Requirement of RAD52 Group Genes for Postreplication Repair of UV-Damaged DNA in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, replication through DNA lesionsis promoted by Rad6-Rad18-dependent processes that include translesionsynthesis by DNA polymerases ${eta}$ and ${zeta}$ and a Rad5-Mms2-Ubc13-controlledpostreplicational repair (PRR) pathway which repairs the discontinuitiesin the newly synthesized DNA that form opposite from DNA lesionson the template strand. Here, we examine the contributions ofthe RAD51, RAD52, and RAD54 genes and of the RAD50 and XRS2genes to the PRR of UV-damaged DNA. We find that deletions ofthe RAD51, RAD52, and RAD54 genes impair the efficiency of PRRand that almost all of the PRR is inhibited in the absence ofboth Rad5 and Rad52. We suggest a role for the Rad5 pathwaywhen the lesion is located on the leading strand template andfor the Rad52 pathway when the lesion is located on the laggingstrand template. We surmise that both of these pathways operatein a nonrecombinational manner, Rad5 by mediating replicationfork regression and template switching via its DNA helicaseactivity and Rad52 via a synthesis-dependent strand annealingmode. In addition, our results suggest a role for the Rad50and Xrs2 proteins and thereby for the MRX complex in promotingPRR via both the Rad5 and Rad52 pathways.

INTRODUCTION

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INTRODUCTION

DNA lesions in the template strand block the progression ofthe replication fork. Genetic studies of the yeast Saccharomycescerevisiae have indicated a crucial role for the Rad6-Rad18ubiquitin conjugating enzyme complex (3, 4) in promoting replicationthrough DNA lesions via three different pathways that includeDNA polymerase ${eta}$ (Pol ${eta}$ )- and Pol ${zeta}$ -dependent translesion synthesis(TLS) and an Mms2-Ubc13-Rad5-dependent postreplicational repair(PRR) pathway which promotes the repair of discontinuities thatform in the DNA synthesized from damaged templates (20, 33,39, 51).

UV light induces the formation of cyclobutane pyrimidine dimers(CPDs) and (6-4) photoproducts in DNA. Both in yeast and inhumans, Pol ${eta}$ promotes error-free synthesis through the CPDs;consequently, inactivation of Pol ${eta}$ confers an increase in theincidence of UV mutagenesis (21, 32, 43, 57) and causes a cancer-pronesyndrome, the variant form of xeroderma pigmentosum, in humans(19, 30). Pol ${zeta}$ promotes TLS through the UV lesions by extendingfrom the nucleotides inserted opposite the CPD or the (6-4)photoproduct by another DNA Pol (17, 23). By contrast to Pol ${eta}$ ,which mediates error-free TLS through the CPDs, Pol ${zeta}$ promoteserror-prone TLS through the UV lesions (26-28).

Although the mechanism by which the Mms2-Ubc13-Rad5-dependentPRR pathway operates is not defined, it is likely to involvea transient template switching mechanism and a copy choice typeof DNA synthesis wherein the newly synthesized daughter strandof the undamaged complementary sequence is used as a templatefor bypassing the lesion (5). In the Mms2-Ubc13-Rad5 complex,the Mms2-Ubc13 complex promotes the assembly of lysine 63-linkedpolyubiquitin chains (13) and Rad5 functions as an ubiquitinligase (E3) for promoting Mms2-Ubc13-dependent ubiquitination(12, 54). In addition to the E3 activity, Rad5 has a DNA-dependentATPase activity, characteristic of the SWI2/SNF2 family of ATPasesto which it belongs (18, 22). Genetic studies of yeast haveindicated that both the ATPase and E3 activities of Rad5 areindispensable for its role in PRR (9).

All the Rad6-Rad18 lesion bypass processes are dependent uponlysine 164 ubiquitination of PCNA. In DNA-damaged yeast cells,PCNA becomes monoubiquitinated at its lysine 164 residue viathe action of Rad6-Rad18, and subsequently, this lysine residueis polyubiquitinated via a lysine 63-linked polyubiquitin chainby the Mms2-Ubc13-Rad5 enzyme complex (12). Genetic studiesof yeast have indicated the requirement of PCNA monoubiquitinationfor Pol ${eta}$ - and Pol ${zeta}$ -dependent TLS and of PCNA polyubiquitinationfor Rad5-dependent PRR (10, 12, 44).

