Chromatin Assembly Factor I Mutants Defective for PCNA Binding Require Asf1/Hir Proteins for Silencing

Chromatin assembly factor I (CAF-I) is a conserved histone H3/H4deposition complex. Saccharomyces cerevisiae mutants lackingCAF-I subunit genes (CAC1 to CAC3) display reduced heterochromaticgene silencing. In a screen for silencing-impaired cac1 alleles,we isolated a mutation that reduced binding to the Cac3p subunitand another that impaired binding to the DNA replication proteinPCNA. Surprisingly, mutations in Cac1p that abolished PCNA bindingresulted in very minor telomeric silencing defects but causedsilencing to be largely dependent on Hir proteins and Asf1p,which together comprise an alternative silencing pathway. Consistentwith these phenotypes, mutant CAF-I complexes defective forPCNA binding displayed reduced nucleosome assembly activityin vitro but were stimulated by Asf1p-histone complexes. Furthermore,these mutant CAF-I complexes displayed a reduced preferencefor depositing histones onto newly replicated DNA. We also observeda weak interaction between Asf1p and Cac2p in vitro, and wehypothesize that this interaction underlies the functional synergybetween these histone deposition proteins.

INTRODUCTION

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Introduction

Chromatin assembly factor I (CAF-I) is a heterotrimeric proteincomplex that delivers histones H3 and H4 to DNA ( 43, 54) duringDNA replication or DNA repair ( 6, 7, 16). Both the biochemicalactivity and primary structure of CAF-I have been evolutionarilyconserved from budding yeast to humans ( 18 19 20, 33, 51).The human CAF-I subunit genes for p150, p60, and p48 are homologousto the yeast CAC1, CAC2, and CAC3 genes, respectively. The specificityof CAF-I for replicated DNA molecules is imparted by specificrecognition of the DNA polymerase processivity factor PCNA bythe large subunit of CAF-I in both yeast and human cells ( 37,61).

In yeast, CAC gene deletions result in reduced position-dependentgene silencing at all three silenced loci: telomeres, the silentmating loci, and ribosomal DNA ( 4, 5, 19, 26, 41). Becausemutations in histone termini ( 21, 24; reviewed in reference10) and histone-modifying enzymes (reviewed in references 8and 38) affect the magnitude of position-dependent gene silencing,this chromatin-mediated phenomenon is analogous to heterochromaticsilencing in multicellular organisms. In mammalian cells, CAF-Iinteracts directly with heterochromatin protein 1 (HP1) andlocalizes to heterochromatin in late S phase ( 29, 47). Furthermore,overexpression of a fragment of the p150 CAF-I subunit interfereswith chromatin-mediated transcriptional silencing in mouse cells( 48). Together, these data suggest a conserved role for CAF-Iin heterochromatin formation.

The yeast ASF1 gene is a member of a second histone depositionpathway important for chromatin assembly that largely overlapsthe role of CAF-I in silencing. ASF1 was identified in two independentgenetic screens for high-dosage disrupters of position-dependentgene silencing ( 23, 40). The Drosophila homologue of Asf1pwas purified in a complex with acetylated forms of histonesH3 and H4 as a factor that stimulates the nucleosome assemblyactivity of CAF-I in vitro ( 51). Yeast Asf1p also stimulatesthe activity of CAF-I in vitro ( 36), demonstrating that thisactivity is conserved. asf1 ${Delta}$ mutants display minor defects inheterochromatic gene silencing ( 23, 40, 51). However, cac ${Delta}$ asf1 ${Delta}$ double mutants display synergistic reductions in heterochromaticgene silencing, consistent with the in vitro synergy data (51).

HIR genes, first identified as transcriptional repressors (31, 58), are part of the ASF1-mediated silencing pathway ( 36).Like cac ${Delta}$ asf1 ${Delta}$ cells, cac ${Delta}$ hir ${Delta}$ double mutant cells display synergisticreduction of position-dependent gene silencing at both telomeresand the silent mating loci, exhibit slow growth after germination,and display increased sensitivity to methyl methanesulfonate( 17, 32). These phenotypes occur regardless of which of thethree cac ${Delta}$ or four hir ${Delta}$ gene deletions are combined ( 17, 32),suggesting that CAF-I and the Hir proteins function as independentcomplexes. Hir1p and Hir2p proteins interact with Asf1p in vitroand in cell extracts ( 36); in vivo interactions between Hir1pand Asf1p have been observed in two-hybrid experiments ( 46).Also, some mutant PCNA proteins block the contribution of ASF1and HIR genes to telomeric silencing ( 36). Thus, silencingby both the CAF-I and Asf1p/Hir pathways is a PCNA-dependentprocess.

To better understand the contribution of CAF-I to heterochromatinformation, we conducted a genetic screen for silencing-impairedalleles of the CAC1 gene. Analysis of one allele resulted indiscovery of an amino acid required for interaction betweenthe Cac1p and Cac3p proteins. Another allele, termed cac1-13,encoded a single amino acid change in a consensus PCNA-bindingmotif and impaired binding to PCNA by Cac1p. Mutations in thismotif caused mild telomeric silencing defects in otherwise wild-typecells, but caused dramatic silencing defects in the absenceof ASF1 or the HIR1 genes. We also discovered a weak interactionbetween Asf1p and the Cac2p subunit of CAF-I in vitro. We proposethat Asf1p/Hir proteins functionally assist CAF-I via this directinteraction and that this assistance is critical for nucleosomeformation in vivo when the Cac1p-PCNA interaction is impaired.

