Your search keyword '"Kathleen A. Hershberger"' showing total 18 results

1. Mild pentachlorophenol-mediated uncoupling of mitochondria depletes ATP but does not cause an oxidized redox state or dopaminergic neurodegeneration in Caenorhabditis elegans

Author

Zachary R. Markovich, Jessica H. Hartman, Ian T. Ryde, Kathleen A. Hershberger, Abigail S. Joyce, Patrick L. Ferguson, and Joel N. Meyer

Subjects

Mitochondrial uncoupling, Dopaminergic neurodegeneration, Adverse outcome pathway, Redox tone, Caenorhabditis elegans, Toxicology. Poisons, RA1190-1270

Abstract

Aims: Mitochondrial dysfunction is implicated in several diseases, including neurological disorders such as Parkinson’s disease. However, there is uncertainty about which of the many mechanisms by which mitochondrial function can be disrupted may lead to neurodegeneration. Pentachlorophenol (PCP) is an organic pollutant reported to cause mitochondrial dysfunction including oxidative stress and mitochondrial uncoupling. We investigated the effects of PCP exposure in Caenorhabditis elegans, including effects on mitochondria and dopaminergic neurons. We hypothesized that mild mitochondrial uncoupling by PCP would impair bioenergetics while decreasing oxidative stress, and therefore would not cause dopaminergic neurodegeneration. Results: A 48-hour developmental exposure to PCP causing mild growth delay (∼10 % decrease in growth during 48 h, covering all larval stages) reduced whole-organism ATP content > 50 %, and spare respiratory capacity ∼ 30 %. Proton leak was also markedly increased. These findings suggest a main toxic mechanism of mitochondrial uncoupling rather than oxidative stress, which was further supported by a concomitant shift toward a more reduced cellular redox state measured at the whole organism level. However, exposure to PCP did not cause dopaminergic neurodegeneration, nor did it sensitize animals to a neurotoxic challenge with 6-hydroxydopamine. Whole-organism uptake and PCP metabolism measurements revealed low overall uptake of PCP in our experimental conditions (50 μM PCP in the liquid exposure medium resulted in organismal concentrations of

Published

2022

2. 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

3. Resistance of mitochondrial DNA to cadmium and Aflatoxin B1 damage-induced germline mutation accumulation in C. elegans

Author

Tess C Leuthner, Laura Benzing, Brendan F Kohrn, Christina M Bergemann, Michael J Hipp, Kathleen A Hershberger, Danielle F Mello, Tymofii Sokolskyi, Kevin Stevenson, Ilaria R Merutka, Sarah A Seay, Simon G Gregory, Scott R Kennedy, and Joel N Meyer

Subjects

Mutation Accumulation, Aflatoxin B1, Germ Cells, Mutation, Genetics, Animals, Caenorhabditis elegans, DNA, Mitochondrial, Cadmium, Mitochondria

Abstract

Mitochondrial DNA (mtDNA) is prone to mutation in aging and over evolutionary time, yet the processes that regulate the accumulation of de novo mtDNA mutations and modulate mtDNA heteroplasmy are not fully elucidated. Mitochondria lack certain DNA repair processes, which could contribute to polymerase error-induced mutations and increase susceptibility to chemical-induced mtDNA mutagenesis. We conducted error-corrected, ultra-sensitive Duplex Sequencing to investigate the effects of two known nuclear genome mutagens, cadmium and Aflatoxin B1, on germline mtDNA mutagenesis in Caenorhabditis elegans. Detection of thousands of mtDNA mutations revealed pervasive heteroplasmy in C. elegans and that mtDNA mutagenesis is dominated by C:G → A:T mutations generally attributed to oxidative damage. However, there was no effect of either exposure on mtDNA mutation frequency, spectrum, or trinucleotide context signature despite a significant increase in nuclear mutation rate after aflatoxin B1 exposure. Mitophagy-deficient mutants pink-1 and dct-1 accumulated significantly higher levels of mtDNA damage compared to wild-type C. elegans after exposures. However, there were only small differences in mtDNA mutation frequency, spectrum, or trinucleotide context signature compared to wild-type after 3050 generations, across all treatments. These findings suggest mitochondria harbor additional previously uncharacterized mechanisms that regulate mtDNA mutational processes across generations.