By contrast to inactivation of RAD6 and RAD18, which confersa large increase in UV sensitivity because of the inhibitionof different Rad6-Rad18-dependent lesion bypass processes, mutationsin the RAD52 epistasis group of genes confer only a modest increasein UV sensitivity (40). Instead, the genes of the RAD52 groupplay a crucial role in homology-dependent recombinational repairof double-strand DNA breaks that are induced upon exposure toionizing radiation, such as X rays and ${gamma}$ rays; hence, inactivationof these genes confers a large increase in sensitivity to ionizingradiation (25, 47, 50). Rad51, Rad52, and Rad54 are three keyproteins indispensable for recombinational repair. Rad51 formsan extended helical filament on single-stranded (ss) DNA (34,46, 48). This nucleoprotein filament then invades the homologousregion in duplex DNA, resulting in the formation of a three-strandedD loop. Rad52 and Rad54 stimulate the DNA pairing function ofRad51; Rad52 enhances the ability of Rad51 to displace RPA fromss DNA (42, 45), and Rad54 functionally cooperates with Rad51at different steps of the pairing reaction. Rad54, a Swi2/Snf2family DNA-dependent ATPase, physically interacts with Rad51;it stabilizes Rad51-ss DNA filaments and stimulates the DNApairing reaction of Rad51 (31, 36, 41), and it also dissociatesRad51 from duplex DNA via its DNA translocase activity (1),thereby freeing up the primer end to initiate DNA synthesis.

Mutations in the RAD50, MRE11, and XRS2 genes also render cellshighly sensitive to ionizing radiation and defective in double-strandbreak (dsb) repair (25, 50). In addition to a role in dsb repairby homologous recombination, these genes are required for dsbrepair by nonhomologous end joining (25, 50). Mre11, Rad50,and Xrs2 exist in a stable complex, the MRX complex, in yeastcells (52, 55). Rad50 belongs to the structural maintenanceof chromosome family of proteins, and like the other membersof this family, it has a bipartite ATPase domain located atits amino and carboxy termini, which are separated by a long,antiparallel coiled-coil domain. The protein folds onto itself,and the two termini form a globular ATPase domain. Two moleculesof Mre11 bind to two molecules of Rad50 in the vicinity of theglobular ATPase domain. The globular head, formed by two moleculesof Rad50 and two molecules of Mre11, contains two DNA bindingsites in it, which could promote the alignment of the two DNAends for dsb repair by nonhomologous end joining, and whichcould also mediate the alignment of DNA ends with the sisterchromatid in recombination (2, 8, 14-16). Xrs2 binds the Rad50-Mre11complex, and it helps target the MRX complex to DNA ends (53).

Here, we have examined the roles of the RAD51, RAD52, and RAD54genes and of the RAD50 and XRS2 genes in PRR of DNA synthesizedfrom UV-damaged templates. Although all these genes contributeto the PRR of UV damaged DNA in yeast cells, rather unexpectedly,they differ in their modus operandi. By contrast to Rad51, Rad52,and Rad54, which carry out PRR in a manner independent of theRad5-mediated PRR, we find that Rad50 and Xrs2 contribute toPRR via both the Rad5- and Rad52-mediated PRR pathways.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Strains. For postreplication repair studies, yeast strains were treatedwith ethidium bromide to obtain [rho°] derivatives lackingmitochondrial DNA. The following yeast strains used in thesestudies are all derived from EMY74.7, MATa his3- ${Delta}$ 1 leu2-3,112trp1 ${Delta}$ ura3-52: YR1-65, rad1 ${Delta}$ [rho°]; YR1-118, rad1 ${Delta}$ rad5 ${Delta}$ [rho°];YR1-347, The rad1 ${Delta}$ rad50 ${Delta}$ [rho°]; YR1-315, rad1 ${Delta}$ rad51 ${Delta}$ [rho°];YR1-231, rad1 ${Delta}$ rad52 ${Delta}$ [rho°]; YR1-318, rad1 ${Delta}$ rad54 ${Delta}$ [rho°];YR1-350, rad1 ${Delta}$ xrs2 ${Delta}$ [rho°]; YR1-241, rad1 ${Delta}$ rad5 ${Delta}$ rad52 ${Delta}$ [rho°];YR1-385, rad1 ${Delta}$ rad50 ${Delta}$ rad5 ${Delta}$ [rho°]; YR1-400, rad1 ${Delta}$ xrs2 ${Delta}$ rad5 ${Delta}$ [rho°]; YR1-356, rad1 ${Delta}$ rad50 ${Delta}$ rad52 ${Delta}$ [rho°]; and YR1-408,rad1 ${Delta}$ xrs2 ${Delta}$ rad52 ${Delta}$ [rho°].