MATERIALS AND METHODS

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Materials and Methods

Plasmids. For T7 promoter-driven Cac2p expression, a NotI fragment witha triple hemagglutinin tag ( 50) was cloned into a NotI sitegenerated at the 3' end of CAC2. A 1.4-kb NdeI fragment of thisplasmid was inserted into pET15b (Novagen) to create pPK83.For T7 promoter-driven Cac1p expression, the 5' end of the CAC1gene was amplified by PCR to add a 2x polyomavirus epitope (PY)tag ( 35) to the N terminus using the oligonucleotides 5'-CCGGATCCGAAAATGGAATATATGCCAATGGGAATGGAATACATGCCTATGGAAATGGAGCAACATCTCTC-3'and 5'-TAAAAGCTTGTCTTCAGC-3'. A 2.3-kb BamHI fragment containingthe PY2-CAC1 gene was cloned into BamHI-digested pRSET-B (Invitrogen)to generate pPK122. For T7 promoter-driven Cac3p expression,the BamHI-SalI fragment from pPK115 ( 36) was cloned into BamHI-XhoI-digestedpRSET-B to create pPK123.

For expressing glutathione S-transferase (GST) fusion proteins,fragments of the CAC1 gene were cloned into pGEX-KG ( 11); detailsof constructs used are available upon request. All GST fusion-expressingplasmids were sequenced to ensure that no errors were introducedduring subcloning or PCR.

Yeast strains and medium. All strains used in this study are isogenic with the W303 geneticbackground ( 49), with the genotype leu2-3,112 ura3-1 his3-11,15trp1-1 ade2-1 can1-100. The URA3-VIIL telomere and cac1 ${Delta}$ , hir1 ${Delta}$ ,and asf1 ${Delta}$ gene deletions in W303 were described previously (17, 19, 36). The ADE2-VR telomere was integrated into the W303background using plasmid pHR10-6 ( 39). Standard procedureswere used for genetic crosses and tetrad analysis, and standardyeast medium was used for scoring genetic marker segregation( 15). SD is synthetic dextrose medium; 5-fluoro-orotic acid(FOA) was added to SD medium at a concentration of 1 mg/ml;medium with low adenine contained 5 mg/liter.

Yeast strains used in this study include PKY620 (MATa cac1 ${Delta}$ ::hisGADE2-VR), PKY557 (MATa cac ${Delta}$ 1::LEU2 ADE2-VR URA3-VIIL), PKY618(MAT ${alpha}$ cac1 ${Delta}$ ::hisG hir1 ${Delta}$ ::HIS3 ADE2-VR URA3-VIIL), PKY619 (MAT ${alpha}$ cac1 ${Delta}$ ::hisGADE2-VR URA3-VIIL), PKY950 (MAT ${alpha}$ cac1 ${Delta}$ ::LEU2 asf1 ${Delta}$ ::HIS3,URA3-VIIL),and PKY2095 [MAT ${alpha}$ cac1 ${Delta}$ ::hisG hir1 ${Delta}$ ::HIS3 ade3 ${Delta}$ (hht1-hhf1)-1216/pPK107(URA3 ADE3 CAC1 ARS/CEN)]. The (hht1-hhf1)-1216 allele was obtainedin a genetic screen and causes viability of hir1 ${Delta}$ strains tobe dependent on the CAC1 gene.

The CAC1-FLAG allele described previously ( 36) was shown tofully complement the telomeric silencing and UV sensitivityphenotypes of a cac1 ${Delta}$ strain (data not shown). Furthermore, weobserved that the CAC1-FLAG allele restores wild-type levelsof telomeric silencing to a cac1 ${Delta}$ hir1 ${Delta}$ strain, which is a moresensitive assay for CAC1 function ( 17).

Telomeric silencing assays using the URA3-VIIL reporter ( 9)were performed as previously described ( 36).

Mutagenesis of CAC1 and recovery of silencing-defective alleles. In vitro PCR-based mutagenesis of CAC1 was performed as described( 27); details of oligonucleotides used and PCR conditions areavailable upon request. Yeast strain PKY2095 was transformedsimultaneously with mutagenized PCR products and XhoI- and BamHI-digestedpPK150 (CAC1 TRP1 ARS/CEN) ( 36); colonies were grown on mediumlacking tryptophan to select for recombination of the mutantalleles into the plasmid backbone. A total of 236 colonies wereeither replica-plated or patched to -Trp +FOA plates to curePKY2095 of the wild-type CAC1 URA3 plasmid pPK107. Because (hht1-hhf1)-1216cells require CAC1 for viability, transformants capable of growthon -Trp +FOA contained nonnull cac1 alleles. Trp⁺, FOA-resistanttransformants were then mated to PKY620, which contains an ADE2-VR-markedtelomere and wild-type HIR1 and HHT1-HHF1 genes but lacks theCAC1 gene. The resulting diploids therefore contained a colonycolor marker to assay telomeric silencing, had both chromosomalcopies of CAC1 deleted, contained a mutated cac1 allele on theplasmid, had one functional copy of the HIR1 gene, and had threeout of four wild-type histone H3/H4 loci.

Diploid cells were streaked onto -Trp +low adenine plates toselect for the plasmid and test for telomeric silencing defects.Candidate cac1 alleles were isolated from strains that appearedmostly white or sectored, indicating a silencing defect. Themutations responsible for silencing defects were mapped by subcloningand sequenced on both strands. All mutant proteins accumulatedto levels similar to the wild-type protein (data not shown).Also, addition of the C-terminal FLAG tag did not alter thesilencing phenotypes of any of the alleles (data not shown).Additional alleles generated by site-directed mutagenesis allmaintained viability of strain PKY2095 in the absence of a wild-typeCAC1 gene (data not shown).

Protein purification. Overproduction and purification of yeast PCNA in Escherichiacoli were performed as described ( 1). CAF-I, CafI-13, CafI-20,and the Cac1/3 complex were purified from infected Sf9 cells,GST-Asf1p and Asf1p were purified from E. coli, and the Asf1p+ H3/H4 complex was formed and purified as described ( 36).Other GST fusion proteins were prepared essentially as described( 18) (details are available on request), except that the glutathione-agaroseresin was washed with buffer containing 300 mM NaCl prior toelution.