Published

2022

4. Resistance of mitochondrial DNA to chemical-induced germline mutations is independent of mitophagy in C. elegans

Author

Tess C Leuthner, Laura Benzing, Brendan F Kohrn, Christina M Bergemann, Michael J Hipp, Kathleen A Hershberger, Danielle F Mello, Tymofii Sokolskyi, Ilaria R Merutka, Sarah A Seay, Scott R Kennedy, and Joel N Meyer

Abstract

Mitochondrial DNA (mtDNA) is prone to mutation in aging and over evolutionary time, yet the processes that regulate the accumulation of de novo mtDNA mutations and modulate mtDNA heteroplasmy are not fully elucidated. Mitochondria lack certain DNA repair processes, which could contribute to polymerase error-induced mutations and increase susceptibility to chemical-induced mtDNA mutagenesis. We conducted error-corrected, ultra-sensitive Duplex Sequencing to investigate the effects of two known nuclear genome mutagens, cadmium and Aflatoxin B1, on germline mtDNA mutagenesis in Caenorhabditis elegans. After 1,750 generations, we detected 2,270 single nucleotide mutations. Heteroplasmy is pervasive in C. elegans and mtDNA mutagenesis is dominated by C:G → A:T mutations generally attributed to oxidative damage, yet there was no effect of either exposure on mtDNA mutation frequency, spectrum, or trinucleotide context signature. Mitophagy may play a role in eliminating mtDNA damage or deleterious mutations, and mitophagy-deficient mutants pink-1 and dct-1 accumulated significantly higher levels of mtDNA damage compared to wild-type C. elegans after exposures. However, there were only small differences in overall mutation frequency, spectrum, or trinucleotide context signature compared to wild-type after 3,050 generations, across all treatments. These findings suggest mitochondria harbor additional previously uncharacterized mechanisms that regulate mtDNA mutational processes across generations.

Published

2022

5. 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

6. Phosphoproteomic profiling of human myocardial tissues distinguishes ischemic from non-ischemic end stage heart failure.

Author

Matthew A Schechter, Michael K H Hsieh, Linda W Njoroge, J Will Thompson, Erik J Soderblom, Bryan J Feger, Constantine D Troupes, Kathleen A Hershberger, Olga R Ilkayeva, Whitney L Nagel, Gina P Landinez, Kishan M Shah, Virginia A Burns, Lucia Santacruz, Matthew D Hirschey, Matthew W Foster, Carmelo A Milano, M Arthur Moseley, Valentino Piacentino, and Dawn E Bowles

Subjects

Medicine, Science

Abstract

The molecular differences between ischemic (IF) and non-ischemic (NIF) heart failure are poorly defined. A better understanding of the molecular differences between these two heart failure etiologies may lead to the development of more effective heart failure therapeutics. In this study extensive proteomic and phosphoproteomic profiles of myocardial tissue from patients diagnosed with IF or NIF were assembled and compared. Proteins extracted from left ventricular sections were proteolyzed and phosphopeptides were enriched using titanium dioxide resin. Gel- and label-free nanoscale capillary liquid chromatography coupled to high resolution accuracy mass tandem mass spectrometry allowed for the quantification of 4,436 peptides (corresponding to 450 proteins) and 823 phosphopeptides (corresponding to 400 proteins) from the unenriched and phospho-enriched fractions, respectively. Protein abundance did not distinguish NIF from IF. In contrast, 37 peptides (corresponding to 26 proteins) exhibited a ≥ 2-fold alteration in phosphorylation state (p

Published

2014

7. 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

8. 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

9. 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

10. 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

11. 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

12. 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

13. Sirtuin 5 is required for mouse survival in response to cardiac pressure overload

Author

Juan Liu, Jason W. Locasale, Angelical Martin, Matthew D. Hirschey, Kathleen A. Hershberger, Dennis M. Abraham, Hongbo Gu, and Lan Mao

Subjects

0301 basic medicine, medicine.medical_specialty, SIRT5, Systole, Cardiomegaly, Biology, Mitochondrion, Biochemistry, Mitochondria, Heart, Muscle hypertrophy, 03 medical and health sciences, Mice, Internal medicine, medicine, Animals, Sirtuins, Molecular Biology, Beta oxidation, Pressure overload, Mice, Knockout, Cell Biology, Survival Analysis, 030104 developmental biology, Endocrinology, Glucose, Metabolism, Sirtuin, biology.protein, NAD+ kinase, Oxidation-Reduction

