. Fritz

Subjects

Alcoholic liver disease, RNA-seq, Liver, NMN, ATF3, ERK1/2, Medicine, Genetics, QH426-470

Abstract

Abstract Background Chronic alcohol consumption is a significant cause of liver disease worldwide. Several biochemical mechanisms have been linked to the initiation and progression of alcoholic liver disease (ALD) such as oxidative stress, inflammation, and metabolic dysregulation, including the disruption of NAD+/NADH. Indeed, an ethanol-mediated reduction in hepatic NAD+ levels is thought to be one factor underlying ethanol-induced steatosis, oxidative stress, steatohepatitis, insulin resistance, and inhibition of gluconeogenesis. Therefore, we applied a NAD+ boosting supplement to investigate alterations in the pathogenesis of early-stage ALD. Methods To examine the impact of NAD+ therapy on the early stages of ALD, we utilized nicotinamide mononucleotide (NMN) at 500 mg/kg intraperitoneal injection every other day, for the duration of a Lieber-DeCarli 6-week chronic ethanol model in mice. Numerous strategies were employed to characterize the effect of NMN therapy, including the integration of RNA-seq, immunoblotting, and metabolomics analysis. Results Our findings reveal that NMN therapy increased hepatic NAD+ levels, prevented an ethanol-induced increase in plasma ALT and AST, and changed the expression of 25% of the genes that were modulated by ethanol metabolism. These genes were associated with a number of pathways including the MAPK pathway. Interestingly, our analysis revealed that NMN treatment normalized Erk1/2 signaling and prevented an induction of Atf3 overexpression. Conclusions These findings reveal previously unreported mechanisms by which NMN supplementation alters hepatic gene expression and protein pathways to impact ethanol hepatotoxicity in an early-stage murine model of ALD. Overall, our data suggest further research is needed to fully characterize treatment paradigms and biochemical implications of NAD+-based interventions.

Published

2019

5. SIRT6 Promotes Hepatic Beta-Oxidation via Activation of PPARα

Author

Shoshana Naiman, Frank K. Huynh, Reuven Gil, Yair Glick, Yael Shahar, Noga Touitou, Liat Nahum, Matan Y. Avivi, Asael Roichman, Yariv Kanfi, Asaf A. Gertler, Tirza Doniger, Olga R. Ilkayeva, Ifat Abramovich, Orly Yaron, Batia Lerrer, Eyal Gottlieb, Robert A. Harris, Doron Gerber, Matthew D. Hirschey, and Haim Y. Cohen

Subjects

Biology (General), QH301-705.5

Abstract

Summary: The pro-longevity enzyme SIRT6 regulates various metabolic pathways. Gene expression analyses in SIRT6 heterozygotic mice identify significant decreases in PPARα signaling, known to regulate multiple metabolic pathways. SIRT6 binds PPARα and its response element within promoter regions and activates gene transcription. Sirt6+/− results in significantly reduced PPARα-induced β-oxidation and its metabolites and reduced alanine and lactate levels, while inducing pyruvate oxidation. Reciprocally, starved SIRT6 transgenic mice show increased pyruvate, acetylcarnitine, and glycerol levels and significantly induce β-oxidation genes in a PPARα-dependent manner. Furthermore, SIRT6 mediates PPARα inhibition of SREBP-dependent cholesterol and triglyceride synthesis. Mechanistically, SIRT6 binds PPARα coactivator NCOA2 and decreases liver NCOA2 K780 acetylation, which stimulates its activation of PPARα in a SIRT6-dependent manner. These coordinated SIRT6 activities lead to regulation of whole-body respiratory exchange ratio and liver fat content, revealing the interactions whereby SIRT6 synchronizes various metabolic pathways, and suggest a mechanism by which SIRT6 maintains healthy liver. : How the pro-longevity enzyme SIRT6 coordinates between various metabolic pathways is still obscure. Here, Naiman et al. show that SIRT6 activates PPARα to promote fatty acid beta oxidation and inhibit pyruvate oxidation during fasting. This ultimately decides the energy source under nutrient-limited conditions, promoting fat usage over other energy sources. Keywords: SIRT6, PPARα, beta-oxidation, liver, deacetylase, fasting

Published

2019

6. Lipids Reprogram Metabolism to Become a Major Carbon Source for Histone Acetylation

Author

Eoin McDonnell, Scott B. Crown, Douglas B. Fox, Betül Kitir, Olga R. Ilkayeva, Christian A. Olsen, Paul A. Grimsrud, and Matthew D. Hirschey

Subjects

histone, acetylation, epigenetics, metabolism, fatty acid, lipids, gene expression, proteomics, metabolomics, Biology (General), QH301-705.5

Abstract

Cells integrate nutrient sensing and metabolism to coordinate proper cellular responses to a particular nutrient source. For example, glucose drives a gene expression program characterized by activating genes involved in its metabolism, in part by increasing glucose-derived histone acetylation. Here, we find that lipid-derived acetyl-CoA is a major source of carbon for histone acetylation. Using 13C-carbon tracing combined with acetyl-proteomics, we show that up to 90% of acetylation on certain histone lysines can be derived from fatty acid carbon, even in the presence of excess glucose. By repressing both glucose and glutamine metabolism, fatty acid oxidation reprograms cellular metabolism, leading to increased lipid-derived acetyl-CoA. Gene expression profiling of octanoate-treated hepatocytes shows a pattern of upregulated lipid metabolic genes, demonstrating a specific transcriptional response to lipid. These studies expand the landscape of nutrient sensing and uncover how lipids and metabolism are integrated by epigenetic events that control gene expression.

Published

2016

7. Remodeling of the Acetylproteome by SIRT3 Manipulation Fails to Affect Insulin Secretion or β Cell Metabolism in the Absence of Overnutrition

Author

Brett S. Peterson, Jonathan E. Campbell, Olga Ilkayeva, Paul A. Grimsrud, Matthew D. Hirschey, and Christopher B. Newgard

Subjects

Biology (General), QH301-705.5

Abstract

Summary: SIRT3 is a nicotinamide adenine dinucleotide (NAD+)-dependent mitochondrial protein deacetylase purported to influence metabolism through post-translational modification of metabolic enzymes. Fuel-stimulated insulin secretion, which involves mitochondrial metabolism, could be susceptible to SIRT3-mediated effects. We used CRISPR/Cas9 technology to manipulate SIRT3 expression in β cells, resulting in widespread SIRT3-dependent changes in acetylation of key metabolic enzymes but no appreciable changes in glucose- or pyruvate-stimulated insulin secretion or metabolomic profile during glucose stimulation. Moreover, these broad changes in the SIRT3-targeted acetylproteome did not affect responses to nutritional or ER stress. We also studied mice with global SIRT3 knockout fed either standard chow (STD) or high-fat and high-sucrose (HFHS) diets. Only when chronically fed HFHS diet do SIRT3 KO animals exhibit a modest reduction in insulin secretion. We conclude that broad changes in mitochondrial protein acetylation in response to manipulation of SIRT3 are not sufficient to cause changes in islet function or metabolism. : Peterson et al. report that ablation of SIRT3 in 832/13 β cells dramatically alters the mitochondrial acetylproteome but does not affect insulin secretion, metabolomic profile, or β cell survival. Moreover, SIRT3 knockout causes a modest reduction in insulin secretion in mice fed a high-fat and high-sucrose but not a standard chow diet. Keywords: acetylation, metabolism, insulin secretion, pancreatic islets, mitochondria, post-translational modifications, diabetes

Published

2018

8. Acyl-CoA thioesterase-2 facilitates mitochondrial fatty acid oxidation in the liver[S]

Author

Cynthia Moffat, Lavesh Bhatia, Teresa Nguyen, Peter Lynch, Miao Wang, Dongning Wang, Olga R. Ilkayeva, Xianlin Han, Matthew D. Hirschey, Steven M. Claypool, and Erin L. Seifert

Subjects

β-oxidation, mitochondria, mitochondrial thioesterase, mitochondrial proton leak, cardiolipin, mouse, Biochemistry, QD415-436

Abstract

Acyl-CoA thioesterase (Acot)2 localizes to the mitochondrial matrix and hydrolyses long-chain fatty acyl-CoA into free FA and CoASH. Acot2 is expressed in highly oxi­dative tissues and is poised to modulate mitochondrial FA oxidation (FAO), yet its biological role is unknown. Using a model of adenoviral Acot2 overexpression in mouse liver (Ad-Acot2), we show that Acot2 increases the utilization of FA substrate during the daytime in ad libitum-fed mice, but the nighttime switch to carbohydrate oxidation is similar to control mice. In further support of elevated FAO in Acot2 liver, daytime serum ketones were higher in Ad-Acot2 mice, and overnight fasting led to minimal hepatic steatosis as compared with control mice. In liver mitochondria from Ad-Acot2 mice, phosphorylating O2 consumption was higher with lipid substrate, but not with nonlipid substrate. This increase depended on whether FA could be activated on the outer mitochondrial membrane, suggesting that the FA released by Acot2 could be effluxed from mitochondria then taken back up again for oxidation. This circuit would prevent the build-up of inhibitory long-chain fatty acyl-CoA esters. Altogether, our findings indicate that Acot2 can enhance FAO, possibly by mitigating the accumulation of FAO intermediates within the mitochondrial matrix.

Published

2014

9. NRF2 activation promotes the recurrence of dormant tumour cells through regulation of redox and nucleotide metabolism

Author

Jason W. Locasale, Laura C. Noteware, Brock McKinney, Ryan Lupo, Rachel Newcomb, James V. Alvarez, Douglas B. Fox, Matthew D. Hirschey, Juan Liu, and Nina Marie G. Garcia

Subjects

Transcription, Genetic, NF-E2-Related Factor 2, Receptor, ErbB-2, Endocrinology, Diabetes and Metabolism, Down-Regulation, Breast Neoplasms, Biology, medicine.disease_cause, digestive system, environment and public health, Article, NRF2, Mice, Breast cancer, Her2, Downregulation and upregulation, Physiology (medical), Cell Line, Tumor, Internal Medicine, medicine, Animals, Homeostasis, Humans, Transcription factor, Tumor metabolism, Cell Death, Glutaminase, Breast cancer recurrence, Nucleotides, Cancer, ROS, Cell Biology, respiratory system, Residual disease, medicine.disease, In vitro, Cancer research, Dormancy, Female, Neoplasm Recurrence, Local, Reactive Oxygen Species, Oxidation-Reduction, Oxidative stress, Signal Transduction

Abstract

The survival and recurrence of dormant tumour cells following therapy is a leading cause of death in cancer patients. The metabolic properties of these cells are likely distinct from those of rapidly growing tumours. Here we show that Her2 down-regulation in breast cancer cells promotes changes in cellular metabolism, culminating in oxidative stress and compensatory upregulation of the antioxidant transcription factor, NRF2. NRF2 is activated during dormancy and in recurrent tumours in animal models and breast cancer patients with poor prognosis. Constitutive activation of NRF2 accelerates recurrence, while suppression of NRF2 impairs it. In recurrent tumours, NRF2 signalling induces a transcriptional metabolic reprogramming to re-establish redox homeostasis and upregulate de novo nucleotide synthesis. The NRF2-driven metabolic state renders recurrent tumour cells sensitive to glutaminase inhibition, which prevents reactivation of dormant tumour cells in vitro, suggesting that NRF2-high dormant and recurrent tumours may be targeted. These data provide evidence that NRF2-driven metabolic reprogramming promotes the recurrence of dormant breast cancer.

