Molecular Characterization of the Role of the Schizosaccharomyces pombe nip1+/ctp1+ Gene in DNA Double-Strand Break Repair in Association with the Mre11-Rad50-Nbs1 Complex

The Schizosaccharomyces pombe nip1⁺/ctp1⁺ gene was previouslyidentified as an slr (synthetically lethal with rad2) mutant.Epistasis analysis indicated that Nip1/Ctp1 functions in Rhp51-dependentrecombinational repair, together with the Rad32 (spMre11)-Rad50-Nbs1complex, which plays important roles in the early steps of DNAdouble-strand break repair. Nip1/Ctp1 was phosphorylated inasynchronous, exponentially growing cells and further phosphorylatedin response to bleomycin treatment. Overproduction of Nip1/Ctp1suppressed the DNA repair defect of an nbs1-s10 mutant, whichcarries a mutation in the FHA phosphopeptide-binding domainof Nbs1, but not of an nbs1 null mutant. Meiotic DNA double-strandbreaks accumulated in the nip1/ctp1 mutant. The DNA repair phenotypesand epistasis relationships of nip1/ctp1 are very similar tothose of the Saccharomyces cerevisiae sae2/com1 mutant, suggestingthat Nip1/Ctp1 is a functional homologue of Sae2/Com1, althoughthe sequence similarity between the proteins is limited to theC-terminal region containing the RHR motif. We found that theRxxL and CxxC motifs are conserved in Schizosaccharomyces speciesand in vertebrate CtIP, originally identified as a cofactorof the transcriptional corepressor CtBP. However, these twomotifs are not found in other fungi, including Saccharomycesand Aspergillus species. We propose that Nip1/Ctp1 is a functionalcounterpart of Sae2/Com1 and CtIP.

INTRODUCTION

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INTRODUCTION

DNA double-strand breaks (DSBs), among the most critical typesof DNA damage, can lead to chromosomal aberrations, disruptionof genome integrity, and cancer. DSBs are caused not only byexogenous sources such as ${gamma}$ irradiation but also by endogenousfactors such as free radicals generated by aerobic respiration.DSBs can also arise as a result of replication fork collapse.In addition, programmed DSBs are created at recombination hotspots during meiosis.

When DSBs arise in mitotic cells, DNA damage checkpoints areactivated, resulting in cell cycle arrest and induction of appropriaterepair machinery (reviewed in reference 27). DSBs can be repairedby two major DNA repair pathways: homologous recombination (HR)and nonhomologous end-joining (NHEJ) repair mechanisms (reviewedin references 35, 51, 58, and 60). In HR repair, the ends ofa DSB are resected to produce recombinogenic DNA with 3' single-strandoverhangs. The resulting single-stranded DNA region pairs withhomologous DNA of the intact sister chromatid, forming a D-loopstructure. The repair process proceeds with DNA synthesis byusing the sister chromatid as a template, essentially withoutloss of genetic information. In NHEJ, the broken ends are aligned,may or may not be processed, and are then directly rejoined.NHEJ repair is thus a potentially error-prone process. Bothpathways are highly conserved from yeast to humans.

In the budding yeast Saccharomyces cerevisiae, the organismin which HR has been most extensively studied, and most likelyin other organisms as well, meiotic HR is initiated by programmed,Spo11-dependent DSBs (31). These DSBs are formed by a topoisomerase-liketrans-esterase mechanism mediated by Spo11. Spo11 covalentlyattached at the DNA ends has been identified as an intermediatein meiotic cell extracts (32). In addition, a large number ofother gene products are involved in this step, including Mre11,Rad50, Xrs2, Mer2, Mei4, Rec102, Rec104, Rec114, and Ski8 (4,37, 56, 63; reviewed in reference 31).

After the formation of DSBs, the ends are immediately processedto expose 3' single-strand overhangs that are essential forhomologous pairing and strand exchange. This process involvesthe removal of covalently attached Spo11 from the DNA ends andnucleolytic resection of the DNA strand whose end was attachedto Spo11. Mre11, Rad50, and Xrs2 are required for processingof the DNA ends, in addition to being required for DSB formation(7, 32, 50). Sae2 (also called Com1) is also required for thisresection step (33, 54, 55). Mutants lacking these proteinsare sensitive to DNA-damaging agents and defective in strandresection of DSB ends during mitosis (5, 13, 42). Thus, Mre11,Rad50, Xrs2, and Sae2/Com1 are implicated in DSB end-processingmechanisms during both mitotic and meiotic cell cycles.

Mre11, Rad50, and Xrs2 form a protein complex called the MRXcomplex (14). Mre11 is a DNA-binding protein that contains fourphosphodiesterase motifs, which are responsible for nucleaseactivity. Rad50 is a split ABC-type ATPase which contains twoheptad repeats that are located at its center and that foldinto a coiled-coil, bringing the two N- and C-terminal ATPasemotifs, Walker A and B, into close proximity (17). These structuralfeatures are characteristic of SMC (structural maintenance ofchromosome) family proteins. Rad50 was recently reported tohave adenylate kinase activity, which is required for the efficienttethering of DNA molecules (6). Both Mre11 and Rad50 are conservedamong eukaryotes. However, conservation of the Xrs2 amino acidsequence is quite low compared to that of Mre11 and Rad50 andonly limited regions or short sequence motifs are conserved,as described below.

The fission yeast Schizosaccharomyces pombe, which is distantlyrelated to S. cerevisiae, possesses the rad32 gene as its MRE11homologue (61, 72, 73). rad32 was originally identified as arad mutant showing sensitivity to various DNA-damaging treatments,and cloning and sequencing revealed that it corresponded toMRE11. The S. pombe rad50 gene was isolated by taking advantageof its sequence similarity to Rad50 homologues from S. cerevisiae,Caenorhabditis elegans, and humans (28).

The vertebrate Nbs1 protein, which forms a complex with Mre11and Rad50, is the functional counterpart of Xrs2. The overallsequence similarity between these two proteins is weak and islimited to an N-terminal forkhead-associated (FHA) domain anda small C-terminal conserved domain. Nbs1, but not Xrs2, containsa BRCA1 C-terminal (BRCT) domain in the N-terminal region nextto the FHA domain (8, 41, 70). Based on this information, Russell,Rhind, and colleagues identified Nbs1 in S. pombe (10). We independentlyidentified Nbs1 in a genetic screen of rad2 ${Delta}$ -synthetic lethalitymutants, as described below (67).

Human and budding yeast Mre11 has a single-strand endonucleaseactivity, a 3'-5' double-strand exonuclease activity, and aweak hairpin-opening activity. Both ATP and Rad50 stimulatethe 3'-5' exonuclease and hairpin-opening activities of Mre11,and ATP may regulate the DNA binding of Mre11 complexes viaRad50 (23, 30, 48, 52, 62, 69). Since point mutations that abolishthe nuclease activity of Mre11 do not impair most forms of DSBrepair in mitotic cells, the contribution of the Mre11/Rad50complex to the DSB repair process is largely independent ofits nuclease activity. Importantly, Mre11 removes Spo11 covalentlybound to the break site by endonucleolytic cleavage a few basesfrom the site of attachment, leading to the release of a Spo11-oligonucleotidecomplex (50).