Biochemical experiments. For GST fusion coprecipitation experiments with Cac1p, Cac2p,and Cac3p, 2.5 µg of GST or GST-Cac1p or 10 µl ofGST-Asf1p were bound to 10 µl of glutathione agarose (Sigma)and incubated with 5 µl of ³⁵S-labeled in vitro-translatedCac1p, Cac2p, or Cac3p (T7 single tube protein transcription/translation;Novagen) in 200 µl of buffer A with 25 mM NaCl and 50µg of ethidium bromide per ml. Reactions were rotatedat 4°C for 1 h, followed by three 1-ml washes in bufferA-500 mM NaCl (GST-Cac1p experiments and GST-Asf1p + Cac2p)or buffer A-25 mM NaCl (GST-Asf1p + Cac3p) or buffer A-250 mMNaCl (GST-Asf1p + Cac1p). Bound proteins were eluted with sodiumdodecyl sulfate (SDS) sample buffer and separated by sodiumdodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)followed by autoradiography. For GST fusion coprecipitationexperiments with PCNA, 4 µg of GST-Cac1p was incubatedwith 35 ng of PCNA in 100 µl of buffer A-100 mM NaCl-50µg/ml ethidium bromide. Reactions were rotated at 4°Cfor 1 h followed by three washes of 1 ml of buffer A-500 mMNaCl. Bound proteins were eluted with SDS sample buffer andseparated by SDS-PAGE followed by Western analysis.

To coimmunoprecipitate CAF-I and Asf1p, 100 ng of affinity-purifiedCAF-I or Cac1/3 was incubated with 60 ng of Asf1p ± H3/H4for 10 min at 30°C in a 30-µl reaction in buffer A-50mM NaCl followed by addition of 10 µl of 50% anti-PY antibody( 35), cross-linked to protein A-Sepharose ( 13) and 10 µlof 50% G50-Sepharose. This mixture was rotated at 4°C for1 h, followed by three washes of 1 ml of buffer A-100 mM NaCl.Proteins were eluted with SDS sample buffer, separated by SDS-PAGE,and analyzed by immunoblotting.

Glycerol gradient sedimentation was performed by incubating200 ng of CAF-I, 350 ng of Asf1p + H3/H4, and/or 1,000 ng ofAsf1p in 30 µl of buffer A-50 mM NaCl at 30°C for10 min, followed by addition of 70 µl of buffer A-50 mMNaCl. Each protein mixture was overlaid onto a 5-ml 10 to 40%glycerol gradient and centrifuged at 200,000 x g at 4°Cfor 24 h. The gradients were separated into 380-µl fractions,and 5 µl was separated by SDS-PAGE followed by immunoblotanalysis. Protein standards were chymotrypsinogen A (25 kDa),chicken egg albumin (45 kDa), bovine serum albumin (68 kDa),aldolase (158 kDa), and catalase (240 kDa).

Nucleosome assembly assays and micrococcal nuclease (MNase)digestions were performed as described ( 19, 36), except thatthe human cells used to make the replication extracts were HeLaand not 293 cells.

RESULTS

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Results

Isolation of silencing-defective cac1 alleles. To isolate silencing-defective cac1 alleles, we made use ofour discovery that CAC1 is essential for viability in yeaststrains that lack the HIR1 gene and contain a mutation in theHHT1-HHF1locus, one of the two histone H3- and H4-encoding loci(M. D. Adams and P. D. Kaufman, unpublished results) (Fig. 1A).To ensure that our screen would yield nonnull cac1 alleles,we first selected cac1 alleles that maintained the viabilityof a haploid cac1 ${Delta}$ hir1 ${Delta}$ hht1-hhf1 strain (Fig. 1A). Viable cellswere then mated to cac1 ${Delta}$ ADE2-VR cells (Fig. 1B). In the resultingdiploid cells, the only source of CAC1 was the mutagenized gene.The diploids also contained one wild-type copy of the HIR1 andHHT1-HHF1 genes, so any silencing defects detected by the telomericADE2-VR reporter resulted solely from the mutant cac1 allele.In the secondary screen, mutant cac1 alleles that reduced silencingof the telomeric ADE2 gene were then isolated based on colonycolor (Fig. 1B; see Materials and Methods). This screen resultedin isolation of six silencing-defective CAC1 alleles (termedcac1-11 through cac1-16), and we present data here concerninga subset of these.

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FIG. 1. Isolation of silencing-impaired cac1 alleles. (A) Isolation of nonnull cac1 alleles (see text and Materials and Methods for details). Strain PKY2095 [cac1 ${Delta}$ hir1 ${Delta}$ (hht1-hhf1)-1216/pPK107 (URA3-CAC1)] was transformed with plasmids bearing the TRP1 gene and the indicated cac1 alleles or a vector control. Transformants were patched onto SC -Trp +FOA medium to select against plasmid pPK107 and incubated for 4 days at 30°C. Growth indicates the ability of the indicated cac1 allele to maintain viability of the hir1 ${Delta}$ (hht1-hhf1)-1216 cells. (B) Identification of cac1 alleles with telomeric silencing defects. Cells containing the ADE2 gene at telomere VR and the indicated cac1 alleles were plated on -Trp + low adenine plates and grown for 6 days at 30°C followed by 1 day at 4°C. (C) Map of the Cac3p (violet) and PCNA (orange) binding sites on Cac1p and locations of cac1 allele mutations. The highly charged K/E/R-rich and E/D-rich regions of the protein are indicated in purple and blue, respectively. Protein binding data from Fig. 2 are summarized on the right. ND, not determined.

Mutation of the Cac3p-binding site of Cac1p. The three alleles cac1-13, cac1-14, and cac1-15 each containedmutations within the region of Cac1p that we identify here asthe Cac3p binding site (Fig. 1C). To map the Cac3p binding siteon Cac1p, we tested various GST-Cac1p protein fusions for theability to coprecipitate in vitro-translated Cac3p. We observedthat GST fused to Cac1p amino acids 87 to 429 would efficientlyprecipitate Cac3p and that Cac1p amino acids 215 to 429 weresufficient for this interaction (Fig. 2A, lanes 2 and 7). Incontrast, GST fused to Cac1p residues 87 to 306 or 427 to 606or unfused GST did not bind Cac3p (Fig. 2A, lanes 6, 8, and9). We concluded that Cac1p residues 215 to 429 contain theCac3 binding site (Fig. 1C).