Published

2020

10. In vivo metabolic imaging identifies lipid vulnerability in a preclinical model of Her2+/Neu breast cancer residual disease and recurrence

Author

Megan C. Madonna, Joy E. Duer, Brock J. McKinney, Enakshi D. Sunassee, Brian T. Crouch, Olga Ilkayeva, Matthew D. Hirschey, James V. Alvarez, and Nirmala Ramanujam

Subjects

Oncology, Pharmacology (medical), Radiology, Nuclear Medicine and imaging

Abstract

Recurrent cancer cells that evade therapy is a leading cause of death in breast cancer patients. This risk is high for women showing an overexpression of human epidermal growth factor receptor 2 (Her2). Cells that persist can rely on different substrates for energy production relative to their primary tumor counterpart. Here, we characterize metabolic reprogramming related to tumor dormancy and recurrence in a doxycycline-induced Her2+/Neu model of breast cancer with varying times to recurrence using longitudinal fluorescence microscopy. Glucose uptake (2-NBDG) and mitochondrial membrane potential (TMRE) imaging metabolically phenotype mammary tumors as they transition to regression, dormancy, and recurrence. “Fast-recurrence” tumors (time to recurrence ~55 days), transition from glycolysis to mitochondrial metabolism during regression and this persists upon recurrence. “Slow-recurrence” tumors (time to recurrence ~100 days) rely on both glycolysis and mitochondrial metabolism during recurrence. The increase in mitochondrial activity in fast-recurrence tumors is attributed to a switch from glucose to fatty acids as the primary energy source for mitochondrial metabolism. Consequently, when fast-recurrence tumors receive treatment with a fatty acid inhibitor, Etomoxir, tumors report an increase in glucose uptake and lipid synthesis during regression. Treatment with Etomoxir ultimately prolongs survival. We show that metabolic reprogramming reports on tumor recurrence characteristics, particularly at time points that are essential for actionable targets. The temporal characteristics of metabolic reprogramming will be critical in determining the use of an appropriate timing for potential therapies; namely, the notion that metabolic-targeted inhibition during regression reports long-term therapeutic benefit.

Published

2021

11. NAD metabolism modulates inflammation and mitochondria function in diabetic kidney disease

Author

Komuraiah Myakala, Xiaoxin X Wang, Nataliia V. Shults, Bryce A. Jones, Xiaoping Yang, Avi Z Rosenberg, Brandon Ginley, Pinaki Sarder, Leonid Brodsky, Yura Jang, Chan Hyun Na, Yue Qi, Xu Zhang, Udayan Guha, Ci Wu, Shivani Bansal, Junfeng Ma, Amrita Cheema, Chris Albanese, Matthew D Hirschey, Teruhiko Yoshida, Jeffrey B. Kopp, Julia Panov, and Moshe Levi

Abstract

Diabetes mellitus is the leading cause of cardiovascular and renal disease in the United States. In spite of the beneficial interventions available for patients with diabetes, there remains a need for additional therapeutic targets and therapies in diabetic kidney disease (DKD). Inflammation and oxidative stress are increasingly recognized as important causes of renal diseases. Inflammation is closely associated with mitochondrial damage. The molecular connection between inflammation and mitochondrial metabolism remains to be elucidated. Recently, nicotinamide adenine nucleotide (NAD+) metabolism has been found to regulate immune function and inflammation. In the present studies we tested the hypothesis that enhancing NAD metabolism could prevent inflammation in and progression of DKD. We found that treatment ofdb/dbmice with type 2 diabetes with nicotinamide riboside (NR) prevented several manifestations of kidney dysfunction (i.e., albuminuria, increased urinary kidney injury marker-1 (KIM1) excretion and pathologic changes). These effects were associated with decreased inflammation, at least in part via inhibiting the activation of the cyclic GMP-AMP synthase-stimulator of interferon genes (cGAS-STING) signaling pathway. An antagonist of the serum stimulator of interferon genes (STING) and whole-body STING deletion in diabetic mice showed similar renoprotection. Further analysis found that NR increased SIRT3 activity and improved mitochondrial function, which led to decreased mitochondrial DNA damage, a trigger for mitochondrial DNA leakage which activates the cGAS-STING pathway. Overall, these data show that NR supplementation boosted NAD metabolism to augment mitochondrial function, reducing inflammation and thereby preventing progression of diabetic kidney disease.

Published

2021

12. Early-life mitochondrial DNA damage results in lifelong deficits in energy production mediated by redox signaling in Caenorhabditis elegans

Author

Ian T. Ryde, Latasha L. Smith, Olga Ilkayeva, John P. Rooney, Kathleen A. Hershberger, Jonathan D. Hibshman, Laura L. Maurer, Lauren J. Donoghue, Matthew D. Hirschey, Joel N. Meyer, Elena A. Turner, Jina J. Kim, Dhaval P. Bhatt, Rakesh Bodhicharla, and Rashmi Joglekar

Subjects

0301 basic medicine, Mitochondrial DNA, Medicine (General), Redox signaling, Bioenergetics, QH301-705.5, Clinical Biochemistry, Mitochondrial DNA damage, Context (language use), Mitochondrion, Biochemistry, DNA, Mitochondrial, 03 medical and health sciences, Environmental toxicants, 0302 clinical medicine, R5-920, Animals, Biology (General), Caenorhabditis elegans, chemistry.chemical_classification, Reactive oxygen species, biology, Organic Chemistry, biology.organism_classification, Nuclear DNA, Cell biology, Mitochondria, Metabolic pathway, 030104 developmental biology, chemistry, Developmental exposures, Mitochondrial function, Oxidation-Reduction, 030217 neurology & neurosurgery, Research Paper, DNA Damage

Abstract

The consequences of damage to the mitochondrial genome (mtDNA) are poorly understood, although mtDNA is more susceptible to damage resulting from some genotoxicants than nuclear DNA (nucDNA), and many environmental toxicants target the mitochondria. Reports from the toxicological literature suggest that exposure to early-life mitochondrial damage could lead to deleterious consequences later in life (the “Developmental Origins of Health and Disease” paradigm), but reports from other fields often report beneficial (“mitohormetic”) responses to such damage. Here, we tested the effects of low (causing no change in lifespan) levels of ultraviolet C (UVC)-induced, irreparable mtDNA damage during early development in Caenorhabditis elegans. This exposure led to life-long reductions in mtDNA copy number and steady-state ATP levels, accompanied by increased oxygen consumption and altered metabolite profiles, suggesting inefficient mitochondrial function. Exposed nematodes were also developmentally delayed, reached smaller adult size, and were rendered more susceptible to subsequent exposure to chemical mitotoxicants. Metabolomic and genetic analysis of key signaling and metabolic pathways supported redox and mitochondrial stress-response signaling during early development as a mechanism for establishing these persistent alterations. Our results highlight the importance of early-life exposures to environmental pollutants, especially in the context of exposure to chemicals that target mitochondria., Graphical abstract Image 1, Highlights • Early life mtDNA damage led to lifelong deficits in mitochondrial function. • C. elegans developed slowly and were sensitive to chemical exposures as adults. • Redox signaling is a mechanism that establishes these persistent alterations. • Data are consistent with the Developmental Origins of Health and Disease model.

Published

2021

13. SIRT6 Promotes Hepatic Beta-Oxidation via Activation of PPARα

Author

Ifat Abramovich, Doron Gerber, Matthew D. Hirschey, Olga Ilkayeva, Yael Shahar, Asaf A. Gertler, Asael Roichman, Yair Glick, Noga Touitou, Haim Y. Cohen, Orly Yaron, Matan Y. Avivi, Liat Nahum, Robert A. Harris, Frank K. Huynh, Reuven Gil, Yariv Kanfi, Eyal Gottlieb, Shoshana Naiman, Batia Lerrer, and Tirza Doniger

Subjects

0301 basic medicine, Pyruvate decarboxylation, SIRT6, Male, Response element, Blotting, Western, Mice, Transgenic, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Mice, Nuclear Receptor Coactivator 2, 0302 clinical medicine, Gene expression, Coactivator, medicine, Animals, Humans, Immunoprecipitation, Sirtuins, PPAR alpha, Acetylcarnitine, Beta oxidation, lcsh:QH301-705.5, Cells, Cultured, Chemistry, Acetylation, Cell biology, Metabolic pathway, 030104 developmental biology, HEK293 Cells, Liver, lcsh:Biology (General), Oxidation-Reduction, 030217 neurology & neurosurgery, medicine.drug

Abstract

Summary: The pro-longevity enzyme SIRT6 regulates various metabolic pathways. Gene expression analyses in SIRT6 heterozygotic mice identify significant decreases in PPARα signaling, known to regulate multiple metabolic pathways. SIRT6 binds PPARα and its response element within promoter regions and activates gene transcription. Sirt6+/− results in significantly reduced PPARα-induced β-oxidation and its metabolites and reduced alanine and lactate levels, while inducing pyruvate oxidation. Reciprocally, starved SIRT6 transgenic mice show increased pyruvate, acetylcarnitine, and glycerol levels and significantly induce β-oxidation genes in a PPARα-dependent manner. Furthermore, SIRT6 mediates PPARα inhibition of SREBP-dependent cholesterol and triglyceride synthesis. Mechanistically, SIRT6 binds PPARα coactivator NCOA2 and decreases liver NCOA2 K780 acetylation, which stimulates its activation of PPARα in a SIRT6-dependent manner. These coordinated SIRT6 activities lead to regulation of whole-body respiratory exchange ratio and liver fat content, revealing the interactions whereby SIRT6 synchronizes various metabolic pathways, and suggest a mechanism by which SIRT6 maintains healthy liver. : How the pro-longevity enzyme SIRT6 coordinates between various metabolic pathways is still obscure. Here, Naiman et al. show that SIRT6 activates PPARα to promote fatty acid beta oxidation and inhibit pyruvate oxidation during fasting. This ultimately decides the energy source under nutrient-limited conditions, promoting fat usage over other energy sources. Keywords: SIRT6, PPARα, beta-oxidation, liver, deacetylase, fasting

Published

2019

14. Quantifying Competition among Mitochondrial Protein Acylation Events Induced by Ethanol Metabolism

Author

Frank K. Huynh, Kristofer S. Fritz, Colin T. Shearn, Nichole Reisdorph, Peter Harris, David J. Orlicky, Cole R. Michel, Richard Reisdorph, Mohammed A. Assiri, Laura Saba, Hadi R. Ali, Matthew D. Hirschey, Youngho Yun, and John O. Marentette

Subjects

Male, 0301 basic medicine, SIRT5, Proteome, SIRT3, Acylation, Mitochondrion, Biochemistry, Article, Mice, 03 medical and health sciences, Succinylation, Protein acylation, Sirtuin 3, Animals, Sirtuins, Ethanol metabolism, Liver Diseases, Alcoholic, Mice, Knockout, Ethanol, 030102 biochemistry & molecular biology, biology, Chemistry, General Chemistry, Mitochondria, 030104 developmental biology, Sirtuin, biology.protein, Metabolic Networks and Pathways

Abstract

Mitochondrial dysfunction is one of many key factors in the etiology of alcoholic liver disease (ALD). Lysine acetylation is known to regulate numerous mitochondrial metabolic pathways, and recent reports demonstrate that alcohol-induced protein acylation negatively impacts these processes. To identify regulatory mechanisms attributed to alcohol-induced protein post-translational modifications, we employed a model of alcohol consumption within the context of wild type (WT), sirtuin 3 knockout (SIRT3 KO), and sirtuin 5 knockout (SIRT5 KO) mice to manipulate hepatic mitochondrial protein acylation. Mitochondrial fractions were examined by label-free quantitative HPLC-MS/MS to reveal competition between lysine acetylation and succinylation. A class of proteins defined as "differential acyl switching proteins" demonstrate select sensitivity to alcohol-induced protein acylation. A number of these proteins reveal saturated lysine-site occupancy, suggesting a significant level of differential stoichiometry in the setting of ethanol consumption. We hypothesize that ethanol downregulates numerous mitochondrial metabolic pathways through differential acyl switching proteins. Data are available via ProteomeXchange with identifier PXD012089.