A specific class of separation-of-function mutants of S. cerevisiaeRAD50, named rad50S, allow DSB formation but are totally defectivein the processing of Spo11-induced meiotic DSBs, as observedin nuclease-deficient mre11 mutants, and thus they accumulateunprocessed DSBs with covalently attached Spo11 protein at the5' ends (2, 32). SAE2/COM1 gene deletion mutants possess a meioticphenotype very similar to that of rad50S point mutants (13,42, 54, 55), and Spo11-oligonucleotide complexes are not observedin rad50S or sae2 ${Delta}$ /Com1 ${Delta}$ mutants. These observations imply thatSae2/Com1 is involved in DSB end processing in collaborationwith the MRX(N) complex. However, no clear Sae2/Com1 homologueswith structural or functional similarity have been reportedin organisms other than Saccharomyces species.

In addition to being involved in repair processes per se, theMre11 complex is also involved in sensing DSB ends. Bindingof Mre11 to break sites is a prerequisite for the recruitmentand activation of protein kinases, including Tel1/SpTel1 andMec1/SpRad3 (S. cerevisiae/S. pombe), which are homologues ofmammalian ATM and ATR, respectively. Upon MRX(N)-dependent activation,ATM phosphorylates downstream substrates, including Mre11 andNbs1 (19, 36, 49). S. cerevisiae Sae2/Com1 is also phosphorylatedin a Tel1- and Mec1-dependent manner, and the Mec1 dependencyis much stronger than that of Tel1 (5). Importantly, Sae2/Com1negatively regulates the DNA damage checkpoint in a phosphorylation-dependentmanner (12).

The S. pombe rad2⁺ gene encodes a structure-specific endonucleasehomologous to mammalian Fen-1 and S. cerevisiae Rad27, whichis required for Okazaki fragment maturation during DNA replication(47). Loss of the nuclease activity in combination with somesingle mutations that cause defects in HR in S. cerevisiae andS. pombe is lethal (16, 59). We used this relationship to isolatepreviously unidentified S. pombe genes involved in HR. We constructedtwo slr (synthetic lethality with rad2 ${Delta}$ ) libraries consistingof mutants that were inviable in a rad2 ${Delta}$ background (64, 67).Among these mutants, we identified the rhp57⁺, rad60⁺, rad62⁺,fbh1⁺, nbs1⁺, rad32⁺, and mcl1⁺ genes, mutations of which areall epistatic to rhp51 ${Delta}$ mutations, with the exception of mcl1,which is colethal with the rhp51 ${Delta}$ mutation (44-46, 64, 65, 67;unpublished results).

In this study, we characterized the slr9 mutant, which was isolatedin our second screen (67). Slr9 expressed from a multicopy plasmidsuppressed the DNA repair defect of an Nbs1 mutant containinga mutation in its FHA domain, a phosphopeptide-binding domain.From this genetic interaction, we renamed Slr9 Nbs1-interactingprotein 1 (Nip1). Further, epistasis analysis suggested thatNip1 functions in Rhp51-dependent recombinational repair, togetherwith the Rad32 (spMre11)-Rad50-Nbs1 (MRN) complex. Nip1 is phosphorylatedin asynchronous exponentially growing cells and is more extensivelyphosphorylated in response to bleomycin treatment. Interestingly,meiotic DNA DSBs accumulate in the nip1 ${Delta}$ mutant. Therefore, wepropose that Nip1 functions to regulate the nuclease activityof the MRN complex. Some, but not all, of these mutant propertiesare similar to those of S. cerevisiae sae2/com1 mutants. Nip1and Sae2/Com1 have a sequence similarity that is limited tothe C-terminal region, containing an RHR motif, implying thatNip1 is a functional counterpart of Sae2/Com1. Possible functionalhomologues of Sae2/Com1 and Nip1 in higher eukaryotes includethe human CtIP protein and the Arabidopsis thaliana gamma response1 protein (AtGR1). Very recently, Russell's group has identifiedthe S. pombe ctp1⁺ gene as a cell cycle-regulated gene requiredfor HR (39). nip1⁺ is identical to ctp1⁺.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Yeast strains, media, and genetic methods. The S. pombe strains used in this study are listed in Table1. All of the original slr mutants had the genotype h^–Msmt-0 slr rad2⁺ leu1-32 ura4-D18 ade6-704 (67). Standard proceduresand media were used for propagation and genetic manipulations,as previously described (43). The sensitivity of S. pombe cellsto ${gamma}$ and UV irradiation was analyzed as previously described(46).

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TABLE 1. S. pombe strains used in this study

Cloning of the slr9⁺/nip1⁺ gene, which complements the slr9-1 mutation. slr9-1 cells were transformed with an S. pombe genomic library(67) constructed with the vector pSP102 (64), and methyl methanesulfonate(MMS)-resistant transformants were selected on plates containing0.004% MMS (64). Plasmids conferring MMS resistance to slr9-1mutants were isolated, and their inserts were sequenced. The5' and 3' regions of slr9⁺/nip1⁺ cDNAs were amplified by PCRwith the S. pombe cDNA library constructed in the vector pGADGH(Clontech) as a template and the primer sets 5' AD/IWA590 and3' AD/IWA217, respectively. The sequences of 5' AD, 3' AD, IWA217,and IWA590 are 5'-CTATTCGATGATGAAGATACCCCACCAAACCC-3', 5'-GTGAACTTGCGGGGTTTTTCAGTATCTACGAT-3',5'-TAAAGCACTTCCTGCTTACG-3', and 5'-TTTCGTCATTCCAAGTAGGC-3',respectively.

FLAG tagging and mutagenesis of Nip1. Genomic DNA containing the slr9⁺/nip1⁺ region was cloned intothe SmaI site of pBluescript II SK (+). An NdeI recognitionsite was created at the nip1 stop codon by site-direct mutagenesiswith the QuikChange site-directed mutagenesis kit (Stratagene).The 3xFLAG sequence created by annealing of an oligonucleotideset, IWA533 and IWA534, was inserted into the NdeI site of nip1,yielding pSK-nip1F. The sequences of IWA533 and IWA534 are 5'-TATGGACTACAAAGACCATGACGGTGATTATAAAGATCATGACATCGATTACAAGGATGACGATGACAAGCA-3'and 5'-TATGCTTGTCATCGTCATCCTTGTAATCGATGTCATGATCTTTATAATCACCGTCATGGTCTTTGTAGTCCA-3'.The ura4⁺ marker was inserted into the PstI site of pSK-nip1F.The plasmid was digested at the unique EcoO65I site within thenip1 sequence and used for transformation of S. pombe YA119.Pop-out clones having lost the ura4⁺ marker were selected onthe basis of resistance to 5-fluoroorotic acid. To generatenip1 point mutants, site-directed mutagenesis was performedwith pSK-nip1F and the following primer sets: IWA963 (5'-GCTAGACTTAAAGCTCAATTGGTCTTGG-3')and IWA964 (5'-CCAAGACCAATTGAGCTTTAAGTCTAGC-3') for the S35Amutation, IWA965 (5'-GCTACGTGAAGCACAACCATTAGCTCC-3') and IWA966(5'-GGAGCTAATGGTTGTGCTTCACGTAGC-3') for the T175A mutation,IWA1097 (5'-AATCCCTCCGCATGCACCCACTCTTCCTG-3') and IWA1098 (5'-CAGGAAGAGTGGGTGCATGCGGAGGGATT-3')for the S114A mutation, and IWA1099 (5'-CATTTACGAGCAAGGGCACCTGAAGACATG-3')and IWA1100 (5'-CATGTCTTCAGGTGCCCTTGCTCGTAAATG-3') for the S165Amutation. The kanMX6 sequence was inserted at the Bsp1407I site,which was located 67 bp distal from the nip1 stop codon. TheDNA fragments of the nip1 genomic region containing kanMX6 weretransformed into S. pombe. All mutants were confirmed by PCR,Southern blotting, and sequencing analysis.

