Activation of the Protein Deacetylase SIRT6 by Long-chain Fatty Acids and Widespread Deacylation by Mammalian Sirtuins

Mammalian sirtuins (SIRT1 through SIRT7) are members of a highly conserved family of NAD⁺-dependent protein deacetylases that function in metabolism, genome maintenance, and stress responses. Emerging evidence suggests that some sirtuins display substrate specificity toward other acyl groups attached to the lysine ϵ-amine. SIRT6 was recently reported to preferentially hydrolyze long-chain fatty acyl groups over acetyl groups. Here we investigated the catalytic ability of all sirtuins to hydrolyze 13 different acyl groups from histone H3 peptides, ranging in carbon length, saturation, and chemical diversity. We find that long-chain deacylation is a general feature of mammalian sirtuins, that SIRT1 and SIRT2 act as efficient decrotonylases, and that SIRT1, SIRT2, SIRT3, and SIRT4 can remove lipoic acid. These results provide new insight into sirtuin function and a means for cellular removal of an expanding list of endogenous lysine modifications. Given that SIRT6 is a poor deacetylase in vitro, but binds and prefers to hydrolyze long-chain acylated peptides, we hypothesize that binding of certain free fatty acids (FFAs) could stimulate deacetylation activity. Indeed, we demonstrate that several biologically relevant FFAs (including myristic, oleic, and linoleic acids) at physiological concentrations induce up to a 35-fold increase in catalytic efficiency of SIRT6 but not SIRT1. The activation mechanism is consistent with fatty acid inducing a conformation that binds acetylated H3 with greater affinity. Binding of long-chain FFA and myristoylated H3 peptide is mutually exclusive. We discuss the implications of discovering endogenous, small-molecule activators of SIRT6.     

The status and conservation of the Cape Gannet Morus capensis

The Cape Gannet Morus capensis is one of several seabird species endemic to the Benguela upwelling ecosystem (BUS) but whose population has recently decreased, leading to an unfavourable IUCN Red List assessment. Application of ‘JARA’ (‘Just Another Red-List Assessment,’ a Bayesian state-space tool used for IUCN Red List assessments) to updated information on the areas occupied by Cape Gannets and the nest densities of breeding birds at their six colonies, suggested that the species should be classified as Vulnerable. However, the rate of decrease of Cape Gannets in their most-recent generation exceeded that of the previous generation, primarily as a result of large decreases at Bird Island, Lambert’s Bay, and Malgas Island, off South Africa’s west coast (the western part of their range). Since the 1960s, there has been an ongoing redistribution of the species from northwest to southeast around southern Africa, and ～70% of the population now occurs on the south coast of South Africa, at Bird Island in Algoa Bay, on the eastern border of the BUS. Recruitment rather than adult survival may be limiting the present population; however, information on the seabird’s demographic parameters and mortality in fisheries is lacking for colonies in the northern part of the BUS. Presently, major threats to Cape Gannet include: substantially decreased availability of their preferred prey in the west; heavy mortalities of eggs, chicks and fledglings at and around colonies, inflicted by Cape Fur Seals Arctocephalus pusillus and other seabirds; substantial disturbance at colonies caused by Cape Fur Seals attacking adult gannets ashore; oiling; and disease.     

Mechanism of nicotinamide inhibition and transglycosidation by Sir2 histone/protein deacetylases

Silent information regulator 2 (Sir2) enzymes catalyze NAD+-dependent protein/histone deacetylation, where the acetyl group from the lysine epsilon-amino group is transferred to the ADP-ribose moiety of NAD+, producing nicotinamide and the novel metabolite O-acetyl-ADP-ribose. Sir2 proteins have been shown to regulate gene silencing, metabolic enzymes, and life span. Recently, nicotinamide has been implicated as a direct negative regulator of cellular Sir2 function; however, the mechanism of nicotinamide inhibition was not established. Sir2 enzymes are multifunctional in that the deacetylase reaction involves the cleavage of the nicotinamide-ribosyl, cleavage of an amide bond, and transfer of the acetyl group ultimately to the 2'-ribose hydroxyl of ADP-ribose. Here we demonstrate that nicotinamide inhibition is the result of nicotinamide intercepting an ADP-ribosyl-enzyme-acetyl peptide intermediate with regeneration of NAD+ (transglycosidation). The cellular implications are discussed. A variety of 3-substituted pyridines was found to be substrates for enzyme-catalyzed transglycosidation. A Br?nsted plot of the data yielded a slope of +0.98, consistent with the development of a nearly full positive charge in the transition state, and with basicity of the attacking nucleophile as a strong predictor of reactivity. NAD+ analogues including beta-2'-deoxy-2'-fluororibo-NAD+ and a His-to-Ala mutant were used to probe the mechanism of nicotinamide-ribosyl cleavage and acetyl group transfer. We demonstrate that nicotinamide-ribosyl cleavage is distinct from acetyl group transfer to the 2'-OH ribose. The observed enzyme-catalyzed formation of a labile 1'-acetylated-ADP-fluororibose intermediate using beta-2'-deoxy-2'-fluororibo-NAD+ supports a mechanism where, after nicotinamide-ribosyl cleavage, the carbonyl oxygen of acetylated substrate attacks the C-1' ribose to form an initial iminium adduct.     