Published

2019

15. Statin therapy inhibits fatty acid synthase via dynamic protein modifications

Author

Matthew D. Hirschey, Thompson Jw, Scott B. Crown, Paul A. Grimsrud, Robert Stevens, Gregory R. Wagner, Trub A, Donald S. Backos, Olga Ilkayeva, and Zhang G

Subjects

Fatty acid synthase, Text mining, biology, business.industry, Chemistry, biology.protein, lipids (amino acids, peptides, and proteins), Statin therapy, Pharmacology, business

Abstract

Statins are a class of drug widely prescribed for the prevention of cardiovascular disease, with pleiotropic cellular effects. Statins inhibit HMG-CoA reductase (HMGCR), which converts the reactive HMG-CoA into mevalonate. Recent discoveries revealed HMG-CoA is a highly reactive metabolite that can non-enzymatically modify proteins and impact their activity. Therefore, we predicted that inhibition of HMGCR by statins would increase HMG-CoA levels and subsequent protein modifications. We found a strong increase in HMG-CoA levels, but only a single protein being modified. Fatty acid synthase (FAS) was modified on active site residues and, importantly, the modification is located on non-lysine residues. The dynamic modifications occur only on a subpool of FAS that is located near HMGCR and alters cellular signaling around the ER and Golgi. These results uncover communication between cholesterol and lipid biosynthesis by the substrate of one pathway inhibiting another in a rapid and reversible manner.

Published

2021

16. Sirtuin 5 Is Regulated by the SCFCyclin F Ubiquitin Ligase and Is Involved in Cell Cycle Control

Author

Christine A. Mills, Daniel J. Burke, Xianxi Wang, Dhaval P. Bhatt, Jeanette Gowen Cook, Matthew D. Hirschey, Debojyoti Lahiri, Jacob Peter Matson, Michael J. Emanuele, and Paul A. Grimsrud

Subjects

0303 health sciences, biology, Cell Biology, Cell cycle, Ubiquitin ligase, Cell biology, 03 medical and health sciences, 0302 clinical medicine, SCF complex, Cyclin-dependent kinase, Skp1, biology.protein, CUL1, Cell division control protein 4, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology, Cyclin

Abstract

The ubiquitin-proteasome system is essential for cell cycle progression. Cyclin F is a cell cycle-regulated substrate adapter F-box protein for the Skp1, CUL1, and F-box protein (SCF) family of E3 ubiquitin ligases. Despite its importance in cell cycle progression, identifying cyclin F-bound SCF complex (SCFCyclin F) substrates has remained challenging. Since cyclin F overexpression rescues a yeast mutant in the cdc4 gene, we considered the possibility that other genes that genetically modify cdc4 mutant lethality could also encode cyclin F substrates. We identified the mitochondrial and cytosolic deacylating enzyme sirtuin 5 (SIRT5) as a novel cyclin F substrate. SIRT5 has been implicated in metabolic processes, but its connection to the cell cycle is not known. We show that cyclin F interacts with and controls the ubiquitination, abundance, and stability of SIRT5. We show SIRT5 knockout results in a diminished G1 population and a subsequent increase in both S and G2/M. Global proteomic analyses reveal cyclin-dependent kinase (CDK) signaling changes congruent with the cell cycle changes in SIRT5 knockout cells. Together, these data demonstrate that SIRT5 is regulated by cyclin F and suggest a connection between SIRT5, cell cycle regulation, and metabolism.

Published

2021

17. Deglutarylation of glutaryl-CoA dehydrogenase by deacylating enzyme SIRT5 promotes lysine oxidation in mice

Author

Dhaval P. Bhatt, C. Allie Mills, Kristin A. Anderson, Bárbara J. Henriques, Tânia G. Lucas, Sara Francisco, Juan Liu, Olga R. Ilkayeva, Alexander E. Adams, Shreyas R. Kulkarni, Donald S. Backos, Michael B. Major, Paul A. Grimsrud, Cláudio M. Gomes, and Matthew D. Hirschey

Subjects

Mice, Glutaryl-CoA Dehydrogenase, Lysine, Tryptophan, Animals, Sirtuins, Cell Biology, Oxidation-Reduction, Protein Processing, Post-Translational, Molecular Biology, Biochemistry

Abstract

A wide range of protein acyl modifications has been identified on enzymes across various metabolic processes; however, the impact of these modifications remains poorly understood. Protein glutarylation is a recently identified modification that can be nonenzymatically driven by glutaryl-CoA. In mammalian systems, this unique metabolite is only produced in the lysine and tryptophan oxidative pathways. To better understand the biology of protein glutarylation, we studied the relationship between enzymes within the lysine/tryptophan catabolic pathways, protein glutarylation, and regulation by the deglutarylating enzyme sirtuin 5 (SIRT5). Here, we identify glutarylation on the lysine oxidation pathway enzyme glutaryl-CoA dehydrogenase (GCDH) and show increased GCDH glutarylation when glutaryl-CoA production is stimulated by lysine catabolism. Our data reveal that glutarylation of GCDH impacts its function, ultimately decreasing lysine oxidation. We also demonstrate the ability of SIRT5 to deglutarylate GCDH, restoring its enzymatic activity. Finally, metabolomic and bioinformatic analyses indicate an expanded role for SIRT5 in regulating amino acid metabolism. Together, these data support a feedback loop model within the lysine/tryptophan oxidation pathway in which glutaryl-CoA is produced, in turn inhibiting GCDH function via glutaryl modification of GCDH lysine residues and can be relieved by SIRT5 deacylation activity.

Published

2022

18. Early-life mitochondrial DNA damage results in lifelong deficits in energy production mediated by redox signaling inCaenorhabditis elegans

Author

Jina J. Kim, Ian T. Ryde, Latasha L. Smith, Elena A. Turner, Jonathan D. Hibshman, Matthew D. Hirschey, Joel N. Meyer, Laura L. Maurer, Kathleen A. Hershberger, Dhaval P. Bhatt, Olga Ilkayeva, John P. Rooney, Rashmi Joglekar, and Lauren J. Donoghue

Subjects

chemistry.chemical_classification, Reactive oxygen species, Metabolic pathway, Mitochondrial DNA, chemistry, biology, Mechanism (biology), Context (language use), Mitochondrion, biology.organism_classification, Caenorhabditis elegans, Nuclear DNA, Cell biology

Abstract

The consequences of damage to the mitochondrial genome (mtDNA) are poorly understood, although mtDNA is more susceptible to damage than nuclear DNA (nucDNA), and many environmental toxicants target the mitochondria. Reports from the toxicological literature suggest that exposure to early-life mitochondrial damage could lead to deleterious consequences later in life (the “Developmental Origins of Health and Disease” paradigm) but reports from other fields often report beneficial (“mitohormetic”) responses to such damage. Here, we test the effects of low (causing no change in lifespan) levels of ultraviolet C (UVC)-induced, irreparable mtDNA damage during early development inCaenorhabditis elegans. This exposure led to life-long reductions in mtDNA copy number and steady-state ATP levels, accompanied by increased oxygen consumption and altered metabolite profiles, suggesting inefficient mitochondrial function. Exposed nematodes were also developmentally delayed, reached smaller adult size, and were rendered more susceptible to subsequent exposure to chemical mitotoxicants. Metabolomic and genetic analysis of key signaling and metabolic pathways supported redox signaling during early development as a mechanism for establishing these persistent alterations. Our results highlight the importance of early-life exposures to environmental pollutants, especially in the context of exposure to chemicals that target mitochondria.

Published

2020

19. In Vivo Optical Metabolic Imaging of Long-Chain Fatty Acid Uptake in Orthotopic Models of Triple-Negative Breast Cancer

Author

Andrei Goga, Joy Duer, Matthew D. Hirschey, Joyce V. Lee, Nirmala Ramanujam, Megan C. Madonna, Baris Avsaroglu, Brian T. Crouch, Riley Deutsch, Caigang Zhu, Roujia Wang, and Jeremy Williams

Subjects

0301 basic medicine, Cancer Research, lcsh:RC254-282, fluorescence microscopy, Article, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, In vivo, oncogene addition, medicine, Triple-negative breast cancer, chemistry.chemical_classification, Mammary tumor, Oncogene, breast murine tumor lines, In vitro toxicology, Fatty acid, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, medicine.disease, Transport inhibitor, fatty acid uptake, 030104 developmental biology, Oncology, chemistry, 030220 oncology & carcinogenesis, metastatic potential, Cancer research, metabolism

Abstract

Targeting a tumor&rsquo, s metabolic dependencies is a clinically actionable therapeutic approach, however, identifying subtypes of tumors likely to respond remains difficult. The use of lipids as a nutrient source is of particular importance, especially in breast cancer. Imaging techniques offer the opportunity to quantify nutrient use in preclinical tumor models to guide development of new drugs that restrict uptake or utilization of these nutrients. We describe a fast and dynamic approach to image fatty acid uptake in vivo and demonstrate its relevance to study both tumor metabolic reprogramming directly, as well as the effectiveness of drugs targeting lipid metabolism. Specifically, we developed a quantitative optical approach to spatially and longitudinally map the kinetics of long-chain fatty acid uptake in in vivo murine models of breast cancer using a fluorescently labeled palmitate molecule, Bodipy FL c16. We chose intra-vital microscopy of mammary tumor windows to validate our approach in two orthotopic breast cancer models: a MYC-overexpressing, transgenic, triple-negative breast cancer (TNBC) model and a murine model of the 4T1 family. Following injection, Bodipy FL c16 fluorescence increased and reached its maximum after approximately 30 min, with the signal remaining stable during the 30&ndash, 80 min post-injection period. We used the fluorescence at 60 min (Bodipy60), the mid-point in the plateau region, as a summary parameter to quantify Bodipy FL c16 fluorescence in subsequent experiments. Using our imaging platform, we observed a two- to four-fold decrease in fatty acid uptake in response to the downregulation of the MYC oncogene, consistent with findings from in vitro metabolic assays. In contrast, our imaging studies report an increase in fatty acid uptake with tumor aggressiveness (6NR, 4T07, and 4T1), and uptake was significantly decreased after treatment with a fatty acid transport inhibitor, perphenazine, in both normal mammary pads and in the most aggressive 4T1 tumor model. Our approach fills an important gap between in vitro assays providing rich metabolic information at static time points and imaging approaches visualizing metabolism in whole organs at a reduced resolution.

Published

2020

20. Discovering the landscape of protein modifications

Author

E. Keith Keenan, Matthew D. Hirschey, and Derek K. Zachman

Subjects

Proteomics, 0303 health sciences, Protein adducts, Protein Conformation, Computational Biology, Proteins, Cell Biology, Computational biology, Biology, Article, 03 medical and health sciences, Protein acylation, Structure-Activity Relationship, 0302 clinical medicine, Amino acid composition, Artificial Intelligence, Posttranslational modification, Animals, Humans, Databases, Protein, Molecular Biology, Protein Processing, Post-Translational, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Protein modifications modulate nearly every aspect of cell biology in organisms, ranging from Archaea to Eukaryotes. The earliest evidence of covalent protein modifications was found in the early 20th century by studying the amino acid composition of proteins by chemical hydrolysis. These discoveries challenged what defined a canonical amino acid. The advent and rapid adoption of mass-spectrometry-based proteomics in the latter part of the 20th century enabled a veritable explosion in the number of known protein modifications, with more than 500 discrete modifications counted today. Now, new computational tools in data science, machine learning, and artificial intelligence are poised to allow researchers to make significant progress in discovering new protein modifications and determining their function. In this review, we take an opportunity to revisit the historical discovery of key post-translational modifications, quantify the current landscape of covalent protein adducts, and assess the role that new computational tools will play in the future of this field.