Preparation of cell extracts. Cells were grown in YES or EMM medium (43) at 30°C to $~$ 10⁷cells/ml. Bleomycin (10 mU/ml; Sigma) or mock solution (distilledwater) was added to cultures, and incubation was continued for4.5 h. Cells were collected by low-speed centrifugation, washedwith distilled water, resuspended in 400 µl HB buffer[25 mM morpholinepropanesulfonic acid (MOPS; pH 7.2), 100 mMNaCl, 15 mM MgCl₂, 15 mM EGTA, 60 mM β-glycerophosphate,15 mM para-nitrophenylphosphate, 0.5 mM sodium vanadate, 10µg/ml pepstatin, 10 µg/ml chymostatin, 120 µg/ml4-(2-aminoethyl) benzenesulfonyl fluoride hydrochloride, 1.57mg/ml benzamidine, 5 µg/ml leupeptin, 5 µg/ml bestatin,0.01% Triton X-100), and lysed by vortexing with glass beads.Clarified lysates obtained by centrifugation were used as cellextracts.

Antibodies. Antiserum against the recombinant S. pombe Nbs1 protein wasraised in rabbits. The antibody was affinity purified from theimmune serum as previously described (53). The anti-FLAG M2monoclonal antibody was purchased from Sigma.

Western blotting. The protein concentration of cell extracts was measured witha protein assay kit (Bio-Rad), and aliquots of cell extractscontaining 50 µg protein were used for Western blot analysis.The anti-FLAG M2 monoclonal antibody was used as the primaryantibody to detect Nip1-3xFLAG, and the rabbit anti-Nbs1 antibodywas used to detect untagged Nbs1. The ECL Plus system (GE HealthcareBio-Science) was used for detection of immunocomplexes.

Immunoprecipitation. Aliquots (200 µl, $~$ 2 mg total protein) of the cell extractsdescribed above were incubated with 20 µl anti-FLAG M2agarose ( $~$ 50% suspension) (Sigma) at 4°C for 3 h to precipitatethe Nip1-3xFLAG fusion protein. The beads were washed with HBbuffer, and the precipitates were subjected to Western blotting.When phosphatase treatment was performed, lambda phosphatase(NEB) was added to a reaction mixture containing precipitatedbeads in 10 µl phosphatase buffer (NEB) at 30°C for30 min, followed by Western blotting analysis.

Induction of meiosis and detection of meiotic DSBs. To monitor meiosis-associated DSBs, pat1-114 haploid cells weresynchronously induced to undergo meiosis and then processedfor DNA plug preparation as previously described (9). Agarose-embeddedchromosomal DNA was fractionated by pulsed-field gel electrophoresis(PFGE) on a 0.8% chromosomal-grade agarose gel in 1x Tris-acetate-EDTAbuffer with the CHEF-MAPPER system (Bio-Rad) under the followingconditions: temperature, 14°C; run time, 48 h; voltage,2 V/cm; included angle, 106°; initial and final switchingtimes, 20 and 30 min, respectively. The DNA was stained withethidium bromide.

Nucleotide sequence accession number. The nucleotide sequence data obtained in this study, includingexon and intron information, have been deposited with the DDBJunder accession number AB363065.

RESULTS

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RESULTS

Cloning of the slr9⁺/nip1⁺ gene. In previous studies, we constructed two slr mutant librariesin which we collected mutants with mutations that caused syntheticlethality in the rad2 ${Delta}$ background and that also conferred sensitivityto MMS (64, 67). In this study, we analyzed slr9, which correspondsto mutant no. 45 from the second screen (67). To clone the slr9⁺gene, the slr9-1 mutant was transformed with an S. pombe genomiclibrary. Transformants which MMS sensitivity complemented tothe wild-type level were isolated, and plasmid DNA was recovered.Sequence analysis revealed that one plasmid contained a 2.2-kbgenomic fragment in which a putative open reading frame (ORF),SPCC338.08, and a very questionable ORF, SPCC338.09, were annotated.The 5' and 3' regions of the SPCC338.08 cDNA were isolated fromthe S. pombe cDNA library by PCR with the primer sets 5' AD/IWA590and 3' AD/IWA217, and the amplified regions were sequenced.The gene structure is shown in Fig. 1A. SPCC338.08 is transcribedfrom 429 bp upstream to 958 bp downstream of the putative initiationcodon. Since there were several stop codons and no ATG upstreamfrom the putative initiation codon, this appeared to be theactual initiation codon. An intron that had not been predictedin the database was found in the 3' region. Thus, the SPCC338.08gene product is encoded by two exons and consists of 294 aminoacids, although the database had predicted 285 amino acids.For SPCC338.09, cDNA was not amplified by PCR with the primerset from the cDNA library, and thus, the SPCC338.09 ORF maynot be transcribed, at least during vegetative growth. Therefore,we concluded that SPCC338.08, but not SPCC338.09, correspondsto the slr9 gene.

