The NAD(+)-dependent deacetylase SIRT2 attenuates oxidative stress and mitochondrial dysfunction and improves insulin sensitivity in hepatocytes

Vera Monica Lemos Da Silva
Oxford Univ Press, 2017
Article

Résumé

Insulin resistance is a major predictor of the development of metabolic disorders. Sirtuins (SIRTs) have emerged as potential targets that can be manipulated to counteract age-related diseases, including type 2 diabetes. SIRT2 has been recently shown to exert important metabolic effects, but whether SIRT2 regulates insulin sensitivity in hepatocytes is currently unknown. The aim of this study is to investigate this possibility and to elucidate underlying molecular mechanisms. Here, we show that SIRT2 is downregulated in insulin-resistant hepatocytes and livers, and this was accompanied by increased generation of reactive oxygen species, activation of stress-sensitive ERK1/2 kinase, and mitochondrial dysfunction. Conversely, SIRT2 overexpression in insulin-resistant hepatocytes improved insulin sensitivity, mitigated reactive oxygen species production and ameliorated mitochondrial dysfunction. Further analysis revealed a reestablishment of mitochondrial morphology, with a higher number of elongated mitochondria rather than fragmented mitochondria instigated by insulin resistance. Mechanistically, SIRT2 was able to increase fusion-related protein Mfn2 and decrease mitochondrial-associated Drp1. SIRT2 also attenuated the downregulation of TFAM, a key mtDNA-associated protein, contributing to the increase in mitochondrial mass. Importantly, we found that SIRT2 expression in PBMCs of human subjects was negatively correlated with obesity and insulin resistance. These results suggest a novel function for hepatic SIRT2 in the regulation of insulin sensitivity and raise the possibility that SIRT2 activators may offer novel opportunities for preventing or treating insulin resistance and type 2 diabetes.

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https://infoscience.epfl.ch/record/232182?ln=fr

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Vera Monica Lemos Da Silva
Oxford Univ Press, 2017
Article

Résumé

Official source

https://infoscience.epfl.ch/record/232182?ln=fr

À propos de ce résultat

Concepts associés (16)

Concepts associés

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Publications associées (84)

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The role of nicotinamide riboside kinases in mammalian NAD⁺ metabolism

Joanna Ratajczak

NAD+ has emerged as a central metabolic node and an important co-substrate for the activity of various enzymes, including the protein deacetylase SIRT1. Different strategies to increase NAD+ bioavailability have been shown to boost SIRT1 activity, which results in protection against metabolic disease, neurodegenerative disorders and certain types of cancer. Nicotinamide riboside (NR) and nicotinamide mononucleotide (NMN) have recently been discovered as new NAD+ precursors. Recent studies have shown that dietary supplementation with NR or NMN prevented against high-fat diet-induced body weight gain. However, the physiological role of NR in mammalian metabolism remains largely unexplored. In this project, we focused on the first step of NR metabolism â the phosphorylation of NR by nicotinamide riboside kinases (NRK1 and NRK2). We have investigated the role of NRKs in the metabolism of NAD+ precursors and mammalian physiology in vivo. The results obtained indicate that NRKs are the rate-limiting and essential step for NR- and NMN-driven NAD+ synthesis in hepatocytes and that NMN has to be extracellularly converted to NR for its use as an NAD+ precursor. Accordingly, animals lacking NRK1 have defects in NR/NMN utilization. We demonstrated that effective NR utilization is key for the maintenance of metabolic homeostasis as NRK1 whole-body KO mice display numerous alterations in glucose and lipid management. Using NRK1 liver-specific KO mice, we demonstrate that NRK1 is required to maintain hepatic NAD+ levels and mitochondrial function upon high-fat feeding. Consequently, NRK1LKO mice are sensitized to diet-induced glucose intolerance and insulin resistance. Finally, we show that both isoforms of NRK are redundant in mediating NR/NMN effects in muscle. Hence, this work identifies NRKs as a novel valuable target in the fight against metabolic disease and indicates that the regulation of NRK will enable us to find novel ways of enhancing NAD+ availability. Moreover, it has unveiled a critical role of NRK1 for the metabolism of diverse forms of Vitamin B3 and highlights how circulating NR is key to preserve metabolic health upon dietary challenges.

