Molecular modeling study for conformational changes of Sirtuin 2 due to substrate and inhibitor binding

Sirtuin is a member of NAD⁺-dependent deacetylase family. The structural details of Sirtuin 2 (SIRT2) complex will be very useful to discover the drug which might have beneficial effects on various diseases like cancer, diabetes, etc. Unfortunately, SIRT2 complex structure is not available yet, hence molecular docking was carried out to dock the substrate (NAD⁺ and acetylated lysine) and inhibitor (sirtinol) in the NAD⁺ binding site. The suitable binding orientation of substrate and inhibitor in the SIRT2 active site was selected and subjected to 5?ns molecular dynamics simulations to adjust the binding orientation of inhibitor and substrate as well as to identify the conformational changes in the active site. The result provides an insight about 3D SIRT2 structural details as well as the importance of F96 in deacetylation function. In addition, our simulations revealed the displacement of F96 upon substrate and inhibitor binding, inducing an extended conformation of loop3 and changing its interactions with the rest of SIRT2. We believe that our study could be helpful to gain a structural insight of SIRT2 and to design the receptor-based inhibitors.     

Insight into the Mechanism of Intramolecular Inhibition of the Catalytic Activity of Sirtuin 2 (SIRT2)

Sirtuin 2 (SIRT2) is a NAD⁺-dependent deacetylase that has been associated with neurodegeneration and cancer. SIRT2 is composed of a central catalytic domain, the structure of which has been solved, and N- and C-terminal extensions that are thought to control SIRT2 function. However structural information of these N- and C-terminal regions is missing. Here, we provide the first full-length molecular models of SIRT2 in the absence and presence of NAD⁺. We also predict the structural alterations associated with phosphorylation of SIRT2 at S331, a modification that inhibits catalytic activity. Bioinformatics tools and molecular dynamics simulations, complemented by in vitro deacetylation assays, provide a consistent picture based on which the C-terminal region of SIRT2 is suggested to function as an autoinhibitory region. This has the capacity to partially occlude the NAD⁺ binding pocket or stabilize the NAD⁺ in a non-productive state. Furthermore, our simulations suggest that the phosphorylation at S331 causes large conformational changes in the C-terminal region that enhance the autoinhibitory activity, consistent with our previous findings that phosphorylation of S331 by cyclin-dependent kinases inhibits SIRT2 catalytic activity. The molecular insight into the role of the C-terminal region in controlling SIRT2 function described in this study may be useful for future design of selective inhibitors targeting SIRT2 for therapeutic applications.     

PARP-1 inhibition does not restore oxidant-mediated reduction in SIRT1 activity

Sirtuin1 (SIRT1) deacetylase and poly(ADP-ribose)-polymerase-1 (PARP-1) respond to environmental cues, and both require NAD⁺ cofactor for their enzymatic activities. However, the functional link between environmental/oxidative stress-mediated activation of PARP-1 and SIRT1 through NAD⁺ cofactor availability is not known. We investigated whether NAD⁺ depletion by PARP-1 activation plays a role in environmental stimuli/oxidant-induced reduction in SIRT1 activity. Both H₂O₂ and cigarette smoke (CS) decreased intracellular NAD⁺ levels in vitro in lung epithelial cells and in vivo in lungs of mice exposed to CS. Pharmacological PARP-1 inhibition prevented oxidant-induced NAD⁺ loss and attenuated loss of SIRT1 activity. Oxidants decreased SIRT1 activity in lung epithelial cells; however increasing cellular NAD⁺ cofactor levels by PARP-1 inhibition or NAD⁺ precursors was unable to restore SIRT1 activity. SIRT1 was found to be carbonylated by CS, which was not reversed by PARP-1 inhibition or selective SIRT1 activator. Overall, these data suggest that environmental/oxidant stress-induced SIRT1 down-regulation and PARP-1 activation are independent events despite both enzymes sharing the same cofactor.     

A fluorometric assay of SIRT1 deacetylation activity through quantification of nicotinamide adenine dinucleotide

Sirtuins are nicotinamide adenine dinucleotide (NAD⁺)-dependent deacetylases that catalyze the deacetylation of proteins such as histones and p53. A sensitive and convenient fluorometric assay for evaluating the SIRT1 enzymatic activity was developed here. Specifically, the remaining NAD⁺ after the deacetylation was determined by converting NAD⁺ to a highly fluorescent cyclized α-adduct compound. By this assay, we found that nicotinamide, Cu²⁺, and Zn²⁺ antagonize the activity of SIRT1. Resveratrol stimulates the enzymatic activity specifically with 7-amino-4-methylcoumarin (AMC)-labeled acetylated peptide. Epigallocatechin galate (EGCG) inhibits SIRT1 activity with both AMC-labeled and unlabeled peptide. However, a combination of vitamin C with EGCG can reverse the inhibition of EGCG with the unlabeled peptide or stimulate the deacetylation of AMC-labeled peptide by SIRT1. The assay does not require any isotopic material and thus is biologically safe. It can be adapted to a 96-well microplate for high-throughput screening. Notably, the acetylated peptides with or without fluorescent labels may be used in the assay, which facilitates the substrate specificity study of SIRT1 activators or inhibitors in vitro.     