Published

2020

21. β-Cell-specific ablation of sirtuin 4 does not affect nutrient-stimulated insulin secretion in mice

Author

Zhihong Lin, Aeowynn J Coakley, Christopher B. Newgard, Jonathan E. Campbell, Thi-Tina N. Nguyen, Brett S. Peterson, Matthew D. Hirschey, Kristin A. Anderson, Samuel B. Stephens, Fiara M S Llaguno, and Frank K. Huynh

Subjects

0301 basic medicine, medicine.medical_specialty, Physiology, Endocrinology, Diabetes and Metabolism, Affect (psychology), Mitochondrial Proteins, 03 medical and health sciences, Islets of Langerhans, Mice, 0302 clinical medicine, Leucine, Physiology (medical), Diabetes mellitus, Internal medicine, Insulin-Secreting Cells, Glucose Intolerance, Insulin Secretion, medicine, Animals, Sirtuins, Insulin secretion, Cell specific, Mice, Knockout, biology, Chemistry, Nutrients, medicine.disease, Mitochondria, 030104 developmental biology, Endocrinology, Glucose, Sirtuin, biology.protein, Beta cell, Insulin Resistance, Protein Processing, Post-Translational, 030217 neurology & neurosurgery, Research Article

Abstract

Sirtuins are a family of proteins that regulate biological processes such as cellular stress and aging by removing posttranslational modifications (PTMs). We recently identified several novel PTMs that can be removed by sirtuin 4 (SIRT4), which is found in mitochondria. We showed that mice with a global loss of SIRT4 [SIRT4-knockout (KO) mice] developed an increase in glucose- and leucine-stimulated insulin secretion, and this was followed by accelerated age-induced glucose intolerance and insulin resistance. Because whole body SIRT4-KO mice had alterations to nutrient-stimulated insulin secretion, we hypothesized that SIRT4 plays a direct role in regulating pancreatic β-cell function. Thus, we tested whether β-cell-specific ablation of SIRT4 would recapitulate the elevated insulin secretion seen in mice with a global loss of SIRT4. Tamoxifen-inducible β-cell-specific SIRT4-KO mice were generated, and their glucose tolerance and glucose- and leucine-stimulated insulin secretion were measured over time. These mice exhibited normal glucose- and leucine-stimulated insulin secretion and maintained normal glucose tolerance even as they aged. Furthermore, 832/13 β-cells with a CRISPR/Cas9n-mediated loss of SIRT4 did not show any alterations in nutrient-stimulated insulin secretion. Despite the fact that whole body SIRT4-KO mice demonstrated an age-induced increase in glucose- and leucine-stimulated insulin secretion, our current data indicate that the loss of SIRT4 specifically in pancreatic β-cells, both in vivo and in vitro, does not have a significant impact on nutrient-stimulated insulin secretion. These data suggest that SIRT4 controls nutrient-stimulated insulin secretion during aging by acting on tissues external to the β-cell, which warrants further study.

Published

2020

22. A cell-nonautonomous mechanism of yeast chronological aging regulated by caloric restriction and one-carbon metabolism

Author

Elisa Enriquez-Hesles, Margaret B. Wierman, Ryan D. Fine, Sean M. Santos, Daniel L. Smith, Nazif Maqani, James R. Bain, Agata Kalita, Matthew D. Hirschey, Matthew D. Sutcliffe, Jeffrey S. Smith, John L. Hartman, Kevin A. Janes, and Michael J. Muehlbauer

Subjects

0301 basic medicine, RT, retention time, Cell, QTL, quantitative trait locus, Biochemistry, cell-nonautonomous, chemistry.chemical_compound, AMP-activated protein kinase, chronological life span, media_common, chemistry.chemical_classification, Growth medium, biology, Cell Cycle, Longevity, TOR, target of rapamycin, Amino acid, Cell biology, medicine.anatomical_structure, CFUs, colony forming units, Metabolome, TCA, tricarboxylic acid cycle, Research Article, DNA Replication, CR, caloric restriction, media_common.quotation_subject, Saccharomyces cerevisiae, CRCM, CR conditioned media, serine, 03 medical and health sciences, SC, synthetic complete, medicine, NR, nonrestricted, GAAC, general amino acid control, Molecular Biology, CLS, chronological life span, Caloric Restriction, amino acids, 030102 biochemistry & molecular biology, aging, Cell Biology, biology.organism_classification, one-carbon metabolism, Yeast, Carbon, Culture Media, Citric acid cycle, AMPK, AMP-activated protein kinase, BCAA, branched chain amino acids, 030104 developmental biology, chemistry, biology.protein

Abstract

Caloric restriction (CR) improves health span and life span of organisms ranging from yeast to mammals. Understanding the mechanisms involved will uncover future interventions for aging-associated diseases. In budding yeast, Saccharomyces cerevisiae, CR is commonly defined by reduced glucose in the growth medium, which extends both replicative and chronological life span (CLS). We found that conditioned media collected from stationary-phase CR cultures extended CLS when supplemented into nonrestricted (NR) cultures, suggesting a potential cell-nonautonomous mechanism of CR-induced life span regulation. Chromatography and untargeted metabolomics of the conditioned media, as well as transcriptional responses associated with the longevity effect, pointed to specific amino acids enriched in the CR conditioned media (CRCM) as functional molecules, with L-serine being a particularly strong candidate. Indeed, supplementing L-serine into NR cultures extended CLS through a mechanism dependent on the one-carbon metabolism pathway, thus implicating this conserved and central metabolic hub in life span regulation.

Published

2020

23. Making data-driven hypotheses for gene functions by integrating dependency, expression, and literature data

Author

Matthew D. Hirschey

Subjects

Data sharing, Open science, ComputingMethodologies_PATTERNRECOGNITION, Dependency (UML), business.industry, Interface (Java), Computer programming, Human genome, Computational biology, Expression (computer science), business, Data-driven

Abstract

Identifying the key functions of human genes is a major biomedical research goal. While some genes are well-studied, most human genes we know little about. New tools in data science -- a combination of computer programming, math & statistics, and topical expertise -- combined with the rapid adoption of open science and data sharing allow scientists to access publicly available datasets and interrogate these data before performing any experiments. We present here a new research tool called data-driven hypothesis (DDH) for predicting pathways and functions for thousands of genes across the human genome. Importantly, this method integrates gene essentiality, gene expression, and literature mining to identify candidate molecular functions or pathways of known and unknown genes. Beyond single gene queries, DDH can uniquely handle queries of defined gene ontology pathways or custom gene lists containing multiple genes. The DDH project holds tremendous promise to generate hypotheses, data, and knowledge in order to provide a deep understanding of the dynamic properties of mammalian genes. We present this tool via an intuitive online interface, which will provide the scientific community a platform to query and prioritize experimental hypotheses to test in the lab.

Published

2020

24. A cell non-autonomous mechanism of yeast chronological aging regulated by caloric restriction and one-carbon metabolism

Author

Daniel L. Smith, Kevin A. Janes, Elisa Enriquez-Hesles, John L. Hartman, Sean M. Santos, Ryan D. Fine, Jeffrey S. Smith, Matthew D. Sutcliffe, James R. Bain, Nazif Maqani, Margaret B. Wierman, Agata Kalita, Michael J. Muehlbauer, and Matthew D. Hirschey

Subjects

chemistry.chemical_classification, Growth medium, biology, Mechanism (biology), media_common.quotation_subject, Saccharomyces cerevisiae, Cell, Longevity, Caloric theory, biology.organism_classification, Yeast, Cell biology, Amino acid, chemistry.chemical_compound, medicine.anatomical_structure, chemistry, medicine, media_common

Abstract

Caloric restriction (CR) improves healthspan and lifespan of organisms ranging from yeast to mammals. Understanding the mechanisms involved will uncover future interventions for aging associated diseases. In budding yeast,Saccharomyces cerevisiae, CR is commonly defined by reduced glucose in the growth medium, which extends both replicative and chronological lifespan (CLS). We found that conditioned media collected from stationary phase CR cultures extended CLS when supplemented into non-restricted (NR) cultures, suggesting a potential cell non-autonomous mechanism of CR-induced lifespan regulation. Chromatography and untargeted metabolomics of the conditioned media, as well as transcriptional responses associated with the longevity effect, pointed to specific amino acids enriched in the CR conditioned media (CRCM) as functional molecules, with L-serine being a particularly strong candidate. Indeed, supplementing L-serine into NR cultures extended CLS through a mechanism dependent on the one-carbon metabolism pathway, thus implicating this conserved and central metabolic hub in lifespan regulation.

Published

2020

25. Multiple metabolic changes mediate the response of Caenorhabditis elegans to the complex I inhibitor rotenone

Author

Dhaval P. Bhatt, Matthew D. Hirschey, Elena A. Turner, Anthony L. Luz, Joel N. Meyer, Claudia P. Gonzalez-Hunt, Olga Ilkayeva, and Ian T. Ryde

Subjects

0301 basic medicine, Bioenergetics, Glyoxylate cycle, Context (language use), Toxicology, Article, Animals, Genetically Modified, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Oxygen Consumption, Rotenone, Animals, Glycolysis, Caenorhabditis elegans, Beta oxidation, Electron Transport Complex I, biology, Dose-Response Relationship, Drug, Uncoupling Agents, Isocitrate lyase, biology.organism_classification, Cell biology, Mitochondria, 030104 developmental biology, chemistry, Energy Metabolism, 030217 neurology & neurosurgery

Abstract

Rotenone, a mitochondrial complex I inhibitor, has been widely used to study the effects of mitochondrial dysfunction on dopaminergic neurons in the context of Parkinson’s disease. Although the deleterious effects of rotenone are well documented, we found that young adult Caenorhabditis elegans showed resistance to 24- and 48-hour rotenone exposures. To better understand the response to rotenone in C. elegans, we evaluated mitochondrial bioenergetic parameters after 24- and 48-hour exposures to 1μM or 5 μM rotenone. Results suggested upregulation of mitochondrial complexes II and V following rotenone exposure, without major changes in oxygen consumption or steady-state ATP levels after rotenone treatment at the tested concentrations. We found evidence that the glyoxylate pathway (an alternate pathway not present in higher metazoans) was induced by rotenone exposure; gene expression measurements showed increases in mRNA levels for two complex II subunits and for isocitrate lyase, the key glyoxylate pathway enzyme. Targeted metabolomics analyses showed alterations in the levels of organic acids, amino acids, and acylcarnitines, consistent with the metabolic restructuring of cellular bioenergetics pathways including activation of complex II, the glyoxylate pathway, glycolysis, and fatty acid oxidation. This expanded understanding of how C. elegans responds metabolically to complex I inhibition via multiple bioenergetic adaptations, including the glyoxylate pathway, will be useful in interrogating the effects of mitochondrial and bioenergetic stressors and toxicants.

Published

2020

26. Deglutarylation of GCDH by SIRT5 controls lysine metabolism in mice

Author

Sara Martins Francisco, Paul A. Grimsrud, Tânia G. Lucas, Dhaval P. Bhatt, Matthew D. Hirschey, Olga Ilkayeva, Cláudio M. Gomes, Alexander E. Adams, C. Allie Mills, Kristin A. Anderson, Shreyas R. Kulkarni, Donald S. Backos, Juan Liu, and Bárbara J. Henriques

Subjects

chemistry.chemical_classification, SIRT5, biology, Catabolism, Metabolite, Lysine, Tryptophan, Oxidative phosphorylation, complex mixtures, chemistry.chemical_compound, Enzyme, chemistry, Biochemistry, Sirtuin, biology.protein

Abstract

A wide range of protein acyl modifications has been identified on enzymes across various metabolic processes; however, the impact of these modifications remains poorly understood. Protein glutarylation is a recently identified modification that can be non-enzymatically driven by glutaryl-CoA. In mammalian systems, this unique metabolite is only produced in the lysine and tryptophan oxidative pathways. To better understand the biology of protein glutarylation, we studied the relationship between enzymes within the lysine/tryptophan catabolic pathways, protein glutarylation, and regulation by the deglutarylating enzyme Sirtuin 5 (SIRT5). Here, we identify glutarylation on the lysine oxidation pathway enzyme glutaryl-CoA dehydrogenase (GCDH). We show increased GCDH glutarylation when glutaryl-CoA production is stimulated by lysine catabolism. Our data reveal glutarylation of GCDH impacts its function, ultimately decreasing lysine oxidation. We then demonstrate the ability of SIRT5 to deglutarylate GCDH, restoring its enzymatic activity. Finally, metabolomic and bioinformatic analyses indicate an expanded role for SIRT5 in regulating amino acid metabolism. Together, these data support a model whereby a feedback loop exists within the lysine/tryptophan oxidation pathway, in which glutaryl-CoA is produced, in turn inhibiting GCDH function via glutaryl modification of GCDH lysine residues, and can be relieved by SIRT5 deacylation activity.

