Sir2 regulates histone H3 lysine 9 methylation and heterochromatin assembly in fission yeast

Hypoacetylated histones are a hallmark of heterochromatin in organisms ranging from yeast to humans. Histone deacetylation is carried out by both NAD(+)-dependent and NAD(+)-independent enzymes. In the budding yeast Saccharomyces cerevisiae, deacetylation of histones in heterochromatic chromosomal domains requires Sir2, a phylogenetically conserved NAD(+)-dependent deacetylase. In the fission yeast Schizosaccharomyces pombe, NAD(+)-independent histone deacetylases are required for the formation of heterochromatin, but the role of Sir2-like deacetylases in this process has not been evaluated. Here, we show that spSir2, the S. pombe Sir2-like protein that is the most closely related to the S. cerevisiae Sir2, is an NAD(+)-dependent deacetylase that efficiently deacetylates histone H3 lysine 9 (K9) and histone H4 lysine 16 (K16) in vitro. In sir2 Delta cells, silencing at the donor mating-type loci, telomeres, and the inner centromeric repeats (imr) is abolished, while silencing at the outer centromeric repeats (otr) and rDNA is weakly reduced. Furthermore, Sir2 is required for hypoacetylation and methylation of H3-K9 and for the association of Swi6 with the above loci in vivo. Our findings suggest that the NAD(+)-dependent deacetylase Sir2 plays an important and conserved role in heterochromatin assembly in eukaryotes.     

Substrate specificity and kinetic mechanism of the Sir2 family of NAD+-dependent histone/protein deacetylases

The Silent information regulator 2 (Sir2) family of enzymes consists of NAD(+)-dependent histone/protein deacetylases that tightly couple the hydrolysis of NAD(+) and the deacetylation of an acetylated substrate to form nicotinamide, the deacetylated product, and the novel metabolite O-acetyl-ADP-ribose (OAADPR). In this paper, we analyzed the substrate specificity of the yeast Sir2 (ySir2), the yeast HST2, and the human SIRT2 homologues toward various monoacetylated histone H3 and H4 peptides, determined the basic kinetic mechanism, and resolved individual chemical steps of the Sir2 reaction. Using steady-state kinetic analysis, we have shown that ySir2, HST2, and SIRT2 exhibit varying catalytic efficiencies and display a preference among the monoacetylated peptide substrates. Bisubstrate kinetic analysis indicates that Sir2 enzymes follow a sequential mechanism, where both the acetylated substrate and NAD(+) must bind to form a ternary complex, prior to any catalytic step. Using rapid-kinetic analysis, we have shown that after ternary complex formation, nicotinamide cleavage occurs first, followed by the transfer of the acetyl group from the donor substrate to the ADP-ribose portion of NAD(+) to form OAADPr and the deacetylated product. Product and dead-end inhibition analyses revealed that nicotinamide is the first product released followed by random release of OAADPr and the deacetylated product.     

Coenzyme specificity of Sir2 protein deacetylases: implications for physiological regulation

Sir2 (silent information regulator 2) enzymes catalyze a unique protein deacetylation reaction that requires the coenzyme NAD(+) and produces nicotinamide and a newly discovered metabolite, O-acetyl-ADP-ribose (OAADPr). Conserved from bacteria to humans, these proteins are implicated in the control of gene silencing, metabolism, apoptosis, and aging. Here we examine the role of NAD(+) metabolites/derivatives and salvage pathway intermediates as activators, inhibitors, or coenzyme substrates of Sir2 enzymes in vitro. Also, we probe the coenzyme binding site using inhibitor binding studies and alternative coenzyme derivatives as substrates. Sir2 enzymes showed an exquisite selectivity for the nicotinamide base coenzyme, with the most dramatic losses in binding affinity/reactivity resulting from relatively minor changes in the nicotinamide ring, either by reduction, as in NADH, or by converting the amide to its acid analogue. Both ends of the dinucleotide NAD(+) are shown to be critical for high selectivity and high affinity. Among the NAD(+) metabolites tested none were able to allosterically activate, although all led to various extents of inhibition, consistent with competition at the coenzyme binding site. Nicotinamide was the most potent inhibitor examined, suggesting that cellular nicotinamide levels would provide an effective small molecule regulator of protein deacetylation and generation of OAADPr. The presented findings also suggest that changes in the physiological NAD(+):NADH ratio, without a change in NAD(+), would yield little alteration in Sir2 activity. That is, NADH is an extremely ineffective inhibitor of Sir2 enzymes (average IC(50) of 17 mm). We propose that changes in both free nicotinamide and free NAD(+) afford the greatest contribution to cellular activity of Sir2 enzymes but with nicotinamide having a more dramatic effect during smaller fluctuations in concentration.     

