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49 results on '"Chellappa, Karthikeyani"'

1. A subpopulation of lipogenic brown adipocytes drives thermogenic memory

Author

Lundgren, Patrick, Sharma, Prateek V., Dohnalová, Lenka, Coleman, Kyle, Uhr, Giulia T., Kircher, Susanna, Litichevskiy, Lev, Bahnsen, Klaas, Descamps, Hélène C., Demetriadou, Christina, Chan, Jacqueline, Chellappa, Karthikeyani, Cox, Timothy O., Heyman, Yael, Pather, Sarshan R., Shoffler, Clarissa, Petucci, Christopher, Shalem, Ophir, Raj, Arjun, Baur, Joseph A., Snyder, Nathaniel W., Wellen, Kathryn E., Levy, Maayan, Seale, Patrick, Li, Mingyao, and Thaiss, Christoph A.

Published
2023
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3. A microbiome-dependent gut–brain pathway regulates motivation for exercise

Author

Dohnalová, Lenka, Lundgren, Patrick, Carty, Jamie R. E., Goldstein, Nitsan, Wenski, Sebastian L., Nanudorn, Pakjira, Thiengmag, Sirinthra, Huang, Kuei-Pin, Litichevskiy, Lev, Descamps, Hélène C., Chellappa, Karthikeyani, Glassman, Ana, Kessler, Susanne, Kim, Jihee, Cox, Timothy O., Dmitrieva-Posocco, Oxana, Wong, Andrea C., Allman, Erik L., Ghosh, Soumita, Sharma, Nitika, Sengupta, Kasturi, Cornes, Belinda, Dean, Nitai, Churchill, Gary A., Khurana, Tejvir S., Sellmyer, Mark A., FitzGerald, Garret A., Patterson, Andrew D., Baur, Joseph A., Alhadeff, Amber L., Helfrich, Eric J. N., Levy, Maayan, Betley, J. Nicholas, and Thaiss, Christoph A.

Published
2022
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4. NAD precursors cycle between host tissues and the gut microbiome

Author

Chellappa, Karthikeyani, McReynolds, Melanie R., Lu, Wenyun, Zeng, Xianfeng, Makarov, Mikhail, Hayat, Faisal, Mukherjee, Sarmistha, Bhat, Yashaswini R., Lingala, Siddharth R., Shima, Rafaella T., Descamps, Hélène C., Cox, Timothy, Ji, Lixin, Jankowski, Connor, Chu, Qingwei, Davidson, Shawn M., Thaiss, Christoph A., Migaud, Marie E., Rabinowitz, Joshua D., and Baur, Joseph A.

Published
2022
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5. NAD+ flux is maintained in aged mice despite lower tissue concentrations

Author

McReynolds, Melanie R., Chellappa, Karthikeyani, Chiles, Eric, Jankowski, Connor, Shen, Yihui, Chen, Li, Descamps, Hélène C., Mukherjee, Sarmistha, Bhat, Yashaswini R., Lingala, Siddharth R., Chu, Qingwei, Botolin, Paul, Hayat, Faisal, Doke, Tomohito, Susztak, Katalin, Thaiss, Christoph A., Lu, Wenyun, Migaud, Marie E., Su, Xiaoyang, Rabinowitz, Joshua D., and Baur, Joseph A.

Published
2021
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6. Opposing roles of nuclear receptor HNF4α isoforms in colitis and colitis-associated colon cancer.