UV irradiation and sedimentation in alkaline sucrose gradients. For postreplication repair experiments, alkaline sucrose gradientsedimentation is used to determine the size of nuclear DNA synthesizedin cells following UV irradiation. To avoid confusion betweenUV-damaged nuclear DNA synthesized after UV irradiation thathas not been repaired and undamaged mitochondrial DNA, whichcould be similar in size, these experiments are best performedwith [rho°] strains, which lack mitochondrial DNA. Although[rho°] strains are respiratory deficient in medium containingglucose as a carbon source, the growth of [rho°] cells andthat of [rho⁺] cells are very similar.

Yeast cells were grown to logarithmic phase in synthetic completemedium lacking uracil but containing 5 µg of uridine/ml.When the cells reached a density of 0.5 x 10⁷ to 1.0 x 10⁷ cellsper ml, they were UV irradiated at room temperature in the samegrowth medium in 150- by 20-mm petri dishes with constant stirringat a dose rate of 0.1 J/m²/s. To avoid photoreactivation, alloperations after UV irradiation were performed in yellow light.Following UV irradiation, cells were labeled with radioisotopeand incubated for various times, followed by conversion to spheroplasts.Briefly, after UV irradiation, cells collected by filtrationwere resuspended in fresh uridine medium at a density of 1 x10⁸ to 2 x 10⁸ cells per ml. Pulse-labeling was achieved bythe addition of 100 µCi of [³H]6'-uracil (20 to 25 Ci/mmol,1 mCi/ml; Moravek Biochemicals and Radiochemicals, Brea, CA)to 1 ml of cells, followed by vigorous shaking for 15 min at30°C. Cells were then washed, resuspended in synthetic completemedium containing 1.67 mg of uracil (high-uracil medium)/ml,and incubated for an additional period of 30 min or 6 h. Cellswere converted to spheroplasts as described previously (9),and a 0.3-ml aliquot of the spheroplast suspension was layereddirectly onto a 0.2-ml lysing layer (0.79 M sorbitol, 0.66 MEDTA, 2.5% sarkosyl, 0.3 M NaCl) on top of a 15 to 30% (wt/vol)linear alkaline sucrose gradient made in 0.3 M NaOH, 0.7 M NaCl,40 mM EDTA, 1% Sarkosyl (pH 12.5). Centrifugation was carriedout in an SW41 rotor (Beckman) at 21,000 rpm for 15 h and 30min at 4°C as described previously (9). Processing of sampleswas done as described previously (9).

UV sensitivity. Cells grown to mid-logarithmic phase in yeast extract-peptone-dextrosemedium were washed and sonicated to disperse clumps. Followingsonication, they were pelleted by centrifugation and suspendedin sterile distilled water to a density of 2 x 10⁸ cells perml. The cell suspensions were diluted, spread onto the surfaceof yeast extract-peptone-dextrose plates, and irradiated ata dose rate of 0.1 J/m²/s for doses of 10 J/m² and below orat 1 J/m²/s for doses above 10 J/m². Plates were incubated inthe dark, and colonies were counted after 3 to 5 days.