Resveratrol attenuates excessive ethanol exposure-induced β-cell senescence in rats: A critical role for the NAD+/SIRT1-p38MAPK/p16 pathway

Resveratrol has been found to improve ethanol-induced diabetes. Although pancreatic β-cell senescence-induced β-cell mass loss plays a critical role in the progression of diabetes, the exact mechanism by which resveratrol improves ethanol-triggered β-cell senescence and its role in ethanol-induced diabetes remains unknown. Male Sprague-Dawley rats were fed either control or ethanol liquid diets containing 2.4 g/kg·bw ethanol with or without 100 mg/kg·bw resveratrol for 22 weeks. Resveratrol decreased the ethanol-induced augmentation in senescence-associated β-galactosidase (SA-β-gal)-positive area and attenuated reduction in β-cell mass, which were based on elevated levels of SIRT1 and proliferation marker Ki67 and reduced levels of senescence-associated markers (p-p38MAPK and p16^INK4a). Similarly, resveratrol rescued the reduction in NAD⁺/NADH ratio and SIRT1 and inhibited the upregulation of p-p38MAPK and p16^INK4a in ethanol-treated INS-1 cells. Furthermore, supplementation with NAD⁺ inducer nicotinamide mononucleotide, SIRT1 activator SRT1720 or p38MAPK inhibitor SB203580 effectively reversed ethanol-induced β-cell senescence, while supplementation with SIRT1 inhibitor Ex527 or NAD⁺ inhibitor FK866 abrogated resveratrol-mediated antisenescence effects in INS-1 cells. Together, our results indicate that resveratrol improves ethanol-triggered β-cell senescence and consequently recovers β-cell mass loss by inhibiting p38MAPK/p16 pathway through an NAD⁺/SIRT1 dependent pathway.     

SIRT2 induces the checkpoint kinase BubR1 to increase lifespan

Mice overexpressing the mitotic checkpoint kinase gene BubR1 live longer, whereas mice hypomorphic for BubR1 (BubR1^H/H) live shorter and show signs of accelerated aging. As wild‐type mice age, BubR1 levels decline in many tissues, a process that is proposed to underlie normal aging and age‐related diseases. Understanding why BubR1 declines with age and how to slow this process is therefore of considerable interest. The sirtuins (SIRT1‐7) are a family of NAD⁺‐dependent deacetylases that can delay age‐related diseases. Here, we show that the loss of BubR1 levels with age is due to a decline in NAD⁺ and the ability of SIRT2 to maintain lysine‐668 of BubR1 in a deacetylated state, which is counteracted by the acetyltransferase CBP. Overexpression of SIRT2 or treatment of mice with the NAD⁺ precursor nicotinamide mononucleotide (NMN) increases BubR1 abundance in vivo. Overexpression of SIRT2 in BubR1^H/H animals increases median lifespan, with a greater effect in male mice. Together, these data indicate that further exploration of the potential of SIRT2 and NAD⁺ to delay diseases of aging in mammals is warranted.     

NAD+ ameliorates endotoxin‐induced acute kidney injury in a sirtuin1–dependent manner via GSK‐3β/Nrf2 signalling pathway

Acute kidney injury (AKI) is a substantial worldwide public health concern with no specific and effective therapies in clinic. NAD⁺ is a pivotal determinant of cellular energy metabolism involved in the progression of AKI; however, its mechanism in kidney injury remains poorly understood. Sirtuin 1 (SIRT1) is an NAD⁺‐dependent deacetylase associated with renal protection and acute stress resistance. In this study, we have investigated the role of NAD⁺ in AKI and the potential mechanism(s) involved in its renoprotective effect. NAD⁺ was notably decreased and negatively correlated with kidney dysfunction in AKI, restoring NAD⁺ with NMN significantly ameliorates LPS‐induced oxidative stress and apoptosis and attenuates renal damage. We also found that the protection of NAD⁺ is associated with SIRT1 expressions and performs in a SIRT1‐dependent manner. Inhibition of SIRT1 blunted the protective effect of NAD⁺ and up‐regulated the activity of glycogen synthase kinase‐3β (GSK‐3β) that was concomitant with mitigated Nrf2 nuclear accumulation, thereby exacerbates AKI. These findings suggest that NAD⁺/SIRT1/GSK‐3β/Nrf2 axis is an important mechanism that can protect against AKI which might be a potential therapeutic target for the treatment of AKI.     