Author

Chellappa, Karthikeyani, Deol, Poonamjot, Evans, Jane R, Vuong, Linh M, Chen, Gang, Briançon, Nadege, Bolotin, Eugene, Lytle, Christian, Nair, Meera G, and Sladek, Frances M

Subjects
Animals, Colitis: complications, pathology, Colonic Neoplasms: pathology, Disease Models, Animal, Hepatocyte Nuclear Factor 4: analysis, Mice, Protein Isoforms: analysis
Abstract

HNF4α has been implicated in colitis and colon cancer in humans but the role of the different HNF4α isoforms expressed from the two different promoters (P1 and P2) active in the colon is not clear. Here, we show that P1-HNF4α is expressed primarily in the differentiated compartment of the mouse colonic crypt and P2-HNF4α in the proliferative compartment. Exon swap mice that express only P1- or only P2-HNF4α have different colonic gene expression profiles, interacting proteins, cellular migration, ion transport and epithelial barrier function. The mice also exhibit altered susceptibilities to experimental colitis (DSS) and colitis-associated colon cancer (AOM+DSS). When P2-HNF4α-only mice (which have elevated levels of the cytokine resistin-like β, RELMβ, and are extremely sensitive to DSS) are crossed with Retnlb(-/-) mice, they are rescued from mortality. Furthermore, P2-HNF4α binds and preferentially activates the RELMβ promoter. In summary, HNF4α isoforms perform non-redundant functions in the colon under conditions of stress, underscoring the importance of tracking them both in colitis and colon cancer.

Published
2016

8. CD38 ecto-enzyme in immune cells is induced during aging and regulates NAD+ and NMN levels

Author

Chini, Claudia C. S., Peclat, Thais R., Warner, Gina M., Kashyap, Sonu, Espindola-Netto, Jair Machado, de Oliveira, Guilherme C., Gomez, Lilian S., Hogan, Kelly A., Tarragó, Mariana G., Puranik, Amrutesh S., Agorrody, Guillermo, Thompson, Katie L., Dang, Kevin, Clarke, Starlynn, Childs, Bennett G., Kanamori, Karina S., Witte, Micaela A., Vidal, Paola, Kirkland, Anna L., De Cecco, Marco, Chellappa, Karthikeyani, McReynolds, Melanie R., Jankowski, Connor, Tchkonia, Tamara, Kirkland, James L., Sedivy, John M., van Deursen, Jan M., Baker, Darren J., van Schooten, Wim, Rabinowitz, Joshua D., Baur, Joseph A., and Chini, Eduardo N.

Published
2020
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9. Differential Effects of Hepatocyte Nuclear Factor 4α Isoforms on Tumor Growth and T-Cell Factor 4/AP-1 Interactions in Human Colorectal Cancer Cells

Author

Vuong, Linh M, Chellappa, Karthikeyani, Dhahbi, Joseph M, Deans, Jonathan R, Fang, Bin, Bolotin, Eugene, Titova, Nina V, Hoverter, Nate P, Spindler, Stephen R, Waterman, Marian L, and Sladek, Frances M

Subjects
Biochemistry and Cell Biology, Bioinformatics and Computational Biology, Biological Sciences, Biomedical and Clinical Sciences, Genetics, Oncology and Carcinogenesis, Cancer, Colo-Rectal Cancer, Digestive Diseases, Biotechnology, Human Genome, Cancer Genomics, 2.1 Biological and endogenous factors, Animals, Base Sequence, Binding, Competitive, Colorectal Neoplasms, Consensus Sequence, Gene Expression Regulation, Neoplastic, Gene Ontology, HCT116 Cells, Hepatocyte Nuclear Factor 1-alpha, Hepatocyte Nuclear Factor 4, Humans, Male, Mice, Nude, Neoplasm Transplantation, Polymorphism, Single Nucleotide, Protein Binding, Protein Isoforms, Transcription Factor AP-1, Transcriptome, Tumor Burden, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences, Health sciences
Abstract