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FIG. 2. Protein binding defects of Cac1p mutants. (A) Cac1-15p does not bind Cac3p in vitro. GST fusion proteins (amino acids 87 to 429 of Cac1p, Cac1-15p, Cac1-21p, or Cac1-22p, amino acids 87 to 306, 215 to 429, or 427 to 606 of Cac1p, or an unfused GST control) were incubated with in vitro-translated Cac3p and washed extensively in the presence of 500 mM NaCl. Bound proteins were eluted with SDS sample buffer, separated by SDS-12.5% PAGE, and visualized by autoradiography. The input (lane 1) contains 1/10 of the amount of translation product input into the binding assays. The upper panel labeled autoradiogram shows in vitro-translated Cac3p, and the lower panel labeled Coomassie shows the input GST fusion proteins for the same experiment. The GST-Cac1p proteins were susceptible to proteolysis, resulting in the pattern of bands shown in the lower panel. (B) Evolutionary conservation of the consensus PCNA-binding motif in CAC1 homologues from human (GenBank accession number XM009408), mouse (NM013733), Xenopus laevis (AF222339), Drosophila melanogaster (AF367177), Arabidopsis thalania (AB027229), Schizosaccharomyces pombe (AL034463), and S. cerevisiae (NP015343). The consensus PCNA-binding motif is shown at the top of the shaded rectangle. Mutations in the cac-13 and cac1-20 alleles are indicated. Residues comprising the PCNA-binding motif are in bold. (C) Cac1-13p and Cac1-20p are defective in PCNA binding. GST fusion proteins (amino acids 87 to 429 of Cac1p, Cac1-13p, Cac1-14p, or Cac1-20p [lanes 2 to 5] or amino acids 427 to 606 of Cac1p [lane 6]) were incubated with purified recombinant yeast PCNA or in vitro-translated Cac3p. Samples were washed extensively in the presence of 500 mM NaCl, and bound proteins were eluted with SDS sample buffer and separated by SDS-15% PAGE. Cac3p was visualized by autoradiography, and PCNA was visualized by immunoblotting. The lower panel labeled Ponceau shows the input GST fusion protein for the PCNA coprecipitation experiment. For Cac3p, the input lane contains 1/30 of the amount of translation product input into the binding assays; for PCNA, the input lane contains 1/10 of the amount input (lane 1).

We then tested the effects of the mutations identified in thegenetic screen on Cac3p binding by generating GST fusion proteinsof amino acids 87 to 429 from each cac1 mutant. GST-Cac1-13pand GST-Cac1-14p bound to Cac3p with wild-type affinity (Fig.2C). In contrast, GST-Cac1-15p did not coprecipitate Cac3p (Fig.2A, lane 3). Cac1-15p contains two amino acid changes, F257Land L276P, and both reside within the Cac3p binding region.To determine which of these substitutions impaired Cac3p binding,we separated them, creating the cac1-21allele, encoding thesingle L276P substitution, and the cac1-22 allele, encodingthe F257L change. GST-Cac1-21p only weakly associated with Cac3p;in contrast, GST-Cac1-22p bound Cac3p with wild-type efficiency(Fig. 2A, lanes 4 and 5). We therefore concluded that the L276Psubstitution alone greatly impaired Cac3p binding. Thus, isolationof cac1-15 allowed us to identify a single amino acid importantfor interaction between Cac1p and Cac3p.

Mutation of the PCNA-binding site of Cac1p. The cac1-13 allele encodes a single amino acid change at aminoacid 233, converting a phenylalanine to leucine (Fig. 1C). Thismutation falls within a seven-amino-acid region, residues 227to 234 (QSRIGNFF), which matches a characterized PCNA-bindingmotif [Qxx(I/L/V)xx(F/Y)(F/Y)] (Fig. 2B) ( 55). The structureof a peptide containing this motif bound to human PCNA showsthat the aromatic residues in this motif are buried in a hydrophobicpocket on the interdomain loop of PCNA ( 12). Furthermore, mutationof either of these aromatic residues to alanine in the cellcycle regulator p21 disrupts PCNA binding ( 30). We note thatthe aromatic residues of this motif are conserved in Cac1p homologs(Fig. 2B), although the initial glutamine is not found in thegenes from multicellular species (see Discussion).

Both human p150 and yeast Cac1p bind PCNA ( 25, 61), but thesite of interaction on CAF-I had not been determined previously.To determine whether the conserved aromatic residues in Cac1pcontribute to PCNA binding, we tested the interaction betweenmutant GST-Cac1p proteins and purified recombinant yeast PCNA.Consistent with previous experiments ( 61), GST-Cac1p aminoacids 87 to 429 coprecipitated purified recombinant yeast PCNA(Fig. 2C, lane 2). Notably, Cac1-13p was much less efficientat coprecipitating PCNA than was wild-type Cac1p. In contrastGST-Cac1-14p, which has mutations just outside of the PCNA-bindingmotif (amino acids 191, 217, and 265; see Fig. 1C), bound PCNAwith wild-type affinity. GST-Cac1p and GST-Cac1-13p bound toCac3p with equal efficiency, suggesting that Cac1-13p was specificallydefective in PCNA binding (Fig. 2C, autoradiogram). To moredramatically alter the PCNA-binding motif, we also directlychanged both aromatic residues to create the cac1-20 allele(F233A, F234G; Fig. 1C and 2B). We observed that Cac1-20p alsodisplayed reduced binding to PCNA but retained normal affinityfor Cac3p (Fig. 2C, lane 4). Therefore, Cac1-13p and Cac1-20pwere specifically defective in PCNA binding, demonstrating thatalterations of the canonical PCNA-binding motif disrupt theCac1p-PCNA interaction.

