The Journal of Biological Chemistry © 2002 by The American Society for Biochemistry and Molecular Biology, Inc. Vol. 277, No. 21, Issue of May 24, pp. 18881-18890, 2002 Printed in U.S.A. Manipulation of a Nuclear NAD Salvage Pathway Delays Aging without Altering Steady-state NAD+ Levels* Received for publication, December 10, 2001, and in revised form, March 4, 2002 Published, JBC Papers in Press, March 7, 2002, DOI 10.1074/jbc.M111773200 Rozalyn M. Anderson$§, Kevin J. Bitterman$§, Jason G. WoodiH, Oliver Medvediki, Haim Coheni ||, Stephen S. Lin**, Jill K. Manchester**, Jeffrey I. Gordon**, and David A. Sinclair! $$ From the ^.Department of Pathology, Harvard Medical School, Boston, Massachusetts 02115 and the **Department of Molecular Biology and Pharmacology, Washington University School of Medicine, St. Louis, Missouri 63110 Yeast deprived of nutrients exhibit a marked life span extension that requires the activity of the NAD+-dependent histone deacetylase, Sir2p. Here we show that increased dosage of NPT1, encoding a nicotinate phosphoribosyltransferase critical for the NAD+ salvage pathway, increases Sir2-dependent silencing, stabilizes the rDNA locus, and extends yeast replicative life span by up to 60%. Both NPT1 and SIR2 provide resistance against heat shock, demonstrating that these genes act in a more general manner to promote cell survival. We show that Nptl and a previously uncharacterized salvage pathway enzyme, Nma2, are both concentrated in the nucleus, indicating that a significant amount of NAD+ is regenerated in this organelle. Additional copies of the salvage pathway genes, PNC1, NMA1, and NMA2, increase telomeric and rDNA silencing, implying that multiple steps affect the rate of the pathway. Although S/i?2-dependent processes are enhanced by additional NPT1, steady-state NAD+ levels and NAD+/NADH ratios remain unaltered. This finding suggests that yeast life span extension may be facilitated by an increase in the availability of NAD+ to Sir2, although not through a simple increase in steady-state levels. We propose a model in which increased flux through the NAD+ salvage pathway is responsible for the Sir2-dependent extension of life span. Physiological studies and, more recently, DNA array analysis of gene expression patterns have confirmed that aging is a complex biological process. In contrast, genetic studies in model organisms have demonstrated that relatively minor changes to an organism's environment or genetic makeup can dramatically slow the aging process. For example, the life span of many diverse organisms can be greatly extended simply by limiting calorie intake, in a dietary regime known as caloric restriction (1-3). How can simple changes have such profound effects on a complex process such as aging? A picture is emerging in which * Work was supported in part by The Ellison Foundation, The American Federation for Aging Research, and The Arminese Foundation. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. § Both authors contributed equally to this work. || Supported by a Taplan Fellowship. H Supported by a National Science Foundation scholarship. Supported by a Leukemia and Lymphoma Society Special Fellowship. To whom correspondence should be addressed: Dept. of Pathology, Harvard Medical School, 200 Longwood Ave., Boston, MA 02115. Tel.: 617-432-3931; Fax: 617-432-1313; E-mail: david_sinclair@hms. harvard.edu. all eukaryotes possess a surprisingly conserved regulatory system that governs the pace of aging (4, 5). Such a regulatory system may have arisen in evolution to allow organisms to survive in adverse conditions by redirecting resources from growth and reproduction to pathways that provide stress resistance (4, 6). One model that has proven particularly useful in the identification of regulatory factors of aging is the budding yeast Saccharomyces cerevisiae. Replicative life span in S. cerevisiae is typically defined as the number of buds or "daughter cells" produced by an individual "mother cell" (7). Mother cells undergo age-dependent changes, including an increase in size, a slowing of the cell cycle, enlargement of the nucleolus, an increase in steady-state NAD+ levels, increased gluconeogene-sis and energy storage, and sterility resulting from the loss of silencing at telomeres and mating-type loci (8-13). An alternative measure of yeast life span, known as chronological aging, is the length of time a population of non-dividing cells remains viable when deprived of nutrients (14). Increased chronological life span correlates with increased resistance to heat shock and oxidative stress, suggesting that cumulative damage to cellular components is a major cause of this type of aging (14, 15). The extent of overlap between replicative and chronological aging is currently unclear. One cause of yeast replicative aging has been shown to stem from the instability of the repeated ribosomal DNA (rDNA)1 locus (16). This instability gives rise to circular forms of rDNA called extrachromosomal rDNA circles that replicate but fail to segregate to daughter cells. Eventually, extrachromosomal rDNA circles accumulate to over 1000 copies, which are thought to kill cells by titrating essential transcription and/or replication factors (16-18). Regimens that reduce rDNA recombination such as caloric restriction or a fobl deletion extend replicative life span (17, 19, 20). A key regulator of aging in yeast is the Sir2 silencing protein (17), a nicotinamide adenine dinucleotide (NAD+)-dependent deacetylase (21-24). Sir2 is a component of the heterotrimeric Sir2/3/4 complex that catalyzes the formation of silent hetero-chromatin at telomeres and the two silent mating-type loci (25). Sir2 is also a component of the regulator of nucleolar silencing and telophase exit complex that is required for silencing at the rDNA locus and exit from telophase (26, 27). This complex has also recently been shown to directly stimulate transcription of 1 The abbreviations used are: rDNA, ribosomal DNA; NaMN, nicotinic acid mononucleotide; NaAD, desamido-NAD+; NaM, nicotinamide; NaMNAT, nicotinate mononucleotide adenylyltransferase; ORF, open reading frame; GFP, green fluorescence protein; HA, hemagglutinin; SC, synthetic complete; MMS, methylmethane sulfonate; 3xHA, triple hemagglutinin epitope. > S W O < > d •z < o This paper is available on line at http://www.jbc.org 18881 18882 Increased Nuclear NAD Synthesis Extends Life Span rRNA by polymerase I and to be involved in the regulation of nucleolar structure (28). Biochemical studies have shown that Sir2 can readily deacetylate the amino-terminal tails of histones H3 and H4, resulting in the formation of O-acetyl-ADP-ribose and nicotinamide (21-23, 29). Strains with additional copies of SIR2 display increased rDNA silencing (30) and a 30% longer life span (17). It has recently been shown that additional copies of the Caenorhabditis elegans SIR2 homolog, sir-2.1, greatly extend life span in that organism (31). This implies that the SIR2-de-pendent regulatory pathway for aging arose early in evolution and has been well conserved (4). Yeast life span, like that of metazoans, is also