Published

2020

27. Sirtuin 5 Is Regulated by the SCF

Author

Christine A, Mills, Xianxi, Wang, Dhaval P, Bhatt, Paul A, Grimsrud, Jacob Peter, Matson, Debojyoti, Lahiri, Daniel J, Burke, Jeanette Gowen, Cook, Matthew D, Hirschey, and Michael J, Emanuele

Subjects

SKP Cullin F-Box Protein Ligases, Saccharomyces cerevisiae Proteins, F-Box Proteins, Gene Expression Profiling, Ubiquitin-Protein Ligases, Cell Cycle, Ubiquitination, Cell Cycle Proteins, Saccharomyces cerevisiae, HEK293 Cells, Gene Expression Regulation, Fungal, Mutation, Humans, Sirtuins, Genes, Lethal, Protein Processing, Post-Translational, HeLa Cells, Signal Transduction, Research Article

Abstract

The ubiquitin-proteasome system is essential for cell cycle progression. Cyclin F is a cell cycle-regulated substrate adapter F-box protein for the Skp1, CUL1, and F-box protein (SCF) family of E3 ubiquitin ligases. Despite its importance in cell cycle progression, identifying cyclin F-bound SCF complex (SCF(Cyclin F)) substrates has remained challenging. Since cyclin F overexpression rescues a yeast mutant in the cdc4 gene, we considered the possibility that other genes that genetically modify cdc4 mutant lethality could also encode cyclin F substrates. We identified the mitochondrial and cytosolic deacylating enzyme sirtuin 5 (SIRT5) as a novel cyclin F substrate. SIRT5 has been implicated in metabolic processes, but its connection to the cell cycle is not known. We show that cyclin F interacts with and controls the ubiquitination, abundance, and stability of SIRT5. We show SIRT5 knockout results in a diminished G(1) population and a subsequent increase in both S and G(2)/M. Global proteomic analyses reveal cyclin-dependent kinase (CDK) signaling changes congruent with the cell cycle changes in SIRT5 knockout cells. Together, these data demonstrate that SIRT5 is regulated by cyclin F and suggest a connection between SIRT5, cell cycle regulation, and metabolism.

Published

2020

28. Ablation of Sirtuin5 in the postnatal mouse heart results in protein succinylation and normal survival in response to chronic pressure overload

Author

Juan Liu, Jason W. Locasale, Kathleen A. Hershberger, Paul A. Grimsrud, Dennis M. Abraham, and Matthew D. Hirschey

Subjects

0301 basic medicine, Pressure overload, Cardiac function curve, medicine.medical_specialty, SIRT5, biology, business.industry, Cell Biology, Cardiac Ablation, Biochemistry, 03 medical and health sciences, Protein succinylation, Succinylation, Protein acylation, 030104 developmental biology, Endocrinology, Internal medicine, Sirtuin, biology.protein, Medicine, business, Molecular Biology

Abstract

Mitochondrial Sirtuin 5 (SIRT5) is an NAD+-dependent demalonylase, desuccinylase, and deglutarylase that controls several metabolic pathways. A number of recent studies point to SIRT5 desuccinylase activity being important in maintaining cardiac function and metabolism under stress. Previously, we described a phenotype of increased mortality in whole-body SIRT5KO mice exposed to chronic pressure overload compared with their littermate WT controls. To determine whether the survival phenotype we reported was due to a cardiac-intrinsic or cardiac-extrinsic effect of SIRT5, we developed a tamoxifen-inducible, heart-specific SIRT5 knockout (SIRT5KO) mouse model. Using our new animal model, we discovered that postnatal cardiac ablation of Sirt5 resulted in persistent accumulation of protein succinylation up to 30 weeks after SIRT5 depletion. Succinyl proteomics revealed that succinylation increased on proteins of oxidative metabolism between 15 and 31 weeks after ablation. Heart-specific SIRT5KO mice were exposed to chronic pressure overload to induce cardiac hypertrophy. We found that, in contrast to whole-body SIRT5KO mice, there was no difference in survival between heart-specific SIRT5KO mice and their littermate controls. Overall, the data presented here suggest that survival of SIRT5KO mice may be dictated by a multitissue or prenatal effect of SIRT5.

Published

2018

29. Reactive Acyl-CoA Species Modify Proteins and Induce Carbon Stress

Author

Alec G. Trub and Matthew D. Hirschey

Subjects

0301 basic medicine, chemistry.chemical_element, Nutrient sensing, medicine.disease_cause, Biochemistry, Article, Substrate Specificity, 03 medical and health sciences, Acyl-CoA, chemistry.chemical_compound, Protein acylation, 0302 clinical medicine, medicine, Animals, Humans, Molecular Biology, chemistry.chemical_classification, Reactive oxygen species, Metabolism, Carbon, Oxidative Stress, Metabolic pathway, 030104 developmental biology, chemistry, Acyl Coenzyme A, Protein Processing, Post-Translational, 030217 neurology & neurosurgery, Oxidative stress

Abstract

In recent years, our understanding of the scope and diversity of protein post-translational modifications has rapidly expanded. In particular, mitochondrial proteins are decorated with an array of acyl groups that can occur non-enzymatically. Interestingly, these modifying chemical moieties are often associated with intermediary metabolites from core metabolic pathways. In this review, we describe biochemical reactions and biological mechanisms that activate carbon metabolites for protein post-translational modification. We explore the emerging links between the intrinsic reactivity of metabolites, non-enzymatic protein acylation, and possible signaling roles for this system. Finally, we propose a model of ‘carbon stress’, similar to oxidative stress, as an effective way to conceptualize the relationship between wide-spread protein acylation, nutrient sensing, and metabolic homeostasis.

Published

2018

30. Metabolic control by sirtuins and other enzymes that sense NAD+, NADH, or their ratio

Author

Christian A. Olsen, Kristin A. Anderson, Andreas Stahl Madsen, and Matthew D. Hirschey

Subjects

0301 basic medicine, chemistry.chemical_classification, biology, Biophysics, Cell Biology, Mitochondrion, Nicotinamide adenine dinucleotide, Biochemistry, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Glycerol-3-phosphate dehydrogenase, Enzyme, chemistry, Oxidoreductase, Sirtuin, biology.protein, NAD+ kinase

Abstract

NAD+ is a dinucleotide cofactor with the potential to accept electrons in a variety of cellular reduction-oxidation (redox) reactions. In its reduced form, NADH is a ubiquitous cellular electron donor. NAD+, NADH, and the NAD+/NADH ratio have long been known to control the activity of several oxidoreductase enzymes. More recently, enzymes outside those participating directly in redox control have been identified that sense these dinucleotides, including the sirtuin family of NAD+-dependent protein deacylases. In this review, we highlight examples of non-redox enzymes that are controlled by NAD+, NADH, or NAD+/NADH. In particular, we focus on the sirtuin family and assess the current evidence that the sirtuin enzymes sense these dinucleotides and discuss the biological conditions under which this might occur; we conclude that sirtuins sense NAD+, but neither NADH nor the ratio. Finally, we identify future studies that might be informative to further interrogate physiological and pathophysiological changes in NAD+ and NADH, as well as enzymes like sirtuins that sense and respond to redox changes in the cell.

Published

2017

31. Mechanism-Based Inhibitors of the Human Sirtuin 5 Deacylase: Structure-Activity Relationship, Biostructural, and Kinetic Insight

Author

Christian A. Olsen, Andreas Stahl Madsen, Marina Auth, Clemens Steegborn, Nima Rajabi, Dhaval P. Bhatt, Matthew D. Hirschey, Kathrin R. Troelsen, Martin Pannek, and Martin Fontenas

Subjects

0301 basic medicine, SIRT5, Mechanism based, Crystallography, X-Ray, 010402 general chemistry, 01 natural sciences, Article, Catalysis, Substrate Specificity, Structure-Activity Relationship, 03 medical and health sciences, Drug Discovery, Animals, Humans, Sirtuins, Structure–activity relationship, Zebrafish, chemistry.chemical_classification, Molecular Structure, biology, 010405 organic chemistry, Drug discovery, General Medicine, General Chemistry, Zebrafish Proteins, biology.organism_classification, Small molecule, 3. Good health, 0104 chemical sciences, Histone Deacetylase Inhibitors, Kinetics, 030104 developmental biology, Enzyme, Biochemistry, chemistry, Sirtuin, biology.protein

Abstract

The sirtuin enzymes are important regulatory deacylases in a variety of biochemical contexts and may therefore be potential therapeutic targets through either activation or inhibition by small molecules. Here, we describe the discovery of the most potent inhibitor of sirtuin 5 (SIRT5) reported to date. We provide rationalization of the mode of binding by solving co-crystal structures of selected inhibitors in complex with both human and zebrafish SIRT5, which provide insight for future optimization of inhibitors with more “drug-like” properties. Importantly, enzyme kinetic evaluation revealed a slow, tight-binding mechanism of inhibition, which is unprecedented for SIRT5. This is important information when applying inhibitors to probe mechanisms in biology.

Published

2017

32. Chronic Ethanol Metabolism Inhibits Hepatic Mitochondrial Superoxide Dismutase via Lysine Acetylation

Author

Donald S. Backos, Hadi R. Ali, David J. Orlicky, Matthew D. Hirschey, James R. Roede, Kristofer S. Fritz, Peter Harris, Colin T. Shearn, Mohammed A. Assiri, Samantha R. Roy, and Yongliang Liang

Subjects

Male, 0301 basic medicine, endocrine system, Lysine, SOD2, Medicine (miscellaneous), Mitochondrion, Toxicology, medicine.disease_cause, Article, Superoxide dismutase, Mice, 03 medical and health sciences, mental disorders, medicine, Animals, Ethanol metabolism, reproductive and urinary physiology, Ethanol, biology, Superoxide Dismutase, Acetylation, Mitochondria, Mice, Inbred C57BL, Oxidative Stress, Psychiatry and Mental health, 030104 developmental biology, Liver, Biochemistry, Sirtuin, biology.protein, Oxidative stress

Abstract

Background Chronic ethanol (EtOH) consumption is a major cause of liver disease worldwide. Oxidative stress is a known consequence of EtOH metabolism and is thought to contribute significantly to alcoholic liver disease (ALD). Therefore, elucidating pathways leading to sustained oxidative stress and downstream redox imbalances may reveal how EtOH consumption leads to ALD. Recent studies suggest that EtOH metabolism impacts mitochondrial antioxidant processes through a number of proteomic alterations, including hyperacetylation of key antioxidant proteins. Methods To elucidate mechanisms of EtOH-induced hepatic oxidative stress, we investigate a role for protein hyperacetylation in modulating mitochondrial superoxide dismutase (SOD2) structure and function in a 6-week Lieber–DeCarli murine model of EtOH consumption. Our experimental approach includes immunoblotting immunohistochemistry (IHC), activity assays, mass spectrometry, and in silico modeling. Results We found that EtOH metabolism significantly increased the acetylation of SOD2 at 2 functionally relevant lysine sites, K68 and K122, resulting in a 40% decrease in enzyme activity while overall SOD2 abundance was unchanged. In vitro studies also reveal which lysine residues are more susceptible to acetylation. IHC analysis demonstrates that SOD2 hyperacetylation occurs near zone 3 within the liver, which is the main EtOH-metabolizing region of the liver. Conclusions Overall, the findings presented in this study support a role for EtOH-induced lysine acetylation as an adverse posttranslational modification within the mitochondria that directly impacts SOD2 charge state and activity. Last, the data presented here indicate that protein hyperacetylation may be a major factor contributing to an imbalance in hepatic redox homeostasis due to chronic EtOH metabolism.