Bypassing the catalytic activity of SIR2 for SIR protein spreading in Saccharomyces cerevisiae

Sir protein spreading along chromosomes and silencing in Saccharomyces cerevisiae requires the NAD+-dependent histone deacetylase activity of Sir2p. We tested whether this requirement could be bypassed at the HM loci and telomeres in cells containing a stably expressed, but catalytically inactive mutant of Sir2p, sir2-345p, plus histone mutants that mimic the hypoacetylated state normally created by Sir2p. Sir protein spreading was rescued in sir2-345 mutants expressing histones in which key lysine residues in their N-termini had been mutated to arginine. Mating in these mutants was also partially restored upon overexpression of Sir3p. Together, these results indicate that histone hypoacetylation is sufficient for Sir protein spreading in the absence of production of 2'-O-acetyl-ADP ribose by sir2p and Sir2p's enzymatic function for silencing can be bypassed in a subset of cells in a given population. These results also provide genetic evidence for the existence of additional critical substrates of Sir2p for silencing in vivo.     

Structure of the yeast Hst2 protein deacetylase in ternary complex with 2'-O-acetyl ADP ribose and histone peptide

Sir2 proteins are NAD(+)-dependant protein deactylases that have been implicated in playing roles in gene silencing, DNA repair, genome stability, longevity, metabolism, and cell physiology. To define the mechanism of Sir2 activity, we report the 1.5 A crystal structure of the yeast Hst2 (yHst2) Sir2 protein in ternary complex with 2'-O-acetyl ADP ribose and an acetylated histone H4 peptide. The structure captures both ligands meeting within an enclosed tunnel between the small and large domains of the catalytic protein core and permits the assignment of a detailed catalytic mechanism for the Sir2 proteins that is consistent with solution and enzymatic studies. Comparison of the ternary complex with the yHst2/NAD(+) complex, also reported here, and nascent yHst2 structure also reveals that NAD(+) binding accompanies intramolecular loop rearrangement for more stable NAD(+) and acetyl-lysine binding, and that acetyl-lysine peptide binding induces a trimer-monomer protein transition involving nonconserved Sir2 residues.     

Hydrolysis of O-acetyl-ADP-ribose isomers by ADP-ribosylhydrolase 3

O-acetyl-ADP-ribose (OAADPr), produced by the Sir2-catalyzed NAD(+)-dependent histone/protein deacetylase reaction, regulates diverse biological processes. Interconversion between two OAADPr isomers with acetyl attached to the C-2″ and C-3″ hydroxyl of ADP-ribose (ADPr) is rapid. We reported earlier that ADP-ribosylhydrolase 3 (ARH3), one of three ARH proteins sharing structural similarities, hydrolyzed OAADPr to ADPr and acetate, and poly(ADPr) to ADPr monomers. ARH1 also hydrolyzed OAADPr and poly(ADPr) as well as ADP-ribose-arginine, with arginine in α-anomeric linkage to C-1″ of ADP-ribose. Because both ARH3- and ARH1-catalyzed reactions involve nucleophilic attacks at the C-1″ position, it was perplexing that the ARH3 catalytic site would cleave OAADPr at either the 2″- or 3″-position, and we postulated the existence of a third isomer, 1″-OAADPr, in equilibrium with 2″- and 3″-isomers. A third isomer, consistent with 1″-OAADPr, was identified at pH 9.0. Further, ARH3 OAADPr hydrolase activity was greater at pH 9.0 than at neutral pH where 3″-OAADPr predominated. Consistent with our hypothesis, IC(50) values for ARH3 inhibition by 2″- and 3″-N-acetyl-ADPr analogs of OAADPr were significantly higher than that for ADPr. ARH1 also hydrolyzed OAADPr more rapidly at alkaline pH, but cleavage of ADP-ribose-arginine was faster at neutral pH than pH 9.0. ARH3-catalyzed hydrolysis of OAADPr in H(2)(18)O resulted in incorporation of one (18)O into ADP-ribose by mass spectrometric analysis, consistent with cleavage at the C-1″ position. Together, these data suggest that ARH family members, ARH1 and ARH3, catalyze hydrolysis of the 1″-O linkage in their structurally diverse substrates.     