extended by interventions that resemble caloric restriction (19,32). Mutations that reduce the activity of the glucose-responsive cAMP (adenosine 3',5'-monophos-phate)-dependent (protein kinase A) pathway extend life span in wild type cells but not in mutant sir2 strains, demonstrating that SIR2 is a key downstream component of the caloric restriction pathway (19). In bacteria, NAD+ is synthesized de novo from tryptophan and recycled in four steps from nicotinamide via the NAD+ salvage pathway (see Fig. 5 below). The first step in the bacterial NAD+ salvage pathway, the hydrolysis of nicotinamide to nicotinic acid and ammonia, is catalyzed by the pncA gene product (33). An S. cerevisiae gene with homology to pncA, YGL037, was recently assigned the name PNC1 (34). A nico-tinate phosphoribosyltransferase, encoded by the NPT1 gene in S. cerevisiae, converts the nicotinic acid from this reaction to nicotinic acid mononucleotide (NaMN) (35-38). At this point, the NAD+ salvage pathway and the de novo NAD+ pathway converge and NaMN is converted to desamido-NAD+ (NaAD) by a nicotinate mononucleotide adenylyltransferase (NaM-NAT). In S. cerevisiae, there are two putative ORFs with homology to bacterial NaMNAT genes, YLR328 (39) and an un-characterized ORF, YGR010 (23, 39). We refer to these two ORFs as NMA1 and NMA2, respectively. In Salmonella, the final step in the regeneration of NAD+ is catalyzed by an NAD synthetase (40). An as yet uncharacterized ORF, QNS1, is predicted to encode an NAD synthetase (23). In yeast, null mutations in NPT1 reduce steady-state NAD+ levels by ~2-fold (23) and abolish the longevity provided by limiting calories (19). One current hypothesis explaining how caloric restriction extends replicative life span is that decreased metabolic activity causes an increase in NAD+ levels, which then stimulate Sir2 activity (reviewed in Campisi (68) and Guarente (69)). In this study, we tested this theory by examining whether additional copies of NPT1 can promote Sir2-dependent life span extension and whether this correlates with increased NAD+ levels. We show that additional NPT1 extends replicative life span in a SZR2-dependent manner via the caloric restriction pathway. We find that these long-lived strains do not have increased NAD+ levels or altered NAD+/ NADH ratios, despite the fact that every SZR2-dependent process we examined was enhanced. Interestingly, increased dosage of SIR2 or NPT1 provides resistance to heat shock, indicating that these genes act in a general manner to promote cell survival. We find that additional copies of all the salvage pathway genes increase rDNA and telomeric silencing with exception of QNS1. We show that Nptl and Nma2 are concentrated in the nucleus, raising the possibility that a substantial fraction of NAD+ is recycled within this organelle. We discuss the potential for extending life span in higher organisms by stimulation of the conserved NAD+ salvage pathway. Generations Generations Fig. 1. Increased dosage of NPT1 delays aging by mimicking caloric restriction. Life span was determined by scoring the number of daughter cells produced by each mother cell before cessation of cell division (7,10). Cells were pre-grown for a minimum of 48 h on complete glucose medium. A, mortality curves for wild type (PSY316AT, circles), 2xNPTl (YDS1544, diamonds), and 5xNPTl (YDS1548, triangles) on medium with 2% glucose. Average life spans are 21.9, 30.8, and 35.1 generations, respectively. B, mortality curves for wild type (PSY316AT, circles), sir2::TRPl (YDS1594, downward triangles), 2xNPTl (YDS1544, squares), sir2::TRPl 2xNPTl (YDS1573, diamonds), and 5-ssNPTl 2xSIR2 (YDS1577, upward triangles) on 2% glucose medium. Average life spans were 23.7, 14.4, 13.9, 31.0, and 31.9 generations, respectively. C, mortality curves for wild type on 2% glucose (PSY316AT, circles) and 0.5% glucose medium (PSY316AT, squares) and for 2nNPTl on 0.5% glucose medium (YDS1544, triangles). Average life spans are 21.9, 31.7, and 34.5 generations, respectively. EXPERIMENTAL PROCEDURES Plasmids and Strains—Strains used in this study are listed in Table II (see below). W303AR5 sir3::URA3 (16), W303AR5 sir4::HIS3, Increased Nuclear NAD Synthesis Extends Life Span 18883 Table I Steady-state NAD+ and NADH levels in various long- and short-lived strains Genotype NAD+ NADH NAD+/NADH, ATP ratio Air amol/pg protein" amol/pg protein" lxNPTl (wild type) 23.7(3.2) 9.3 (0.8) 2.8 (0.5) 15.5 (3) 2xNPTl 21.9 (2.0) 6.0 (0.6) 3.3(0.3) 7.6(1.6) 2xNPTl sir2:-TRPl 22.5 (1.6) 7.0(0.3) 2.4(0.9) 5.3(1.1) sir2::TRPl 23.6(1.2) 7.0 (0.6) 2.8(1.2) 7.9(1.9) ' Average of five independent experiments (S.E.). wt(URAS) wt (URA3 LEU2) 2xNPT1 2XSIH2 2V.SIR2 2xNPT1 no treatment heat shock • « $ 0 • • • «t W303AR5 sir2::TRPl, and PSY316AT have been described previously (41). Deletion of SIR2 in PSY316AT was performed using Scal/Pvull-linearized pC369 (41). JS209, JS241, JS237, and JS218 were gifts from J. Smith (42). The coding region and 1.1 kb of upstream sequence of NPT1 were amplified by PCR (43), and the 2.4-kb product fragment was subcloned into the pRS306 based vector pSP400 between Notl and Sacl (gift from L. Guarente, M.I.T.) and the 2^-based vector pDB20 (44) to generate pSPNPTland pDBNPTl, respectively. Additional copies of NPT1 were integrated at the URA3 locus using plasmid pSPNPTl linearized with Stul. Integrants were first identified by PCR. The NPT1 copy-number was then determined by probing for NPT1 and ACT 1 DNA on Southern blots. The density of the NPT1 band was compared with an ACT1 band using ImageQuaNT software (Molecular Dynamics, Sunnyvale, CA). Strains carrying an additional copy of SIR2 were generated by integrating plasmids p306SIR2 or p305SIR2 (17) linearized with Xcml. High copy SIR2 was introduced on the 2;u,-based plasmid p2;u,SIR2 (gift of L. Pillus, University of California at San Diego). W303AR5 was transformed to Ura+ and Leu+ prototrophy by integrating pRS306 or pRS305 (45) linearized with Stul and Xcml, respectively. YDS1595 was generated from W303AR5 by selecting a colony that had experienced an ADE2 loss event. YDS1595 was transformed with Stul-cut pRS402 (carrying the ADE2 gene) to create YDS1596. W303cdc25-10 was a gift from S. Lin (M. I. T.) (19). The NPT1 deletion strain, YDS1580, was generated by replacing the wild type gene with the kanr marker as described previously (46). The coding region and 650 bp upstream of PNC 1/YGL037 was amplified by PCR from genomic DNA. The 1350-bp Sacl/Notl fragment was cloned into the vector pSR400 to generate pSPYGL037. The coding region and 500 bp upstream of NMA2IYGR010 were amplified by PCR from genomic template, and the 1730-bp Sacl/Notl fragment was cloned into pSP400 to generate pSPYGROlO. The coding region of NMA1/YLR328 and 450 bp upstream were amplified from genomic template by PCR, and the 2150-bp fragment was cloned into pRS306 to generate p306YLR328. The coding region and 600 bp upstream of QNS1IYHR074 were amplified by PCR, and the 2.8-kb Sacl/Notl fragment was cloned into pSP400 to make pSPYHR074. Additional copies of PNC1/YGL037, NMA1I YLR328, NMA2/YGR010, and QNS1/YHR074 