Abstract

In mitochondria, the sirtuin SIRT5 is an NAD+-dependent protein deacylase that controls several metabolic pathways. Although a wide range of SIRT5 targets have been identified, the overall function of SIRT5 in organismal metabolic homeostasis remains unclear. Given that SIRT5 expression is highest in the heart and that sirtuins are commonly stress-response proteins, we used an established model of pressure overload-induced heart muscle hypertrophy caused by transverse aortic constriction (TAC) to determine SIRT5's role in cardiac stress responses. Remarkably, SIRT5KO mice had reduced survival upon TAC compared with wild-type mice but exhibited no mortality when undergoing a sham control operation. The increased mortality with TAC was associated with increased pathological hypertrophy and with key abnormalities in both cardiac performance and ventricular compliance. By combining high-resolution MS-based metabolomic and proteomic analyses of cardiac tissues from wild-type and SIRT5KO mice, we found several biochemical abnormalities exacerbated in the SIRT5KO mice, including apparent decreases in fatty acid oxidation and glucose oxidation as well as an overall decrease in mitochondrial NAD+/NADH. Together, these abnormalities suggest that SIRT5 deacylates protein substrates involved in cellular oxidative metabolism to maintain mitochondrial energy production. Overall, the functional and metabolic results presented here suggest an accelerated development of cardiac dysfunction in SIRT5KO mice in response to TAC, explaining increased mortality upon cardiac stress. Our findings reveal a key role for SIRT5 in maintaining cardiac oxidative metabolism under pressure overload to ensure survival.

Published

2017

14. Nicotinamide mononucleotide requires SIRT3 to improve cardiac function and bioenergetics in a Friedreich’s ataxia cardiomyopathy model

Author

Kathleen A. Hershberger, Lan Mao, R. Mark Payne, Paul A. Grimsrud, Angelical Martin, Xiaojing Liu, Huaxia Cui, Dhaval P. Bhatt, Jason W. Locasale, Juan Liu, Matthew D. Hirschey, Michael J. Muehlbauer, and Dennis M. Abraham

Subjects

0301 basic medicine, Cardiac function curve, Ataxia, SIRT3, biology, Chemistry, Cardiomyopathy, General Medicine, Pharmacology, medicine.disease, 03 medical and health sciences, 030104 developmental biology, Biochemistry, Sirtuin, biology.protein, medicine, Protein deacetylase, NAD+ kinase, medicine.symptom, Nicotinamide mononucleotide, Research Article

Abstract

Increasing NAD+ levels by supplementing with the precursor nicotinamide mononucleotide (NMN) improves cardiac function in multiple mouse models of disease. While NMN influences several aspects of mitochondrial metabolism, the molecular mechanisms by which increased NAD+ enhances cardiac function are poorly understood. A putative mechanism of NAD+ therapeutic action exists via activation of the mitochondrial NAD+-dependent protein deacetylase sirtuin 3 (SIRT3). We assessed the therapeutic efficacy of NMN and the role of SIRT3 in the Friedreich's ataxia cardiomyopathy mouse model (FXN-KO). At baseline, the FXN-KO heart has mitochondrial protein hyperacetylation, reduced Sirt3 mRNA expression, and evidence of increased NAD+ salvage. Remarkably, NMN administered to FXN-KO mice restores cardiac function to near-normal levels. To determine whether SIRT3 is required for NMN therapeutic efficacy, we generated SIRT3-KO and SIRT3-KO/FXN-KO (double KO [dKO]) models. The improvement in cardiac function upon NMN treatment in the FXN-KO is lost in the dKO model, demonstrating that the effects of NMN are dependent upon cardiac SIRT3. Coupled with cardio-protection, SIRT3 mediates NMN-induced improvements in both cardiac and extracardiac metabolic function and energy metabolism. Taken together, these results serve as important preclinical data for NMN supplementation or SIRT3 activator therapy in Friedreich's ataxia patients.

