Cdc14 Module Controls Activation of the Yen1 Holliday Junction Resolvase to Promote Genome Stability

Molecular Cell

Article The Cdk/Cdc14 Module Controls Activation of the Yen1 Holliday Junction Resolvase to Promote Genome Stability Christie L. Eissler,1,2 Gerard Mazo´n,3 Brendan L. Powers,1,2 Sergey N. Savinov,2 Lorraine S. Symington,3 and Mark C. Hall1,2,* 1Department

of Biochemistry for Cancer Research Purdue University, West Lafayette, IN 47907, USA 3Department of Microbiology and Immunology, Columbia University Medical Center, New York, NY 10032, USA *Correspondence: [email protected] http://dx.doi.org/10.1016/j.molcel.2014.02.012 2Center

SUMMARY

Faithful genome transmission during cell division requires precise, coordinated action of DNA metabolic enzymes, including proteins responsible for DNA damage detection and repair. Dynamic phosphorylation plays an important role in controlling repair enzymes during the DNA damage response (DDR). Cdc14 phosphatases oppose cyclin-dependent kinase (Cdk) phosphorylation and have been implicated in the DDR in several model systems. Here, we have refined the substrate specificity of budding yeast Cdc14 and, using this insight, identified the Holliday junction resolvase Yen1 as a DNA repair target of Cdc14. Cdc14 activation at anaphase triggers nuclear accumulation and enzymatic activation of Yen1, likely to resolve persistent recombinational repair intermediates. Consistent with this, expression of a phosphomimetic Yen1 mutant increased sister chromatid nondisjunction. In contrast, lack of Cdk phosphorylation resulted in constitutive activity and elevated crossover-associated repair. The precise timing of Yen1 activation, governed by core cell-cycle regulators, helps coordinate DNA repair with chromosome segregation and safeguards against genome destabilization. INTRODUCTION Robust regulatory systems have evolved to maximize faithful transmission of genetic information from one cell generation to the next. Genome instability arising from a variety of sources contributes to human disease. In many cases, such as the repair of DNA damage, genome stability requires rapid and reversible cellular responses to environmental challenges, and therefore cells often make use of dynamic regulatory protein modifications such as phosphorylation. Reversible phosphorylation by opposing kinase and phosphatase activities not only controls the activation of DNA repair pathways but also plays a critical role 80 Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc.

in coordinating repair with cell division. Cyclin-dependent kinases (Cdks) directly regulate most cell-cycle events and also are required for an effective response to various types of DNA damage and maintenance of genome stability (Enserink et al., 2009; Trovesi et al., 2013). Reversal of Cdk phosphorylation events is essential for completion of mitosis and initiation of cytokinesis, and can be achieved by several different phosphatases, including the Cdc14 family (Queralt and Uhlmann, 2008). Cdc14 phosphatases contribute to genome stability in a variety of ways through the dephosphorylation of key Cdk substrates. Work in yeasts has implicated Cdc14 in promoting proper chromosome segregation, mitotic spindle function, DNA replication, and cytokinesis (Mocciaro and Schiebel, 2010). Cdc14 has been implicated in a variety of cell-division functions in metazoans as well, based primarily on knockdown and/or overexpression studies. These include centriole duplication, centrosome separation, cytokinesis, spindle assembly, and mitotic exit (Mocciaro and Schiebel, 2010). However, the specific biological functions of metazoan Cdc14 proteins remain unclear, and few direct substrates have been identified outside of yeast model systems. The lack of knowledge of direct targets hampers our mechanistic understanding of Cdc14 contributions to genome stability. In addition to the biological functions described above, several recent studies have provided evidence linking Cdc14 to the DNA damage response (DDR) and DNA repair. Human Cdc14B is activated by nucleolar release in response to genotoxic stress to promote the G2 DNA damage checkpoint (Bassermann et al., 2008). In fission yeast, release of Clp1 from the nucleolus in response to replication stress contributes to full activation of DNA damage checkpoint signaling (Broadus and Gould, 2012; Dı´az-Cuervo and Bueno, 2008). Interestingly, deletion of the CDC14A or CDC14B genes from chicken or human cultured cells was recently reported to cause defective repair of DNA damage without compromising checkpoint activation (Mocciaro et al., 2010). Likewise, Cdc14B-deficient mice exhibit premature aging, and embryo fibroblasts from these animals have defective DNA damage repair but an apparently normal checkpoint response (Wei et al., 2011). Collectively, these studies clearly indicate that Cdc14 proteins in multiple organisms are activated by DNA damage and contribute in some way to the cellular DDR. Specific targets of Cdc14 involved in DNA repair or DNA damage checkpoints have not been identified.