Identification of macrodomain proteins as novel O-acetyl-ADP-ribose deacetylases

Sirtuins are a family of protein lysine deacetylases, which regulate gene silencing, metabolism, life span, and chromatin structure. Sirtuins utilize NAD(+) to deacetylate proteins, yielding O-acetyl-ADP-ribose (OAADPr) as a reaction product. The macrodomain is a ubiquitous protein module known to bind ADP-ribose derivatives, which diverged through evolution to support many different protein functions and pathways. The observation that some sirtuins and macrodomains are physically linked as fusion proteins or genetically coupled through the same operon, provided a clue that their functions might be connected. Indeed, here we demonstrate that the product of the sirtuin reaction OAADPr is a substrate for several related macrodomain proteins: human MacroD1, human MacroD2, Escherichia coli YmdB, and the sirtuin-linked MacroD-like protein from Staphylococcus aureus. In addition, we show that the cell extracts derived from MacroD-deficient Neurospora crassa strain exhibit a major reduction in the ability to hydrolyze OAADPr. Our data support a novel function of macrodomains as OAADPr deacetylases and potential in vivo regulators of cellular OAADPr produced by NAD(+)-dependent deacetylation.     

Sir2 deacetylates histone H3 lysine 56 to regulate telomeric heterochromatin structure in yeast

At telomeric heterochromatin in yeast, the Sir protein complex spreads from Rap1 sites to silence adjacent genes. This cascade is believed to occur when Sir2, an NAD(+)-dependent enzyme, deacetylates histone H3 and H4 N termini, in particular histone H4 K16, enabling more Sir protein binding. Lysine 56 of histone H3 is located at the entry-exit points of the DNA superhelix surrounding the nucleosome, where it may control DNA compaction. We have found that K56 substitutions disrupt silencing severely without decreasing Sir protein binding at the telomere. Our in vitro and in vivo data indicate that Sir2 deacetylates K56 directly in telomeric heterochromatin to compact chromatin and prevent access to RNA polymerase and ectopic bacterial dam methylase. Since the spread of Sir proteins is necessary but not sufficient for silencing, we propose that silencing occurs when Sir2 deacetylates H3 K56 to close the nucleosomal entry-exit gates, enabling compaction of heterochromatin.     

Analysis of O-acetyl-ADP-ribose as a target for Nudix ADP-ribose hydrolases

The Sir2 family of NAD(+)-dependent histone/protein deacetylases has been implicated in a wide range of biological activities, including gene silencing, life span extension, and chromosomal stability. Recent evidence has indicated that these proteins produce a novel metabolite O-acetyl-ADP-ribose (OAADPr) during deacetylation. Cellular studies have demonstrated that this metabolite exhibits biological effects when microinjected in living cells. However, the molecular targets of OAADPr remain to be identified. Here we have analyzed the ADP-ribose-specific Nudix family of hydrolases as potential in vivo metabolizing enzymes of OAADPr. In vitro, we found that the ADP-ribose hydrolases (yeast YSA1, mouse NudT5, and human NUDT9) cleaved OAADPr to the products AMP and acetylated ribose 5'-phosphate. Steady-state kinetic analyses revealed that YSA1 and NudT5 hydrolyzed OAADPr with similar kinetic constants to those obtained with ADP-ribose as substrate. In dramatic contrast, human NUDT9 was 500-fold less efficient (k(cat)/K(m) values) at hydrolyzing OAADPr compared with ADP-ribose. The inability of OAADPr to inhibit the reaction of NUDT9 with ADP-ribose suggests that NUDT9 binds OAADPr with low affinity, likely due to steric considerations of the additional acetylated-ribose moiety. We next explored whether Nudix hydrolytic activities against OAADPr could be observed in cell extracts from yeast and human. Using a detailed analysis of the products generated during the consumption of OAADPr in extracts, we identified two robust enzymatic activities that were not consistent with the known Nudix hydrolases. Instead, we identified cytoplasmic esterase activities that hydrolyze OAADPr to acetate and ADP-ribose, whereas a distinct activity residing in the nucleus is consistent with an OAADPr-specific acetyltransferase. These findings establish for the first time that select members of the ADP-ribose hydrolases are potential targets of OAADPr metabolism. However, the predominate endogenous activities observed from diverse cell extracts represent novel enzymes.     