NAMPT maintains mitochondria content via NRF2-PPARα/AMPKα pathway to promote cell survival under oxidative stress

Mitochondria plays a key role in regulating cell death process under stress conditions and it has been indicated that NAMPT overexpression promotes cell survival under genotoxic stress by maintaining mitochondrial NAD⁺ level. NAMPT is a rate-limiting enzyme for NAD⁺ production in mammalian cells and it was suggested that NAMPT and NMNAT3 are responsible for mitochondrial NAD⁺ production to maintain mitochondrial NAD⁺ pool. However, subsequent studies suggested mitochondrial may lack the NAMPT-NMANT3 pathway to maintain NAD⁺ level. Therefore, how NAMPT overexpression rescues mitochondrial NAD⁺ content to promote cell survival in response to genotoxic stress remains elusive. Here, we show that NAMPT promotes cell survival under oxidative stress via both SIRT1 dependent p53-CD38 pathway and SIRT1 independent NRF2-PPARα/AMPKα pathway, and the NRF2-PPARα/AMPKα pathway plays a more profound role in facilitating cell survival than the SIRT1-p53-CD38 pathway does. Mitochondrial content and membrane potential were significantly reduced in response to H2O2 treatment, whereas activated NRF2-PPARα/AMPKα pathway by NAMPT overexpression rescued the mitochondrial membrane potential and content, suggesting that maintained mitochondrial content and integrity by NAMPT overexpression might be one of the key mechanisms to maintain mitochondrial NAD⁺ level and subsequently dictate cell survival under oxidative stress. Our results indicated that NRF2 is a novel down-stream target of NAMPT, which mediates anti-apoptosis function of NAMPT via maintaining mitochondrial content and membrane potential.     

NAD+-dependent Deacetylase SIRT3 Regulates Mitochondrial Protein Synthesis by Deacetylation of the Ribosomal Protein MRPL10

A member of the sirtuin family of NAD⁺-dependent deacetylases, SIRT3, is located in mammalian mitochondria and is important for regulation of mitochondrial metabolism, cell survival, and longevity. In this study, MRPL10 (mitochondrial ribosomal protein L10) was identified as the major acetylated protein in the mitochondrial ribosome. Ribosome-associated SIRT3 was found to be responsible for deacetylation of MRPL10 in an NAD⁺-dependent manner. We mapped the acetylated Lys residues by tandem mass spectrometry and determined the role of these residues in acetylation of MRPL10 by site-directed mutagenesis. Furthermore, we observed that the increased acetylation of MRPL10 led to an increase in translational activity of mitochondrial ribosomes in Sirt3^−/− mice. In a similar manner, ectopic expression and knockdown of SIRT3 in C2C12 cells resulted in the suppression and enhancement of mitochondrial protein synthesis, respectively. Our findings constitute the first evidence for the regulation of mitochondrial protein synthesis by the reversible acetylation of the mitochondrial ribosome and characterize MRPL10 as a novel substrate of the NAD⁺-dependent deacetylase, SIRT3.     

GABA protects pancreatic beta cells against apoptosis by increasing SIRT1 expression and activity

We have previously shown that GABA protects pancreatic islet cells against apoptosis and exerts anti-inflammatory effects. Notably, GABA inhibited the activation of NF-κB in both islet cells and lymphocytes. NF-κB activation is detrimental to beta cells by promoting apoptosis. However, the mechanisms by which GABA mediates these effects are unknown. Because the above-mentioned effects mimic the activity of sirtuin 1 (SIRT1) in beta cells, we investigated whether it is involved. SIRT1 is an NAD⁺-dependent deacetylase that enhances insulin secretion, and counteracts inflammatory signals in beta cells. We found that the incubation of a clonal beta-cell line (rat INS-1) with GABA increased the expression of SIRT1, as did GABA receptor agonists acting on either type A or B receptors. NAD⁺ (an essential cofactor of SIRT1) was also increased. GABA augmented SIRT1 enzymatic activity, which resulted in deacetylation of the p65 component of NF-κB, and this is known to interfere with the activation this pathway. GABA increased insulin production and reduced drug-induced apoptosis, and these actions were reversed by SIRT1 inhibitors. We examined whether SIRT1 is similarly induced in newly isolated human islet cells. Indeed, GABA increased both NAD⁺ and SIRT1 (but not sirtuins 2, 3 and 6). It protected human islet cells against spontaneous apoptosis in culture, and this was negated by a SIRT1 inhibitor. Thus, our findings suggest that major beneficial effects of GABA on beta cells are due to increased SIRT1 and NAD⁺, and point to a new pathway for diabetes therapy.     