RESULTS

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RESULTS

Defective postreplication repair in the rad51 ${Delta}$ , rad52 ${Delta}$ , and rad54 ${Delta}$ mutants. To determine the effects of the rad51 ${Delta}$ , rad52 ${Delta}$ , and rad54 ${Delta}$ mutationson PRR, we examined the sizes of newly synthesized DNA in rad1 ${Delta}$ rad51 ${Delta}$ , rad1 ${Delta}$ rad52 ${Delta}$ , and rad1 ${Delta}$ rad54 ${Delta}$ mutant strains. Because ofthe absence of nucleotide excision repair in the rad1 ${Delta}$ strain,UV lesions are not removed from DNA and replication of suchlesion-containing DNA templates becomes highly dependent uponthe various lesion bypass processes. As we have shown previously(9), and the results are presented here for comparison (Fig.1A), when rad1 ${Delta}$ cells are UV irradiated at 3.5 J/m² and the sizeof newly synthesized DNA is examined by pulse-labeling of DNAwith [³H]uracil for 15 min, followed by a chase for 30 min,the DNA sediments toward the top of the alkaline sucrose gradient,indicating the presence of discontinuities in the newly synthesizedDNA (Fig. 1A). By contrast, in unirradiated rad1 ${Delta}$ cells, thesize of newly synthesized DNA following the 15-min pulse and30-min chase period becomes the same as that in uniformly labeledcells. Incubation of rad1 ${Delta}$ cells for 6 h following the 15-minpulse after UV irradiation results in the formation of normal-sizeDNA, indicating that postreplicative gap filling processes haverestored normal size to DNA synthesized from the UV-damagedtemplates (Fig. 1A). In the rad1 ${Delta}$ rad51 ${Delta}$ , rad1 ${Delta}$ rad52 ${Delta}$ , and rad1 ${Delta}$ rad54 ${Delta}$ cells, however, we find that normal-size DNA is not reconstitutedin cells UV irradiated at 3.5 J/m² and then given a 15-min pulsefollowed by a 6-h recovery period, and the efficiency of PRRis reduced to about the same extent in all three mutant strains(Fig. 1B, C, and D).

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FIG. 1. Requirement of RAD51, RAD52, and RAD54 genes for postreplication repair of UV-damaged DNA. Sedimentation in alkaline sucrose gradients of nuclear DNA from cells incubated for different periods following UV irradiation with 3.5 J/m². The rad1 ${Delta}$ (A), rad1 ${Delta}$ rad51 ${Delta}$ (B), rad1 ${Delta}$ rad52 ${Delta}$ (C), and rad1 ${Delta}$ rad54 ${Delta}$ (D) strains were UV irradiated at 3.5 J/m² and then pulse-labeled with [³H]uracil for 15 min, followed by a 30-min ( ${Delta}$ ) or 6-h (•) chase in high-uracil medium. Synthesis of normal-size DNA from unirradiated cells pulse-labeled with [³H]uracil for 15 min was followed by a 6-h chase ( ${circ}$ ). The data for the rad1 ${Delta}$ strain in panel A shown here for comparison are taken from reference 9.

Rad5 and Rad52 control alternate pathways of PRR. Since an increase in UV sensitivity is observed when deletionmutations of the genes in the RAD52 group are combined withthe rad6 ${Delta}$ or rad18 ${Delta}$ mutations, RAD52 and the other genes of thisgroup are presumed to function in PRR via a pathway that operatesindependently of Rad6-Rad18-mediated lesion bypass pathways.Because Rad6-Rad18-dependent PRR is subsumed via the Rad5-Mms2-Ubc13action (9, 51), we examined whether the introduction of therad5 ${Delta}$ mutation enhances the PRR defect of the rad52 ${Delta}$ mutation.As shown in Fig. 2, the rad1 ${Delta}$ rad5 ${Delta}$ rad52 ${Delta}$ strain displays a muchhigher level of PRR defect than the rad1 ${Delta}$ rad5 ${Delta}$ strain or therad1 ${Delta}$ rad52 ${Delta}$ strain (compare Fig. 1 and 2). In fact, comparedto the intermediate level of repair capacity that remains inthe rad1 ${Delta}$ rad5 ${Delta}$ or the rad1 ${Delta}$ rad52 ${Delta}$ strain, there is little, ifany, evidence of repair in the rad1 ${Delta}$ rad5 ${Delta}$ rad52 ${Delta}$ strain. Fromthese observations, we infer that PRR in yeast cells is effectedvia two pathways, a Rad6-Rad18 and Rad5-Mms2-Ubc13-dependentpathway and a Rad52-dependent pathway, and these two pathwaysfunction independently of one another for promoting replicationthrough UV lesions.