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FIG. 1. Nip1 protein motifs. (A) Structure of the nip1 gene. The isolated cDNA contains nucleotides –429 to +958. The ORF of nip1 consists of two exons separated by one intron. Three serine residues and one threonine residue in consensus phosphorylation site sequences for ATM/ATR and CDK are indicated by circles. Underlined sequences are highly conserved sequences; one contains the RxxL and CxxC motifs, and the other contains the Sae2 RHR motif. (B) Schematic presentation of the S. pombe Nip1 protein. The serine at position 35 and the threonine at position 175 are potential phosphorylation sites for ATM/ATR kinases, and the two serines at positions 114 and 165 are potential CDK phosphorylation sites. The N-terminal region (22 to 160) is predicted to form a coiled-coil structure by the COILS program (40). (C) Sequence alignment of the region containing the Sae2 RHR motif. The consensus sequence is (G/S/T)RHR. The Sae2 motif is found in many eukaryotes, including fungi. (D) Sequence alignment of the region containing the RxxL (D-box) and CxxC motifs of two fission yeast, S. pombe and Schizosaccharomyces japonicus, five vertebrates, two higher plants, a nematode, and two protists. Abbreviations for the species whose sequences are shown in panels C and D and accession numbers for the Nip1 homologues are as follows: Spo, S. pombe; Sja, S. japonicus; nig, Aspergillus niger (CAK45154); Aor, Aspergillus oryzae (BAE61104); Afu, Aspergillus fumigatus (XP_750508); Acl, Aspergillus clavatus (XP_001269402); Ate, Aspergillus terreus (XP_001209515); nid, Aspergillus nidulans (XP_662716); Aca, Ajellomyces capsulatus (XP_001545011); Cim, Coccidioides immitis RS (XP_001248767); Bfu, Botryotinia fuckeliana (XP_001552631); Ssc, Sclerotinia sclerotioru (EDO02392); Pno, Phaeosphaeria nodorum SN15 (EAT90897); Ncr, Neurospora crassa (XP_957865); glo, Chaetomium globosum (EAQ85759); Yli, Yarrowia lipolytica (XP_502193); Cne, Cryptococ-cus neoformans (XP_572699); Cci, Coprinopsis cinerea (EAU86571); Uma, Ustilago maydis (XP_758978); Hsa, Homo sapiens (AAC14371); Mmu, Mus musculus (house mouse, NP_001074692); Gga, Gallus gallus (XP_419158); Xla, Xenopus laevis (African clawed frog, NP_001085825); Dre, Danio rerio (zebra fish, NP_001012518); Ath, Arabidopsis thaliana (Q9ZRT1); Osa, Oryza sativa (EAZ01661); Ddi, Dictyostelium discoideum (XP_635231); Cel, C. elegans (NP_499398); Cpa, Cryptosporidium parvum (XP_628681); Sce, S. cerevisiae (CAA96887); Sca, Saccharomyces cariocanus (ABI48902); Spa, Saccharomyces pastorianus (ABI48905); Vpo, Vanderwaltozyma polyspora (EDO17800); Dha, Debaryomyces hansenii (CAG86377); Ago, Ashbya gossypii (NP_984048); Kla, Kluyveromyces lactis (CAG98790); gla, Candida glabrata (CAG62002).

To confirm the identity of the slr9 gene, we replaced the SPCC338.08ORF with the ura4⁺ marker. The resulting deletion mutant (YA1097)exhibited a phenotype very similar to that of the originallyisolated slr9-1 mutant, including slow growth, sensitivity toMMS, and synthetic lethality with rad2 ${Delta}$ (data not shown). Sequencingof the genomic DNA revealed that the slr9-1 mutant had a CG-to-TAtransition mutation that converted Arg162 (CGA) to a stop codon(TGA) in SPCC338.08. Thus, SPCC338.08 contains the slr9 gene.Since slr9 interacts genetically with nbs1, as described below,we named it Nbs1-interacting protein 1, nip1⁺.

Nip1 contains RxxL, CxxC, and RHR motifs in the C-terminal region. BLAST and PSI-BLAST searches allowed the identification of potentiallyimportant Nip1 motifs (Fig. 1B to D). A summary of these motifsis schematically presented in Fig. 1B. The RHR motif in theC-terminal region is the representative signature of Sae2/Com1homologues (Fig. 1C). SAE2/COM1 is an S. cerevisiae gene thatwas originally identified in mutants defective in meiotic recombination(42, 54). Although the region containing the RHR motif is limited(approximately 30 amino acids), this region is well conservedfrom Saccharomyces Sae2/Com1 to human CtIP. CtIP was originallydiscovered as a cofactor of the transcriptional corepressorCtBP (C terminus-binding protein), a coregulator that bindsto the C terminus of adenovirus E1A (57), BRCA1 (74, 81), andthe retinoblastoma tumor suppressor protein RB (24) (for reviews,see references 11 and 75). The Arabidopsis thaliana gamma response1 (AtGR1) protein also exhibits sequence similarity to the RHRmotif in the C terminus. The gene that encodes it was originallyidentified as induced by ${gamma}$ irradiation with no known function(18). Very recently, it has been identified as a functionaland structural homologue of Sae2/Com1 (66).

We identified the RxxL and CxxC motifs approximately 30 to 50amino acids upstream of the RHR motif in Nip1 homologues fromvertebrates, plants, nematodes, protists, and fission yeast,but not in Nip1 homologues from other fungi, including Saccharomycesand Aspergillus (Fig. 1D). The RxxL motif is also called theD-box, which is a representative signature of APC/C substrates(3, 25, 34). The presence of this motif suggests that Nip1 familyproteins are proteolytically regulated during the cell cycleby APC/C-mediated ubiquitination.

The conserved CxxC sequences are found in proteins with a D-box,but not in proteins lacking this motif (Fig. 1D). The CxxC motifin Rad50 is involved in zinc chelation (29). In addition, theN-terminal region of Nip1, like those of CtIP and AtGR1, ispredicted to form a coiled-coil structure (Fig. 1B). The CtIPN terminus is involved in homodimerization (20). Therefore,Nip1 family proteins have two potentially important domainsenabling them to dimerize, the CxxC motif and the N-terminalcoiled-coil region.

Nip1 contains two potential CDK-dependent phosphorylation sitesand two Rad3/Tel1-dependent phosphorylation sites. CtIP hasone CDK-dependent and two ATM-dependent phosphorylation sites(38, 79). However, these sites do not seem to be conserved betweenNip1 and CtIP.

nip1 is a novel rhp51 epistasis group gene. We first examined the DNA repair activity of a nip1 deletionstrain (Fig. 2). The nip1 ${Delta}$ mutant is sensitive to various DNA-damagingtreatments, such as UV and ${gamma}$ irradiation, bleomycin, and MMS.Bleomycin is a radiomimetic reagent that causes both single-strandbreaks and DSBs in DNA. To determine whether Nip1 is involvedin the Rhp51-dependent recombinational repair pathway, a nip1 ${Delta}$ rhp51 ${Delta}$ double mutant was constructed and its UV repair phenotypewas compared to that of the single mutants. As shown in Fig.2A, the nip1 ${Delta}$ rhp51 ${Delta}$ double mutant was as sensitive to UV as therhp51 ${Delta}$ single mutant. Thus, Nip1 is involved in an Rhp51 recombinase-dependentrecombinational repair pathway.