were integrated at the URA3 locus of W303AR5 and PSY316AT by transformation. All amplified DNA was confirmed to be free of mutations by sequencing. HA-tagged NPT1 was generated using a tag-kanr integration method (47) in strains W303AR5 and W303cdc25-10 (19). A green fluorescence protein (GFP) cassette was introduced at the carboxyl terminus of Nptl, Nmal, and Nma2 as described previously (48). The functionality of tagged proteins was confirmed by assaying rDNA silencing. Life Span Determination—Replicative life span determination was performed as described (16). Cells were grown on YPD medium (1% yeast extract, 2% bactopeptone, 2% glucose w/v) unless otherwise stated with a minimum of 40 cells per experiment. Each experiment was performed at least twice independently. Statistical significance of life span differences was determined using the Wilcoxon rank sum test. Differences are stated to be different when the confidence is higher than 95%. mRNA and Protein Determination—Northern and Western blots were performed using standard techniques. NPT1 transcripts were detected using a probe derived from the complete open reading frame of the NPT1 gene. ACT1 mRNA was detected using a full-length ACT1 probe (gift of G. Fink, M. I. T.). The HA epitope tag was detected using monoclonal antibody HA. 11 (Covance Research Products, Richmond, CA). Actin was detected with monoclonal antibody MAB1501R (Chemi-con, Temecula, CA). Yeast Assays and GFP Localization—Yeast strains were grown at 30 °C unless otherwise stated. The extent of silencing at the ribosomal DNA locus was determined using two assays. For the ADE2 silencing assay, cells were pre-grown on synthetic complete (SC) medium (1.67% yeast nitrogen base, 2% glucose, 40 mg/liter each of histidine, uridine, B 0.15 3- 0.10 CO > cn 0.05 3? Fig. 2. NPT1 and SIR2 provide resistance to heat shock. A, strains were grown for 3 days post-diauxic shift in SC medium and incubated for 1 h at 55 °C before plating 10-fold dilutions on SC plates. B, strains were treated as in A and plated on SC at low density. Colonies that arose after 24 h were scored and expressed as a percentage of colonies arising from the untreated sample. Values represent the average of three independent experiments (± S.D.). Strains: W303AR URA3 (YDS1568), W303AR URA3 LEU2 (YDS1563), and isogenic derivatives of W303AR, 2xNPTl-URA3 (YDS1503), 2xSIR2-URA3 (YDS1572), and 2xNPTl-URA3 2xSIR2-LEU2 (YDS1561). tryptophan, adenine, and leucine) for 3 days. Cells were resuspended in SC medium and serially diluted 10-fold in phosphate-buffered saline and spotted onto SC medium lacking adenine. MET15 silencing assays were performed on Pb2+-containing plates as previously described (42). Telomeric silencing was assayed on SC medium containing 0.7 mg/liter adenine. Cells were grown for 3 days and placed at 4 °C for 3 days to enhance color. Heat shock assays were performed essentially as described (14). Strains were pre-grown overnight in SC-complete medium with limiting histidine (20 mg/ml), diluted to 1 X 10s cells/ml in 3 ml of the same medium and grown for 5 days. Cultures were diluted 10-fold in expired medium, incubated for 1 h at 55 °C, and spotted on SC plates. Ribosomal DNA recombination rates were determined as previously described (49). At least 10,000 colonies were examined for each strain and each experiment was performed in triplicate. NAD+ and NADH determinations were measured as described elsewhere (50). Cells expressing a GFP fusions were grown to mid log phase in YPD medium or YPD low glucose (0.5% w/v) then incubated in phosphate-buffered saline containing 20 ju,m Hoechst 33342 DNA stain (Sigma Chemical Co.) for 5 min. Images were captured at 100X magnification on a Nikon E600 fluorescence microscope and analyzed using Photoshop 6.0 software. RESULTS Increased Dosage of NPT1 Increases Longevity but Not Steady-state NAD+ Levels—SIR2 is a limiting component of longevity in yeast and requires NAD+ for catalysis. Studies in Escherichia coli have shown that PncB catalyzes a rate-limiting step in the salvage pathway that recycles NAD+ (35, 37, > s W O < > d •z < 53 o 18884 Increased Nuclear NAD Synthesis Extends Life Span Table II Yeast strains used in this study Strain Genotype W303AR5 YDS878 YDS924 YDS882 YDS 1503 YDS 1504 YDS 1505 YDS 1506 YDS1496 YDS 1494 YDS1587 YDS 1495 YDS 1572 YDS1561 YDS 1595 YDS 1596 YDS 1568 YDS 1563 YDS 15 88 YDS 15 89 YDS 1590 YDS1614 YDS 1531 W303cdc25-10 YDS 153 7 YDS1611 YDS 1625 YDS 1624 PSY316AT YDS 1594 YDS 1544 YDS 1548 YDS 1527 YDS 1577 YDS 1573 YDS 1591 YDS 1592 YDS 1593 JS209 JS241 JS237 JS218 YDS1583 YDS 1522 YDS 1580 YDS 1581 YDS 1493 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, Ms3-ll,15, RDN1 ::ADE2, RADS W303 MATa,, ade2-l, leu2-3,112, canl-100, trpl-l„ ura3-52, his3-ll,15, RDN1::ADE2, RADS, sir2:TRPl W303AR5 MATu, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,lS, RDN1::ADE2, RADS, sir3:HIS3 W303 MATa, ade2-l, Ieu2-3,U2, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RAD5, sir4:HIS3 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, URA3/NPT1 W303 MATa, ade2-l, Ieu2-3,112, canl-100, trpl-1, ura3-S2, his3-ll,lS, RDN1::ADE2, RADS, sir2:TRPl, URA3/NPT1 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, sir3:H!S3, URA3/NPT1 W303 MATa, ade2-l, Ieu2-3,U2, canl-100, trpl-1, ura3-S2, Ms3-ll,15, RDN1 ::ADE2, RADS, sir4:HIS3, URA3/NPT1 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-S2, his3-ll,lS, RDN1::ADE2, RAD5, pDBNPTl W303 MATa, ade2-l, Ieu2-3,U2, canl-100, trpl-1, ura3-S2, his3-U,lS, RDN1::ADE2, RADS, sir2:TRPl, pDBNPTl W303 MATa, ade2-l, Ieu2-3,112, canl-100, trpl-1, ura3-S2, Ms3-ll,lS, RDN1::ADE2, RADS, sir3:H!S3, pDBNPTl W303 MATa, ade2-l, Ieu2-3,U2, canl-100, trpl-1, ura3-S2, his3-ll,15, RDN1::ADE2, RAD5, sir4:HIS3, pDBNPTl W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, LEU2/SIR2 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, URA3/NPT1, LEU2/SIR2 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RADS W303 MATa, ADE2, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,lS, RAD5 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, URA3, his3-ll,15, RDN1::ADE2, RADS W303 MATa, ode2-l, LEU2, canl-100, trpl-1, URA3, his3-ll,15, RDN1::ADE2, RADS W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-S2, his3-ll,15, RDN1::ADE2, RADS, pSPYGL037 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, pSPYGROlO W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,lS, RDN1::ADE2, RADS, p306YLR328 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-U,15, RDN1..ADE2, RADS, p306YHR074 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, NPT1-HA W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1 ::ADE2, RADS, cdc2S-10 W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,lS, RDN1 ::ADE2, RADS, cdc2S-10, NPT1-HA W303 MATa, ade2-l, Ieu2-3,U2, canl-100, trpl-1, ura3-S2, his3-U,15, RDN1::ADE2, RAD5, NPT1-GFP W303 MATa, ade2-l, Ieu2-3,U2, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, NMA1-GFP W303 MATa, ade2-l, leu2-3,112, canl-100, trpl-1, ura3-52, his3-ll,15, RDN1::ADE2, RADS, NMA2-GFP MATa, ura3-53 leu2-3,112 his3-A200 ade2-l,01 canl-100 ADE2-TEL V-R PSY316 MATa, ura3-53 leu2-3,112 his3-A200ade2-l,01 canl-100 ADE2-TEL V-R, sir2:TRPl ?SY3\6MATa, ura3-S3 leu2-3,112 his3-A200ade2-l,01 canl-100ADE2-TEL V-R, URA3/NPT1 PSY316 MATa, ura3-S3 leu2-3,112 his3-A200ade2-l,01 canl-100 ADE2-TEL V-R, (4x)URA3/NPTl PSY316 MATa, ura3-S3 Ieu2-3,U2 his3-A200ade2-l,01 canl-100 ADE2-TEL V-R, pDBNPTl PSY316 MATa, ura3-S3 leu2-3,112 his3-A200ade2-l,01 canl-100 ADE2-TEL V-R, (4x)URA3/NPTl, LEU2/SIR2 ?SY3\6MATa, ura3-53 Ieu2-3,U2his3-A200ade2-l,01 canl-100ADE2-TEL V-R, sir2::HIS3, URA3/NPT1 PSY316 MATa, ura3-S3 leu2-3,112 his3-A200ade2-l,01 canl-100 ADE2-TEL V-R, pSPYGL037 PSY316 MATa, ura3-53 leu2-3,112 his3-A200 ade2-l,01 canl-100 ADE2-TEL V-R, pSPYGROlO PSY316M4r Kl w o < > d •z < tri o Increased Nuclear NAD Synthesis Extends Life Span 18885 adenine no adenine RDN1 ::MET1S met15A METIS B wtdxwpn) 5XNPT1 5xNPT1 SirS 2xNPT1 5XNPT12xSIR2 su2 2xSIR2 2\iSIR2 1 «.