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FIG. 2. RAD5 and RAD52 control alternate pathways for postreplication repair of UV-damaged DNA. Sedimentation in alkaline sucrose gradients of nuclear DNA from cells incubated for different periods following UV irradiation with 3.5 J/m². The rad1 ${Delta}$ rad5 ${Delta}$ (A) and rad1 ${Delta}$ rad5 ${Delta}$ rad52 ${Delta}$ (B) strains were UV irradiated at 3.5 J/m² and then pulse-labeled with [³H]uracil for 15 min, followed by a 30-min ( ${Delta}$ ) or 6-h (•) chase in high-uracil medium. Synthesis of normal-size DNA from unirradiated cells pulse-labeled with [³H]uracil for 15 min was followed by a 6-h chase ( ${circ}$ ). The data for the rad1 ${Delta}$ rad5 ${Delta}$ strain in panel A shown here for comparison are taken from reference 9.

Impaired PRR in rad50 ${Delta}$ and xrs2 ${Delta}$ mutants. Since the RAD50, MRE11, and XRS2 genes function in the repairof dsb's by homologous recombination that is mediated by theproteins encoded by the RAD52 group genes, we determined whetherthe MRX complex contributes also to efficient PRR and whetherit carries out its role via the Rad52-dependent PRR pathway.To examine this, the rad50 ${Delta}$ and xrs2 ${Delta}$ mutations were combinedwith the rad1 ${Delta}$ mutation and the sizes of newly synthesized DNAexamined in the double mutants following UV irradiation. Asshown in Fig. 3A and B, normal-size DNA is not reconstitutedin the rad1 ${Delta}$ rad50 ${Delta}$ and rad1 ${Delta}$ xrs2 ${Delta}$ strains that were UV irradiatedat 3.5 J/m² and then given a 15-min pulse followed by a 6-hrecovery period. Although the efficiency of PRR is affectedin both of the mutant strains, in different experiments we haveconsistently observed a higher level of PRR defect in the rad1 ${Delta}$ xrs2 ${Delta}$ strain than in the rad1 ${Delta}$ rad50 ${Delta}$ strain (Fig. 3A and B).

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FIG. 3. Involvement of RAD50 and XRS2 in postreplication repair of UV-damaged DNA. Sedimentation in alkaline sucrose gradients of nuclear DNA from cells incubated for different periods following UV irradiation with 3.5 J/m². The rad1 ${Delta}$ rad50 ${Delta}$ (A), rad1 ${Delta}$ xrs2 ${Delta}$ (B), rad1 ${Delta}$ rad50 ${Delta}$ rad5 ${Delta}$ (C), rad1 ${Delta}$ xrs2 ${Delta}$ rad5 ${Delta}$ (D), rad1 ${Delta}$ rad50 ${Delta}$ rad52 ${Delta}$ (E), and rad1 ${Delta}$ xrs2 ${Delta}$ rad52 ${Delta}$ (F) strains were UV irradiated at 3.5 J/m2 and then pulse-labeled with [³H]uracil for 15 min, followed by a 30-min ( ${Delta}$ ) or 6-h (•) chase in high-uracil medium. Synthesis of normal-size DNA from unirradiated cells pulse-labeled with [³H]uracil for 15 min was followed by a 6-h chase ( ${circ}$ ).

To examine the possibility that Rad50 and Xrs2 function in theRad52-dependent PRR pathway, we examined the efficiency of PRRin the rad1 ${Delta}$ rad50 ${Delta}$ rad52 ${Delta}$ and rad1 ${Delta}$ xrs2 ${Delta}$ rad52 ${Delta}$ strains. As expected,the PRR deficiency in these strains was no greater than thatin the rad1 ${Delta}$ rad52 ${Delta}$ strain, thus suggesting a role for Rad50 andXrs2 in the Rad52-dependent PRR pathway (compare Fig. 3E and Fwith Fig. 1C).

To verify that the role of Rad50 and Xrs2 was restricted tothe Rad52-dependent pathway and that they did not contributeto Rad5-dependent PRR, we examined the PRR efficiency of therad1 ${Delta}$ rad50 ${Delta}$ rad5 ${Delta}$ and rad1 ${Delta}$ xrs2 ${Delta}$ rad5 ${Delta}$ mutant strains. However,surprisingly, the PRR defect in these mutant strains was nogreater than that observed in the rad1 ${Delta}$ rad5 ${Delta}$ strain (compareFig. 3C and D with Fig. 2A). These observations lead us to concludethat the role of Rad50 and Xrs2 in PRR is not restricted justto the Rad52-dependent pathway but contributes also to Rad5-dependentPRR.