A yeast sir2 mutant temperature sensitive for silencing

A screen for Saccharomyces cerevisiae temperature-sensitive silencing mutants identified a strain with a point mutation in the SIR2 gene. The mutation changed Ser276 to Cys. This amino acid is in the highly conserved NAD(+) binding pocket of the Sir2 family of proteins. Haploid strains of either mating type carrying the mutation were severely defective at mating at 37 degrees but normal at 25 degrees . Measurements of RNA from the HMR locus demonstrated that silencing was lost rapidly upon shifting the mutant from the low to the high temperature, but it took >8 hours to reestablish silencing after a shift back to 25 degrees . Silencing at the rDNA locus was also temperature sensitive. On the other hand, telomeric silencing was totally defective at both temperatures. Enzymatic activity of the recombinant wild-type and mutant Sir2 protein was compared by three different assays. The mutant exhibited less deacetylase activity than the wild-type protein at both 37 degrees and 25 degrees . Interestingly, the mutant had much more NAD(+)-nicotinamide exchange activity than wild type, as did a mutation in the same region of the protein in the Sir2 homolog, Hst2. Thus, mutations in this region of the NAD(+) binding pocket of the protein are able to carry out cleavage of NAD(+) to nicotinamide but are defective at the subsequent deacetylation step of the reaction.     

Linking chromatin function with metabolic networks: Sir2 family of NAD(+)-dependent deacetylases

Chromatin remodeling enzymes rely on coenzymes derived from metabolic pathways, suggesting a tight synchronization among apparently diverse cellular processes. A unique example of this link is the recently described NAD(+)-dependent protein and/or histone deacetylases. The founding member of this family - yeast silent information regulator 2 (ySir2) - is involved in gene silencing, chromosomal stability and ageing. Sir2-like enzymes catalyze a reaction in which the cleavage of NAD(+)and histone and/or protein deacetylation are coupled to the formation of O-acetyl-ADP-ribose, a novel metabolite. The dependence of the reaction on both NAD(+) and the generation of this potential second messenger offers new clues to understanding the function and regulation of nuclear, cytoplasmic and mitochondrial Sir2-like enzymes.     

Sir2 regulates skeletal muscle differentiation as a potential sensor of the redox state

Sir2 is a NAD(+)-dependent histone deacetylase that controls gene silencing, cell cycle, DNA damage repair, and life span. Prompted by the observation that the [NAD(+)]/[NADH] ratio is subjected to dynamic fluctuations in skeletal muscle, we have tested whether Sir2 regulates muscle gene expression and differentiation. Sir2 forms a complex with the acetyltransferase PCAF and MyoD and, when overexpressed, retards muscle differentiation. Conversely, cells with decreased Sir2 differentiate prematurely. To inhibit myogenesis, Sir2 requires its NAD(+)-dependent deacetylase activity. The [NAD(+)]/[NADH] ratio decreases as muscle cells differentiate, while an increased [NAD(+)]/[NADH] ratio inhibits muscle gene expression. Cells with reduced Sir2 levels are less sensitive to the inhibition imposed by an elevated [NAD(+)]/[NADH] ratio. These results indicate that Sir2 regulates muscle gene expression and differentiation by possibly functioning as a redox sensor. In response to exercise, food intake, and starvation, Sir2 may sense modifications of the redox state and promptly modulate gene expression.