«/• CSS ma S3 npt1 ZxNPTJ 2\iNPT1 m m m adenine no adenrne sh2 2.5 o 2.0 I 1.5 c o g 1.0 S 0.5 o.o J- 2xNPT1 2xS!R2 2xNPTJ 2xS/f?2 Strain 6*3 2xWP7J • • • # 1xWP7f • • • * 2xNPTl • • • * • • • ■* Strain Fig. 3. Additional NPT1 increases silencing and rDNA stability. A, strains with an ADE2 marker at the rDNA were pre-grown on SC plates and spotted as 10-fold serial dilutions on SC plates. Increased silencing is indicated by growth retardation on media lacking adenine. Strains: W303-1AADE2 (YDS1596), W303-1ARDNl:\ADE2 (W303AR5), and W303AR5 derivatives 2xNPTl (YDS1503), 2xSIR2 (YDS1572), and 2xNPTl 2nSIR2 (YDS1561). B, silencing of MET15 at the rDNA locus was assayed by streaking isogenic derivatives of JS237 on rich medium containing 0.07% PbNOs and incubating for 5 days at 30 °C. Increased silencing is indicated by accumulation of a brown pigment. Relevant genotypes: metl5h (JS209), MET15 (JS241), RND1::MET15 (JS237), sir2::TRPl (JS218), 2xSIR2 (YDS1583), 2liSIR2 (YDS1522), nptlA::kanr (YDS1580), 2xNPTl (YDS1581), and 2ixNPTl (YDS1493). C, silencing of an ADE2 marker at the rDNA locus was determined in strains with lxNPTl, 2xNPTl, and 2/jNPTI in the following backgrounds: wild type (W303AR5, YDS1503, YDS1496), sir2::TRPl (YDS878, YDS1504, YDS1494), sir3::HIS3 (YDS924, YDS1505, YDS1587), and sir4::HIS3 (YDS882, YDS1506, YDS1495). D, strains with an ADE2 marker at the telomere were streaked onto SC medium containing limiting amounts of adenine. Increased silencing is indicated by accumulation of red pigment. Relevant genotypes: (PSY316AT), 2xNPTl (YDS1544), 5xNPTl (YDS1548), 5xNPTl 2xSIR2 (YDS1577), and 5xNPTl SIR2::TRP1 (YDS1573). sir2::TRPl (YDS1594). E, strains in A were assayed for rDNA stability by examining the rate of loss of an ADE2 marker integrated at the rDNA locus. Cells were plated on YPD medium and the frequency of half-sectored colonies, reflecting a marker loss event at the first cell division, was measured. More than 10,000 colonies were examined for each strain and each experiment was performed in triplicate. Average recombination frequencies (± S.D.) per cell division are shown. F, ribosomal DNA recombination rates for wild type (W303AR), sir2::TRPl (YDS878), and 2xNPTl sir2::TRPl (YDS1504) strains. Assays were performed as in E. O o > S W o > d •z < o 38). We asked whether additional copies of the yeast pncB homolog, NPT1, could increase NAD+ production to Sir2 and hence extend yeast life span. NPT1 was integrated at the URA3 locus under the control of its native promoter. Strains that carried one or four tandem copies of NPT1 were then identified by Southern blotting. We refer to the resulting genotypes as 2xNPTl and 5-xNPTl, respectively. For the replicative life span assay, cells were grown for at least 2 days on fresh yeast extract/peptone/glucose (YPD) medium to ensure that they had fully recovered from conditions of 18886 Increased Nuclear NAD Synthesis Extends Life Span NPH ACT1 -* 14 • B n-HA «-HA Npt1-GFP Hoechst Merge • eV* Nma2-GFP Hoechst Merge • * r t IM- * m Fig. 4. Analysis of expression and localization of salvage pathway components. A, 3xHA tag sequence was inserted in-frame with the 3'-end of the native NPTl ORF in W303AR5 (YDS1531) and W303cdcl0-25 (YDS1537). Cells were grown in YPD medium at 30 °C and treated as described. Levels of NPTl mRNA were examined for W303AR5 grown in YPD (0.5 and 2.0% glucose) and W303cdc25-10 grown in YPD (2% glucose). A 1.8-kb NPTl transcript was detected and levels were normalized to actin (ACT1) control. Similar results were obtained in the PSY316 strain background (not shown). B, protein extracts from cultures in A were analyzed by Western blot to detect the HA-tagged Nptl using a-HA antibody. Two bands of 53 and 40 kDa were detected in the Nptl-HA strains, and no bands were detected in the untagged control strain (not shown). Actin levels served as a loading control. Similar results were obtained in the PSY316 strain background (not shown). C, levels of NPT1 mRNA were examined in wild type W303AR5 (YDS1531) log phase cultures after 1-h exposure to the following: MMS (0.02% v/v), paraquat (5 mil), or heat shock (55 °C). D, protein extracts of cultures in C were analyzed as in B. In E and F, a green fluorescence protein (GFP) sequence was inserted in-frame at the 3'-end of the native NPT1 and NMA2 ORFs in W303AR5 (YDS1611 and YDS1624, respectively). Cells were grown in YPD medium at 30 °C to mid log phase and photographed live. Regions of overlap between GFP (green) and Hoechst DNA stain (red) appear yellow in the merged image. caloric restriction prior to the assay. Daughter cells that emerged from previously non-budded mother cells were then micro-manipulated away and scored. As shown in Fig. 1A, the 2xNPTl strain lived an average of —40% longer than the wild type strain and the 5-xNPTl strain lived a striking —60% longer. The iVPTi-induced life span extension was completely abrogated by a sir2 deletion and not significantly enhanced by an additional copy of SIR2 (Fig. LB) indicating that the life span extension provided by NPTl is mediated by Sir2. It has recently been shown that wild type cells grown in low glucose medium (0.5% w/v) have an average life span significantly greater than those grown on standard (2%) glucose medium (19, 32). As shown in Fig. 1C, on low glucose medium the life span of the 5xNPTl strain was not significantly greater than the wild type strain. The fact that the effect of NPT1 and low glucose were not additive suggests that these two regimens act via the same pathway. Biochemical studies have shown that Sir2 requires NAD+ as a cofactor. This has led to the hypothesis that replicative life span may be extended by increased NAD+ levels. Consistent with this idea, NAD+ levels have been shown to increase significantly in old cells, perhaps as a defense against aging or as the result of decreased metabolic activity (50). To date, the intracellular levels of NAD+ in any long-lived strain have not been reported. We found that steady-state NAD+ levels and NAD+/NADH ratios in the 2xNPTl strain were not significantly different from the wild type (Table I). We also examined sir2 and 2-xNPTl sir2 strains and again found no difference from wild