A major cause of cell death caused by genotoxic stress is thought to be due to the depletion of NAD(+) from the nucleus and the cytoplasm. Here we show that NAD(+) levels in mitochondria remain at physiological levels following genotoxic stress and can maintain cell viability even when nuclear and cytoplasmic pools of NAD(+) are depleted. Rodents fasted for 48 hr show increased levels of the NAD(+) biosynthetic enzyme Nampt and a concomitant increase in mitochondrial NAD(+). Increased Nampt provides protection against cell death and requires an intact mitochondrial NAD(+) salvage pathway as well as the mitochondrial NAD(+)-dependent deacetylases SIRT3 and SIRT4. We discuss the relevance of these findings to understanding how nutrition modulates physiology and to the evolution of apoptosis.
Nicotinamide adenine dinucleotide (NAD)؉ -dependent sirtuins have been identified to be key regulators in the lifespan extending effects of calorie restriction (CR) in a number of species. In this study we report for the first time that promotion of the NAD ؉ -dependent sirtuin, SIRT1-mediated deacetylase activity, may be a mechanism by which CR influences Alzheimer disease (AD)-type amyloid neuropathology. Most importantly, we report that the predicted attenuation of -amyloid content in the brain during CR can be reproduced in mouse neurons in vitro by manipulating cellular SIRT1 expression/activity through mechanisms involving the regulation of the serine/threonine Rho kinase ROCK1, known in part for its role in the inhibition of the non-amyloidogenic ␣-secretase processing of the amyloid precursor protein. Conversely, we found that the expression of constitutively active ROCK1 in vitro cultures significantly prevented SIRT1-mediated response, suggesting that ␣-secretase activity is required for SIRT1-mediated prevention of AD-type amyloid neuropathology. Consistently we found that the expression of exogenous human (h) SIRT1 in the brain of hSIRT1 transgenics also resulted in decreased ROCK1 expression and elevated ␣-secretase activity in vivo. These results demonstrate for the first time a role for SIRT1 activation in the brain as a novel mechanism through which CR may influence AD amyloid neuropathology. The study provides a potentially novel pharmacological strategy for AD prevention and/or treatment.Sirtuins are a family of NAD ϩ -dependent histone/protein deacetylases that are highly conserved in their catalytic domains and are distributed across all kingdoms of life (1-4). These enzymes utilize NAD ϩ as a substrate to catalyze deacetylation of specific acetylated-protein substrates (1, 5). Sirtuins can deacetylate a variety of substrates and are, therefore, involved in a broad range of physiological functions, including control of gene expression, metabolism, and aging (6). Accumulating evidence implicates sirtuins in calorie restriction (CR)-mediated health effects including increased organism longevity in yeast, worms, flies, and mammals (1-4, 6). Mammalian genomes encode seven distinct sirtuins (SIRT1-SIRT7). SIRT1 is induced by CR 4 in several tissues and has been implicated in various effects such as stress resistance, reduced apoptosis, and metabolic changes associated with CR (1). SIRT1 is also expressed in the developing and the adult mammalian brain (7). Based on these considerations and on the evidence that CR prevents AD-type amyloid neuropathology in animal models (8, 9), we sought to test the hypothesis that CR may reduce AD-type amyloid neuropathology through mechanisms involving promotion of SIRT1. The relevance of CR treatment in experimental models of AD to human pathology is supported by recent epidemiological evidence suggesting that humans who maintain a low calorie diet have a reduced risk of developing AD (10 -12).Abnormal A deposition within the brain is a hallmark of AD neuropat...