EPFL2017

Chargement

Hematopoietic stem cells (HSC) are responsible for the life-long maintenance of our blood system. Their long-term capacity to both self-renew and differentiate and the ability to efficiently âhomeâ to their bone marrow niches when injected in the blood stream, makes these rare cells ideal candidates for transplantation for the treatment of various blood cancers. However, countless attempts to expand HSC in vitro without losing their stem cell potential have failed, which is, to a large extent, linked to our poor understanding of the mechanisms that control HSC fate. Recent discoveries have revealed a crucial role of metabolism in controlling HSC function in vivo. However, because of major technical difficulties, we do not yet know the underlying mechanisms behind the metabolic control of HSC fate. Traditional, population-level experimental approaches link the fate of a stem cell to a cell surface protein expression phenotype. This method does not take into account the large heterogeneity of metabolic states in HSC. Consequently, to get mechanistic insights on HSC fate decision-making, metabolism must be studied at single cell level. Therefore, the overall goal of this thesis is to establish novel tools to study metabolic regulation of HSC at single cell level. Here we specifically focused on two functional metabolic read-outs, protein turnover and mitochondrial pH. Mitochondrial matrix pH is one of the most important functional parameters of mitochondria, as it is directly related to the efficiency of ATP production and thus reflects the metabolic state of the mitochondria. Here, a new ratiometric fluorescent probe, 5FA-PIP-Cy5-DA, able to reliably quantify mitochondrial pH, has been developed. It selectively accumulates in mitochondria of live cells and can be used to sensitively detect mitochondrial pH fluctuations upon various external stimuli. Spectral properties of 5FA-PIP-Cy5-DA allow it to be combined with the total mitochondrial membrane potential-dependent probes, enabling simultaneous imaging of total mitochondrial potential and mitochondrial pH. To complement the data on mitochondrial pH in live cells with an additional independent parameter of mitochondrial metabolism, a method of correlated TEM and nanoscale secondary ion mass-spectrometry (NanoSIMS) imaging was developed, that for the first time allows to study the subcellular protein turnover in single stem cells. Application of these novel tools to study HSC metabolism revealed a striking correlation between the levels of mitochondrial protein turnover and mitochondrial pH. This correlation reflects the burst in mitochondrial metabolism upon HSC activation. Intriguingly, an extreme burst in both mitochondrial pH alkalinization and protein turnover rate was observed for the most potent long-term HSC (LT-HSC) upon their activation and induction of differentiation. A new model is proposed to explain the link between the observed activation of mitochondrial protein structure reorganization and increase in mitochondrial pH level of LT-HSC undergoing differentiation. Finally, to demonstrate the broad range of applicability of the new mitochondrial pH probe, we applied it to measure the impact of anticancer treatment on mitochondrial metabolism in ovarian cancer cells exposed to two anticancer drugs, RAPTA-T and cis-platin. Distinctly different mitochondrial pH responses were measured for these two drugs, revealing alternative mechanisms behind their impact on mitochondria.

EPFL2018

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The mitochondrial unfolded protein response in mammalian physiology

Johan Auwerx, Virginija Jovaisaite, Adrienne Joëlle Laurence Mottis

Mitochondria, the main site of cellular energy harvesting, are derived from proteobacteria that evolved within our cells in endosymbiosis. Mitochondria retained vestiges of their proteobacterial genome, the circular mitochondrial DNA, which encodes 13 subunits of the oxidative phosphorylation multiprotein complexes in the electron transport chain (ETC), while the remaining similar to 80 ETC components are encoded in the nuclear DNA (nDNA). A further similar to 1,400 proteins, which are essential for mitochondrial function are also encoded in nDNA. Thus, a majority of mitochondrial proteins are translated in the cytoplasm, then imported, processed, and assembled in the mitochondria. An intricate protein quality control (PQC) network, constituted of chaperones and proteases that refold or degrade defective proteins, maintains mitochondrial proteostasis and ensures the cell and organism health. The mitochondrial unfolded protein response is a relatively recently discovered PQC pathway, which senses the proteostatic disturbances specifically in the mitochondria and resolves the stress by retrograde signaling to the nucleus and consequent transcriptional activation of protective genes. This PQC system does not only transiently resolve the local stress but also can have long-lasting effects on whole body metabolism, fitness, and longevity. A delicate tuning of its activation levels might constitute a treatment of various diseases, such as metabolic diseases, cancer, and neurodegenerative disorders.

Springer Verlag2014

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The role of nicotinamide riboside kinases in mammalian NAD⁺ metabolism

Joanna Ratajczak

EPFL2017

EPFL2018