type, indicating that the failure to detect increased NAD+ levels was not due to the activity of Sir2. NPT1 and SIR2 Increase Resistance to Heat Shock but Not to Other Stresses—Mutations in components of the C. elegans and Drosophila insulin/insulin-like growth factor-1 pathway allow animals to live up to twice as long as controls (5). In C. elegans this longevity is coupled to stress resistance (4). In contrast, the chico mutation in Drosophila, which extends life span by —50% in homozygotes, does not appear to protect against heat shock or oxidative stress (51). The link between sir2.1 life span extension and stress resistance in C. elegans has not been examined, although there is evidence from yeast that the Sir2/3/4 complex may be involved in such a response. The yeast sir4-42 mutation increases replicative life span as well as resistance to starvation and heat shock (52), which raises the possibility that the SIR2 longevity pathway may also influence stress resistance. To explore this, we examined the ability of extra copies of NPT1 and SIR2 to confer resistance to a variety of stresses, including heat shock, starvation, and exposure to methylmeth-ane sulfonate (MMS) or paraquat. MMS is a DNA-damaging agent that causes a variety of DNA lesions, whereas paraquat induces oxidative stress by generating reactive oxygen species. Additional copies of either NPT1, SIR2, or both did not provide resistance against paraquat or MMS, nor did they enhance the ability to survive in stationary phase (data not shown). To assay heat-shock resistance, strains with an additional copy of NPT1 or SIR2 were grown to stationary phase in SC medium, heat-shocked for 1 h at 55 °C, then spotted in 10-fold serial dilutions onto SC plates. As shown in Fig. 2A, strains with a single additional copy of NPT1 or SIR2 were significantly more resistant to heat shock than the otherwise isogenic wild type control strain. No additive effect of NPT1 and SIR2 was apparent, consistent with these two genes acting in the same pathway. To provide a more quantitative measure of this phenotype, strains were subjected to 1 h heat shock and plated for single colonies, and the number of colonies after 24 h was scored as a percentage of the untreated sample. As shown in Fig. 2B, additional copies oiNPTl and SIR2, or both, provided —3-fold greater survival than wild type, consistent with our earlier finding. Additional NPT1 Increases Silencing and rDNA Stability—We wished to determine the molecular basis of the SIR2-dependent life span extension provided by additional NPTl. A simple model predicts that increased dosage of NPTl would stimulate the NAD+ salvage pathway, which would in turn increase Sir2 activity. We thus examined the effect of additional copies of NPTl on the SZR2-dependent processes of silencing and stability at the rDNA locus. To determine the effect of NPTl on rDNA silencing, we O o > 3 W o > d •z < o Increased Nuclear NAD Synthesis Extends Life Span 18887 PNCt NO NPTÍ £>Ac-ADP-ribose NaM silencing J NAD salvage I .,An-> I 1 pattmsy I" ' I NaMN NMA! NMA? seer ne B instability I AGING I no adenine ADE2 • • wt(1 x/wnj LIS 2XNPT1 EZB 2xPNC1 2XNMA2 fTTI 2XNMA1 • • • 2xQNS1 • • wt 2X.NPT1 2Y.NMA2 sir2 2Y.PNC1 2xNMA 7 Fig. 5. Multiple limiting components in the NAD+ salvage pathway. A, the putative steps in NAD+ biosynthesis in S. cerevisiae based on the known steps in Salmonella. The yeast genes that are thought to mediate each step are shown in italics. NaMN, nicotinic acid mononucleotide; NaAD, desamido-NAD+; NaM, nicotinamide; Na, nicotinic acid. Adapted from Smith et al. (23). B, silencing ofADE2 at the rDNA locus in strains ADE2 (YDS1596), wild type (W303AR5), 2xNPTl (YDS1503), 2xPNCl (YDS1588), 2xNMA2 (YDS1589), 2xNMAl (YDS1590), and 2xQNSl (YDS1614). Increased silencing is indicated by growth retardation on media lacking adenine. C, strains with an ADE2 marker at the telomere were streaked onto SC medium containing limiting amounts of adenine. Silencing is indicated by the accumulation of a red pigment. Strains tested: wild type (PSY316AT), 2xNPTl (YDS1544), 5xNPTl (YDS1548), sir2::TRPl (YDS1594), 2xPNCl (YDS1591), 2xNMA2 (YDS1592), and 2xNMAl (YDS1593). utilized strains with either an ADE2 or MET15 marker integrated at the rDNA locus (RDN1) (Table II). We used two marker genes to ensure that the effects we observed were not simply due to changes in adenine or methionine biosynthesis. Silencing of ADE2 results in slower growth of cells on media lacking adenine and the accumulation of a red pigment on plates with limiting adenine. Silencing of MET15 leads to production of a brown pigment on Pb2+-containing medium. Strains with additional copies of SIR2 were included for comparison. The 2xNPTl strains showed higher levels of rDNA silencing than wild type in the ADE2 assay (Fig. 3A, compare growth on adenine with growth on no adenine) and the MET15 assay (Fig. 3B). Introduction of an additional copy ofNPTl into the 2xSIR2 strain did not further increase silencing, again consistent with the placement of these two genes in the same pathway. Strains carrying SIR2 and NPT1 on high copy 2/x-based plasmids also showed increased levels of rDNA silencing, although not as great as strains carrying single extra copies, for reasons that remain unclear (Fig. 3, B and C). An additional copy of NPT1 also increased silencing in sir3 and sir4 null strains (Fig. 3C). High copy NPT1 had a disruptive effect on rDNA silencing in the sir3 strain, whereas this effect was not observed in the sir4 strain. This can be explained by the fact that sir4 mutants relocalize Sir2 to the rDNA, which may counteract the high levels of Nptl. Additional copies ofNPTl in a sir2 mutant caused a slight increase in rDNA silencing that was considerably weaker than SZR2-dependent silencing. The basis of this apparent increase is unclear. To determine whether this was a global effect on silencing, we examined silencing at a telomeric locus. An additional copy of NPT1 was introduced into PSY316AT, which has an ADE2 marker inserted in the subtelomeric region of chromosome V (53). As shown in Fig. 3D, additional copies of NPT1 increased telomeric silencing in an SZR2-dependent manner. Instability of the rDNA has been shown to be a major cause of yeast replicative aging. To test whether NPT1 extends life span by increasing stability at this locus, we determined the rate of rDNA recombination in 2-xNPTl and 2xSIR2 strains. This was achieved by measuring the rate of loss of an ADE2 marker inserted at the rDNA. As shown in Fig. 3E, an additional copy of NPT1 decreased rDNA recombination by 2-fold, similar to the 2xSIR2 and 2xNPTl 2xSIR2 strains. When sir2 was deleted from the 2xNPTl strain, rDNA recombination increased dramatically to the levels of a sir2 null strain (Fig. 3F). These results are consistent with a model in which NPT1 extends replicative life span by increasing the ability of Sir2 to inhibit rDNA recombination. One plausible explanation for the increase in rDNA silencing associated with additional copies of NPT1 is that the telomeric Sir2 in these strains is relocalized to the rDNA, which would result in the