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

Cdc14 enzymes historically have been thought to possess general specificity for proline-directed Ser/Thr phosphorylation sites (Gray et al., 2003; Kaiser et al., 2002; Visintin et al., 1998), matching the minimal consensus of Cdks and other prolinedirected kinases. We recently found that Cdc14 enzymes from diverse eukaryotes are actually highly specific for a subset of Cdk-type phosphorylation sites containing phosphoserine (pSer) and basic amino acids immediately downstream of pSer-Pro (Bremmer et al., 2012). The unexpected, strict enzymatic specificity of Cdc14 raises the possibility that substrates can be predicted bioinformatically. In this study, we further refined the features of optimal Cdc14 substrates, and using this information identified the Holliday junction resolvase Yen1 as an early anaphase Cdc14 substrate. Yen1 was previously identified as a preferential S phase cyclinCdk target in vitro (Loog and Morgan, 2005), and its enzymatic activity was shown to be inhibited by phosphorylation until anaphase in vivo (Matos et al., 2011). Here we demonstrate that Cdk and Cdc14 are responsible for controlling the enzymatic activation and nucleocytoplasmic localization of Yen1, effectively restricting its DNA repair function during cell division to anaphase. We provide evidence that this regulation contributes to genome stability during the mitotic cell cycle, as proposed previously (Matos et al., 2011). This work provides a link between Cdc14 and DNA repair in budding yeast and reveals a mechanism by which DNA repair events are coordinated with the cell-division machinery to ensure faithful segregation of chromosomes. RESULTS Refinement of Cdc14 Specificity and Prediction of Yen1 as a Substrate Cdc14 enzymes display a strong preference for basic amino acids downstream of pSer-Pro (Bremmer et al., 2012). Phosphopeptides lacking basic residues in the +2 to +6 region relative to pSer-Pro are poor substrates. However, we did not previously explore the preference for Lys and Arg in enough detail to define which specific positions are critical for Cdc14 activity. We reasoned that identification of additional strong consensus site features might allow us to discover Cdc14 substrates using motif prediction algorithms. To define the basic amino acid requirement in more detail, we generated a small phosphopeptide library based on the previously defined Cdc14 substrate site at residue 71 in the securin ortholog Pds1 (Holt et al., 2008). We first tested the contribution of an individual Lys or Arg at positions +2 through +6 to Cdc14 catalytic efficiency. The results are displayed as a heat map in Figure 1A (see Table S1 for rates, available online). Consistent with our previous results, Cdc14 was unreactive toward the phosphopeptide lacking basic amino acids in this region. Only a basic amino acid at +3 provided activity close to the wild-type substrate. Moreover, Lys provided approximately 4-fold higher activity than Arg. We also tested combinations of basic amino acids to determine which patterns provided the best catalytic efficiency. Of the multibasic peptides, only those with Lys at +3 produced significant activity (Figure 1B; Table S1). For several of these,

