Kinetic and Structural Basis for Acyl-Group Selectivity and NAD<sup>+</sup> Dependence in Sirtuin-Catalyzed Deacylation

Feldman, Jessica L.; Dittenhafer‐Reed, Kristin E.; Kudo, Norio; Thelen, Julie N.; Ito, Akihiro; Yoshida, Minoru; Denu, John M.

doi:10.1021/acs.biochem.5b00150

Cited by 162 publications

(240 citation statements)

References 49 publications

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“…These findings are in keeping with the presence of nuclear metabolic territories as recently predicted (41,42) and prompted us to investigate whether nuclear NADH distribution could be influenced by SIRT1. Importantly, the K m of SIRT1 for NAD + seems to fall into the physiological range of NAD + bioavailability in the nucleus (43).…”

Section: Resultsmentioning

confidence: 99%

Spatial dynamics of SIRT1 and the subnuclear distribution of NADH species

Aguilar-Arnal

Ranjit

Stringari

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Sirtuin 1 (SIRT1) is an NAD + -dependent deacetylase that functions as metabolic sensor of cellular energy and modulates biochemical pathways in the adaptation to changes in the environment. SIRT1 substrates include histones and proteins related to enhancement of mitochondrial function as well as antioxidant protection. Fluctuations in intracellular NAD + levels regulate SIRT1 activity, but how SIRT1 enzymatic activity impacts on NAD + levels and its intracellular distribution remains unclear. Here, we show that SIRT1 determines the nuclear organization of protein-bound NADH. Using multiphoton microscopy in live cells, we show that free and bound NADH are compartmentalized inside of the nucleus, and its subnuclear distribution depends on SIRT1. Importantly, SIRT6, a chromatin-bound deacetylase of the same class, does not influence NADH nuclear localization. In addition, using fluorescence fluctuation spectroscopy in single living cells, we reveal that NAD + metabolism in the nucleus is linked to subnuclear dynamics of active SIRT1. These results reveal a connection between NAD + metabolism, NADH distribution, and SIRT1 activity in the nucleus of live cells and pave the way to decipher links between nuclear organization and metabolism.S irtuins (SIRTs) are a conserved family of deacetylases that target a variety of proteins located in virtually all cellular compartments (1). Deacetylation by SIRTs may control many functional aspects of target proteins (2). Because SIRT deacetylase activity depends on the energy carrier NAD + , these enzymes are thought to operate as cellular metabolic sensors. In addition, because histones are targeted by nuclear SIRT, these enzymes could link variations in cellular metabolism to chromatin function.There are seven mammalian SIRTs (SIRT1 to SIRT7) with distinct subcellular locations. SIRT2 is mainly cytoplasmic; SIRT3, SIRT4, and SIRT5 are found in the mitochondrial compartment; and SIRT1, SIRT6, and SIRT7 are located in the cell nucleus (1). In mammals, SIRT1 contributes to development and protects from metabolic and cardiovascular disease, neurodegeneration, and cancer (3). SIRT1 has been reported to promote healthy aging and regulate lifespan (4, 5). At the cellular level, SIRT1 regulates lipid and glucose homeostasis, apoptosis, DNA repair, and mitochondrial function. Variations in NAD + levels control SIRT1 activity (6-9), a relevant finding in the regulation of circadian rhythms (10). Circadian rhythms in NAD + levels have been observed (11,12), which lead to fluctuating SIRT1 deacetylase activity (9) that, in turn, results into cyclic acetylation of specific SIRT1 targets (6, 9, 13). SIRT1 and SIRT6 segregate circadian metabolism by driving transcription of a differential subset of circadian genes (14). SIRT6 is a chromatinbound protein that was first characterized as a regulator of genome stability (15). The other nuclear SIRT, SIRT7, appears to be highly localized in the nucleolus and possibly involved in Pol-I-dependent transcription (16), and it has been shown to regula...

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Section: Resultsmentioning

confidence: 99%

Spatial dynamics of SIRT1 and the subnuclear distribution of NADH species

Aguilar-Arnal

Ranjit

Stringari

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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“…Molecular Modeling; Structural Basis for Deacylation and NADH Inhibition-The findings that SIRT1-3 and SIRT6 can remove long-chain acyl groups prompted us to investigate the molecular basis for accommodation of long acyl-amide substrates in the active sites of sirtuins 1-3 and 6. The active sites of SIRT2 and -6 have been recognized to contain a hydrophobic pocket accommodating the long acyl chain of a myristoylated peptide (18,68) that is distinct from the NAD ϩ cofactor binding site (75). Based on published x-ray crystal structures, we analyzed the hydrophobicity of the active sites of SIRT1-3 and SIRT6 and found that a hydrophobic pocket was also present in SIRT1 and SIRT3 (Fig.…”