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FIG. 2. Genetic interactions of Nip1 with Rhp51 and the MRN complex. (A) Killing curve for UV irradiation suggests that Nip1 functions in the Rhp51-dependent repair pathway. The strains used were SP129 (wild type, crosses), YA1097 (nip1 ${Delta}$ , closed circles), YA1177 (rhp51 ${Delta}$ , squares), and YA1268 (nip1 ${Delta}$ rhp51 ${Delta}$ , open circles). (B) The rad32 ${Delta}$ (YA1077), nbs1 ${Delta}$ (SPN341), and nip1 ${Delta}$ (YA1097) single mutants showed very similar sensitivities to ${gamma}$ and UV irradiation. SP129 was used as the wild-type control. (C and D) A nip1 ${Delta}$ nbs1 ${Delta}$ double mutant showed sensitivities to UV, bleomycin, and MMS that were similar to those of the single mutants. The strains used were SP129 (wild type, crosses), YA1097 (nip1 ${Delta}$ , open circles), YA1184 (nbs1 ${Delta}$ , squares), and YA1233 (nip1 ${Delta}$ nbs1 ${Delta}$ , closed circles).

slr10 is an FHA domain mutant of nbs1. Mutant no. 16 isolated in our previous second screen (67) wasnamed slr10 in this study. We identified the slr10⁺ gene bythe same procedures used to clone the slr9⁺/nip1⁺ gene. Twotransformants of slr10, clones 2-36 and 7, displayed MMS resistancesimilar to that of wild-type cells (Fig. 3A). Plasmids wereisolated from clones 2-36 and 7 and analyzed. DNA sequencingrevealed that clone 2-36 contained a genomic fragment identicalto that of previously isolated pNT101, which contains the nbs1⁺gene (67). On the basis of this result, the genomic sequenceof the nbs1 locus in the slr10 mutant was determined. We foundthat the isolated slr10 mutant had a GC-to-AT transition mutationthat converted Gly103 (GGT) to Asp (GAT). Genetic mapping alsoshowed that slr10 was very close to nbs1 on chromosome II (datanot shown). A newly reconstructed strain carrying the same mutationas that in nbs1 exhibited a phenotype indistinguishable fromthat of the original slr10 mutant (data not shown). Therefore,we concluded that slr10 is an allele of nbs1. Hereafter, theslr10 mutation is referred to as nbs1-s10.

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FIG. 3. Isolation and characterization of the nbs1-s10 allele. (A) Two plasmids restored normal MMS resistance to an slr10 mutant (no. 16). Two mutant no. 16 transformants, transformed by clone 2-36 (nbs1⁺) and clone 7 (nip1⁺), exhibit a sensitivity to MMS (0.004%) similar to that of the wild-type strain (SP185). (B) Sequence alignment of the FHA domain of human (h), mouse (m), and S. pombe (sp) Nbs1, and S. cerevisiae (sc) Xrs2. The arrowhead indicates the conserved Gly103 residue that is mutated to Asp in the slr10 mutant. (C) Expression of wild-type Nbs1 and Nbs1-s10 proteins detected by Western blotting. Wild-type (SP129), nbs1-s10 (YA1128), and nbs1 ${Delta}$ (YA1184) cells were analyzed. (D) The sensitivity to UV and bleomycin of the nbs1-s10 mutant was intermediate between those of the control and nbs1 ${Delta}$ mutant strains. The strains used for the spot tests were the same as in panel C. (E) nbs1⁺, but not nbs1-s10, fully complemented the DNA damage sensitivity of the nbs1-s10 mutant. Wild-type (WT, SP129) and nbs1-s10 (YA1128) cells were transformed with the pSP102 vector alone, pSP102 carrying nbs1-s10, or pSP102 carrying nbs1⁺, and the sensitivity of the transformants to HU, UV, bleomycin, and MMS was analyzed. (F) The DNA damage sensitivity of the nbs1-s10 mutant, but not of the nbs1 ${Delta}$ mutant, was suppressed by nip1⁺ expressed from a multicopy plasmid, pSP102. Wild-type (SP129), nbs1-s10 (YA1128), and nbs1 ${Delta}$ (YA1184) cells were transformed with the pSP102 vector, pSP102 carrying nip1⁺, or pSP102 carrying nbs1⁺, and the sensitivity of the transformants to HU, UV, bleomycin, and MMS was analyzed.

Gly103 is within the FHA domain and is a conserved amino acidamong Nbs1 homologues (Fig. 3B). The nbs1-s10 mutant was slightlyless sensitive to UV, bleomycin, hydroxyurea (HU), and MMS thanwas the nbs1 ${Delta}$ mutant (Fig. 3D and data not shown). The amountof cellular Nbs1-s10 protein was similar to that of wild-typeNbs1 (Fig. 3C), and overexpression of Nbs1-s10 from a plasmidvector did not suppress the sensitivity to various DNA-damagingtreatments (Fig. 3E). These results suggest that the nbs1-s10mutation does not cause instability of Nbs1, but rather thatthe defect in DNA repair in Nbs1-s10 is probably due to defectsin FHA domain function. Overexpression of nbs1-s10 from a multicopyplasmid did not affect DNA repair in wild-type cells, indicatingthat nbs1-s10 is a recessive mutation.

Nip1 is a multicopy suppressor of nbs1-s10. Clone 7 plasmid contained genomic DNA encoding the nip1⁺ gene,and sequencing analysis revealed that the original slr10 mutantdid not have a nip1 mutation. Therefore, nip1⁺ is a multicopysuppressor of nbs1-s10 with respect to UV, bleomycin, HU, andMMS sensitivity (Fig. 3F). Importantly, plasmid-expressed nip1⁺did not suppress nbs1 ${Delta}$ sensitivity to DNA-damaging agents (Fig.3F), indicating that nip1⁺ is an allele-specific multicopy suppressorof the nbs1-s10 mutation.

Nip1 and Nbs1 function in the same repair pathway. The allele-specific multicopy suppression of nbs1-s10 by nip1⁺described above suggested a functional interaction between Nip1and Nbs1. We therefore analyzed the epistatic relationshipsof these genes with regard to DNA repair (Fig. 2B to D). Thenip1 ${Delta}$ single mutant displayed sensitivities similar to that ofthe nbs1 ${Delta}$ mutant in response to ${gamma}$ or UV irradiation, MMS, andHU. The sensitivities of the nip1 ${Delta}$ mutant to these DNA-damagingagents were comparable to those of a rad32 ${Delta}$ single mutant (Fig.2B and C). We then constructed a nip1 ${Delta}$ nbs1 ${Delta}$ double mutant andcompared its sensitivities to those of the single mutants. Asshown in Fig. 2C and D, the double mutant was as sensitive aseach single mutant to UV, bleomycin, and MMS. Therefore, Nip1is likely to function in the same repair pathway as Nbs1.

Nip1 is phosphorylated in response to DNA damage. The observed genetic interaction between Nip1 and Nbs1 in theDNA damage response led us to examine whether there is a directphysical interaction between the two proteins. We constructeda yeast strain expressing C-terminally FLAG-tagged Nip1 at theoriginal genomic locus that showed normal repair activity (Fig.4B). Nip1 was immunoprecipitated from cell extracts preparedfrom either normal or bleomycin-treated cells with an anti-FLAGantibody. However, Nbs1 was not detected by Western blotting.Moreover, Rad32 was not detected (data not shown). When immunoprecipitationwas performed with Rad32 tagged with hemagglutinin epitopesas bait, Nip1 signals were not detected in the Rad32-containingimmunocomplexes, although Nbs1 coprecipitated with Rad32 (datanot shown).