Published

2017

33. Loss of sirtuin 4 leads to elevated glucose- and leucine-stimulated insulin levels and accelerated age-induced insulin resistance in multiple murine genetic backgrounds

Author

James D. Johnson, Xiaoke Hu, Frank K. Huynh, Zhihong Lin, and Matthew D. Hirschey

Subjects

Blood Glucose, Male, 0301 basic medicine, medicine.medical_specialty, Mice, 129 Strain, medicine.medical_treatment, Lysine, In Vitro Techniques, Mitochondrion, Article, Mitochondrial Proteins, 03 medical and health sciences, Insulin resistance, Leucine, Internal medicine, Genetics, medicine, Animals, Insulin, Sirtuins, Genetic Predisposition to Disease, Genetics (clinical), Mice, Knockout, biology, Age Factors, Lipid metabolism, Metabolism, Lipid Metabolism, medicine.disease, Up-Regulation, Mice, Inbred C57BL, Phenotype, 030104 developmental biology, Endocrinology, Sirtuin, Knockout mouse, biology.protein, Female, Insulin Resistance, Protein Processing, Post-Translational, Biomarkers, Metabolism, Inborn Errors

Abstract

Several inherited metabolic disorders are associated with an accumulation of reactive acyl-CoA metabolites that can non-enzymatically react with lysine residues to modify proteins. While the role of acetylation is well-studied, the pathophysiological relevance of more recently discovered acyl modifications, including those found in inherited metabolic disorders, warrants further investigation. We recently showed that sirtuin 4 (SIRT4) removes glutaryl, 3-hydroxy-3-methylglutaryl, 3-methylglutaryl, and 3-methylglutaconyl modifications from lysine residues. Thus, we used SIRT4 knockout mice, which can accumulate these novel post-translational modifications, as a model to investigate their physiological relevance. Since SIRT4 is localized to mitochondria and previous reports have shown SIRT4 influences metabolism, we thoroughly characterized glucose and lipid metabolism in male and female SIRT4KO mice across different genetic backgrounds. While only minor perturbations in overall lipid metabolism were observed, we found SIRT4KO mice consistently had elevated glucose- and leucine-stimulated insulin levels in vivo and developed accelerated age-induced insulin resistance. Importantly, elevated leucine-stimulated insulin levels in SIRT4KO mice were dependent upon genetic background since SIRT4KO mice on a C57BL/6NJ genetic background had elevated leucine-stimulated insulin levels but not SIRT4KO mice on the C57BL/6J background. Taken together, the data suggest that accumulation of acyl modifications on proteins in inherited metabolic disorders may contribute to the overall metabolic dysfunction seen in these patients.

Published

2017

34. Role of NAD+ and mitochondrial sirtuins in cardiac and renal diseases

Author

Matthew D. Hirschey, Angelical Martin, and Kathleen A. Hershberger

Subjects

0301 basic medicine, chemistry.chemical_classification, Kidney, biology, business.industry, Nicotinamide adenine dinucleotide, Pharmacology, Mitochondrion, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Enzyme, medicine.anatomical_structure, chemistry, Nephrology, Sirtuin, biology.protein, medicine, NAD+ kinase, Signal transduction, business

Abstract

The coenzyme nicotinamide adenine dinucleotide (NAD+) has key roles in the regulation of redox status and energy metabolism. NAD+ depletion is emerging as a major contributor to the pathogenesis of cardiac and renal diseases and NAD+ repletion strategies have shown therapeutic potential as a means to restore healthy metabolism and physiological function. The pleotropic roles of NAD+ enable several possible avenues by which repletion of this coenzyme could have therapeutic efficacy. In particular, NAD+ functions as a co-substrate in deacylation reactions carried out by the sirtuin family of enzymes. These NAD+-dependent deacylases control several aspects of metabolism and a wealth of data suggests that boosting sirtuin activity via NAD+ supplementation might be a promising therapy for cardiac and renal pathologies. This Review summarizes the role of NAD+ metabolism in the heart and kidney, and highlights the mitochondrial sirtuins as mediators of some of the beneficial effects of NAD+-boosting therapies in preclinical animal models. We surmise that modulating the NAD+-sirtuin axis is a clinically relevant approach to develop new therapies for cardiac and renal diseases.

Published

2017

35. Investigating RNA expression profiles altered by nicotinamide mononucleotide therapy in a chronic model of alcoholic liver disease

Author

Kristofer S. Fritz, Juan Liu, John O. Marentette, Mohammed A. Assiri, Laura Saba, Hadi R. Ali, Matthew D. Hirschey, Peter Harris, and Youngho Yun

Subjects

0301 basic medicine, Alcoholic liver disease, lcsh:Medicine, Pharmacology, medicine.disease_cause, 0302 clinical medicine, Drug Discovery, ATF3, Nicotinamide Mononucleotide, Nicotinamide mononucleotide, biology, ERK1/2, Chemistry, Alanine Transaminase, 3. Good health, Liver, 030220 oncology & carcinogenesis, Sirtuin, Metabolome, Molecular Medicine, Primary Research, Signal Transduction, lcsh:QH426-470, Protective Agents, 03 medical and health sciences, Genetics, medicine, Animals, Metabolomics, Aspartate Aminotransferases, Ethanol metabolism, Molecular Biology, Liver Diseases, Alcoholic, NMN, Ethanol, Gene Expression Profiling, lcsh:R, medicine.disease, Mice, Inbred C57BL, lcsh:Genetics, Disease Models, Animal, 030104 developmental biology, Gene Expression Regulation, Chronic Disease, biology.protein, RNA, NAD+ kinase, Steatosis, Steatohepatitis, RNA-seq, Oxidative stress

Abstract

Background Chronic alcohol consumption is a significant cause of liver disease worldwide. Several biochemical mechanisms have been linked to the initiation and progression of alcoholic liver disease (ALD) such as oxidative stress, inflammation, and metabolic dysregulation, including the disruption of NAD+/NADH. Indeed, an ethanol-mediated reduction in hepatic NAD+ levels is thought to be one factor underlying ethanol-induced steatosis, oxidative stress, steatohepatitis, insulin resistance, and inhibition of gluconeogenesis. Therefore, we applied a NAD+ boosting supplement to investigate alterations in the pathogenesis of early-stage ALD. Methods To examine the impact of NAD+ therapy on the early stages of ALD, we utilized nicotinamide mononucleotide (NMN) at 500 mg/kg intraperitoneal injection every other day, for the duration of a Lieber-DeCarli 6-week chronic ethanol model in mice. Numerous strategies were employed to characterize the effect of NMN therapy, including the integration of RNA-seq, immunoblotting, and metabolomics analysis. Results Our findings reveal that NMN therapy increased hepatic NAD+ levels, prevented an ethanol-induced increase in plasma ALT and AST, and changed the expression of 25% of the genes that were modulated by ethanol metabolism. These genes were associated with a number of pathways including the MAPK pathway. Interestingly, our analysis revealed that NMN treatment normalized Erk1/2 signaling and prevented an induction of Atf3 overexpression. Conclusions These findings reveal previously unreported mechanisms by which NMN supplementation alters hepatic gene expression and protein pathways to impact ethanol hepatotoxicity in an early-stage murine model of ALD. Overall, our data suggest further research is needed to fully characterize treatment paradigms and biochemical implications of NAD+-based interventions.

Published

2019

36. NRF2-dependent metabolic reprogramming is required for tumor recurrence following oncogene inhibition

Author

Douglas B. Fox, Matthew D. Hirschey, James V. Alvarez, Juan Liu, Jason W. Locasale, Laura C. Noteware, Ryan Lupo, and Rachel Newcomb

Subjects

0303 health sciences, Oncogene, Anabolism, Glutaminase, business.industry, Regulator, medicine.disease, medicine.disease_cause, 3. Good health, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, Downregulation and upregulation, 030220 oncology & carcinogenesis, medicine, Cancer research, business, Transcription factor, Oxidative stress, 030304 developmental biology

Abstract

SummaryOncogenic signaling pathways both directly and indirectly regulate anabolic metabolism, and this is required for tumor growth. Targeted therapies that inhibit oncogenic signaling have dramatic impacts on cellular metabolism. However, it is not known whether the acquisition of resistance to these therapies is associated with – or driven by – alterations in cellular metabolism. To address this, we used a conditional mouse model of Her2-driven breast cancer to study metabolic adaptations following Her2 inhibition, during residual disease, and after tumor recurrence. We found that Her2 downregulation caused widespread changes in cellular metabolism, culminating in oxidative stress. Tumor cells adapted to this metabolic stress by upregulation of the antioxidant transcription factor, NRF2. Constitutive NRF2 expression persisted during residual disease and tumor recurrence, and NRF2 was both sufficient to promote tumor recurrence, and necessary for recurrent tumor growth. These results are supported by clinical data showing that the NRF2 transcriptional program is activated in recurrent breast tumors, and that NRF2 is associated with poor prognosis in patients with breast cancer. Mechanistically, NRF2 signaling in recurrent tumors induced metabolic reprogramming to re-establish redox homeostasis and upregulate de novo nucleotide synthesis. Finally, this NRF2-driven metabolic state rendered recurrent tumor cells sensitive to glutaminase inhibition, suggesting that NRF2-high recurrent tumors can be therapeutically targeted. Together, these data provide evidence that NRF2-driven metabolic reprogramming is required for breast cancer recurrence following oncogene inhibition.SignificanceAlthough tumor recurrence is the leading cause of mortality in breast cancer, the cellular properties that allow tumor cells to evade therapy and form recurrent tumors remain largely uncharacterized. Similarly, very little is known about how tumor metabolism changes following therapy, or whether alterations in cellular metabolism drive tumor recurrence. In this study, we identify the antioxidant transcription factor NRF2 as a critical positive regulator of breast cancer recurrence. We find that NRF2-dependent metabolic reprogramming is both sufficient and required to promote tumor recurrence. Additionally, we demonstrate that the NRF2-driven metabolic state renders recurrent tumors sensitive to glutaminase inhibitors, suggesting a novel therapeutic approach for the treatment of recurrent breast cancer.

Published

2019

37. Lipids Reprogram Metabolism to Become a Major Carbon Source for Histone Acetylation

Author

Douglas B. Fox, Matthew D. Hirschey, Paul A. Grimsrud, Olga Ilkayeva, Scott B. Crown, Christian A. Olsen, Eoin McDonnell, and Betül Kitir

Subjects

0301 basic medicine, Nutrient sensing, histone, General Biochemistry, Genetics and Molecular Biology, Article, Histones, lipids, 03 medical and health sciences, Mice, proteomics, Acetyl Coenzyme A, Cell Line, Tumor, Animals, Humans, Epigenetics, Amino Acid Sequence, Beta oxidation, lcsh:QH301-705.5, acetylation, Regulation of gene expression, biology, epigenetics, Gene Expression Profiling, Lipid metabolism, Lipid Metabolism, metabolomics, Carbon, Histone Deacetylase Inhibitors, 030104 developmental biology, Histone, Biochemistry, Gene Expression Regulation, lcsh:Biology (General), Acetylation, Histone methyltransferase, biology.protein, gene expression, lipids (amino acids, peptides, and proteins), fatty acid, Caprylates, Oxidation-Reduction, metabolism

Abstract

SummaryCells integrate nutrient sensing and metabolism to coordinate proper cellular responses to a particular nutrient source. For example, glucose drives a gene expression program characterized by activating genes involved in its metabolism, in part by increasing glucose-derived histone acetylation. Here, we find that lipid-derived acetyl-CoA is a major source of carbon for histone acetylation. Using 13C-carbon tracing combined with acetyl-proteomics, we show that up to 90% of acetylation on certain histone lysines can be derived from fatty acid carbon, even in the presence of excess glucose. By repressing both glucose and glutamine metabolism, fatty acid oxidation reprograms cellular metabolism, leading to increased lipid-derived acetyl-CoA. Gene expression profiling of octanoate-treated hepatocytes shows a pattern of upregulated lipid metabolic genes, demonstrating a specific transcriptional response to lipid. These studies expand the landscape of nutrient sensing and uncover how lipids and metabolism are integrated by epigenetic events that control gene expression.