loss of telomeric silencing. We have shown that additional copies of NPT1 increase telomeric silencing in a SZR2-dependent manner, arguing against relocalization of Sir2 from telomeres as the mechanism of life span extension. Another possible explanation is that additional NPT1 up-regu-lates Sir2 expression. By Western blotting we found that the steady-state levels of Sir2 did not change in response to additional NPT1 (data not shown). A third possibility for the increase in rDNA silencing is that additional NPT1 stimulates overall Sir2 activity. Although it is not currently possible to measure this activity in vivo, this idea is consistent with our findings that additional NPT1 enhances each of the SIR2-de-pendent processes thus far examined. Caloric Restriction Does Not Alter NPT1 Expression or Localization—Given that additional NPT1 and caloric restriction appear to extend life span via the same pathway, we tested whether caloric restriction acts by increasingNPT1 expression. A triple hemagglutinin epitope (3xHA) tag was added to the carboxyl terminus of Nptl by integrating a 3xHA-kanamycin resistance cassette into the native NPT1 locus. We confirmed that the fusion protein was functional by assaying its ability to maintain wild type levels of rDNA silencing (data not shown). NPT1 levels were then determined in strains grown on (0.5%) glucose medium and in the long-lived cdc25-10 strain, which is considered a genetic mimic of caloric restriction (19). As shown in Fig. 4 (A and B), no increase in NPT1 expression was detected at the mRNA or protein level. In fact under low glucose conditions a consistent ~2-fold decrease in NPT1 expression was observed. We did not detect significant changes in NPT1 expression after heat shock or exposure to MMS or paraquat (Fig. 4, C and D). We conclude that caloric restriction does not increase longevity by up-regulating NPT1 expression. Given that NPT1 expression was not enhanced in response to O o > 3 W O < > d •z < o 18888 Increased Nuclear NAD Synthesis Extends Life Span Fig. 6. Model for life span extension via increased flux through the NAD+ salvage pathway. Type III histone Tryptophan and deacetylases such as Sir2 and Hstl-4 cat- aspartate alyze a key step in the salvage pathway metabolism by converting NAD+ to nicotinamide. Additional copies of PNC1, NPT1, NMA1, and NMA2 increase flux through the NAD+ salvage pathway, which stimulates Sir2 activity and increases life span. Additional copies of QNS1 fail to increase silencing. Unlike other steps in the path- Quinolinate way, its substrate cannot be supplied from a source outside the salvage pathway and is therefore limiting for the reaction. Abbreviations: NAD*, nicotinamide adenine dinucleotide; NaMN, nicotinic acid mononucleotide; NaAD, desamido-NAD+. Exogenous Nicotinic acid TN A 7 Nicotinic acid NPTl PNC1 Nicotinamide BNA genes NaMN QPT1 NMA1 NMA2 NADP+ Increased ► silencing & longevity NaAD QNS1 caloric restriction, we examined the possibility that the activity of this protein may be modulated by other means. Specifically, we examined the subcellular localization of GFP-tagged Nptl in live cells grown in complete or low glucose medium. To our surprise, Nptl was observed throughout the cell with an apparent concentration of the protein in the nucleus of most cells (Fig. 4E). The large regions of exclusion correspond to vacuoles. These findings raise the intriguing possibility that a significant fraction of NAD+ is regenerated in the nucleus. In low glucose medium the localization pattern of Nptl-GFP was unaltered, indicating that there is no gross relocalization of Nptl in response to caloric restriction (data not shown). If our hypothesis is correct that the entire NAD+ salvage pathway exists in the nuclear compartment, then we should expect that other enzymes in the pathway will show a similar localization pattern to Nptl. Based on the bacterial salvage pathway, the step immediately downstream of NPT1 is predicted to be catalyzed by a nicotinate mononucleotide adenylyltransferase (NaMAT). There are two yeast ORFs with similar homology to NaMATs from other species, YLR0328 and YGR010, which we have designated NMA1 and NMA2, respectively. To localize these two proteins, a GFP cassette was integrated in-frame prior to the stop codon of each ORF to generate carboxyl-terminal fusions. As shown in Fig. 4F, Nma2-GFP was concentrated in the nucleus in the majority of cells, in a pattern identical to that of Nptl-GFP. This finding further supports our hypothesis that NAD+ is recycled from nicotinamide entirely within the nucleus. The localization pattern of Nmal could not be determined due to low expression levels (data not shown). Identification of Other Putative Longevity Genes in the NAD+ Salvage Pathway—The discovery that Nma2 shows a similar localization to Nptl prompted us to test whether other genes in the NAD+ salvage pathway could have similar effects to Nptl when overexpressed. Although the bacterial genes in NAD+ salvage pathway have been studied in detail, in S. cerevisiae some of the key genes in the pathway remain to be characterized. PNC1, a recently identified gene, encodes a nicotinami-dase, which catalyzes the conversion of nicotinamide to nicotinic acid, the step immediately upstream of NPTl. As discussed above, the two genes NMA1 and NMA2 encode NaM-NATs, which catalyze the step immediately downstream of NPTl. In bacteria, the next step in the pathway, the generation of NAD+, is catalyzed by an NAD synthetase. An uncharacter-ized ORF, QNS1/YHR074, shows high homology to NAD synthetases. Each of these salvage pathway genes was integrated as a single copy into the URA3 locus of W303AR5 and PSY316AT and assayed for silencing as previously described. Additional copies of either PNC1, NMA1, or NMA2 increased rDNA and telomeric silencing to levels similar to those in a 2-xNPTl strain (Fig. 5, B and C). In contrast, additional copies of QNS1 had no effect on either rDNA silencing (Fig. 5B) or telomeric silencing (data not shown). As discussed below, these results indicate there are multiple steps that can affect the rate of the pathway and that the two homologs NMA1 and NMA2 may have overlapping functions. DISCUSSION NPTl encodes a key component of the yeast salvage pathway that recycles NAD+, a cofactor of Sir2. We have shown that additional copies of NPTl increase life span by up to 60% in a SZR2-dependent manner. It has been proposed that longevity in yeast may be associated with increased NAD+ levels. However, we have shown that in strains with additional copies of NPTl, steady-state NAD+ levels are unaltered. Furthermore, the NAD+/NADH ratios are also similar to wild type cells, indicating that total cellular redox state is not dramatically altered either. We have also shown that sir2 mutants have wild type NAD+ levels, implying that Sir2 is not a major consumer of NAD+. Nevertheless, by virtue of its ability to convert NAD+ to nicotinamide, Sir2 should be responsive to increased flux through the salvage pathway (Fig. 6). Thus, although steady-state levels of NAD+ remain constant, the turnover of this molecule may be elevated. Localization