The nuclear receptor hepatocyte nuclear factor 4α (HNF4α) is tumor suppressive in the liver but amplified in colon cancer, suggesting that it also might be oncogenic. To investigate whether this discrepancy is due to different HNF4α isoforms derived from its two promoters (P1 and P2), we generated Tet-On-inducible human colon cancer (HCT116) cell lines that express either the P1-driven (HNF4α2) or P2-driven (HNF4α8) isoform and analyzed them for tumor growth and global changes in gene expression (transcriptome sequencing [RNA-seq] and chromatin immunoprecipitation sequencing [ChIP-seq]). The results show that while HNF4α2 acts as a tumor suppressor in the HCT116 tumor xenograft model, HNF4α8 does not. Each isoform regulates the expression of distinct sets of genes and recruits, colocalizes, and competes in a distinct fashion with the Wnt/β-catenin mediator T-cell factor 4 (TCF4) at CTTTG motifs as well as at AP-1 motifs (TGAXTCA). Protein binding microarrays (PBMs) show that HNF4α and TCF4 share some but not all binding motifs and that single nucleotide polymorphisms (SNPs) in sites bound by both HNF4α and TCF4 can alter binding affinity in vitro, suggesting that they could play a role in cancer susceptibility in vivo. Thus, the HNF4α isoforms play distinct roles in colon cancer, which could be due to differential interactions with the Wnt/β-catenin/TCF4 and AP-1 pathways.

Published
2015

10. Long-Term NMN Treatment Increases Lifespan and Healthspan in Mice in a Sex Dependent Manner

Author

Kane, Alice E., primary, Chellappa, Karthikeyani, additional, S, M, additional, Arnold, Matthew, additional, Li, Jien, additional, Amorim, Joao A., additional, Diener, Christian, additional, Zhu, Dantong, additional, Mitchell, Sarah J., additional, Griffin, Patrick, additional, Tian, Xiao, additional, Petty, Christopher, additional, Conway, Ryan J., additional, Walsh, Katie, additional, Shelerud, Lukas, additional, Duesing, Charlotte, additional, Mueller, Amber, additional, Li, Karlin, additional, McNamara, Maeve S., additional, Shima, Rafaella T., additional, Mitchell, James R., additional, Bonkowski, Michael S., additional, De Cabo, Rafael, additional, Gibbons, Sean, additional, Wu, Lindsay, additional, Ikeno, Yuji, additional, Baur, Joseph A., additional, Rajman, Luis A., additional, and Sinclair, David A., additional

Published
2024
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12. Quantitative Analysis of NAD Synthesis-Breakdown Fluxes

Author

Liu, Ling, Su, Xiaoyang, Quinn, William J., III, Hui, Sheng, Krukenberg, Kristin, Frederick, David W., Redpath, Philip, Zhan, Le, Chellappa, Karthikeyani, White, Eileen, Migaud, Marie, Mitchison, Timothy J., Baur, Joseph A., and Rabinowitz, Joshua D.

Published
2018
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15. Nuclear Receptor HNF4alpha Binding Sequences are Widespread in Alu Repeats

Author

Bolotin, Eugene, Chellappa, Karthikeyani, Hwang-Verslues, Wendy, Schnabl, Jake M, Yang, Chuhu, and Sladek, Frances M

Abstract

Abstract Background Alu repeats, which account for ~10% of the human genome, were originally considered to be junk DNA. Recent studies, however, suggest that they may contain transcription factor binding sites and hence possibly play a role in regulating gene expression. Results Here, we show that binding sites for a highly conserved member of the nuclear receptor superfamily of ligand-dependent transcription factors, hepatocyte nuclear factor 4alpha (HNF4α, NR2A1), are highly prevalent in Alu repeats. We employ high throughput protein binding microarrays (PBMs) to show that HNF4α binds > 66 unique sequences in Alu repeats that are present in ~1.2 million locations in the human genome. We use chromatin immunoprecipitation (ChIP) to demonstrate that HNF4α binds Alu elements in the promoters of target genes (ABCC3, APOA4, APOM, ATPIF1, CANX, FEMT1A, GSTM4, IL32, IP6K2, PRLR, PRODH2, SOCS2, TTR) and luciferase assays to show that at least some of those Alu elements can modulate HNF4α-mediated transactivation in vivo (APOM, PRODH2, TTR, APOA4). HNF4α-Alu elements are enriched in promoters of genes involved in RNA processing and a sizeable fraction are in regions of accessible chromatin. Comparative genomics analysis suggests that there may have been a gain in HNF4α binding sites in Alu elements during evolution and that non Alu repeats, such as Tiggers, also contain HNF4α sites. Conclusions Our findings suggest that HNF4α, in addition to regulating gene expression via high affinity binding sites, may also modulate transcription via low affinity sites in Alu repeats.