Mechanism of Inhibition of the Human Sirtuin Enzyme SIRT3 by Nicotinamide: Computational and Experimental Studies

Sirtuins are key regulators of many cellular functions including cell growth, apoptosis, metabolism, and genetic control of age-related diseases. Sirtuins are themselves regulated by their cofactor nicotinamide adenine dinucleotide (NAD⁺) as well as their reaction product nicotinamide (NAM), the physiological concentrations of which vary during the process of aging. Nicotinamide inhibits sirtuins through the so-called base exchange pathway, wherein rebinding of the reaction product to the enzyme accelerates the reverse reaction. We investigated the mechanism of nicotinamide inhibition of human SIRT3, the major mitochondrial sirtuin deacetylase, in vitro and in silico using experimental kinetic analysis and Molecular Mechanics-Poisson Boltzmann/Generalized Born Surface Area (MM-PB(GB)SA) binding affinity calculations with molecular dynamics sampling. Through experimental kinetic studies, we demonstrate that NAM inhibition of SIRT3 involves apparent competition between the inhibitor and the enzyme cofactor NAD⁺, contrary to the traditional characterization of base exchange as noncompetitive inhibition. We report a model for base exchange inhibition that relates such kinetic properties to physicochemical properties, including the free energies of enzyme-ligand binding, and estimate the latter through the first reported computational binding affinity calculations for SIRT3:NAD⁺, SIRT3:NAM, and analogous complexes for Sir2. The computational results support our kinetic model, establishing foundations for quantitative modeling of NAD⁺/NAM regulation of mammalian sirtuins during aging and the computational design of sirtuin activators that operate through alleviation of base exchange inhibition.     

Fasting promotes the expression of SIRT1, an NAD+-dependent protein deacetylase, via activation of PPARα in mice

Calorie restriction (CR) extends lifespans in a wide variety of species. CR induces an increase in the NAD⁺/NADH ratio in cells and results in activation of SIRT1, an NAD⁺-dependent protein deacetylase that is thought to be a metabolic master switch linked to the modulation of lifespans. CR also affects the expression of peroxisome proliferator-activated receptors (PPARs). The three subtypes, PPARα, PPARγ, and PPARβ/δ, are expressed in multiple organs. They regulate different physiological functions such as energy metabolism, insulin action and inflammation, and apparently act as important regulators of longevity and aging. SIRT1 has been reported to repress the PPARγ by docking with its co-factors and to promote fat mobilization. However, the correlation between SIRT1 and other PPARs is not fully understood. CR initially induces a fasting-like response. In this study, we investigated how SIRT1 and PPARα correlate in the fasting-induced anti-aging pathways. A 24-h fasting in mice increased mRNA and protein expression of both SIRT1 and PPARα in the livers, where the NAD⁺ levels increased with increasing nicotinamide phosphoribosyltransferase (NAMPT) activity in the NAD⁺ salvage pathway. Treatment of Hepa1-6 cells in a low glucose medium conditions with NAD⁺ or NADH showed that the mRNA expression of both SIRT1 and PPARα can be enhanced by addition of NAD⁺, and decreased by increasing NADH levels. The cell experiments using SIRT1 antagonists and a PPARα agonist suggested that PPARα is a key molecule located upstream from SIRT1, and has a role in regulating SIRT1 gene expression in fasting-induced anti-aging pathways.     

Upregulation of SIRT1 deacetylase in phenylephrine-treated cardiomyoblasts

The sirtuin SIRT1 is an ubiquitous NAD⁺ dependent deacetylase that plays a role in biological processes such as longevity and stress response. In cardiac models, SIRT1 is associated to protection against many stresses. However, the link between SIRT1 and heart hypertrophy is complex and not fully understood. This study focuses specifically on the response of SIRT1 to the α-adrenergic agonist phenylephrine in H9c2 cardiac myoblasts, a cell model of cardiac hypertrophy. After 24 and 48 h of phenylephrine treatment, SIRT1 expression and deacetylase activity were significantly increased. SIRT1 upregulation by phenylephrine was not associated to changes in NAD⁺ levels, but was blocked by inhibitors of AMP-activated Protein Kinase (AMPK) or by AMPK knockdown by siRNA. When SIRT1 was inhibited with sirtinol or downregulated by siRNA, H9c2 cell viability was significantly decreased following phenylephrine treatment, showing that SIRT1 improves cell survival under hypertrophic stress. We so then propose that the increase in SIRT1 activity and expression in H9c2 cells treated with phenylephrine is an adaptive response to the hypertrophic stress, suggesting that adrenergic stimulation of heart cells activates hypertrophic programming and at the same time also promotes a self-protecting and self-regulating mechanism.     