of GFP-tagged enzymes indicated that at least two of the enzymes in the NAD+ salvage pathway are concentrated in the nucleus. Consistent with this, Nmal and Nma2 have been shown by high throughput two-hybrid screening to interact with Srpl, a protein that acts as a receptor for nuclear localization sequences (54). The same two-hybrid screen also found that Nmal and Nma2 can interact with themselves and with each other. Perhaps Nma proteins exist as dimers, as is the case for the Bacillus subtilis NaMNAT (55), or as hexamers, as is the case for Methanococcus jann-aschii (56) and Methanobacterium thermoautotrophicum NaM-NATs (57). It is worth nothing that strains disrupted for either NMA1 or NMA2 are viable, arguing that they may be functionally redundant, given that the conversion of NaMN to NAD+ is apparently essential for viability (58). In vertebrates, NaMNAT/NMNAT activity is primarily observed in the nuclear fraction of liver cell extracts (59), suggesting that nuclear compartmentalization of the pathway may Increased Nuclear NAD Synthesis Extends Life Span 18889 be a universal property of eukaryotic cells. Having the salvage pathway in proximity to chromatin may allow NAD+ to be rapidly regenerated for silencing proteins. Alternatively, it may permit the coordination of a variety of nuclear activities via the alteration of nuclear NAD+ pools. Testing of these hypotheses will not be a simple task but one that will be greatly assisted by the development of a molecular probe for intracellular NAD+. In yeast and many metazoans, a number of long-lived mutants display increased stress resistance. However, there are many examples of mutations that extend life span but provide little protection against stress, indicating that this relationship is not straightforward (4). For example, in yeast the life span extension provided by a cdc25-10 mutation is not accompanied by heat-shock resistance (19). We have shown that additional copies of NPT1 or SIR2 extend life span but do not provide protection against MMS, paraquat, or starvation. Thus, in S. cerevisiae, longevity is not linked to a general increase in stress resistance. The only stress-related phenotype that correlated with longevity was heat-shock resistance. Based on genome-wide analyses of gene expression in sir2A strains, it has been proposed that Sir2 regulates genes other than those at the three silent loci (60), although this interpretation is debated (61). If the interpretation is correct, then it is plausible that the heat-shock resistance we observed in 2xNPTl and 2xSIR2 strains results from Sir2-mediated silencing of genes that suppress heat-shock resistance. In bacteria, the Nptl homolog PncB catalyzes a rate-limiting step in the NAD+ salvage pathway (35, 37, 38). In this study we show that additional copies of PNC 1, NPT1, NMA1, or NMA2 all increase rDNA and telomeric silencing. The implication is that, in yeast, multiple steps can affect the rate of the pathway. Such a proposal is consistent with Metabolic Control Analysis, a theory based on the observation that flux through most metabolic pathways is controlled by multiple enzymes, rather than by a single rate-liming step (62). Of all the genes in the salvage pathway, only QNS1 had no effect on silencing, suggesting that it is the only enzyme in the pathway limited by substrate availability. This is likely due to the fact that the predicted substrate for Qnsl, desamido-NAD+, is the only intermediate that cannot be supplied from a source outside the salvage pathway (see Fig. 6). In yeast and metazoans there are multiple members of the Sir2 family, many of which have been shown (or are predicted) to be NAD+-dependent deacetylases (24, 63). This finding, combined with the fact that some Sir2 family members are cytoplasmic (64, 65), suggests that reversible acetylation may be a much more prevalent regulatory mechanism than previously thought (66). This would place the NAD+ salvage pathway in a pivotal position, coordinating the activity of this group of effector proteins in response to cellular energy status. It is now widely accepted that there are conserved pathways for the regulation of longevity (4, 5). The extent of this conservation is exemplified by the discovery that additional copies of C. elegans sir-2.1 also extend life span in that organism (31). Our findings show that several SZR2-dependent processes can be enhanced by manipulation of the NAD+ salvage pathway in yeast, and this may hold true for higher organisms. We have identified NPT1 homologs in every genome we have examined, and all possess a highly conserved region around a histidine residue that, in Salmonella, greatly stimulates catalysis when phosphorylated (67). This mode of regulation may permit the design of mutations or small molecules that increase Nptl activity. Together, our findings show that Nptl and other members of the salvage pathway are attractive targets for small molecules that may mimic the beneficial effects of caloric restriction. Acknowledgments—We thank D. Moazed, J. Smith, C. Grubmeyer, M. Bryk, F. Winston, A. Andalis, and G. Fink for reagents and advice. We also thank S. Luikenhuis for help with manuscript preparation. REFERENCES 1. Masoro, E. J. (2000) Exp. Gerontol. 35, 299-305 2. Vanfleteren, J. R., and Braeckman, B. P. (1999) Neurobiol. Aging 20, 487-502 3. Zainal, T. A., Oberley, T. D., Allison, D. B., Szweda, L. I., and Weindruch, R. (2000) FASEB J. 14, 1825-1836 4. Kenyon, C. (2001) Cell 105, 165-168 5. Guarente, L., and Kenyon, C. (2000) Nature 408, 255-262 6. Kirkwood, T. B., and Rose, M. R. (1991) Philos. Trans. R Soc. Lond.BBiol. Sei. 332, 15-24 7. Barton, A. (1950) J. Gen. Microbiol. 4, 84-86 8. Sinclair, D. A, Mills, K, and Guarente, L. (1997) Science 277, 1313-1316 9. Mortimer, R. K, and Johnston, J. R. (1959) Nature 183, 1751-1752 10. Kennedy, B. K, Austriaco, N. R., Jr., and Guarente, L. (1994) J. Cell Biol. 127, 1985-1993 11. Kim, S., Villeponteau, B., and Jazwinski, S. M. (1996) Biochem. Biophys. Res. Commun. 219, 370-376 12. Ashrafi, K, Lin, S. S., Manchester, J. K, and Gordon, J. I. (2000) Genes Dev. 14, 1872-1875 13. Lin, S. S., Manchester, J. K, and Gordon, J. I. (2001) J. Biol. Chem. 276, 36000-36007 14. Longo, V. D. (1999) Neurobiol. Aging 20, 479-486 15. Jazwinski, S. M. (2001) Mech. Ageing Dev. 122, 865-882 16. Sinclair, D. A, and Guarente, L. (1997) Cell 91, 1033-1042 17. Kaeberlein, M., McVey, M., and Guarente, L. (1999) Genes Dev. 13, 2570-2580 18. Park, P. U., Defossez, P. A, and Guarente, L. (1999) Mol. Cell. Biol. 19, 3848-3856 19. Lin, S. J., Defossez, P. A, and Guarente, L. (2000) Science 289, 2126-2128 20. Defossez, P. A., Prusty, R., Kaeberlein, M., Lin, S. J., Ferrigno, P., Silver, P. A., Keil, R. L., and Guarente, L. (1999) Mol Cell 3, 447-455 21. Tanner, K. G, Landry, J., Sternglanz, R., and Denu, J. M. (2000) Proc. Natl. Acad. Sei. U. S. A. 97, 14178-14182 22. Imai, S., Armstrong, C. M., Kaeberlein, M., and Guarente, L. (2000) Nature 403, 795-800 23. Smith, J. S., Brachmann, C. B., Celic, I., Kenna, M. A, Muhammad, S., Starai, V. J., Avalos, J. L., Escalante-Semerena, J. C, Grubmeyer, C, Wolberger, C, and