activity was substantially higher than with a single Lys at +3. Enhanced activity in the multibasic peptides correlated best with a basic residue at +4, although this effect was not universal. We conclude that a +3 Lys (Arg to a lesser extent) represents an additional critical feature of Cdc14 substrates, and that optimal activity is achieved with additional basic residues in the immediate vicinity of +3. A stretch of conserved acidic residues lines the peptide binding groove in the human Cdc14B (hCdc14B) crystal structure and was proposed to contribute to recognition of phosphosubstrates containing downstream basic sequences (Gray et al., 2003). This extended acidic patch is insufficient, though, to explain the strong preference for Lys/Arg specifically at +3. To understand the strong +3 effect, we performed docking and molecular dynamics (MD) simulations with the optimal substrate sequence A(pSer)PSKRR and either the hCdc14B structure or a homology model of the budding yeast Cdc14 (ScCdc14) catalytic domain. The ScCdc14 model revealed extensive amino acid conservation for the substrate binding channel (Figure S1C) and resulted in similar positions and contacts for the
1 Ala, pSer, and +1 Pro compared to the empirical structure. Interestingly, the MD simulations with both ScCdc14 (Figure 1C) and hCdc14B (Figure S1B) suggested that the +3 Lys does not contact the acidic groove. Instead, the Lys side chain sits in a conserved pocket adjacent to the +1 Pro cage where it engages in cation-p contacts, stabilized by a hydrogen-bond network (Figures 1C and 1D). In ScCdc14, the invariant Phe47 and Tyr44 both contribute strongly to this interaction. Cation-p interactions at solvent-exposed protein surfaces generally contribute much greater binding energy than ionic contacts (Gallivan and Dougherty, 2000), providing rationale for the +3 requirement. Although both Lys and Arg engage in cation-p interactions, only the longer aliphatic side chain of Lys allowed for a favorable orientation with Tyr44/ Phe47. The shorter Arg side chain prevented the preferred guanidinium-p stacking arrangement (Nandi et al., 1993), explaining the Lys preference. The +4 and +5 Arg both interact with acidic residues in the binding groove through most of the MD simulation. The models are consistent with our biochemical data defining the critical contribution of a +3 basic amino acid and the auxiliary contributions of surrounding basic residues to substrate selectivity. Using pSer, +1 Pro, and +3 Lys or Lys/Arg as fixed consensus features and additional Lys/Arg residues as variable consensus features (Figure 1E), we scanned the yeast proteome for proteins enriched in candidate Cdc14 target sites (Tables S2 and S3). These searches produced just over 60 hits, of which 13 were previously reported Cdc14 substrates. To identify substrates, we first focused on proteins with clusters of optimal Cdc14 sites because regulatory Cdk phosphorylation commonly occurs in clusters on disordered loops (Holt et al., 2009; Moses et al., 2007). Yen1 caught our eye because it contains more optimal Cdc14 sites than any other yeast protein (Table S3). The optimal consensus sites are clustered within a 180 amino acid stretch near the C terminus (Figure 1F), and are well conserved across the order Saccharomycetales. Yen1 is likely a direct Cdk substrate (Loog and Morgan, 2005), and contains a predicted Cdk-regulated nuclear localization signal (NLS) (Kosugi et al., Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc. 81

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

A

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Figure 1. Refinement of Cdc14 Enzymatic Specificity (A and B) The peptide sequence from Pds1 was synthesized with a central phosphoserine (pS), and variants contained different combinations of basic amino acids in the +2 to +6 region (boxed). Heat map cells show positions and identity of basic residues, Lys (K) or Arg (R), in each peptide. Shading indicates relative activity (white, low; black, high) in Cdc14 assays conducted under steady-state conditions that approximate kcat/Km. (C) Representative frame from MD simulation of the ScCdc14 homology model (surface representation) with bound optimal peptide substrate Ac-A(pSer)PSKRRNHMe (ball and stick representation). Residues that contact the substrate KRR are colored (red, acidic; green, hydrophobic; cyan, polar neutral) and labeled in (legend continued on next page)

82 Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc.

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

2009). We therefore proceeded to test whether it is a regulatory target of the opposing Cdk and Cdc14 activities. Yen1 Is Phosphorylated In Vivo by Cdk We first tested whether Yen1 is an in vivo substrate of the cellcycle Cdk, Cdc28. Phosphorylated Yen1 species can be effectively separated from unphosphorylated Yen1 using Phos-tag SDS-PAGE and immunoblotting (Matos et al., 2011). We compared the migration of Yen1-TAP (tandem affinity purification) extracted from cells arrested in G1 and S phase. Mobility was strongly retarded when cells were arrested in S phase, a time when Cdc28 activity is high, compared to G1, when Cdc28 is inactive (Figure 2A). Mutation of the nine Ser-Pro sequences in Yen1 to Ala-Pro (Yen19A) completely abolished the slow-mobility species in S phase cells, demonstrating that Yen1 phosphorylation is dependent on Cdk consensus sites. To test whether phosphorylation is dependent on Cdc28 activity, we used a cdc28-as1 strain in which a Cdc28 active site mutation renders the kinase uniquely sensitive to inhibition by the ATP analog 1-NM-PP1 (Bishop et al., 2000). Cdc28 inhibition resulted in rapid loss of slow-mobility phosphorylated Yen1-TAP but did not affect migration of Yen19A-TAP (Figure 2B). To directly detect phosphorylation, we purified Yen13FLAG from cdc14-1 cultures arrested in late mitosis with high Cdk activity and analyzed it by mass spectrometry (MS). Four peptides containing Ser-Pro sequences, representing each cluster depicted in Figure 1F, were convincingly identified. All were detected predominantly in phosphorylated form (Figure 2C; Figure S2). We conclude that Yen1 is heavily phosphorylated in vivo by Cdc28 at multiple Ser-Pro sites throughout the primary sequence. Yen1 Is an Early Anaphase Cdc14 Substrate To determine whether Yen1 is a Cdc14 substrate, we first synthesized phosphopeptides containing each minimal Cdk consensus site and surrounding sequence and measured the rate of Cdc14-catalyzed dephosphorylation under steadystate conditions. kcat/Km for pSer-Pro sites can vary by as much as three orders of magnitude (Bremmer et al., 2012). For comparison, we analyzed phosphopeptides representing known in vivo Cdc14 substrate sites that exhibit high activity and phosphopeptides from a Cdk site cluster on Cdc16 that are poor substrates. The Yen1 phosphopeptides exhibited a range of activities reflecting our current understanding of Cdc14 specificity (Figure 2D). The four best peptides displayed dephosphorylation rates comparable to our ‘‘gold standards,’’ and all contain the optimal SPxK sequence. Three of these also have at least one additional basic amino acid at +4. The remaining peptides contained either a +3 Arg or