Effect of surface electrostatic interactions on the stability and folding of formate dehydrogenase from Candida methylica

NAD⁺-dependent formate dehydrogenase (FDH-EC 1.2.1.2) is an important enzyme to regenerate valuable NADH required by NAD⁺-dependent oxidoreductases in enzyme catalysis. The limitation in the thermostability of FDH enzyme is a crucial problem for development of biotechnological and industrial processes, despite of its advantages. In this study, to investigate the contribution of surface electrostatic interaction to the thermostability of FDH from Candida methylica (cmFDH) N187E, H13E, Q105R, N300E, N147R N300E/N147R, N187E/Q105R, N187E/N147R,Y160R, Y302R, Y160E and Y302E mutants were designed using a homology model of cmFDH based on Candida boidinii (cb) by considering electrostatic interactions on the protein surface. The effects of site-specific engineering on the stability of this molecule was analyzed according to minimal model of folding and assembly reaction and deduced equilibrium properties of the native system with respect to its thermal and denaturant sensitivities. It was observed that mutations did not change the unfolding pattern of native cmFDH and increased numbers of electrostatic interactions can cause either stabilizing or destabilizing effect on the thermostability of this protein. The thermodynamic and kinetic results suggested that except relatively improved mutants, three out of the nine single mutations increased the melting temperature of cmFDH enzyme.     

Propofol Inhibits SIRT2 Deacetylase through a Conformation-specific,Allosteric Site

meta-Azi-propofol (AziPm) is a photoactive analog of the general anesthetic propofol. We photolabeled a myelin-enriched fraction from rat brain with [³H]AziPm and identified the sirtuin deacetylase SIRT2 as a target of the anesthetic. AziPm photolabeled three SIRT2 residues (Tyr¹³⁹, Phe¹⁹⁰, and Met²⁰⁶) that are located in a single allosteric protein site, and propofol inhibited [³H]AziPm photolabeling of this site in myelin SIRT2. Structural modeling and in vitro experiments with recombinant human SIRT2 determined that propofol and [³H]AziPm only bind specifically and competitively to the enzyme when co-equilibrated with other substrates, which suggests that the anesthetic site is either created or stabilized in enzymatic conformations that are induced by substrate binding. In contrast to SIRT2, specific binding of [³H]AziPm or propofol to recombinant human SIRT1 was not observed. Residues that line the propofol binding site on SIRT2 contact the sirtuin co-substrate NAD⁺ during enzymatic catalysis, and assays that measured SIRT2 deacetylation of acetylated α-tubulin revealed that propofol inhibits enzymatic function. We conclude that propofol inhibits the mammalian deacetylase SIRT2 through a conformation-specific, allosteric protein site that is unique from the previously described binding sites of other inhibitors. This suggests that propofol might influence cellular events that are regulated by protein acetylation state.     

Role of N-terminus in function and dynamics of sirtuin 7: an in silico study

Abstract

The sirtuin family comprises seven NAD⁺-dependent histone deacetylases named SIRT1 to SIRT7. The least investigated SIRT7 is currently considered as a promising therapeutic target for cardiovascular diseases, diabetes and different types of cancer. So far, its structure was not experimentally resolved, except of a fragment of its N-terminus. The aim of this study was to create in silico model of SIRT7 containing its core together with N-terminus, which is known to affect the enzyme’s catalytic activity and to find pockets that could be targeted by structure-based virtual screening. Homology model of SIRT7 was prepared using X-ray structures of other sirtuins and a resolved fragment of the N-terminus of SIRT7 as templates. All atom-unbiased molecular dynamics simulations were performed. It was found that N-terminus of SIRT7 remains in spatial proximity of the catalytic core for considerable fraction of time, and therefore, it may affect its catalytic activity by helping the enzyme to hold the substrate peptide. It may also participate in holding and release of the cofactor. Preferred orientations of NAD⁺?and acetyl-lysine inside SIRT7 were found, with all components forming a stable complex. Molecular dynamics provided an ensemble of conformations that will be targeted with virtual screening. Reliable in silico structure of SIRT7 will be a useful tool in searching for its inhibitors, which can be potential drugs in cancer treatment.

Communicated by Ramaswamy H. Sarma