Epistasis relationship of the rad50 ${Delta}$ and xrs2 ${Delta}$ mutations with the rad5 ${Delta}$ and rad52 ${Delta}$ mutations. Although the RAD50, MRE11, and XRS2 genes function in the repairof dsb's by homologous recombination in collaboration with theRAD52 group of genes, and mutations in the genes encoding theMRX complex and in the genes belonging to the RAD52 group displayepistasis for ${gamma}$ -ray sensitivity, our observation that Rad50 andXrs2 contribute to PRR mediated by both the Rad5- and Rad52-dependentpathways has necessitated a reexamination of the epistasis relationshipsamong these genes for repairing UV damage. As shown in Fig.4A, the rad5 ${Delta}$ rad50 ${Delta}$ strain displays the same UV sensitivity asthe rad5 ${Delta}$ strain and the UV sensitivity of the mms2 ${Delta}$ rad50 ${Delta}$ strainresembles the UV sensitivity profile of the rad50 ${Delta}$ strain. Thus,an epistatic relationship is indicated among the rad5, mms2,and rad50 mutations. Since the UV sensitivity of the rad50 ${Delta}$ rad52 ${Delta}$ strain is about the same as that of the rad50 ${Delta}$ or rad52 ${Delta}$ strains(Fig. 4D), an epistatic relationship is also indicated betweenthe rad50 and rad52 genes. For the xrs2 mutation, however, weobserve increases in the UV sensitivities of the xrs2 ${Delta}$ rad5 ${Delta}$ andxrs2 ${Delta}$ mms2 ${Delta}$ double mutants compared to the UV sensitivity of themore sensitive single-mutant strain (Fig. 4B), and the xrs2 ${Delta}$ rad52 ${Delta}$ double mutant also exhibits a higher level of UV sensitivitythan either of the single mutants (Fig. 4D).

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FIG. 4. Epistasis relationships of rad50 and xrs2 with rad5 and rad52. Survival after UV irradiation of wild-type strain EMY74.7 and its isogenic derivatives. Survival curves represent an average for at least three different experiments for each strain. (A) Epistasis of rad50 ${Delta}$ with mms2 ${Delta}$ and with rad5 ${Delta}$ ; (B) lack of epistasis of xrs2 ${Delta}$ with rad5 ${Delta}$ and with mms2 ${Delta}$ ; (C) increased UV sensitivity of the rad50 ${Delta}$ and xrs2 ${Delta}$ mutations when combined with the rev3 ${Delta}$ or rad30 ${Delta}$ mutations; (D) epistasis of rad50 ${Delta}$ with the rad52 ${Delta}$ mutation and the lack of epistasis between the xrs2 ${Delta}$ and rad52 ${Delta}$ mutations. Error bars represent standard errors.

The epistatic relationship of the rad50 ${Delta}$ mutation with both therad5 ${Delta}$ and rad52 ${Delta}$ mutations and the somewhat increased UV sensitivityof the xrs2 ${Delta}$ mutation with both the rad5 ${Delta}$ and rad52 ${Delta}$ mutationsraised the possibility that as a structural element, the MRXcomplex not only affects the efficiency of PRR mediated by boththe Rad5- and Rad52-dependent pathways but also contributesto TLS mediated by Pols ${eta}$ and ${zeta}$ . For this reason, we examinedthe UV sensitivities of the rad50 ${Delta}$ and xrs2 ${Delta}$ mutations in combinationwith the rad30 ${Delta}$ or the rev3 ${Delta}$ mutation. Such double mutants, however,exhibit higher levels of UV sensitivity than the correspondingsingle mutants (Fig. 4C), which suggests that Rad50 and Xrs2do not contribute to TLS by Pols ${eta}$ and ${zeta}$ .