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FIG. 4. Nip1 is phosphorylated under normal growth conditions and becomes more extensively phosphorylated in response to treatments that cause DNA damage. (A) Nip1 is modified upon DNA damage. Cell extracts from an untagged Nip1 strain (YA119) and a Nip1-FLAG strain (YST153) were analyzed by Western blotting with an anti-FLAG antibody. Under normal conditions, Nip1 migrates to the Nip1-F position. Upon DNA damage, modified Nip1 protein migrates to the position indicated by Nip1-S. non, nontreated; bleo, bleomycin. (B) Phosphatase treatment reveals that the Nip1 modification is a double phosphorylation. Immunocomplexes from the Nip1-FLAG strain were treated with lambda protein phosphatase as described in Materials and Methods. S and F in panels A and B indicate Nip1-S and Nip1-F, respectively. (C) Nip1 mutants with mutations at four possible phosphorylation sites are still phosphorylated upon bleomycin treatment. (Top) Wild-type Nip1 protein has four serine/threonine residues that are potential phosphorylation sites. Combinations of these residues, S35-Q36, S114-P115, S165-P166, and T175-Q176, were mutated to alanines. (Bottom) Three Nip1-FLAG mutants were constructed, an S35A-T175A double mutant named SQ/TQ (YST442), an S114A-S165A double mutant named SP₁/SP₂ (YST445), and an S114A-S165A-SP₁/SP₂ quadruple mutant named SQ/TQ/SP₁/SP₂ (YST447). A wild-type strain (YST438) and the mutant strains were incubated in the presence (+) or absence (–) of bleomycin, and cell extracts were analyzed by Western blotting with the anti-FLAG antibody. The SP₁/SP₂ and SQ/TQ/SP₁/SP₂ mutant proteins migrated to the position corresponding to that of fully dephosphorylated Nip1 (Nip1-FF) but were modified upon treatment with bleomycin and migrated to the Nip1-F position. aa, amino acids. (D) Phosphatase treatment reveals that the modification of the SP₁/SP₂ mutant protein is phosphorylation. Immunocomplexes from the SP₁/SP_2-FLAG strain (YST445) were treated with lambda protein phosphatase as described in Materials and Methods. (E) The SQ/TQ (YST442), SP₁/SP₂ (YST445), and SQ/TQ/SP₁/SP₂ (YST447) mutants do not show a detectable DNA repair defect.

In these experiments, we found that expression of Nip1 proteinwas induced by severalfold upon bleomycin treatment, consistentwith a previous report (71). We also detected a more slowlymigrating band above the normal Nip1 signal in samples fromcells treated with bleomycin (Fig. 4). The slower signal wasalso detected in samples from MMS- or HU-treated cells (Fig.4A), suggesting that Nip1 was modified in response to DNA damage.As protein phosphorylation is one of the major modificationsoccurring in response to DNA damage, we treated Nip1 immunoprecipitateswith protein phosphatase to determine whether Nip1 was phosphorylated.As shown in Fig. 4B, the more slowly migrating signal disappearedafter phosphatase treatment and the Nip1 band migrated fasterthan that from untreated immunoprecipitates from normal cells.We treated Nip1-containing immunoprecipitates from normal cellswith phosphatase and found that Nip1 in normally growing cellsis also phosphorylated (Fig. 4B). These results suggest thatNip1 is phosphorylated during at least two phases, normal growthand in response to DNA damage. Hereafter, the fully phosphorylatedform of Nip1 is designated Nip1-S (slow mobility) and basallyphosphorylated Nip1 is designated Nip1-F (fast mobility).

Nip1 phosphorylation is dependent on the DNA damage checkpoint kinase and the MRN complex. To investigate the genetic requirements for the DNA damage-dependentmodification of Nip1, we monitored Nip1 phosphorylation in variousmutant backgrounds (Fig. 5). In rad32 or nbs1 deletion mutants,a small amount of Nip1-S signal was observed during normal growth.However, the induced accumulation of Nip1-S signal in responseto bleomycin treatment was not observed. In contrast, deletionof rhp51, rhp57, or ku70 did not substantially affect the Nip1phosphorylation pattern, compared to that of wild-type cells,regardless of bleomycin treatment (Fig. 5A and data not shown).These results suggest that the MRN complex is important forNip1 phosphorylation.

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FIG. 5. Genetic requirements of Nip1 phosphorylation. (A) Rad32 and Nbs1, but not Rhp51, are required for the DNA damage-induced phosphorylation of Nip1. (B) Tel1 and Rad3 are required for the DNA damage-induced phosphorylation of Nip1, whereas other downstream checkpoint factors are not essential for phosphorylation.

Next, we examined the involvement of DNA damage checkpoint proteinsin Nip1-S formation (Fig. 5B). We first monitored the effectof deleting rad3⁺, which encodes an ATR kinase homologue, amajor kinase in the DNA damage response in S. pombe. Bleomycin-dependentphosphorylation of Nip1 was not altered in the rad3 deletionmutant. Similar results were obtained with a mutant containinga deletion of rad26, which encodes an ATRIP homologue, an essentialinteractor with ATR. However, phosphorylation was greatly decreasedby deletion of tel1⁺, which encodes a minor kinase in S. pombe,the ATM kinase. This kinase plays an important role in vertebratecells, including human cells. Bleomycin-dependent Nip1 phosphorylationwas almost completely abolished in a rad3 tel1 double-deletionmutant.

Requirements for the checkpoint clamp (rad1 and rad9), the clamploader (rad17), downstream components of the DNA damage checkpoint(crb2 or mrc1), and the downstream kinases chk1 and/or cds1were also examined (Fig. 5B). Single deletion mutations andthe chk1 ${Delta}$ cds1 ${Delta}$ double mutation did not affect Nip1 phosphorylation,suggesting that the Tel1 kinase, but not other downstream components,is required for DNA damage-dependent Nip1 phosphorylation. Inthe absence of Tel1, Rad3 (ATR) can partially substitute forTel1 kinase activity in Nip1 phosphorylation.

Relationship between Nip1 phosphorylation and DNA damage repair. Next, we examined potential Nip1 phosphorylation sites. Nip1phosphorylation is dependent on Tel1 (and Rad3), as describedabove, and these kinases phosphorylate serine and threoninein SQ and TQ consensus sequences. CDK-dependent phosphorylationoccurs at SP consensus sequences. Wild-type Nip1 has four potentialphosphorylation sites fitting these criteria: Ser-35, Ser-114,Ser-165, and Thr-175 (Fig. 1B and 4C). The SQ TQ double mutation(S35A and T175A) was expected to eliminate putative phosphatidylinositol3-kinase (PI3-kinase)-dependent phosphorylation sites. The SP₁SP₂ double mutation (S114A and S165A) was expected to eliminateputative CDK-dependent phosphorylation sites. The SQ TQ SP₁SP₂ quadruple mutation eliminated all four potential sites.We constructed these three nip1 mutants and examined bleomycin-inducedphosphorylation. As shown in Fig. 4C, the SQ TQ mutant displayeda phosphorylation pattern similar to that of the wild-type Nip1protein. In contrast, the Nip1-F signal of the SP₁ SP₂ mutantwas not detected in cell extracts prepared from undamaged normalcells. In these samples, a more rapidly migrating band, Nip1-FF,appeared. We hypothesized that Nip1-FF corresponds to the fullydephosphorylated form of wild-type Nip1 (Fig. 4B), which wasconfirmed by phosphatase treatment (Fig. 4D). Since Nip1 isphosphorylated in asynchronous cultures during normal growth,we conclude that Ser-114 and/or Ser-165 are the site of thisbasal phosphorylation, which may be CDK dependent. However,this SP₁ SP₂ mutant became phosphorylated upon bleomycin treatmentand the modified signal migrated at the same position as wild-typeNip1-F, although Nip1-S was not detected (Fig. 4C and D). TheSQ TQ SP₁ SP₂ quadruple mutant showed a phosphorylation patternvery similar to that of the SP₁ SP₂ mutant. Therefore, it ismost likely that the site(s) of bleomycin-induced phosphorylationis an amino acid residue(s) other than these four S/T residues.