The NAD-dependent histone deacetylase Sir2 plays a key role in connecting cellular metabolism with gene silencing and aging. The androgen receptor (AR) is a ligand-regulated modular nuclear receptor governing prostate cancer cellular proliferation, differentiation, and apoptosis in response to androgens, including dihydrotestosterone (DHT). Here, SIRT1 antagonists induce endogenous AR expression and enhance DHTmediated AR expression. SIRT1 binds and deacetylates the AR at a conserved lysine motif. Human SIRT1 (hSIRT1) repression of DHT-induced AR signaling requires the NAD-dependent catalytic function of hSIRT1 and the AR lysine residues deacetylated by SIRT1. SIRT1 inhibited coactivator-induced interactions between the AR amino and carboxyl termini. DHT-induced prostate cancer cellular contact-independent growth is also blocked by SIRT1, providing a direct functional link between the AR, which is a critical determinant of progression of human prostate cancer, and the sirtuins.
In mammals, nicotinamide phosphoribosyltransferase (NAMPT) and nicotinamide mononucleotide adenylyltransferase 1 (NMNAT-1) constitute a nuclear NAD ؉ salvage pathway which regulates the functions of NAD ؉ -dependent enzymes such as the protein deacetylase SIRT1. One of the major functions of SIRT1 is to regulate target gene transcription through modification of chromatin-associated proteins. However, little is known about the molecular mechanisms by which NAD ؉ biosynthetic enzymes regulate SIRT1 activity to control gene transcription in the nucleus. In this study we show that stable short hairpin RNA-mediated knockdown of NAMPT or NMNAT-1 in MCF-7 breast cancer cells reduces total cellular NAD ؉ levels and alters global patterns of gene expression. Furthermore, we show that SIRT1 plays a key role in mediating the gene regulatory effects of NAMPT and NMNAT-1. Specifically, we found that SIRT1 binds to the promoters of genes commonly regulated by NAMPT, NMNAT-1, and SIRT1 and that SIRT1 histone deacetylase activity is regulated by NAMPT and NMNAT-1 at these promoters. Most significantly, NMNAT-1 interacts with, and is recruited to target gene promoters by SIRT1. Collectively, our results reveal a mechanism for the direct control of SIRT1 deacetylase activity at a set of target gene promoters by NMNAT-1. This mechanism, in collaboration with NAMPT-dependent regulation of nuclear NAD ؉ production, establishes an important pathway for transcription regulation by NAD ؉ .Nicotinamide adenine dinucleotide (NAD ϩ ), a coenzyme in metabolic processes and redox reactions, is an important signaling molecule. NAD ϩ is (i) a substrate for mono-and poly-ADP-ribosylation of proteins, (ii) required for NAD ϩ -dependent protein deacetylation, and (iii) a precursor for calcium mobilizing agents (1). As a signaling molecule, NAD ϩ is consumed as a donor of ADP-ribose, releasing nicotinamide (NAM) 2 as a byproduct. Consequently, resynthesis of NAD ϩ is crucial for maintaining the functions of a wide variety of NAD ϩ -dependent enzymes in the cytoplasm and nucleus. In mammalian cells the enzymes nicotinamide phosphoribosyltransferase (NAMPT) and nicotinamide mononucleotide adenylyltransferase (NMNAT) constitute an NAD ϩ salvage/ recycling pathway using NAM as the precursor (see Fig. 1A) (2). NAMPT, a unique enzyme encoded by a single gene, catalyzes the conversion of NAM to nicotinamide mononucleotide (NMN). NAMPT localizes to both the cytosol and nucleus (3, 4).3 Interestingly, an extracellular form of NAMPT has also been described, although controversy exists regarding its function (5, 6). NMN produced by NAMPT is further converted into NAD ϩ by NMNAT. Three NMNAT enzymes encoded by distinct genes are found in mammals (7-10). Among them, NMNAT-1 is localized exclusively in the nucleus, whereas NMNAT-2 and NMNAT-3 are found in the Golgi and mitochondria, respectively (11). In the nucleus, NAMPT and NMNAT-1 form a nuclear NAD ϩ salvage pathway that supplies NAD ϩ as a substrate for a variety of NAD ϩ -dependent enzymes, including th...
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