DISCUSSION

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DISCUSSION

Here, we show that RAD51, RAD52, and RAD54, which are indispensablefor mediating dsb repair by homologous recombination, contributealso to the repair of discontinuities that form in the newlysynthesized DNA in UV-irradiated yeast cells. The results withthe rad52 ${Delta}$ mutation validate the observations that we reportedpreviously for the rad52-1 point mutation (38). Our observationthat the PRR of UV-damaged DNA is inhibited to a much greaterextent in the rad1 ${Delta}$ rad5 ${Delta}$ rad52 ${Delta}$ mutant than in the rad1 ${Delta}$ rad5 ${Delta}$ orthe rad1 ${Delta}$ rad52 ${Delta}$ strain indicates that Rad5 and Rad52 promotePRR via alternate pathways.

Replication through UV-induced DNA lesions in yeast cells thusis mediated by Rad6-Rad18-dependent processes and by a Rad52-dependentpathway which acts independently of Rad6 and Rad18 (Fig. 5).The existence of alternate PRR pathways raises a number of questions:how do the PRR pathways controlled by Rad6-Rad18 and by theRad52 group of proteins differ? Do they compete for bypassingDNA lesions, and does the action of each pathway extend to repairingthe gaps opposite lesions in both the leading and lagging strandtemplates, or are the two pathways confined to act specificallyon one of the two DNA strands? Although our study yields nodefinitive answers to these questions, the available data allowus to make certain observations that are discussed below.

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FIG. 5. Rad6-Rad18-dependent and Rad51-, Rad52-, and Rad54-dependent pathways for replication of UV-damaged DNA in yeast. It is proposed (see text for details) that Rad5-mediated PRR is restricted to the leading strand and that Rad proteins 51, 52, and 54, which are also likely to involve the other proteins that function with this group, such as Rad55 and Rad57, promote lesion bypass on the lagging strand. Further, it is suggested that both of the PRR pathways utilize nonrecombinational means that involve fork regression and template switching mediated by Rad5 (5) and the SDSA pathway, in which the Rad51-coated ss nucleoprotein filament formed on the strand with the 3'-OH terminus from the gapped region on the lagging strand invades the duplex on the leading strand side, and this is followed by D-loop formation, synthesis, and reannealing reactions (25, 47).

In the Mms2-Ubc13-Rad5-controlled PRR pathway, the Mms2-Ubc13complex promotes the polyubiquitination of PCNA, and Rad5 actsas the ubiquitin ligase. In addition, Rad5 has a DNA helicaseactivity capable of performing replication fork regression (5),a reaction that was envisaged in a model for damage bypass bytemplate switching proposed over 30 years ago (11). The requirementof Rad5, however, is not restricted just to PRR, as it contributesalso to TLS (9). By contrast, all the available genetic evidenceis consistent with the involvement of the Mms2-Ubc13 complexin PRR only (51). Whereas a combination of mutations in genesthat function in competing pathways results in a synergisticenhancement in sensitivity to DNA-damaging agents and in repairdeficiency, a combination of mutations in genes that affectdifferent but noncompeting pathways results in an additive increasein sensitivity to DNA-damaging agents and in repair deficiency.Because the increased UV sensitivity of the mms2 ${Delta}$ rad52 ${Delta}$ doublemutant over that of the corresponding single mutants approximatesan additive rather than a synergistic relationship (51), andbecause the PRR defect of the rad1 ${Delta}$ rad5 ${Delta}$ rad52 ${Delta}$ strain comparedto the PRR defect in the rad1 ${Delta}$ rad5 ${Delta}$ or rad1 ${Delta}$ rad52 ${Delta}$ strain is indicativeof an additive relationship (compare Fig. 1 and 2), we suggestthat the Rad5- and Rad52-dependent PRR pathways act predominantlyin a noncompeting manner.

Genetic experiments in which rad1 ${Delta}$ yeast strains harboring therad18 ${Delta}$ , rad5 ${Delta}$ , or rad52 ${Delta}$ mutation were transformed with a plasmidthat carried a single (6-4) TT photoproduct in each DNA strandand that were 28 bp apart have indicated the requirement ofRad18, Rad5, and Rad52 for replication through this DNA lesion(58). Since a (6-4) TT photoproduct presents a strong blockto synthesis by the TLS Pols, TLS makes only a small contribution( $~$ 4%) to replication through this lesion. Whereas Rad18 was responsiblefor the replication of $~$ 70% of the plasmids and Rad5 was involvedin $~$ 60% of the replication events, Rad52 accounted for $~$ 45% ofthe replication events (58). The nearly equivalent contributionof Rad5 and Rad52 for promoting replication through the (6-4)TT photoproduct suggested in this study is also in accord withthe idea that Rad5 and Rad52 lesion bypass pathways do not compete.The inference that Rad5 and Rad52 modulate PRR via noncompetingpathways suggests that their action is confined to one of thetwo template strands. For reasons that we elaborate upon below,we suggest a role for the Rad5 pathway in promoting replicationwhen the lesion is on the leading strand template and for theRad52 pathway in promoting replication when the lesion is onthe lagging strand template (Fig. 5).