Telomeric silencing phenotypes. To ensure that the telomeric silencing defects observed in thegenetic screen were not specific to the ADE2 gene at telomereVR, we also tested the cac1 alleles for telomeric silencingusing the URA3 gene placed adjacent to telomere VIIL (Fig. 3A).The drug FOA is toxic to cells expressing the URA3 gene ( 2);therefore, growth in the presence of FOA indicated that theURA3 gene was silenced. The URA3-VIIL assay also facilitatedmore quantitative differentiation of the silencing defects causedby the cac1 alleles, which could not be distinguished usingADE2-VR (compare Fig. 1B and 3A). For example, using URA3-VIIL,we observed that very mild reductions in telomeric silencingresulted from all alleles tested except cac1-15, which causeda strong defect (Fig. 3A). Notably, although the amino acidchanges in both the cac1-15 (F257L, L276P) and cac1-21 (L276P)alleles blocked Cac3p binding (Fig. 2A), only cac1-15 causeda strong loss of silencing. Each mutant Cac1p protein accumulatedto wild-type levels (data not shown); thus, differential proteinstability was not responsible for the different silencing phenotypes.Therefore, we concluded that the strong silencing defect causedby cac1-15 required both the F257L and L276P amino acid changes.

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FIG. 3. Telomeric silencing defects of cac1 alleles. Tenfold serial dilutions of cells containing the URA3-VIIL telomere and the indicated cac1 alleles were plated onto SC -Trp or SC -Trp +FOA plates and grown for 5 days at 30°C. Strains used were (A) PKY619 (cac1 ${Delta}$ ), (B) PKY618 (cac1 ${Delta}$ hir1 ${Delta}$ ), and (C) PKY950 (cac1 ${Delta}$ asf1 ${Delta}$ ).

cac1 alleles sensitive to loss of ASF1 and HIR1 genes. To further differentiate among the silencing-defective cac1alleles, we sensitized the telomeric silencing assay by deletionof the ASF1 or HIR gene, both of which contribute to a silencingpathway that functionally overlaps CAF-I ( 17, 36, 51). As observedpreviously, deletion of either the HIR1 or ASF1 gene in thepresence of a wild-type CAC1 gene had little effect on silencing.In contrast, combination of either asf1 ${Delta}$ or hir1 ${Delta}$ gene deletionswith the cac1 alleles reduced the efficiency of telomeric silencingup to 100,000-fold, depending on the particular cac1 allele(Fig. 3B and 3C).

The hir1 ${Delta}$ and asf1 ${Delta}$ deletions had an especially dramatic effecton silencing in combination with the cac1 alleles that impairPCNA binding. In otherwise wild-type cells, the cac1-13 andcac1-20 alleles resulted in nearly wild-type telomeric silencing(Fig. 3A). However, deletion of HIR1 or ASF1 reduced silencingin cac1-13 cells approximately 1,000-fold, and silencing incac1-20 cells was reduced approximately 100,000-fold (Fig. 3B and C).In contrast, the cac1-14 allele, which did not impairPCNA or Cac3p binding (Fig. 2C), displayed much milder silencingdefects when combined with the hir1 ${Delta}$ or asf1 ${Delta}$ deletion. Similarresults were obtained by combining these cac1 alleles with hir2 ${Delta}$ deletions (data not shown), consistent with genetic and biochemicalevidence indicating that Hir proteins function as a complex( 36, 44). We note that the stronger silencing defect in thecac1-20 cells is consistent with the more drastic alterationof the PCNA-binding site in this allele compared to cac1-13(Fig. 2B). These data indicated that mutation of the PCNA-bindingmotif of CAC1 caused telomeric silencing to be almost completelydependent on the ASF1 and the HIR genes.

The cac1-15 mutation caused a significant loss of silencing,similar to that observed in the absence of CAC1, and deletionof either HIR1 or ASF1 similarly exacerbated these phenotypes(Fig. 3). The nearly null phenotypes caused by cac1-15 werestronger than those of the separated point mutations cac1-21and cac1-22. For example, deletion of either HIR1 or ASF1 didnot strongly affect silencing in cac1-22 cells. However, thecac1-21 allele that blocked Cac3p binding (Fig. 2A) had an intermediatephenotype. In this case, telomeric silencing in cac1-21 hir1 ${Delta}$ cells was nearly wild type, but silencing in cac1-21 asf1 ${Delta}$ cellswas reduced almost 10,000-fold compared to CAC1 asf1 ${Delta}$ cells (Fig.3C). These data indicated that disruption of the Cac1p-Cac3pinteraction led to a greater requirement for Asf1p than forHir1p for telomeric silencing. Thus, the ASF1 and HIR geneshave at least one separable function in telomeric silencing(see Discussion).

Stimulation of CAF-I complexes defective in PCNA binding by Asf1p/H3/H4. CAF-I promotes DNA replication-dependent chromatin assemblyin vitro ( 42), and the Asf1p/H3/H4 complex stimulates the chromatinassembly activity of CAF-I ( 36, 51). Our genetic data suggestedthat mutant CAF-I complexes defective in PCNA binding were particularlyreliant on the Hir proteins and Asf1p. We therefore tested whetherthese mutant CAF-I complexes were capable of replication-coupledchromatin assembly and synergy with Asf1/H3/H4 complexes.

Wild-type yeast CAF-I, CafI-13 (Cac1-13p, Cac2p, and Cac3p)and CafI-20 (Cac1-20p, Cac2p, and Cac3p) were overproduced ininsect cells and purified to homogeneity by ion exchange andepitope affinity chromatography using a C-terminal epitope onCac1p (Fig. 4A). Purified CAF-I complexes were tested for chromatinassembly activity in an assay that detects nucleosome-mediatedsupercoiling of newly replicated DNA templates ( 45). In thisassay, wild-type or mutant CAF-I was added to an in vitro DNAreplication reaction containing a plasmid with a simian virus40 (SV40) origin of replication, the SV40 replication initiationprotein T-antigen, [ ${alpha}$ -³²P]dATP to label newly replicated DNA,and HeLa S100 extract which contains proteins required for DNAreplication.