Published
2011

16. Loss of NAD Homeostasis Leads to Progressive and Reversible Degeneration of Skeletal Muscle

Author

Frederick, David W., Loro, Emanuele, Liu, Ling, Davila, Antonio, Jr., Chellappa, Karthikeyani, Silverman, Ian M., Quinn, William J., III, Gosai, Sager J., Tichy, Elisia D., Davis, James G., Mourkioti, Foteini, Gregory, Brian D., Dellinger, Ryan W., Redpath, Philip, Migaud, Marie E., Nakamaru-Ogiso, Eiko, Rabinowitz, Joshua D., Khurana, Tejvir S., and Baur, Joseph A.

Published
2016
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19. The 2021 FASEB science research conference on NAD metabolism and signaling

Author

Gorbunova, Vera, primary, Buschbeck, Marcus, additional, Cambronne, Xiaolu A., additional, Chellappa, Karthikeyani, additional, Corda, Daniela, additional, Du, Juan, additional, Freichel, Marc, additional, Gigas, Jonathan, additional, Green, Alexander E., additional, Gu, Feng, additional, Guberovic, Iva, additional, Jayabalan, Aravinthkumar, additional, Khansahib, Imrankhan, additional, Mukherjee, Sarmistha, additional, Seluanov, Andrei, additional, Simon, Matthew A., additional, Sverkeli, Lars J., additional, Kory, Nora, additional, Levine, Daniel C., additional, Matic, Ivan, additional, Nikiforov, Andrey, additional, Rack, Johannes G. M., additional, Imai, Shin-Ichiro, additional, Sinclair, David A., additional, Toiber, Debra, additional, Zhao, Yongjuan, additional, Mostoslavsky, Raul, additional, Kraus, Lee, additional, and Guse, Andreas H., additional

Published
2021
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20. NAD precursors cycle between host tissues and the gut microbiome

Author

Chellappa, Karthikeyani, primary, McReynolds, Melanie R., additional, Lu, Wenyun, additional, Zeng, Xianfeng, additional, Makarov, Mikhail, additional, Hayat, Faisal, additional, Mukherjee, Sarmistha, additional, Bhat, Yashaswini R., additional, Lingala, Siddharth R., additional, Shima, Rafaella T., additional, Descamps, Hélène C., additional, Cox, Timothy, additional, Ji, Lixin, additional, Jankowski, Connor, additional, Chu, Qingwei, additional, Davidson, Shawn M., additional, Thaiss, Christoph A., additional, Migaud, Marie E., additional, Rabinowtiz, Joshua D., additional, and Baur, Joseph A., additional

Published
2021
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21. Meeting Report The 2021 FASEB science research conference on NAD metabolism and signaling

Author

Gorbunova, Vera, Buschbeck, Marcus, Cambronne, Xiaolu A., Chellappa, Karthikeyani, Corda, Daniela, Du, Juan, Freichel, Marc, Gigas, Jonathan, Green, Alexander E., Gu, Feng, Guberovic, Iva, Jayabalan, Aravinthkumar, Khansahib, Imrankhan, Mukherjee, Sarmistha, Seluanov, Andrei, Simon, Matthew A., Sverkeli, Lars J., Kory, Nora, Levine, Daniel C., Ivan Matic, Nikiforov, Andrey, Rack, Johannes G. M., Imai, Shin-Ichiro, Sinclair, David A., Toiber, Debra, Zhao, Yongjuan, Mostoslavsky, Raul, Kraus, Lee, and Guse, Andreas H.