Analyses of replication products from human cell extracts replicatingsimian virus 40-derived plasmids (49) have indicated that asite-specific T-T dimer when placed in the template of the leadingstrand of newly synthesized DNA blocks the synthesis on theleading strand, but synthesis on the lagging strand continues.When the T-T dimer is placed in the template for the laggingstrand, however, there is little inhibition of replication forkprogression and a small gap is left in the lagging strand, whichpresumably results from the inhibition of Okazaki fragment completion(49). An uncoupling of leading strand synthesis from laggingstrand synthesis similar to that observed in human cells hasalso been suggested to occur in UV-irradiated yeast cells whenthe lesion is on the leading strand template (29). Overall,the various studies with mammalian and yeast cells (6, 7, 29,49) have pointed to the existence of fundamental differencesin the effects a lesion has on replication fork progressionwhen it is located on the leading versus the lagging strandtemplate.

The Rad5 and Rad52 PRR pathways differ in that the former pathwayhas the requirement for PCNA polyubiquitination whereas thelatter pathway requires no such PCNA modification. This raisesthe possibility that when the lesion is on the leading strandtemplate, PCNA polyubiquitination modulates the uncoupling ofleading strand synthesis from lagging strand synthesis. In thatcase, the Rad5 pathway could act primarily when leading strandsynthesis is blocked. The role of the Rad52 PRR pathway wouldthen be relegated to the lagging strand.

The various genetic and biochemical observations with Rad5 havesuggested a role for Rad5 in mediating error-free lesion bypassby transient template switching, wherein its DNA helicase activity,which is highly specialized for replication fork regression,could promote template switching and a copy choice type of DNAsynthesis, in which the lesion on the leading strand is bypassedby template switching using the newly synthesized lagging strandas the template that would be formed upon fork regression (5).Although the proteins encoded by the RAD52 group of genes arerequired for recombinational repair of dsb's, we consider ithighly probable that the gap left opposite the DNA lesion onthe lagging strand is filled in by the action of the Rad52 groupproteins via a nonrecombinational pathway like that depictedin the synthesis-dependent strand annealing (SDSA) model, whereinthe Rad51-coated ss nucleoprotein filament invades the DNA duplexon the leading strand side and the gap on the lagging strandis then filled in by DNA synthesis using the newly synthesizedleading strand as the template (see references 25 and 47 fordetails of the SDSA model). The reason for suggesting a nonrecombinationalmode of PRR for the Rad52-dependent pathway is that recombinationis normally suppressed in yeast cells and it is only in theabsence of Srs2 DNA helicase (24, 40, 56) or in the absenceof Siz1-mediated PCNA sumoylation (10, 35, 37) that the recombinationalrepair pathway becomes activated.

The involvement of Rad50 and Xrs2 in PRR and our observationthat the PRR defect of rad1 ${Delta}$ rad50 ${Delta}$ or rad1 ${Delta}$ xrs2 ${Delta}$ mutants is notincreased in the presence of rad5 ${Delta}$ or rad52 ${Delta}$ mutations might suggestthat the MRX complex contributes to both the Rad5- and Rad52-dependentPRR pathways, and it raises the possibility that the MRX complexplays a structural role in aligning the sister chromatids intoclose proximity, and thereby, this complex contributes to bothof these pathways.

ACKNOWLEDGMENTS

This work was supported by National Institutes of Health grantCA107650.

FOOTNOTES

* Corresponding author. Mailing address: University of Texas Medical Branch at Galveston, 301 University Blvd., Galveston, TX 77555-1061. Phone: (409) 747-8601. Fax: (409) 747-8608. E-mail: l.prakash{at}utmb.edu

Published ahead of print on 4 September 2007.

REFERENCES

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