Published

2017

15. Role of NAD

Author

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

Subjects

Disease Models, Animal, Heart Diseases, Animals, Humans, Sirtuins, Heart, Kidney Diseases, Kidney, NAD, Oxidation-Reduction, Article, Mitochondria, Signal Transduction

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

16. Deacetylation by SIRT3 Relieves Inhibition of Mitochondrial Protein Function

Author

Frank K. Huynh, Donald S. Backos, Angelical Martin, Kathleen A. Hershberger, Laura A. Starzenski, Matthew D. Hirschey, Peter Chhoy, Kristofer S. Fritz, Kristin A. Anderson, Eoin McDonnell, and Brett S. Peterson

Subjects

0301 basic medicine, SIRT3, biology, Chemistry, Lysine, Regulator, Mitochondrion, Cell biology, 03 medical and health sciences, Metabolic pathway, 030104 developmental biology, 0302 clinical medicine, Acetylation, Sirtuin, biology.protein, 030217 neurology & neurosurgery, Function (biology)

Abstract

Lysine acetylation is a chemical modification occurring on cellular proteins that plays important roles in protein regulation. In mitochondria, protein acetylation is regulated by the sirtuin SIRT3, which has been reported to control several metabolic pathways. While the functional relevance of protein acetylation is likely specific for proteins in different pathways, a picture is emerging for mitochondrial protein acetylation to be an important regulator of enzymatic activity. In this review, we integrate qualitative and quantitative proteomic acetylation studies and put forward the hypothesis that acetylation suppresses enzymatic activity, and that SIRT3 serves to relieve the suppression. We discuss the possible mechanisms of suppression, and the future studies needed to fully understand the biological role of acetylation and its regulation by the sirtuins.

Published

2016

17. Targeting sirtuins for the treatment of diabetes

Author

Frank K. Huynh, Kathleen A. Hershberger, and Matthew D. Hirschey

Subjects

Gerontology, SIRT6, SIRT3, biology, business.industry, Lipid metabolism, Type 2 diabetes, medicine.disease, Bioinformatics, Article, Overnutrition, Targeted drug delivery, Diabetes mellitus, Sirtuin, medicine, biology.protein, business

Abstract

Sirtuins are a class of NAD+-dependent deacetylases, such as deacetylases, that have a wide array of biological functions. Recent studies have suggested that reduced sirtuin action is correlated with Type 2 diabetes. Both overnutrition and aging, which are two major risk factors for diabetes, lead to decreased sirtuin function and result in abnormal glucose and lipid metabolism. Therefore, restoring normal levels of sirtuin action in Type 2 diabetes may be a promising method of treating diabetes. This article reviews the biological functions of three of the seven mammalian sirtuins – SIRT1, SIRT3 and SIRT6 – that have demonstrated prominent metabolic roles and early potential for drug targeting. Clinical trials investigating the use of sirtuin activators for treating diabetes are already underway and show promise as alternatives to current diabetes therapies. Thus, further research into sirtuin activators is warranted and may lead to a new class of safe, effective diabetes treatments.

Published

2014

18. Generating Mammalian Sirtuin Tools for Protein-Interaction Analysis

Author

Matthew D. Hirschey, Kathleen A. Hershberger, Jonathan Motley, and Kristin A. Anderson

Subjects

Proteomics, biology, Immunoprecipitation, Immunoblotting, HEK 293 cells, Regulator, Computational Biology, Acetylation, Molecular cloning, Article, HEK293 Cells, Biochemistry, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Sirtuin, biology.protein, Humans, Sirtuins, Protein Interaction Maps, NAD+ kinase, Chromatography, Liquid, Plasmids

Abstract

The sirtuins are a family of NAD(+)-dependent deacylases with important effects on aging, cancer, and metabolism. Sirtuins exert their biological effects by catalyzing deacetylation and/or deacylation reactions in which Acyl groups are removed from lysine residues of specific proteins. A current challenge is to identify specific sirtuin target proteins against the high background of acetylated proteins recently identified by proteomic surveys. New evidence indicates that bona fide sirtuin substrate proteins form stable physical associations with their sirtuin regulator. Therefore, identification of sirtuin interacting proteins could be a useful aid in focusing the search for substrates. Described here is a method for identifying sirtuin protein interactors. Employing basic techniques of molecular cloning and immunochemistry, the method describes the generation of mammalian sirtuin protein expression plasmids and their use to overexpress and immunoprecipitate sirtuins with their interacting partners. Also described is the use of the Database for Annotation, Visualization, and Integrated Discovery for interpreting the sirtuin protein-interaction data obtained.

Published

2013