The three nip1mutants showed no detectable defect in DNA repairin response to UV irradiation, MMS, or bleomycin (Fig. 4E).These results also indicate that none of the four candidatesites is necessary for DNA repair. Therefore, the observed phosphorylationat Ser-114 and/or Ser-165 may not play a direct role in DNArepair, and other, unidentified, phosphorylation sites may becritically important for DNA repair.

Meiotic DSBs accumulate in nip1 ${Delta}$ cells, similar to the phenotype of rad50S mutants. We examined the meiotic functions of Nip1. In meiosis, transientDSB formation is induced and subsequent repair is observed.These events are closely associated with an elevated frequencyof HR. To easily assess the formation and repair of meioticDSBs, we induced pat1-114 haploid cells to undergo highly synchronousmeiosis and analyzed their chromosomal DNA by PFGE. PFGE allowsvisualization of intact chromosomes and meiotically broken DNAas three discrete bands and smeared bands, respectively. Thus,as shown in wild-type cells, we can detect transient DSB formationby the appearance of smeared DNA bands (Fig. 6, wild type at5 h) and successive repair by restoration of the three chromosomalbands (Fig. 6, wild type at 7 h). In nip1 ${Delta}$ cells, a high levelof broken DNA was observed at 5 h in sporulation culture (Fig.6, nip1 ${Delta}$ mutant at 5 h), and it persisted for at least 2 h more(Fig. 6, nip1 ${Delta}$ mutant at 7 h). In contrast, the progression ofpremeiotic DNA synthesis (data not shown) and the time pointsat which DSBs appeared in nip1 ${Delta}$ cells were very similar to thosein wild-type cells (Fig. 6, wild type at 5 h and nip1 ${Delta}$ mutantat 5 h). These features are reminiscent of the rad50S mutant,in which meiotic DSBs accumulate without being repaired (9,78). Next, we compared nip1 ${Delta}$ cells with a mutant impaired inan MRN complex component, Rad32, and a mutant defective in thecatalytic engine that produces meiotic DSBs, Rec12 (the S. pombeSpo11 homologue), to determine whether their phenotypes differed.In rad32 ${Delta}$ cells, smeared DNA remained at 7 h but the smearedsignal was much weaker than in nip1 ${Delta}$ cells, while breaks werenot observed in rec12 ${Delta}$ cells. These meiotic phenotypes of rec12 ${Delta}$ and rad32 ${Delta}$ cells are consistent with the results of Young etal. (77, 78). Importantly, the accumulation of DSBs in the nip1 ${Delta}$ mutant was dependent on Rad32 and Rec12, since nip1 ${Delta}$ rad32 ${Delta}$ andnip1 ${Delta}$ rec12 ${Delta}$ double mutants showed phenotypes very similar tothose of rad32 ${Delta}$ and rec12 ${Delta}$ single mutants, respectively. It alsoshould be pointed out that the migration of chromosome III wasfaster in samples from cells of the nip1 ${Delta}$ and rad32 ${Delta}$ backgroundsthan in samples from wild-type and rec12 ${Delta}$ mutant cells. Althoughthe reasons for this alteration are unknown, the differencemight be attributable to different copy numbers of the ribosomalDNA genes carried in chromosome III.

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FIG. 6. Meiotic DSBs accumulate in nip1 ${Delta}$ mutant cells. pat1-114 haploid cells with various mutations were induced to synchronously undergo meiosis and collected at the indicated time points, and chromosomal DNA was analyzed by PFGE. wt, wild type; Chr., chromosome.

DISCUSSION

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DISCUSSION

In this study, we identified the previously uncharacterizedslr9 gene in fission yeast, which we isolated as a rad2 ${Delta}$ -syntheticlethal mutant (64, 67). We named the gene nip1 on the basisof its genetic interaction with the nbs1-s10 allele. The nip1null mutation elevates sensitivity to various DNA-damaging agents,including UV and ${gamma}$ irradiation, bleomycin, MMS, and HU. Althoughthese agents affect DNA differently, they all directly or indirectlycause DSBs, which are predominantly repaired by HR in yeast.Additionally, nip1 belongs to the same epistasis group as rhp51(Fig. 2). These findings suggest that nip1 is involved in Rhp51-dependentrecombinational repair. The nip1 null mutant exhibited DNA repairdefects very similar to those of the rad32 ${Delta}$ and nbs1 ${Delta}$ mutants.These DNA repair defects were not exacerbated by mutations inthese MRN complex genes. Therefore, we conclude that Nip1 functionsin recombinational repair together with the MRN complex. Importantly,meiotic DSBs accumulated in nip1 ${Delta}$ cells (Fig. 6), similar tothe phenotype of rad50S mutants. These phenotypes, togetherwith epistasis analysis and sequence conservation, suggest thatNip1 is a functional counterpart of the S. cerevisiae Sae2/Com1protein and that these proteins are involved in the processingof DSB ends in collaboration with the MRN(X) complex (13, 33,54, 55).

Although Sae2/Com1 and Nip1 are expected to play similar rolesin vivo, there are some important differences between the twoproteins. SAE2/COM1 null mutants are only slightly sensitiveto MMS, while MRX null mutants show severe sensitivity to MMS(42). In contrast, nip1 ${Delta}$ mutants and mutants with deletions ofMRN genes are in the same epistasis group with regard to DNArepair (Fig. 2). In addition, fungal Sae2/Com1 homologues donot have the D-box or CxxC motif. The Nip1 level in cells iscell cycle regulated (39) and may be regulated by proteolysisinvolving the D-box and APC/C-mediated ubiquitination. Expressionof nip1⁺ is induced by DNA damage (Fig. 4) (71). In contrast,the cellular Sae2/Com1 level is largely unaffected by the cellcycle or DNA damage (5).

The C-terminal regions of human CtIP and A. thaliana AtGR1 sharesignificant homology with Nip1. AtGR1 is a gene that was identifiedin a screen for mRNAs that accumulate in response to ionizingradiation and is cell cycle regulated (18). The AtGR1 gene expressionpattern is similar to that of nip1⁺. Very recently, it has beenidentified as a functional and structural homologue of Sae2/Com1(66).

CtIP was originally identified as a cofactor of the transcriptionalcorepressor CtBP (for reviews, see references 11 and 75). DNAdamage-induced interactions in the BRCA1/BARD1-containing supercomplexinclude CtIP and the MRN complex (26), and CtIP is ubiquitinatedin a BRCA-dependent manner in response to DNA damage (38, 79,80). These reports, together with sequence homology, suggestthat CtIP is a functional homologue of Nip1.