Published

2016

38. From the Cover: Arsenite Uncouples Mitochondrial Respiration and Induces a Warburg-like Effect inCaenorhabditis elegans

Author

Dhaval P. Bhatt, Olga Ilkayeva, Laura L. Maurer, Anthony L. Luz, Tewodros R. Godebo, Matthew D. Hirschey, and Joel N. Meyer

Subjects

0301 basic medicine, ATP synthase, biology, Arsenic toxicity, Mitochondrial disease, Mitochondrion, Toxicology, medicine.disease, Warburg effect, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, Mitochondrial toxicity, 030104 developmental biology, 0302 clinical medicine, chemistry, Anaerobic glycolysis, 030220 oncology & carcinogenesis, biology.protein, medicine, Arsenite

Abstract

Millions of people worldwide are chronically exposed to arsenic through contaminated drinking water. Despite decades of research studying the carcinogenic potential of arsenic, the mechanisms by which arsenic causes cancer and other diseases remain poorly understood. Mitochondria appear to be an important target of arsenic toxicity. The trivalent arsenical, arsenite, can induce mitochondrial reactive oxygen species production, inhibit enzymes involved in energy metabolism, and induce aerobic glycolysis in vitro, suggesting that metabolic dysfunction may be important in arsenic-induced disease. Here, using the model organism Caenorhabditis elegans and a novel metabolic inhibition assay, we report an in vivo induction of aerobic glycolysis following arsenite exposure. Furthermore, arsenite exposure induced severe mitochondrial dysfunction, including altered pyruvate metabolism; reduced steady-state ATP levels, ATP-linked respiration and spare respiratory capacity; and increased proton leak. We also found evidence that induction of autophagy is an important protective response to arsenite exposure. Because these results demonstrate that mitochondria are an important in vivo target of arsenite toxicity, we hypothesized that deficiencies in mitochondrial electron transport chain genes, which cause mitochondrial disease in humans, would sensitize nematodes to arsenite. In agreement with this, nematodes deficient in electron transport chain complexes I, II, and III, but not ATP synthase, were sensitive to arsenite exposure, thus identifying a novel class of gene-environment interactions that warrant further investigation in the human populace.

Published

2016

39. Investigating the Sensitivity of NAD+-dependent Sirtuin Deacylation Activities to NADH

Author

Mohammad Mahdi Daoud, Ana Colaço, Christian A. Olsen, Saswati Chakladar, Peter Fristrup, Frank K. Huynh, Kristin A. Anderson, Donald S. Backos, Christian Beyschau Andersen, Matthew D. Hirschey, Jonas S. Laursen, and Andreas Stahl Madsen

Subjects

0301 basic medicine, Acylation, Lysine, Peptide, Molecular Dynamics Simulation, Biochemistry, Histone Deacetylases, Mass Spectrometry, 03 medical and health sciences, Protein acylation, chemistry.chemical_compound, 0302 clinical medicine, Coumarins, Humans, Sirtuins, Molecular Biology, Chromatography, High Pressure Liquid, Fluorescent Dyes, chemistry.chemical_classification, biology, Nicotinamide, Hydrolysis, Cell Biology, NAD, Recombinant Proteins, Isoenzymes, Solutions, Kinetics, 030104 developmental biology, Glycerol-3-phosphate dehydrogenase, chemistry, Acetylation, 030220 oncology & carcinogenesis, Sirtuin, Enzymology, biology.protein, Biological Assay, NAD+ kinase, Oligopeptides, Protein Processing, Post-Translational

Abstract

Protein lysine posttranslational modification by an increasing number of different acyl groups is becoming appreciated as a regulatory mechanism in cellular biology. Sirtuins are class III histone deacylases that use NAD(+)as a co-substrate during amide bond hydrolysis. Several studies have described the sirtuins as sensors of the NAD(+)/NADH ratio, but it has not been formally tested for all the mammalian sirtuinsin vitro To address this problem, we first synthesized a wide variety of peptide-based probes, which were used to identify the range of hydrolytic activities of human sirtuins. These probes included aliphatic ϵ-N-acyllysine modifications with hydrocarbon lengths ranging from formyl (C1) to palmitoyl (C16) as well as negatively charged dicarboxyl-derived modifications. In addition to the well established activities of the sirtuins, "long chain" acyllysine modifications were also shown to be prone to hydrolytic cleavage by SIRT1-3 and SIRT6, supporting recent findings. We then tested the ability of NADH, ADP-ribose, and nicotinamide to inhibit these NAD(+)-dependent deacylase activities of the sirtuins. In the commonly used 7-amino-4-methylcoumarin-coupled fluorescence-based assay, the fluorophore has significant spectral overlap with NADH and therefore cannot be used to measure inhibition by NADH. Therefore, we turned to an HPLC-MS-based assay to directly monitor the conversion of acylated peptides to their deacylated forms. All tested sirtuin deacylase activities showed sensitivity to NADH in this assay. However, the inhibitory concentrations of NADH in these assays are far greater than the predicted concentrations of NADH in cells; therefore, our data indicate that NADH is unlikely to inhibit sirtuinsin vivo These data suggest a re-evaluation of the sirtuins as direct sensors of the NAD(+)/NADH ratio.

Published

2016

40. A Prob(e)able Route to Lysine Acylation

Author

Matthew D. Hirschey and Gregory R. Wagner

Subjects

0301 basic medicine, Acylation, Clinical Biochemistry, Lysine, macromolecular substances, Biology, Biochemistry, Article, 03 medical and health sciences, Protein acylation, Drug Discovery, Glycolysis, Molecular Biology, Pharmacology, Intermediary Metabolism, Proteins, Malonyl Coenzyme A, enzymes and coenzymes (carbohydrates), 030104 developmental biology, Protein malonylation, Cancer cell, Molecular Medicine, lipids (amino acids, peptides, and proteins), Acyl Coenzyme A

Abstract

Non-enzymatic protein modification driven by thioester reactivity is thought to play a major role in the establishment of cellular lysine acylation. However, the specific protein targets of this process are largely unknown. Here we report an experimental strategy to investigate non-enzymatic acylation in cells. Specifically, we develop a chemoproteomic method that separates thioester reactivity from enzymatic utilization, allowing selective enrichment of non-enzymatic acylation targets. Applying this method to cancer cell lines identifies numerous candidate targets of non-enzymatic acylation, including several enzymes in lower glycolysis. Functional studies highlight malonyl-CoA as a reactive thioester metabolite that can modify and inhibit glycolytic enzyme activity. Finally, we show that synthetic thioesters can be used as novel reagents to probe non-enzymatic acylation in living cells. Our studies provide new insights into the targets and drivers of non-enzymatic acylation, and demonstrate the utility of reactivity-based methods to experimentally investigate this phenomenon in biology and disease.

Published

2017

41. Sensing Mitochondrial Acetyl-CoA to Tune Respiration

Author

Matthew D. Hirschey, Alec G. Trub, and Christine A. Mills

Subjects

Endocrinology, Diabetes and Metabolism, Metabolite, Respiration, Acetyl-CoA, Fatty Acids, Eukaryota, 030209 endocrinology & metabolism, Nutrient sensing, Oxidative phosphorylation, Mitochondrion, Article, Mitochondria, 03 medical and health sciences, chemistry.chemical_compound, Lipoic acid, 0302 clinical medicine, Endocrinology, chemistry, Biochemistry, Acetyl Coenzyme A, Acyl Carrier Protein, Fatty acid synthesis

Abstract

Fatty acid synthesis (FAS) in mitochondria produces a key metabolite called lipoic acid. However, a new study by Van Vranken et al. [1] (Mol. Cell 2018;71:567–580) shows that mitochondrial FAS regulates the assembly of oxidative phosphorylation complexes, thereby functioning as a nutrient sensor for mitochondrial respiration.

Published

2018

42. Sirtuin 4 controls leucine metabolism and insulin secretion by reversing effects of reactive metabolites

Author

Matthew D. Hirschey, Zhihong Lin, J. Darren Stuart, Kristin A. Anderson, and Frank K. Huynh

Subjects

medicine.medical_specialty, biology, Chemistry, Biochemistry, Endocrinology, Leucine metabolism, Internal medicine, Sirtuin, Genetics, medicine, biology.protein, Insulin secretion, Molecular Biology, Biotechnology

Published

2018

43. Fructose and glucose can regulate mammalian target of rapamycin complex 1 and lipogenic gene expression via distinct pathways

Author

Ji Miao, Sudha B. Biddinger, Ivana Semova, Anthony N. Hollenberg, Hong Kang, Matthew D. Hirschey, David Masson, Yue Hu, Satyapal Chahar, Xiaowei Sun, Division of Endocrinology, Children's Hospital Boston, Harvard Medical School, Harvard Medical School [Boston] ( HMS ), Beth Israel Deaconess Medical Center, Lipides - Nutrition - Cancer [Dijon - U1231] ( LNC ), Université de Bourgogne ( UB ) -AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement-Institut National de la Santé et de la Recherche Médicale ( INSERM ), and Duke University Medical Center

Subjects

0301 basic medicine, Male, medicine.medical_specialty, mTORC1, Mechanistic Target of Rapamycin Complex 1, Biochemistry, metabolic syndrome, fructose, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, Internal medicine, Gene expression, medicine, Animals, glucose, Molecular Biology, [ SDV.BBM ] Life Sciences [q-bio]/Biochemistry, Molecular Biology, Triglycerides, lipogenesis, Mice, Knockout, Fatty liver, dyslipidemia, mammalian target of rapamycin (mTOR), Lipid metabolism, Fructose, Cell Biology, medicine.disease, Mice, Inbred C57BL, 030104 developmental biology, Endocrinology, Metabolism, chemistry, Gene Expression Regulation, Liver, Lipogenesis, Metabolic syndrome, Signal transduction, biological phenomena, cell phenomena, and immunity, 030217 neurology & neurosurgery, Signal Transduction

Abstract

International audience; Although calorically equivalent to glucose, fructose appears to be more lipogenic, promoting dyslipidemia, fatty liver disease, cardiovascular disease, and diabetes. To better understand how fructose induces lipogenesis, we compared the effects of fructose and glucose on mammalian target of rapamycin complex 1 (mTORC1), which appeared to have both positive and negative effects on lipogenic gene expression. We found that fructose acutely and transiently suppressed mTORC1 signalingin vitroandin vivoThe constitutive activation of mTORC1 reduced hepatic lipogenic gene expression and produced hypotriglyceridemia after 1 week of fructose feeding. In contrast, glucose did not suppress mTORC1, and the constitutive activation of mTORC1 failed to suppress plasma triglycerides after 1 week of glucose feeding. Thus, these data reveal fundamental differences in the signaling pathways used by fructose and glucose to regulate lipid metabolism.