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confidence: 99%

Investigating the Sensitivity of NAD+-dependent Sirtuin Deacylation Activities to NADH

Madsen

Andersen

Daoud

et al. 2016

Journal of Biological Chemistry

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Protein lysine posttranslational modification by an increasing number of different acyl groups is becoming appreciated as a regulatory mechanism in cellular biology. Sirtuins are class III histone deacylases that use NAD ؉ as a co-substrate during amide bond hydrolysis. Several studies have described the sirtuins as sensors of the NAD ؉ /NADH ratio, but it has not been formally tested for all the mammalian sirtuins in vitro. To address this problem, we first synthesized a wide variety of peptide-based probes, which were used to identify the range of hydrolytic activities of human sirtuins. These probes included aliphatic ⑀-N-acyllysine modifications with hydrocarbon lengths ranging from formyl (C 1 ) to palmitoyl (C 16 ) as well as negatively charged dicarboxyl-derived modifications. In addition to the well established activities of the sirtuins, "long chain" acyllysine modifications were also shown to be prone to hydrolytic cleavage by SIRT1-3 and SIRT6, supporting recent findings. We then tested the ability of NADH, ADP-ribose, and nicotinamide to inhibit these NAD ؉ -dependent deacylase activities of the sirtuins. In the commonly used 7-amino-4-methylcoumarin-coupled fluorescence-based assay, the fluorophore has significant spectral overlap with NADH and therefore cannot be used to measure inhibition by NADH. Therefore, we turned to an HPLC-MS-based assay to directly monitor the conversion of acylated peptides to their deacylated forms. All tested sirtuin deacylase activities showed sensitivity to NADH in this assay. However, the inhibitory concentrations of NADH in these assays are far greater than the predicted concentrations of NADH in cells; therefore, our data indicate that NADH is unlikely to inhibit sirtuins in vivo. These data suggest a re-evaluation of the sirtuins as direct sensors of the NAD ؉ /NADH ratio.

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“…Importantly, of the seven sirtuins encoded in the human genome, only Sirt1, -2, and -3 have a robust deacetylase activity. The other sirtuins have preferences for longer acyl chains (56,57).…”

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confidence: 99%

Insights into Lysine Deacetylation of Natively Folded Substrate Proteins by Sirtuins

Knyphausen

Boor

Kuhlmann

et al. 2016

Journal of Biological Chemistry

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Sirtuins are NAD؉ -dependent lysine deacylases, regulating a variety of cellular processes. The nuclear Sirt1, the cytosolic Sirt2, and the mitochondrial Sirt3 are robust deacetylases, whereas the other sirtuins have preferences for longer acyl chains. Most previous studies investigated sirtuin-catalyzed deacylation on peptide substrates only. We used the genetic code expansion concept to produce natively folded, site-specific, and lysine-acetylated Sirt1-3 substrate proteins, namely Ras-related nuclear, p53, PEPCK1, superoxide dismutase, cyclophilin D, and Hsp10, and analyzed the deacetylation reaction. Some acetylated proteins such as Ras-related nuclear, p53, and Hsp10 were robustly deacetylated by Sirt1-3. However, other reported sirtuin substrate proteins such as cyclophilin D, superoxide dismutase, and PEPCK1 were not deacetylated. Using a structural and functional approach, we describe the ability of Sirt1-3 to deacetylate two adjacent acetylated lysine residues. The dynamics of this process have implications for the lifetime of acetyl modifications on di-lysine acetylation sites and thus constitute a new mechanism for the regulation of proteins by acetylation. Our studies support that, besides the primary sequence context, the protein structure is a major determinant of sirtuin substrate specificity.

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Kinetic and Structural Basis for Acyl-Group Selectivity and NAD⁺ Dependence in Sirtuin-Catalyzed Deacylation

Cited by 162 publications

References 49 publications

Spatial dynamics of SIRT1 and the subnuclear distribution of NADH species

Spatial dynamics of SIRT1 and the subnuclear distribution of NADH species

Investigating the Sensitivity of NAD+-dependent Sirtuin Deacylation Activities to NADH

Insights into Lysine Deacetylation of Natively Folded Substrate Proteins by Sirtuins

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Kinetic and Structural Basis for Acyl-Group Selectivity and NAD+ Dependence in Sirtuin-Catalyzed Deacylation

Cited by 162 publications

References 49 publications

Spatial dynamics of SIRT1 and the subnuclear distribution of NADH species

Spatial dynamics of SIRT1 and the subnuclear distribution of NADH species

Investigating the Sensitivity of NAD+-dependent Sirtuin Deacylation Activities to NADH

Insights into Lysine Deacetylation of Natively Folded Substrate Proteins by Sirtuins

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Kinetic and Structural Basis for Acyl-Group Selectivity and NAD⁺ Dependence in Sirtuin-Catalyzed Deacylation