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FIG. 4. Chromatin assembly activity of CafI-20 complexes. (A) Purified recombinant CAF-I complexes. Purified CAF-I, CafI-13, and CafI-20 (2 µg) were separated by SDS-10% PAGE and stained with Coomassie blue. (B) Chromatin assembly activity. SV40 DNA replication reactions (50 µl) containing 100 ng of DNA (52 fmol of plasmid molecule) were performed with CAF-I complexes alone (lanes 1 to 11) or with the addition of 3.5 pmol of Asf1p/H3/H4 (lanes 12 to 21), H3/H4 alone (lanes 22 to 28), or Asf1p alone (lanes 29 to 35). Indicated amounts of purified CAF-I, CafI-13, or CafI-20 were added (10 ng of CAF-I complex = 59 fmol). The upper panel shows total DNA visualized by ethidium bromide (EtBr) staining; the lower panel shows replicated DNA visualized by autoradiography (autoradiogram). Migration of supercoiled form I DNA molecules is indicated by the symbol I at the right; migration of nicked form II molecules is indicated by the symbol II. Reactions lacking both the replication initiator T antigen and CAF-I or lacking only CAF-I are shown in lanes 1 and 2, respectively.

In the absence of CAF-I, the newly replicated DNA moleculesvisualized by autoradiography had a topoisomer distributionsimilar to that of the total DNA visualized by ethidium bromidestaining (Fig. 4B, lane 2). However, in the presence of sufficientCAF-I, most of the replicated DNA was recovered as form I supercoiledDNA, although most of the total DNA in the reactions was notsupercoiled (Fig. 4B, lane 5). Therefore, wild-type yeast CAF-Ipreferentially assembled nucleosomes onto newly replicated DNAmolecules.

CAF-I functions stoichiometrically during nucleosome assembly( 18, 22, 36, 42), so that addition of substoichiometric amountsof CAF-I results in incomplete supercoiling of DNA templates.Consistent with previous data ( 36), addition of 20 ng (120fmol) of recombinant wild-type yeast CAF-I was required to promoteefficient supercoiling of replicated templates in reactionscontaining 52 fmol of total plasmid molecules (Fig. 4B, lane5). In contrast, addition of 20 ng of either CafI-13 or CafI-20did not result in supercoiling (Fig. 4B, lanes 6 and 9). Additionof larger amounts (75 ng [0.44 pmol]) of CafI-13 or CafI-20did result in increased DNA superhelicity (Fig. 6B, lanes 8and 11), but this effect was not specific to replicated DNAmolecules, as the total DNA visualized by ethidium bromide displayedincreased migration in these cases. These data indicate thatmutation of the PCNA-binding site of Cac1p reduced the specificactivity of CAF-I, and particularly interfered with the preferencefor newly replicated DNA molecules.

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FIG. 6. Direct physical interaction between Asf1p and CAF-I. (A) Glycerol gradient sedimentation of CAF-I and Asf1p. Purified recombinant CAF-I, Asf1p, or Asf1p complexed with histones H3 and H4 were sedimented on linear 10 to 40% glycerol gradients. Thirteen fractions were collected and separated by SDS-12.5% PAGE followed by immunoblotting with an anti-FLAG-M2 epitope antibody (Sigma). Cac1p and Asf1p were both tagged with the FLAG epitope. Sedimentation of molecular size standards is indicated at the bottom (in kilodaltons). (B) Asf1p binds Cac2p in vitro. GST-Asf1p was incubated with in vitro-translated Cac1p (lanes 1 to 3), Cac2p (lanes 4 to 6), or Cac3p (lanes 7 to 9). Samples were washed extensively (see text); bound proteins were eluted with SDS sample buffer, resolved by SDS-12.5% PAGE, and visualized by autoradiography. Input lanes represent 1/10 of the protein added to the reactions. (C) The Asf1p/H3/H4 complex coimmunoprecipitates with CAF-I. Purified recombinant CAF-I (Cac1/2/3p), Cac1/3p, Asf1p, or Asf1p/H3/H4 was mixed and immunoprecipitated with the anti-PY antibody (which recognizes PY-Cac3p). Samples were analyzed by SDS-12.5% PAGE followed by immunoblotting using anti-FLAG-M2 epitope antibody, which recognized Cac1p and Asf1p.

To confirm that the DNA supercoiling that we observed resultedfrom nucleosome formation, the reaction products were digestedwith MNase. MNase preferentially cleaves chromatin in the linkerregion between nucleosomes, resulting in a characteristic ladderof DNA products ( 34). In the absence of CAF-I, some mononucleosome-and subnucleosome-sized DNA fragments were protected from digestion,indicative of a background level of histone interaction withreplicated DNA (Fig. 5A, lanes 1 to 4). As observed previously( 36), addition of 20 ng of wild-type yeast CAF-I resulted information of a spaced ladder of MNase-protected DNA species,indicative of formation of polynucleosomal arrays (Fig. 5A,lanes 5 to 8). Furthermore, addition of 75 ng of either CafI-13or CafI-20 also resulted in nucleosome formation (Fig. 5A, lanes9 to 16). These data demonstrated that the supercoiling of DNAby high levels of the mutant CAF-I complexes did indeed reflectnucleosome assembly.

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FIG. 5. MNase digestion of DNA replication products. DNA replication reactions containing 20 ng of CAF-I, 75 ng of CafI-13, or 75 ng of CafI-20 (A) without or (B) with 3.5 pmol of Asf1p/H3/H4 were digested with 0.2 U of MNase (Sigma) for 0, 10, 20, and 30 min at 22°C. Recovered DNA was separated on a 2% agarose gel and visualized by autoradiography.

We then explored the biochemical synergy between CAF-I and Asf1p.As reported previously ( 36), Asf1p/H3/H4 stimulated wild-typeCAF-I activity. In the absence of Asf1p/H3/H4, 20 ng (0.12 pmol)of CAF-I was required for supercoiling of replicated DNA. However,only 10 ng (59 fmol) of CAF-I was required in the presence of3.5 pmol of Asf1p/H3/H4 (Fig. 4B, lanes 5 and 14). AlthoughAsf1p/H3/H4 was added in much higher concentrations than CAF-I,this amount of Asf1p/H3/H4 did not result in nucleosome formationin the absence of CAF-I (Fig. 4B, lane 12). Additionally, 3.5pmol of Asf1p in the absence of bound histones was unable tostimulate the activity of CAF-I, CafI-13, or CafI-20 to thesame degree observed with equivalent amounts of the Asf1p/H3/H4complex (Fig. 4B, lanes 29 to 35). Furthermore, 3.5 pmol ofhistones H3 and H4 in the absence of Asf1p potently inhibitedDNA replication and converted the DNA to a rapid-migrating form(Fig. 4B, lanes 22 to 28), confirming previous experiments demonstratingthe ability of Asf1p to prevent nonspecific electrostatic interactionsbetween DNA and histones ( 28, 36).