Subjects
aging, Correspondence Gorbunova, Sirtuins, NAD, signaling, Guse, metabolism, PARP
Published
2021

24. NAD+ flux is maintained in aged mice

Author

McReynolds, Melanie, primary, Chellappa, Karthikeyani, additional, Chiles, Eric, additional, Jankowski, Connor, additional, Shen, Yishui, additional, Chen, Li, additional, Descamps, Helene, additional, Mukherjee, Sarmistha, additional, Bhat, Yashaswini, additional, Chu, Qingwei, additional, Botolin, Paul, additional, Thaiss, Cristoph, additional, Lu, Wenyun, additional, Su, Xiaoyang, additional, Rabinowitz, Joshua, additional, and Baur, Joseph, additional

Published
2020
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25. Rapamycin maintains NAD+/NADH redox homeostasis in muscle cells

Author

Zhang, Zhigang, primary, Xu, He N., additional, Li, Siyu, additional, Jr, Antonio Davila, additional, Chellappa, Karthikeyani, additional, Davis, James G., additional, Guan, Yuxia, additional, Frederick, David W., additional, Chu, Weiqing, additional, Zhao, Huaqing, additional, Li, Lin Z., additional, and Baur, Joseph A., additional

Published
2020
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29. Mitochondrial NAD Transport

Author

Baur, Joseph A., primary, Luongo, Timothy, additional, Mukherjee, Sarmistha, additional, Eller, Jared, additional, Chellappa, Karthikeyani, additional, Lu, Mu-Jie, additional, and Cambronne, Lulu, additional

Published
2020
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31. Hypothalamic mTORC2 is essential for metabolic health and longevity

Author

Chellappa, Karthikeyani, primary, Brinkman, Jacqueline A., additional, Mukherjee, Sarmistha, additional, Morrison, Mark, additional, Alotaibi, Mohammed I., additional, Carbajal, Kathryn A., additional, Alhadeff, Amber L., additional, Perron, Isaac J., additional, Yao, Rebecca, additional, Purdy, Cole S., additional, DeFelice, Denise M., additional, Wakai, Matthew H., additional, Tomasiewicz, Jay, additional, Lin, Amy, additional, Meyer, Emma, additional, Peng, Yajing, additional, Arriola Apelo, Sebastian I., additional, Puglielli, Luigi, additional, Betley, J. Nicholas, additional, Paschos, Georgios K., additional, Baur, Joseph A., additional, and Lamming, Dudley W., additional

Published
2019
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Author

Chellappa, Karthikeyani, Chellappa, Karthikeyani, Deol, Poonamjot, Evans, Jane R, Vuong, Linh M, Chen, Gang, Briançon, Nadege, Bolotin, Eugene, Lytle, Christian, Nair, Meera G, Sladek, Frances M, Chellappa, Karthikeyani, Chellappa, Karthikeyani, Deol, Poonamjot, Evans, Jane R, Vuong, Linh M, Chen, Gang, Briançon, Nadege, Bolotin, Eugene, Lytle, Christian, Nair, Meera G, and Sladek, Frances M

Published
2016

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Author

Chellappa, Karthikeyani, Chellappa, Karthikeyani, Deol, Poonamjot, Evans, Jane R, Vuong, Linh M, Chen, Gang, Briançon, Nadege, Bolotin, Eugene, Lytle, Christian, Nair, Meera G, Sladek, Frances M, Chellappa, Karthikeyani, Chellappa, Karthikeyani, Deol, Poonamjot, Evans, Jane R, Vuong, Linh M, Chen, Gang, Briançon, Nadege, Bolotin, Eugene, Lytle, Christian, Nair, Meera G, and Sladek, Frances M