Probing the function of conserved residues in the serine/threonine phosphatase PP2Calpha

Human PP2Calpha is a metal-dependent phosphoserine/phosphothreonine protein phosphatase and is the representative member of the large PPM family. The X-ray structure of human PP2Calpha has revealed an active site containing a dinuclear metal ion center that is coordinated by several invariant carboxylate residues. However, direct evidence for the catalytic function of these and other active-site residues has not been established. Using site-directed mutagenesis and enzyme kinetic analyses, we probed the roles of conserved active-site amino acids within PP2Calpha. Asp-60 bridges metals M1 and M2, and Asp-239 coordinates metal M2, both of which were replaced individually to asparagine residues. These point mutations resulted in >or=1000-fold decrease in k(cat) and >or=30-fold increase in K(m) value for Mn(2+). Mutation of Asp-282 to asparagine caused a 100-fold decrease in k(cat), but no significant effect on K(m) values for metal and substrate, consistent with Asp-282 activating a metal-bound water nucleophile. Mutants T128A, E37Q, D38N, and H40A displayed little or no alterations on k(cat) and K(m) values for substrate or metal ion (Mn(2+)). Analysis of H62Q and R33A yielded k(cat) values that were 20- and 2-fold lower than wild-type, respectively. The mutant R33A showed a 8-fold higher K(m) for substrate, while the K(m) observed with H62Q was unaffected. A pH-rate profile of the H62Q mutant showed loss of the ionization that must be protonated for activity. Br?nsted analysis of substrate leaving group pK(a) values for H62Q indicated a greater dependency (slope -0.84) on leaving group pK(a) in comparison to wild-type (slope -0.33). These data provide strong evidence that His-62 acts as a general acid during the cleavage of the P-O bond.     

Structural identification of 2'- and 3'-O-acetyl-ADP-ribose as novel metabolites derived from the Sir2 family of beta -NAD+-dependent histone/protein deacetylases

The Sir2 (silent information regulator 2) family of histone/protein deacetylases has been implicated in a wide range of biological activities, including gene silencing, life-span extension, and chromosomal stability. Their dependence on beta-NAD(+) for activity is unique among the known classes of histone/protein deacetylase. Sir2 enzymes have been shown to couple substrate deacetylation and beta-NAD(+) cleavage to the formation of O-acetyl-ADP-ribose, a newly described metabolite. To gain a better understanding of the catalytic mechanism and of the biological implications of producing this molecule, we have performed a detailed enzymatic and structural characterization of O-acetyl-ADP-ribose. Through the use of mass spectrometry, rapid quenching techniques, and NMR structural analyses, 2'-O-acetyl-ADP-ribose and 3'-O-acetyl-ADP-ribose were found to be the solution products produced by the Sir2 family of enzymes. Rapid quenching approaches under single-turnover conditions identified 2'-O-acetyl-ADP-ribose as the enzymatic product, whereas 3'-O-acetyl-ADP-ribose was formed by intramolecular transesterification after enzymatic release into bulk solvent, where 2'- and 3'-O-acetyl-ADP-ribose exist in equilibrium (48:52). In addition to (1)H and (13)C chemical shift assignments for each regioisomer, heteronuclear multiple-bond correlation spectroscopy was used to assign unambiguously the position of the acetyl group. These findings are highly significant, because they differ from the previous conclusion, which suggested that 1'-O-acetyl-ADP-ribose was the solution product of the reaction. Possible mechanisms for the generation of 2'-O-acetyl-ADP-ribose are discussed.