Because telomeric silencing in cac1-13 and cac1-20 cells islargely dependent on the ASF1 gene (Fig. 3C), we then testedwhether Asf1p/H3/H4 complexes could stimulate nucleosome assemblyby CafI-13 or CafI-20. Indeed, Asf1p/H3/H4 did stimulate DNAsupercoiling by CafI-13 and CafI-20 (Fig. 4B, lanes 16 to 21),and MNase digestion analysis confirmed that this reflected nucleosomeassembly (Fig. 5B). However, as observed in the absence of Asf1p/H3/H4,the mutant CAF-I complexes were required at two- to fourfoldgreater levels than was wild-type CAF-I to observe efficientnucleosome assembly (Fig. 4B, lanes 16 to 21). Addition of Asf1p/H3/H4to the mutant CAF-I complexes resulted in a similar distributionof total DNA and newly replicated DNA, supporting the hypothesisthat the mutant complexes displayed a reduced preference fornewly replicated DNA molecules. Similar results were observedwhen wild-type CAF-I was added in twofold excess of the amountrequired for nucleosome assembly (Fig. 4B, lane 15). Together,these data suggest that when present in high levels, CAF-I wasable to deposit histones in a manner independent of interactionwith PCNA and that CafI-13 and CafI-20 could only function inthis way. However, this replication-unlinked mode of activitywas still stimulated by Asf1p/H3/H4.

Interaction between Asf1p and Cac2p. Because of the biochemical and genetic synergies between CAF-Iand Asf1p, we tested for direct interaction between these proteins.We did this in three types of experiments: cosedimentation,GST fusion protein coprecipitation, and coimmunoprecipitation.First, purified recombinant yeast CAF-I, Asf1p, and Asf1p complexedwith H3/H4 were analyzed by glycerol gradient sedimentation.Yeast CAF-I sedimented with a peak in fractions 7 to 8 (150kDa), while Asf1p sedimented with a peak in fractions 3 to 5(30 kDa) (Fig. 6A). Preincubation of CAF-I with Asf1p did notsignificantly alter the sedimentation of either protein. Incontrast, Asf1p complexed with H3/H4 sedimented with a peakin fractions 5 to 6 ( ${approx}$ 67 kDa). The Asf1p/H3/H4 complex sedimentedmore broadly when it was preincubated with CAF-I, with one peaksimilar to Asf1p/H3/H4 alone and a second more rapidly migratingpeak in fractions 9 to 10 ( ${approx}$ 160 kDa) (Fig. 6A, CAF-I + Asf1p/H3/H4).These data implied that a fraction of the added Asf1p/H3/H4complexes associated directly with CAF-I in solution.

To determine which subunit of CAF-I interacted with Asf1p, weperformed coprecipitation experiments using GST-Asf1p and invitro-translated Cac1p, Cac2p, and Cac3p (Fig. 6B). NeitherCac1p nor Cac3p was coprecipitated by GST-Asf1p (Fig. 6B, lanes1 to 3 and 7 to 9). In contrast, Cac2p was efficiently coprecipitatedby GST-Asf1p (Fig. 6B, lanes 4 to 6); this interaction was stableto washing in the presence of 500 mM NaCl. Although Asf1p requiredthe presence of histones H3 and H4 for association with CAF-Iin solution (Fig. 6A), histones were not added in these coprecipitationexperiments. There are several possibilities that could explainthis. The interaction between Asf1p and Cac2p could be modulatedby other CAF-I subunits or by the presence of the GST moiety.Alternatively, other proteins in the reticulocyte extract usedfor the translation, including histones, could be involved.We note that GST-Asf1p also binds to Hir1p ( 36), the yeastprotein that displays the highest homology to Cac2p ( 17).

We also analyzed the Asf1p-Cac2p interaction in coimmunoprecipitationexperiments with purified recombinant proteins. CAF-I was incubatedwith Asf1p or Asf1p complexed with H3/H4, followed by immunoprecipitationof CAF-I with an anti-Py antibody that recognizes Py-taggedCac3p. A fraction of the input Asf1p/H3/H4 complexes was coimmunoprecipitatedwith CAF-I, and this association was much less efficient inthe absence of histones (Fig. 6C, lanes 5 and 6), consistentwith the sedimentation experiments (Fig. 6A). Additionally,a purified recombinant Cac1/3p complex lacking Cac2p did notefficiently coimmunoprecipitate Asf1p regardless of added histonesH3/H4 (Fig. 6C, lanes 7 and 8). Together, these data are consistentwith Cac2p’s serving as a binding site for the Asf1p/H3/H4complex.

DISCUSSION

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Discussion

Cac3p binding site on Cac1p. Our results indicate that multiple protein-protein interactionscontribute to the function of the CAF-I protein complex. Forexample, our screen for silencing-defective cac1 alleles recoveredan allele (cac1-15) that strongly reduced silencing and preventedbinding to the Cac3p subunit of the CAF-I complex. Cac1-15pcontained two amino acid changes, F257L and L276P. The L276Pamino acid change alone, encoded by the cac1-21 allele, resultedin loss of Cac3p binding. However, telomeric silencing was largelyunaffected by this mutation. Furthermore cac1-21 cells becamegreatly dependent on the ASF1 but not the HIR1 gene for telomericsilencing. Previous genetic analysis of the silencing rolesof ASF1 and HIR1 genes at telomeres or the silent HML matinglocus revealed no separation of function ( 36). We propose thatthis novel genetic separation of ASF1 and HIR gene functionreflects a function for Asf1p that is not shared by Hir proteins.For example, Cac3p is a member of a family of histone H3/H4-bindingproteins ( 53). Asf1p, another histone H3/H4-binding protein( 3, 28, 36, 51), may directly or indirectly assist in recruitinghistones to the CAF-I complex in the absence of an efficientCac1p-Cac3p interaction.