Boeke, J. D. (2000) Proc. Natl. Acad. Sei. U. S. A. 97, 6658 - 6663 24. Landry, J., Sutton, A., Tafrov, S. T., Heller, R. C, Stebbins, J., Pillus, L., and Sternglanz, R. (2000) Proc. Natl. Acad. Sei. U. S. A. 97, 5807-5811 25. Laurenson, P., and Rine, J. (1992) Microbiol. Rev. 56, 543-560 26. Straight, A. F., Shou, W., Dowd, G. J., Turck, C. W., Deshaies, R. J., Johnson, A. D., and Moazed, D. (1999) Cell 97, 245-256 27. Shou, W., Seol, J. H., Shevchenko, A, Baskerville, C, Moazed, D., Chen, Z. W., Jang, J., Charbonneau, H., and Deshaies, R. J. (1999) Cell 97, 233-244 28. Shou, W., Sakamoto, K. M., Keener, J., Morimoto, K. W., Traverso, E. E., Azzam, R., Hoppe, G. J., Feldman, R. M. R., DeModena, J., Moazed, D., Charbonneaux, H., Nomura, M., and Deshaies, R. J. (2001) Mol. Cell. 8, 45-55 29. Tanny, J. C, and Moazed, D. (2001) Proc. Natl. Acad. Sei. U. S. A 98, 415-420 30. Smith, J. S., Caputo, E., and Boeke, J. D. (1999)Mol Cell. Biol. 19, 3184-3197 31. Tissenbaum, H. A, and Guarente, L. (2001) Nature 410, 227-230 32. Jiang, J. C, Jaruga, E., Repnevskaya, M. V., and Jazwinski, S. M. (2000) FASEB J. 14, 2135-2137 33. Foster, J. W., Kinney, D. M., and Moat, A. G. (1979) J. Bacteriol. 137, 1165-1175 34. Ghislain, M., Talla, E., and Francois, J. M. (2002) Yeast 19, 215-224 35. Wubbolts, M. G., Terpstra, P., van Beilen, J. B., Kingma, J., Meesters, H. A, and Witholt, B. (1990) J. Biol. Chem. 265, 17665-17672 36. Vinitsky, A., Teng, H., and Grubmeyer, C. T. (1991) J. Bacteriol. 173, 536-540 37. Imsande, J. (1964) Biochim. Biophys. Acta 85, 255-273 38. Grubmeyer, C. T., Gross, J. W., and Rajavel, M. (1999) Methods Enzymol. 308, 28-48 39. Emanuelli, M., Carnevali, F., Lorenzi, M., Raffaelli, N., Amici, A., Ruggieri, S., and Magni, G. (1999) FEBS Lett. 455, 13-17 40. Hughes, K. T., Olivera, B. M., and Roth, J. R. (1988) J. Bacteriol. 170, 2113-2120 41. Mills, K. D., Sinclair, D. A., and Guarente, L. (1999) Cell 97, 609-620 42. Smith, J. S., and Boeke, J. D. (1997) Genes Dev. 11, 241-254 43. Lalo, D., Carles, C, Sentenac, A, and Thuriaux, P. (1993) Proc. Natl. Acad. Sei. U. S. A 90, 5524-5528 44. Becker, D. M., Fikes, J. D., and Guarente, L. (1991) Proc. Natl. Acad. Sei. U. S. A. 88, 1968-1972 45. Sikorski, R. S., and Hieter, P. (1989) Genetics 122, 19-27 46. Guldener, U., Heck, S., Fielder, T., Beinhauer, J., and Hegemann, J. H. (1996) Nucleic Acids Res. 24, 2519-2524 47. De Antoni, A, and Gallwitz, D. (2000) Gene 246, 179-185 48. Longtine, M. S., McKenzie, A., 3rd, Demarini, D. J., Shah, N. G., Wach, A, Brachat, A, Philippsen, P., and Pringle, J. R. (1998) Yeast 14, 953-961 49. Keil, R. L., and McWilliams, A. D. (1993) Genetics 135, 711-718 50. Ashrafi, K, Lin, S. S., Manchester, J. K. and Gordon, J. I. (2000) Genes Dev. 14, 1872-1885 51. Clancy, D. J., Gems, D., Harshman, L. G, Oldham, S., Stocker, H., Hafen, E., Leevers, S. J., and Partridge, L. (2001) Science 292, 104-106 52. Kennedy, B. K, and Guarente, L. (1996) Trends Genet 12, 355-359 53. Gottschling, D. E., Aparicio, O. M., Billington, B. L., and Zakian, V. A. (1990) Cell 63, 751-762 18890 Increased Nuclear NAD Synthesis Extends Life Span 54. Uetz, P., Giot, L., Cagney, G., Mansfield, T. A., Judson, R. S., Knight, J. R., Lockshon, D., Narayan, V., Srinivasan, M., Pochart, P., Qureshi-Emili, A., Li, Y., Godwin, B., Conover, D., Kalbfleisch, T., Vijayadamodar, G., Yang, M., Johnston, M., Fields, S., and Rothberg, J. M. (2000) Nature 403, 623-627 55. Olland, A. M., Underwood, K. W., Czerwinski, R. M., Lo, M. C, Aulabaugh, A, Bard, J., Stahl, M. L., Somers, W. S., Sullivan, F. X., and Chopra, R. (2002) J. Biol. Chem. 277, 3698-3707 56. DAngelo, I., Raffaelli, N., Dabusti, V., Lorenzi, T., Magni, G, and Rizzi, M. (2000) Structure Fold Des. 8, 993-1004 57. Saridakis, V., Christendat, D., Kimber, M. S., Dharamsi, A., Edwards, A. M., and Pai, E. F. (2001) J. Biol. Chem. 276, 7225-7232 58. Winzeier, E. A., Shoemaker, D. D., Astromoff, A., Liang, H., Anderson, K., Andre, B., Bangham, R., Benito, R., Boeke, J. D., Bussey, H., Chu, A. M., Connelly, C, Davis, K, Dietrich, F., Dow, S. W., El Bakkoury, M., Foury, F., Friend, S. H., Gentalen, E., Giaever, G., Hegemann, J. H., Jones, T., Laub, M., Liao, H., and Davis, R. W., et al. (1999) Science 285, 901-906 59. Hogeboom, G, and Schneider, W. (1950) J. Biol. Chem. 197, 611-620 60. Bernstein, B. E., Tong, J. K, and Schreiber, S. L. (2000) Proc. Natl. Acad. Sei. U. S. A. 97, 13708-13713 61. Bedalov, A., Gatbonton, T., Irvine, W. P., Gottschling, D. E., and Simon, J. A. (2001) Proc. Natl. Acad. Sei. U. S. A. 98, 15113-15118 62. Fell, D. (1997) Understanding the Control of Metabolism. Frontiers in Metab- olism (Snell, K, ed) pp. 18-25, Portland Press, London 63. Landry, J., Slama, J. T., and Sternglanz, R. (2000) Biochem. Biophys. Res. Commun. 278, 685- 690 64. Perrod, S., Cockell, M. M., Laroche, T., Renauld, H., Ducrest, A. L., Bonnard, C, and Gasser, S. M. (2001) EMBO J. 20, 197-209 65. Afshar, G, and Murnane, J. P. (1999) Gene 234, 161-168 66. Shore, D. (2000) Proc. Natl. Acad. Sei. U. S. A. 97, 14030-14032 67. Rajavel, M., Lalo, D., Gross, J. W., and Grubmeyer, C. (1998) Biochemistry 37, 4181-4188 68. Campisi, J. (2000) Science 289, 2062-2063 69. Guarente, L. (2000) Genes Dev. 14, 1021-1026 Manipulation of a Nuclear NAD+ Salvage Pathway Delays Aging without Altering Steady-state NAD + Levels Rozalyn M. Anderson, Kevin J. Bitterman, Jason G. Wood, Oliver Medvedik, Haim Cohen, Stephen S. Lin, Jill K. Manchester, Jeffrey I. Gordon and David A. Sinclair J. Biol. Chem. 2002, 277:18881-18890. doi: 10.1074/jbc.M111773200 originally published online March 7, 2002 Access the most updated version of this article at doi: 10.1074/jbc.M111773200 Alerts: • When this article is cited • When a correction for this article is posted Click here to choose from all of JBC's e-mail alerts This article cites 68 references, 33 of which can be accessed free at http://www.jbc.Org/content/277/21/18881.full.html#ref-list-1 ADDITIONS AND CORRECTIONS THE JOURNAL OF BIOLOGICAL CHEMISTRY VOL 288, NO 33, p. 24160, August 16, 201 3 2013 by The American Society for Biochemistry and Molecular Biology, Inc. Published in the U.S.A. VOLUME 277 (2002) PAGES 18881-18890 DOI 10.1074/jbc.A113.111773 Manipulation of a nuclear NAD+ salvage pathway delays aging without altering steady-state NAD+ levels. Rozalyn M. Anderson, Kevin J. Bitterman, Jason G. Wood, Oliver Medvedik, Haim Cohen, Stephen S. Lin, Jill K. Manchester, Jeffrey I. Gordon, and David A. Sinclair PAGE 18883: During preparation of the manuscript, the same images of yeast colonies were inadvertently shown for two different wild type controls in Fig. 2A. The panel is for visual purposes only. The quantification of three independent experiments is shown in Fig. 25. The error does not affect the results or conclusions of the study. Authors are urged to introduce these corrections into any reprints they distribute. Secondary (abstract) services are urged to carry notice of these corrections as prominently as they carried the original abstracts. 24160 JOURNAL OF BIOLOGICAL CHEMISTRY ^§fP®lI^ VOLUME 288-NUMBER 33-AUGUST 16, 2013