no basic amino acid at +3, and two were very weak substrates. We also evaluated the ability of Cdc14 to dephosphorylate intact affinity-purified Yen1 at several phosphorylation sites that gave high-quality MS signals (Figure 2E). Consistent with our peptide work, dephosphorylation of the cluster 1 S71 and S245 sites was only slightly better than a non-Cdk site. In contrast, activity toward the optimal sequence at S500 was high. To determine whether Cdc14 can recognize Yen1 as a substrate in vivo, we performed coimmunoprecipitation (coIP) experiments with a Cdc14 substrate trap variant, Cdc14C283S, that is catalytically inactive but retains high-affinity substrate binding (Hall et al., 2008). Wild-type Yen1 copurified with 3HA-Cdc14-C283S (Figure 2F). In contrast, Yen19A and another mutant, Yen19T, containing Thr substitutions at all nine Ser-Pro sites, were not detected in 3HA-Cdc14-C283S immunoprecipitates despite being expressed at similar levels. Thus, Cdc14 physically associates with Yen1 in vivo, dependent on Yen1 Cdk phosphorylation sites. We next ectopically overexpressed Cdc14 in S phase cells and monitored the phosphorylation status of Yen1-TAP by immunoblotting of whole-cell extracts. After Cdc14 expression, Yen1-TAP mobility increased substantially, demonstrating that Cdc14 promotes the dephosphorylation of Yen1 (Figure 2G). We monitored the stability of the mitotic cyclin Clb2 to ensure that under these experimental conditions the overexpressed Cdc14 had not induced mitotic exit via cyclin proteolysis. To test whether Yen1 dephosphorylation in mitosis is dependent on Cdc14 function, we synchronized W303, cdc14-1, or cdc15-2 strains expressing YEN1-TAP in G1 with a factor at 23 C and released them from arrest at 37 C. The phosphorylation status of Yen1-TAP was monitored by immunoblotting (Figure 2H). In W303, Yen1-TAP became phosphorylated roughly 45 min after release and was dephosphorylated as cells entered anaphase and segregated their chromosomes, consistent with previous results (Matos et al., 2011). cdc14-1 and cdc15-2 strains both arrest in late anaphase at 37 C with segregated DNA, the only difference being that cdc15-2 cells transiently release active Cdc14 from nucleolar sequestration in early anaphase via the Cdc fourteen early anaphase release (FEAR) network (Stegmeier et al., 2002), whereas cdc14-1 cells completely lack Cdc14 function. Yen1-TAP was phosphorylated with similar kinetics in both. In contrast, dephosphorylation was absent in cdc14-1 but occurred similar to W303 in cdc15-2. Thus, Cdc14 function is essential for Yen1 dephosphorylation during mitosis. The lack of dependence on Cdc15 argues strongly that Yen1 is a target of FEAR-activated Cdc14 at anaphase onset.

white. Key residues of the substrate are labeled in black. The inset highlights the local arrangement of +3 Lys engaged in cation-p contacts with Tyr44 and Phe47, stabilized by hydrogen bonding (dashed lines). See also Figure S1. (D) Two-dimensional representation of stable (R40% of simulation time) contacts (direct or water bridged) between peptide (black) and ScCdc14 residues obtained from an MD experiment. Percentages represent the fraction of time that the contact was maintained. Purple arrows, hydrogen bonds; red lines, cation-p interactions. Residue colors are as in (C), with basic residues in blue. (E) Summary of Cdc14 substrate features used for substrate prediction. Essential requirements are in large red font. See additional information in Tables S1–S3. (F) Diagram of relevant Yen1 protein features. All nine Ser-Pro Cdk site positions with downstream basic residues are shown and divided into the three clusters used for the purpose of mutagenesis throughout the paper. N, I, and H3 (helix-hairpin-helix) are conserved domains of the XPG nuclease family.