PCNA-binding motifs. The cac1-13 allele encodes a single point mutation (F233L) inone of the aromatic residues of the consensus PCNA-binding motif( 55), and Cac1-13p displayed reduced affinity for PCNA in vitro.Additionally, mutation of the PCNA-binding motif of Cac1p crippledits DNA replication-linked nucleosome assembly activity in vitroand caused telomeric silencing to be dependent on the ASF1/HIRpathway in vivo. However, the silencing phenotypes of the PCNA-binding-defectivecac1 alleles were nearly wild type in an otherwise wild-typestrain. These data underscore the degree of functional overlapbetween CAF-I and the Asf1p/Hir silencing pathways in vivo.One model consistent with our data is that Asf1p/Hir proteinsprovide an alternative route for recruitment of Cac1-13p andCac1-20p to DNA. We propose that the interaction between Asf1pand Cac2p underlies this functional synergy.

The aromatic residues in the PCNA-binding motif of Cac1p havebeen conserved in evolution. Although human p150 protein bindsPCNA ( 25, 37), it lacks the glutamine residue that begins thedefined consensus motif that is present in the budding and fissionyeast genes (Fig. 4A) ( 56). Mutational analysis of severalPCNA-binding proteins has demonstrated that residues outsideof the PCNA-binding motif are important for stable PCNA binding( 30, 62), and variations of this consensus sequence exist (57). For example, the large subunit of DNA polymerase deltafrom several species contains a diverged PCNA-binding motiflacking the initial glutamine ( 60), demonstrating that completeconservation of the PCNA-binding motif is not absolutely requiredfor PCNA binding. Additionally, the transcriptional coactivatorp300 binds PCNA but lacks this consensus altogether, and novelPCNA-binding peptides have been identified in phage displayexperiments ( 14, 59). These latter results underscore the factthat not all PCNA-binding proteins will necessarily interactwith the interdomain loop bound by the canonical PCNA-bindingmotif.

Almouzni and coworkers have demonstrated that human p150 bindsto Xenopus PCNA in vitro, and this interaction was mapped usingGST fusion proteins. Their data suggested that the first 244amino acids of p150 were important for PCNA binding and thatthe first 31 amino acids are required for the interaction (25). However, amino acids 1 to 296 of human p150 are dispensablefor replication-coupled chromatin assembly in vitro ( 18), andthis region of the protein is the least well conserved withhomologs from more distant organisms. In the absence of pointmutation analyses, it is difficult to reconcile these data.One possibility is that PCNA binding by human p150 is complex,containing regions that bind to PCNA in addition to the degeneratePCNA-binding motif shown in Fig. 4A. Consistent with this possibility,the large subunit of DNA polymerase delta appears to containboth canonical and noncanonical PCNA-binding regions ( 59).

Role of Asf1p during DNA synthesis. We demonstrated that the Asf1p/H3/H4 complex interacted withCAF-I by binding the Cac2p subunit. This interaction is conservedin evolution; the Drosophila homologs of these proteins (dASF1protein and the p105 subunit of dCAF-I) have recently been shownto interact directly ( 52). However, the interaction of theDrosophila proteins is independent of histones, whereas we haveobserved that the presence of histones H3 and H4 is importantfor observing the interaction with recombinant protein complexesin solution (Fig. 6A).

We also observed that yeast Asf1p was not quantitatively associatedwith CAF-I in the sedimentation and coimmunoprecipitation experimentsand that an excess of Asf1p/H3/H4 was required to stimulateCAF-I activity (Fig. 4 and 6). Therefore, the interaction betweenthese yeast protein complexes is inefficient and/or transient.Additionally, other proteins or protein modifications may regulatethe CAF-I-Asf1p interaction. For example, Asf1p in yeast formsa stable complex in the absence of histones with Rad53p, a kinasecentral to the DNA damage and intrA-S-phase checkpoints ( 3).When cells are arrested in S-phase with hydroxyurea or afterDNA damage, Asf1p is released from Rad53p and associates withhistones. This provides a mechanism by which the chromatin assemblyactivity of Asf1p is limited to periods of DNA synthesis. Thesedata also suggest that sequestration of Asf1p by Rad53p wouldprohibit Asf1p from interacting with CAF-I in the absence ofDNA synthesis.

The mechanism underlying the functional synergy between Asf1pand CAF-I remains unknown, and several possibilities exist.In vitro, CAF-I functions stoichiometrically to deposit histonesonto DNA ( 18, 22, 36, 42). Stimulation of reduced amounts ofCAF-I by Asf1p could result from more efficient reloading ofhistones onto CAF-I. Alternatively, Asf1p may assist in moreefficient recruitment of CAF-I to replicating DNA. These modelsare not the only possibilities, nor are they mutually exclusive.Future biochemical experiments will be required to determinehow the CAF-I reaction cycle and subunit interactions lead tochromatin assembly in vivo.

ACKNOWLEDGMENTS

We thank Peter Burgers, Bruce Futcher, Daniel Gottschling, andJasper Rine for providing plasmids and antibodies, Jim Kadonagaand Andrew Emili for communication of results prior to publication,Melissa Adams for strain generation, Jasper Rine, Ann Kirchmaier,anonymous reviewers, and members of the Kaufman lab for comments,and Jay Chuang for excellent technical assistance.

This work was supported by Department of Energy funds awardedto P.D.K. and administered through the Lawrence Berkeley NationalLaboratory and by National Institutes of Health grant 1 R01GM55712 and National Science Foundation grant MCB-9982909.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular and Cell Biology, 351 Donner Laboratory, University of California, Berkeley, CA 94720. Phone: (510) 486-5846. Fax: (510) 486-6488. E-mail: pdkaufman{at}lbl.gov.

REFERENCES

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