Published

2018

44. Ablation of

Author

Kathleen A, Hershberger, Dennis M, Abraham, Juan, Liu, Jason W, Locasale, Paul A, Grimsrud, and Matthew D, Hirschey

Subjects

Male, Mice, Knockout, Proteomics, Succinic Acid, Cardiomegaly, Heart, Survival Analysis, Mice, Inbred C57BL, Mice, Metabolism, Gene Expression Regulation, Pressure, Animals, Sirtuins, Female, Protein Processing, Post-Translational, Metabolic Networks and Pathways

Abstract

Mitochondrial Sirtuin 5 (SIRT5) is an NAD(+)-dependent demalonylase, desuccinylase, and deglutarylase that controls several metabolic pathways. A number of recent studies point to SIRT5 desuccinylase activity being important in maintaining cardiac function and metabolism under stress. Previously, we described a phenotype of increased mortality in whole-body SIRT5KO mice exposed to chronic pressure overload compared with their littermate WT controls. To determine whether the survival phenotype we reported was due to a cardiac-intrinsic or cardiac-extrinsic effect of SIRT5, we developed a tamoxifen-inducible, heart-specific SIRT5 knockout (SIRT5KO) mouse model. Using our new animal model, we discovered that postnatal cardiac ablation of Sirt5 resulted in persistent accumulation of protein succinylation up to 30 weeks after SIRT5 depletion. Succinyl proteomics revealed that succinylation increased on proteins of oxidative metabolism between 15 and 31 weeks after ablation. Heart-specific SIRT5KO mice were exposed to chronic pressure overload to induce cardiac hypertrophy. We found that, in contrast to whole-body SIRT5KO mice, there was no difference in survival between heart-specific SIRT5KO mice and their littermate controls. Overall, the data presented here suggest that survival of SIRT5KO mice may be dictated by a multitissue or prenatal effect of SIRT5.

Published

2018

45. List of Contributors

Author

Maria Angulo-Ibanez, Johan Auwerx, Katrin F. Chua, William Giblin, David Gius, Leonard Guarente, Angela H. Guo, Marcia C. Haigis, Sylvana Hassanieh, Kathleen A. Hershberger, Matthew D. Hirschey, Shin-ichiro Imai, Alice E. Kane, Elena Katsyuba, Aleksey G. Kazantsev, Hening Lin, David B. Lombard, Sébastien Moniot, Raul Mostoslavsky, Tiago F. Outeiro, David A. Sinclair, Clemens Steegborn, Adam B. Stein, Éva M. Szegő, Robert A.H. van de Ven, Athanassios Vassilopoulos, Rui-Hong Wang, Wen Yang, Mitsukuni Yoshida, and Weijie You

Published

2018

46. Reactive Acyl-CoA Species and Deacylation by the Mitochondrial Sirtuins

Author

Kathleen A. Hershberger and Matthew D. Hirschey

Subjects

chemistry.chemical_classification, chemistry.chemical_compound, SIRT5, Acyl-CoA, Enzyme, Biochemistry, chemistry, SIRT3, Lysine, NAD+ kinase, Nicotinamide adenine dinucleotide, Mitochondrion

Abstract

The sirtuins are a family of nicotinamide adenine dinucleotide (NAD+)-dependent enzymes that remove acyl-lysine modifications from a variety of proteins, thereby controlling a myriad of cellular processes. In mitochondria, reactive acyl-CoA species lead to a wide range of protein posttranslational modifications. Three sirtuins (SIRT3, SIRT4, and SIRT5) primarily localized in mitochondria remove distinct acyl-groups from lysine side chains, which control protein function. Indeed, high-resolution mass spectrometry-based proteomic studies have identified thousands of acyl-protein modifications across hundreds of mitochondrial proteins. Emerging evidence shows a relationship between physiological stress, changes in carbon metabolism and protein modifications, and a key role for sirtuins in maintaining metabolic homeostasis. In this chapter, we discuss key roles of the mitochondrial sirtuins, with a particular emphasis on cardiac studies. We also highlight key questions remaining in the field, including the mechanisms by which acylation influences protein function and the role of sirtuins in shaping the global mitochondrial acyl-lysine landscape.

Published

2018

47. Intrinsic Mitochondrial Dynamics and Cytoskeletal Properties Underlie Aging Diversity in Dogs

Author

Frank K. Huynh, Olga Ilkayeva, Matthew D. Hirschey, Richard A. Miller, Timothy M. Robinette, Igor M. Sokolov, Justin W. Nicholatos, Saurabh V.P. Tata, Sergiy Libert, Maxim Dokukin, Michael Platov, Michael A. Weinstein, Dmyro Volkov, Adam R. Boyko, Adam B. Francisco, and Jennifer D. Yordy

Subjects

chemistry.chemical_classification, Reactive oxygen species, Bioenergetics, chemistry, media_common.quotation_subject, Respiration, Longevity, Biology, Cytoskeleton, Function (biology), media_common, Cell biology

Abstract

Among its many breeds, dogs exhibit exceptional variation in their rate of aging and average lifespan, which presents an opportunity to identify longevity-associated traits via comparative analysis. Using primary dermal fibroblasts, we investigated mitochondrial dynamics, bioenergetics, and biomechanical properties in short and long-lived dog breeds. We demonstrated that intrinsic cellular properties correlate with canine breed longevity and likely underlie their aging diversity. More specifically, cells from longer lived-breeds have higher mitochondrial uncoupling and more efficient respiration dynamics, which appears to mitigate reactive oxygen species and promote stress tolerance. We also showed that fibroblasts of long-lived dogs had a more flexible cytoskeleton than their short-lived counterparts, which may similarly help protect cellular function. The benefits of these cellular characteristics likely translate upwards to the whole organism, slowing the rate of aging in long-lived dogs. Overall, our data support the uncoupling to survive hypothesis, where higher uncoupling in smaller breeds promotes longevity. The closeness of dogs and humans genetically and environmentally make these results pertinent to human biology.

Published

2018

48. Dysregulated metabolism contributes to oncogenesis

Author

Matthew D. Hirschey, Ralph J. DeBerardinis, Anna Mae E. Diehl, Janice E. Drew, Christian Frezza, Michelle F. Green, Lee W. Jones, Young H. Ko, Anne Le, Michael A. Lea, Jason W. Locasale, Valter D. Longo, Costas A. Lyssiotis, Eoin McDonnell, Mahya Mehrmohamadi, Gregory Michelotti, Vinayak Muralidhar, Michael P. Murphy, Peter L. Pedersen, Brad Poore, Lizzia Raffaghello, Jeffrey C. Rathmell, Sharanya Sivanand, Matthew G. Vander Heiden, Kathryn E. Wellen, Harvard University--MIT Division of Health Sciences and Technology, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Vander Heiden, Matthew G., and Muralidhar, Vinayak

Subjects

Cancer Research, Cancer therapy, Carcinogenesis, Disease, Computational biology, Biology, Mitochondrion, medicine.disease_cause, Host metabolism, Article, Epigenesis, Genetic, Neoplasms, medicine, Humans, Epigenetics, Cell Proliferation, Genetics, Cancer, medicine.disease, Warburg, Cancer metabolism, 3. Good health, Mitochondria, Metabolic pathway, Cell Transformation, Neoplastic, Cancer cell, Energy Metabolism, Reprogramming, Metabolic Networks and Pathways

Abstract

Cancer is a disease characterized by unrestrained cellular proliferation. In order to sustain growth, cancer cells undergo a complex metabolic rearrangement characterized by changes in metabolic pathways involved in energy production and biosynthetic processes. The relevance of the metabolic transformation of cancer cells has been recently included in the updated version of the review “Hallmarks of Cancer”, where dysregulation of cellular metabolism was included as an emerging hallmark. While several lines of evidence suggest that metabolic rewiring is orchestrated by the concerted action of oncogenes and tumor suppressor genes, in some circumstances altered metabolism can play a primary role in oncogenesis. Recently, mutations of cytosolic and mitochondrial enzymes involved in key metabolic pathways have been associated with hereditary and sporadic forms of cancer. Together, these results demonstrate that aberrant metabolism, once seen just as an epiphenomenon of oncogenic reprogramming, plays a key role in oncogenesis with the power to control both genetic and epigenetic events in cells. In this review, we discuss the relationship between metabolism and cancer, as part of a larger effort to identify a broad-spectrum of therapeutic approaches. We focus on major alterations in nutrient metabolism and the emerging link between metabolism and epigenetics. Finally, we discuss potential strategies to manipulate metabolism in cancer and tradeoffs that should be considered. More research on the suite of metabolic alterations in cancer holds the potential to discover novel approaches to treat it.

Published

2015

49. Long-chain Acylcarnitines Reduce Lung Function by Inhibiting Pulmonary Surfactant

Author

Olga Ilkayeva, Radha Uppala, Eric S. Goetzman, Sivakama S. Bharathi, Matthew D. Hirschey, John F. Alcorn, Kevin McHugh, Ye Zou, Jieru Wang, Yi Y. Zuo, Chikara Otsubo, and Dongning Wang

Subjects

medicine.medical_specialty, Lung injury, Mitochondrion, Biology, Biochemistry, Mice, chemistry.chemical_compound, Pulmonary surfactant, Carnitine, Internal medicine, medicine, Animals, Humans, Lung, Molecular Biology, Beta oxidation, Phospholipids, Palmitoylcarnitine, Mice, Knockout, chemistry.chemical_classification, digestive, oral, and skin physiology, Acyl-CoA Dehydrogenase, Long-Chain, food and beverages, Pulmonary Surfactants, Lung Injury, Cell Biology, Metabolism, respiratory system, In vitro, Enzyme, Endocrinology, chemistry

Abstract

The role of mitochondrial energy metabolism in maintaining lung function is not understood. We previously observed reduced lung function in mice lacking the fatty acid oxidation enzyme long-chain acyl-CoA dehydrogenase (LCAD). Here, we demonstrate that long-chain acylcarnitines, a class of lipids secreted by mitochondria when metabolism is inhibited, accumulate at the air-fluid interface in LCAD(-/-) lungs. Acylcarnitine accumulation is exacerbated by stress such as influenza infection or by dietary supplementation with l-carnitine. Long-chain acylcarnitines co-localize with pulmonary surfactant, a unique film of phospholipids and proteins that reduces surface tension and prevents alveolar collapse during breathing. In vitro, the long-chain species palmitoylcarnitine directly inhibits the surface adsorption of pulmonary surfactant as well as its ability to reduce surface tension. Treatment of LCAD(-/-) mice with mildronate, a drug that inhibits carnitine synthesis, eliminates acylcarnitines and improves lung function. Finally, acylcarnitines are detectable in normal human lavage fluid. Thus, long-chain acylcarnitines may represent a risk factor for lung injury in humans with dysfunctional fatty acid oxidation.

Published

2015

50. Metabolic Regulation by Lysine Malonylation, Succinylation, and Glutarylation

Author

Yingming Zhao and Matthew D. Hirschey

Subjects

Special Issue Articles, Regulation of gene expression, SIRT5, Mechanism (biology), Acylation, Lysine, Intracellular Space, Proteins, Metabolism, Biology, NAD, Biochemistry, Analytical Chemistry, Succinylation, Gene Expression Regulation, Gene expression, Sirtuin, biology.protein, Animals, Humans, Sirtuins, Protein Processing, Post-Translational, Molecular Biology

Abstract

Protein acetylation is a well-studied regulatory mechanism for several cellular processes, ranging from gene expression to metabolism. Recent discoveries of new post-translational modifications, including malonylation, succinylation, and glutarylation, have expanded our understanding of the types of modifications found on proteins. These three acidic lysine modifications are structurally similar but have the potential to regulate different proteins in different pathways. The deacylase sirtuin 5 (SIRT5) catalyzes the removal of these modifications from a wide range of proteins in different subcellular compartments. Here, we review these new modifications, their regulation by SIRT5, and their emerging role in cellular regulation and diseases.

Published

2015