The genetic interaction we demonstrated between nip1 and nbs1is allele specific for nbs1-s10 (Fig. 3). The mutation in nbs1-s10alters the evolutionarily conserved glycine in the most C-terminalpart of the FHA domain to an aspartic acid (Fig. 3B). Sincethe FHA domain is a phosphopeptide-binding motif (22) and Nip1is a phosphorylated protein (Fig. 4 and 5), it is likely thatNip1 interacts physically with Nbs1 via its FHA domain. However,we did not detect a direct physical interaction between Nip1and Nbs1 by immunoprecipitation or by yeast two-hybrid analysis(data not shown). Thus, this interaction may be very weak and/ortransient.

Nip1 phosphorylation is puzzling (Fig. 4 and 5). Mutagenesisof the potential CDK phosphorylation target residues abolishedNip1 phosphorylation during normal growth, suggesting that Nip1regulation is cell cycle dependent. In addition, Nip1 is furtherphosphorylated in response to bleomycin, MMS, and HU treatments.Cells carrying rad3 ${Delta}$ , rad26 ${Delta}$ , rad1 ${Delta}$ , rad9 ${Delta}$ , and rad17 ${Delta}$ mutationsexhibited the same level of bleomycin-induced phosphorylationas wild-type cells, but those carrying a tel1 ${Delta}$ mutation exhibitedseverely reduced phosphorylation levels. A rad3 ${Delta}$ tel1 ${Delta}$ doublemutation abolished almost all damage-induced phosphorylationof Nip1 (Fig. 5). A mutant Nip1 protein containing mutationsof all of the canonical phosphorylation sites still migratedmore slowly following bleomycin treatment (Fig. 4). DNA damage-inducedphosphorylation completely depended on the PI3-kinases Rad3and Tel1 (Fig. 5). Therefore, Tel1 and/or Rad3 may phosphorylateresidues other than the consensus sites on Nip1. Alternatively,an unknown downstream kinase activated by Tel1 and/or Rad3 maydirectly phosphorylate Nip1.

In S. cerevisiae, Mec1 is largely responsible for DNA damage-inducedSae2/Com1 phosphorylation in coordination with the checkpointsignaling proteins Ddc1, Rad17, Mec3, and Rad24 (5). However,as shown in Fig. 5, cells carrying rad3 ${Delta}$ , rad26 ${Delta}$ , rad1 ${Delta}$ , rad9 ${Delta}$ ,and rad17 ${Delta}$ mutations exhibited levels of bleomycin-induced phosphorylationsimilar to that of wild-type cells, and cells carrying the tel1 ${Delta}$ mutation exhibited severely decreased phosphorylation. Therefore,unlike S. cerevisiae Sae2/Com1, Nip1 is primarily phosphorylatedby a Tel1-dependent pathway upon bleomycin treatment. The Crb2,Mrc1, Chk1, and Cds1 proteins, downstream factors in the Rad3-and Tel1-dependent checkpoints, are dispensable for Nip1 phosphorylation,suggesting that Nip1 is phosphorylated early in the checkpointpathway.

The rad32 ${Delta}$ and nbs1 ${Delta}$ mutants exhibited reduced levels of Nip1phosphorylation, similar to that of the tel1 ${Delta}$ mutant upon bleomycintreatment. The MRN(X) complex is required for efficient activationof ATM (Tel1) in S. cerevisiae and vertebrates (15, 21, 68).Fission yeast Tel1 is also reported to bind conserved motifsin the C terminus of Nbs1 (76). Therefore, the DNA damage-inducedphosphorylation of Nip1 may proceed in a Tel1-MRN-dependentmanner in the early steps of the DNA damage checkpoint pathway.The fact that DNA damage-induced phosphorylation depends onthe PI3-kinases is consistent with this model.

Human CtIP is also phosphorylated on three serine residues,S327, S664, and S745, in cell cycle-regulated and DNA damage-inducedmanners (38, 79, 80). Phosphorylation on S327 in the putativeCDK phosphorylation motif reaches a maximum in G₂ phase andis important for the CtIP interaction with BRCA1 and for theG₂/M transition checkpoint in response to ${gamma}$ irradiation. S664and S745 are phosphorylated in an ATM-dependent manner in responseto ${gamma}$ irradiation. BRCA1 is also required for CtIP phosphorylationin response to irradiation. There is no distinct orthologueof Brca1 in fission yeast. Nevertheless, the regulation of Nip1phosphorylation is likely conserved in fission yeast, althoughthe function of phosphorylation remains to be elucidated.

In rad32 ${Delta}$ and nbs1 ${Delta}$ mutants, but not in the rhp51 ${Delta}$ mutant, a minoramount of Nip1 is phosphorylated to levels observed in damage-inducedcells in the absence of exogenous DNA damage (Fig. 5A). Thisstate may reflect the accumulation of a specific DNA structurethat induces Nip1 phosphorylation. Nip1 is required to repairRec12 (spSpo11)-induced DSBs in meiosis (Fig. 6). Importantly,the nip1 ${Delta}$ mutant accumulates more abundant broken DNAs than doesthe rad32 ${Delta}$ single mutant. This result suggests that the formationof both Rad32-dependent and Rad32-independent DSBs is processedby Nip1. Taking the results of the epistasis analysis and meioticDSB experiments together, we hypothesize that Nip1 regulatesthe nuclease activity of the Mre11 complex. Alternatively, Nip1per se might be a specific nuclease that works with the MRNcomplex to produce recombinogenic single-stranded DNA. Furtherbiochemical studies are needed to delineate Nip1 activity.

ACKNOWLEDGMENTS

We thank Akira Shinohara and Shunichi Takeda for valuable informationconcerning the homology among Sae2, Nip1, and CtIP; Kanji Furuyafor Nip1 sequence analysis in S. japonicus; and Kouji Hirotafor preliminary experiments of meiotic DSBs. We also thank TetsuroKokubo for helpful discussions and encouragement.

This study was supported in part by Grants-in-Aid for ScientificResearch on Priority Areas from the Ministry of Education, Culture,Sports, Science, and Technology (MECSST) of Japan to K.O. andH.I. and for Scientific Research (B) and for Young Scientists(Startup) from the Japan Society for the Promotion of Science(JSPS) to H.I. and to T.Y., respectively, and by grants fromthe 2007 Strategic Research Project (No. K19011) of YokohamaCity University to H.I. and from the Bio-oriented TechnologyResearch Advancement Institution to K.O.

FOOTNOTES

* Corresponding author. Mailing address: Division of Molecular and Cellular Biology, International Graduate School of Arts and Sciences, Yokohama City University, Suehiro-cho, Tsurumi, Yokohama, Kanagawa 230-0045, Japan. Phone: 81-45-508-7238. Fax: 81-45-508-7269. E-mail: iwasaki{at}tsurumi.yokohama-cu.ac.jp

Published ahead of print on 31 March 2008.

These two authors contributed equally to this work.

Present address: Developmental Biology Program, Memorial Sloan-KetteringCancer Center, New York, NY 10021.

REFERENCES

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