Published
2016

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Author

Vuong, Linh M, Vuong, Linh M, Chellappa, Karthikeyani, Dhahbi, Joseph M, Deans, Jonathan R, Fang, Bin, Bolotin, Eugene, Titova, Nina V, Hoverter, Nate P, Spindler, Stephen R, Waterman, Marian L, Sladek, Frances M, Vuong, Linh M, Vuong, Linh M, Chellappa, Karthikeyani, Dhahbi, Joseph M, Deans, Jonathan R, Fang, Bin, Bolotin, Eugene, Titova, Nina V, Hoverter, Nate P, Spindler, Stephen R, Waterman, Marian L, and Sladek, Frances M

Published
2015

46. NAD+flux is maintained in aged mice despite lower tissue concentrations

Author

McReynolds, Melanie R., Chellappa, Karthikeyani, Chiles, Eric, Jankowski, Connor, Shen, Yihui, Chen, Li, Descamps, Hélène C., Mukherjee, Sarmistha, Bhat, Yashaswini R., Lingala, Siddharth R., Chu, Qingwei, Botolin, Paul, Hayat, Faisal, Doke, Tomohito, Susztak, Katalin, Thaiss, Christoph A., Lu, Wenyun, Migaud, Marie E., Su, Xiaoyang, Rabinowitz, Joshua D., and Baur, Joseph A.

Abstract

NAD+is an essential coenzyme for all living cells. NAD+concentrations decline with age, but whether this reflects impaired production or accelerated consumption remains unclear. We employed isotope tracing and mass spectrometry to probe age-related changes in NAD+metabolism across tissues. In aged mice, we observed modest tissue NAD+depletion (median decrease ∼30%). Circulating NAD+precursors were not significantly changed, and isotope tracing showed the unimpaired synthesis of nicotinamide from tryptophan. In most tissues of aged mice, turnover of the smaller tissue NAD+pool was modestly faster such that absolute NAD+biosynthetic flux was maintained, consistent with more active NAD+-consuming enzymes. Calorie restriction partially mitigated age-associated NAD+decline by decreasing consumption. Acute inflammatory stress induced by LPS decreased NAD+by impairing synthesis in both young and aged mice. Thus, the decline in NAD+with normal aging is relatively subtle and occurs despite maintained NAD+production, likely due to increased consumption.

Published
2021
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47. Abstract 13461: Severe, but Not Mild Decreases in Nicotinamide Adenine Dinucleotide (NAD) Cause Heart Failure

Author

Luongo, Timothy S, Wang, Lin, Chellappa, Karthikeyani, McReynolds, Melanie R, Kelly, Daniel P, Rabinowitz, Joshua D, and Baur, Joseph A

Abstract

Nicotinamide adenine dinucleotide (NAD) plays essential roles in energy metabolism and cell signaling pathways. NAD functions as a coenzyme by accepting electrons during glycolysis and the TCA cycle and subsequently donates them to complex I of the electron transport chain providing the driving force for ATP production. NAD also acts as a co-substrate for several classes of enzymes, including sirtuin deacetylases. Both NAD and the enzyme that is rate limiting for synthesis, Nicotinamide phosphoribosyltransferase (Nampt), are depleted in the failing heart, concurrent with hyperacetylation and mitochondrial dysfunction. Moreover, treatment with NAD precursors reduced cardiac injury in several heart failure models. However, NAD precursors may have systemic effects, and it remains unproven whether depletion of myocardial NAD is causative or merely correlative for the onset and progression of heart failure. To test this, we generated a cardiac-specific tamoxifen-inducible (?MHC-MerCreMer) model for deletion of Nampt (Nampt cKO) in cardiomyocytes. Adult mice were administered tamoxifen for 5 days leading to deletion of Nampt, resulting in a 72% reduction in myocardial NAD after two-weeks. Echocardiography revealed that Nampt cKO mice displayed a significant reduction in left ventricular (LV) contractility as well as cardiac hypertrophy. Despite the further loss of NAD, the majority of animals survived to 8 weeks of age before experiencing sudden deaths resulting in 100% mortality over the next several weeks. Remarkably, we observed only a modest increase in acetylation of mitochondrial proteins, and cardiac mitochondria isolated from Nampt-null mice even at 8 weeks displayed a normal or higher oxygen consumption rate. We found that mitochondrial NAD levels were preferentially maintained and depleted at a slower rate compared to those in bulk tissue. Restoring NAD levels with a single intravenous bolus of nicotinamide riboside substantially extended the survival of these mice, suggesting that NAD half-life can be quite long when the supply is limited. While mild depletion of cardiac NAD has been reported in heart failure, our data indicate that the heart can adapt to much more severe loss of NAD prior to the loss of viability.