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Molecular Cell Regulation of Yen1 by Cdk and Cdc14

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Figure 2. Yen1 Is an In Vivo Substrate of Cdk and Cdc14 (A) Anti-protein A immunoblots from Phos-tag SDS-PAGE. Extracts from cells arrested in G1 or S and expressing Yen1-TAP or Yen19A-TAP from an integrated PYEN1 construct were compared. (B) Same as (A), except asynchronous cdc28-as1 cells were treated with 20 mM 1-NM-PP1 or an equal volume of DMSO for 30 min. Immunoblots using standard and Phos-tag gels are shown to emphasize the phosphorylation dependence of the mobility shift. (C) Ion chromatograms for Yen1 tryptic peptides containing the indicated Cdk phosphorylation sites in both unmodified (
) and phosphorylated (+) forms detected by liquid chromatography (LC)-MS. The identity of the peak in each case was verified by product ion spectra (Figure S2). Unmodified S71 peptide was undetectable. (D) Activity of Cdc14 toward the indicated phosphopeptide substrates was measured under identical steady-state conditions. Data are the average of three trials, and error bars are standard deviations. Peptide sequences are shown in Table S4. (legend continued on next page)

84 Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc.

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

Cdk Sites Regulate Yen1 Biological Function To determine whether regulation of Yen1 at Cdk phosphorylation sites is functionally important, we performed complementation experiments with Yen1 phosphosite mutants. We split the Yen1 Cdk sites into three clusters as depicted in Figures 1F and 2D. For example, Yen1c2A refers to mutation of the four Ser-Pro sites in cluster 2 to Ala-Pro to prevent Cdk phosphorylation, whereas Yen1c2D contains Asp-Pro substitutions at the same sites to mimic constitutive Cdk phosphorylation. Clusters c2 and c3 were of the most interest, because they contained all of the optimal Cdc14 substrate sites and contained the sites that exhibited highest activity in our peptide assays. Although we also evaluated c1 mutations, no strong effects on Yen1 regulation were observed and therefore we focused on the results from c2 and c3. All YEN1 variants were integrated as TAP fusions into mus81D yen1D strains under control of the YEN1 promoter. The Mus81-Mms4 endonuclease performs an overlapping function with Yen1 in homologous recombination (HR)-based DNA repair, and strong phenotypes of yen1D require a mus81D background. mus81D yen1D strains were reported to exhibit a significant slow-growth phenotype (Agmon et al., 2011; Blanco et al., 2010; Ho et al., 2010). Consistent with this, yen1D growth was indistinguishable from the parental W303 strain, whereas mus81D yen1D took nearly twice as long to double (Figure 3A). Wild-type YEN1, yen1c2A, yen1c3A, and yen1c3D all complemented the yen1D growth defect in the mus81D background. In contrast, yen1c2D almost completely failed to complement. Yen1 functions in the repair of double-strand DNA breaks (DSBs) by HR, and strong sensitivity to chemicals that promote DSB formation is observed in mus81D yen1D strains (Agmon et al., 2011; Blanco et al., 2010; Ho et al., 2010). We therefore examined the ability of the YEN1 alleles to complement the acute sensitivity of mus81D yen1D to methyl methanesulfonate (MMS) and hydroxyurea (HU). Similar to the growth experiments, YEN1, yen1c2A, yen1c3A, and yen1c3D all provided full Yen1 function and eliminated the chemical sensitivity (Figures 3B and 3C). yen1c2D failed to complement, demonstrating that it is nonfunctional. In both assays, yen1c1D failed to complement and yen1c1A only partially complemented (Figure S3). Together, the growth and DNA damage sensitivity results are consistent with Cdk phosphorylation within cluster 2 inhibiting the function of Yen1 in repair of DNA damage and Cdc14-mediated dephosphorylation of these sites being required to activate Yen1 function. Cluster 1 sites also affect Yen1 function. However, the dependence on phosphorylation status is unclear because yen1c1A was only partly functional.