Published
2019
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48. Long-term NMN treatment increases lifespan and healthspan in mice in a sex dependent manner.

Author

Kane AE, Chellappa K, Schultz MB, Arnold M, Li J, Amorim J, Diener C, Zhu D, Mitchell SJ, Griffin P, Tian X, Petty C, Conway R, Walsh K, Shelerud L, Duesing C, Mueller A, Li K, McNamara M, Shima RT, Mitchell J, Bonkowski MS, de Cabo R, Gibbons SM, Wu LE, Ikeno Y, Baur JA, Rajman L, and Sinclair DA

Abstract

Nicotinamide adenine dinucleotide (NAD) is essential for many enzymatic reactions, including those involved in energy metabolism, DNA repair and the activity of sirtuins, a family of defensive deacylases. During aging, levels of NAD + can decrease by up to 50% in some tissues, the repletion of which provides a range of health benefits in both mice and humans. Whether or not the NAD + precursor nicotinamide mononucleotide (NMN) extends lifespan in mammals is not known. Here we investigate the effect of long-term administration of NMN on the health, cancer burden, frailty and lifespan of male and female mice. Without increasing tumor counts or severity in any tissue, NMN treatment of males and females increased activity, maintained more youthful gene expression patterns, and reduced overall frailty. Reduced frailty with NMN treatment was associated with increases in levels of Anerotruncus colihominis, a gut bacterium associated with lower inflammation in mice and increased longevity in humans. NMN slowed the accumulation of adipose tissue later in life and improved metabolic health in male but not female mice, while in females but not males, NMN increased median lifespan by 8.5%, possible due to sex-specific effects of NMN on NAD + metabolism. Together, these data show that chronic NMN treatment delays frailty, alters the microbiome, improves male metabolic health, and increases female mouse lifespan, without increasing cancer burden. These results highlight the potential of NAD + boosters for treating age-related conditions and the importance of using both sexes for interventional lifespan studies.

Published
2024
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49. Rapamycin maintains NAD + /NADH redox homeostasis in muscle cells.

Author

Zhang Z, Xu HN, Li S, Jr AD, Chellappa K, Davis JG, Guan Y, Frederick DW, Chu W, Zhao H, Li LZ, and Baur JA

Abstract

Rapamycin delays multiple age-related conditions and extends lifespan in organisms ranging from yeast to mice. However, the mechanisms by which rapamycin influences longevity are incompletely understood. The objective of this study was to investigate the effect of rapamycin on NAD + /NADH redox balance. We report that the NAD + /NADH ratio of C2C12 myoblasts or differentiated myotubes significantly decreases over time in culture, and that rapamycin prevents this effect. Despite lowering the NADH available to support ATP generation, rapamycin increases ATP availability, consistent with lowering energetic demand. Although rapamycin did not change the NAD + /NADH ratio or steady-state ATP concentration in the livers, kidneys, or muscles of young mice, optical redox imaging revealed that rapamycin caused a substantial decline in the NADH content and an increase in the optical redox ratio (a surrogate of NAD + /NADH redox ratio) in muscles from aged mice. Collectively, these data suggest that rapamycin favors a more oxidized NAD + /NADH ratio in aged muscle, which may influence metabolism and the activity of NAD + -dependent enzymes. This study provides new insight into the mechanisms by which rapamycin might influence the aging process to improve health and longevity among the aging population.

Published
2020
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