Cdc14 Is Essential for Yen1 Nuclear Accumulation The apparently normal function of Yen1c3D was somewhat surprising, given the prior evidence that Cdk phosphorylation of S679 prevented Yen1 nuclear localization (Kosugi et al., 2009). To directly test whether Cdc14 is required for nuclear accumulation of Yen1, we examined cdc14-1 cells expressing a Yen1-GFP fusion from the constitutive GPD promoter by fluorescence microscopy (we could not detect Yen1-GFP expressed from its natural promoter). As expected, Yen1-GFP was evenly distributed throughout the cytoplasm of premitotic cells in an asynchronous culture grown at permissive temperature, but exhibited strong nuclear signal in large-budded late mitotic cells that had segregated their DNA (Figure 4A). In some cases, we observed Yen1-GFP accumulation in the nucleus of cells that appeared to be undergoing anaphase and had not fully separated their two chromosome sets (Figure 4B). At 37 C, cdc14-1 cells arrest in late mitosis with segregated DNA; however, Yen1-GFP failed to accumulate in the nucleus under these conditions (Figure 4A). The requirement for Cdc14 function to accumulate Yen1 in the nucleus was completely bypassed by expressing Yen1c3A-GFP. Neither Yen1c1A (Figure S4A) nor Yen1c2A (Figure 4C) bypassed this Cdc14 requirement, and cell-cycle-dependent nuclear localization was not altered by the c1D or c2D mutations (Figure S4B). Thus, the cluster 3 Cdk sites near the putative NLS uniquely control the nucleocytoplasmic distribution of Yen1. Oddly, Yen1c3D-GFP behaved similar to Yen1c3A-GFP (Figure S4B). Instead of being constitutively cytoplasmic, as would be expected if the Ser-to-Asp mutations mimicked the effect of phosphorylation, Yen1c3D-GFP signal was detected in the nucleus at all cell-cycle stages. The Asp mutations clearly do not effectively mimic the inhibitory effect of Cdk phosphorylation on nuclear localization, likely explaining why Yen1c3D appeared fully functional in the complementation assays. Nonetheless, our results clearly show that Cdc14-mediated dephosphorylation of one or both cluster 3 Cdk sites is essential for nuclear accumulation of Yen1 at anaphase onset. The West laboratory found that mutation of S679 to Ala alone causes less nuclear accumulation than mutation of all Cdk consensus sequences (see also Blanco et al., 2014, in this issue of Molecular Cell), consistent with S655 influencing localization as well. Both S655 and S679 lie immediately upstream of consensus classical NLS sequences (KRIR and KKSR, respectively), which could conceivably function as a bipartite NLS. Cdc14 and Cdk1 Directly Regulate Yen1 Enzymatic Activity Because Yen1 resolvase activity is influenced by phosphorylation (Matos et al., 2011), we used an in vitro Holliday junction

(E) Yen1-3FLAG purified from yeast was treated with 250 nM recombinant Cdc14 for 10 min and analyzed by LC-MS. Ion signals for peptides phosphorylated at the indicated residues were integrated, and percent phosphorylation remaining relative to untreated Yen1-3FLAG was calculated using unmodified peptides for normalization. (F) CoIP of the substrate trap 3HA-Cdc14-C283S expressed from PGAL1 and Yen1-TAP, Yen19A-TAP, or Yen19T-TAP expressed from PYEN1 in S phase cells. 3HACdc14-C283S was isolated on anti-HA affinity resin and copurification of Yen1 variants was monitored by immunoblotting. G6PD is a loading control. (G) 3HA-Cdc14 was ectopically overexpressed from PGAL1 for either 1.5 or 3 hr in S phase cells expressing Yen1-TAP or Yen19A-TAP from PYEN1. (H) W303, cdc14-1, and cdc15-2 strains, each expressing Yen1-TAP from PYEN1, were arrested at 23 C in G1 and then released into fresh medium at 37 C. Cells were harvested at the indicated times for analysis by Phos-tag immunoblotting and nuclear staining. The graph shows similar cell-cycle kinetics based on the percentage of anaphase cells (large budded with two DNA masses).

Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc. 85

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

Figure 3. Phosphomimetic Cdk Mutations Block Yen1 Function

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0.0025% MMS

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1 .43 .45 .38 .44 .66 .92

(HJ) resolution assay to explore the effects of purified Cdc14 and Cdk1. We isolated Yen1-3FLAG from cdc14-1 cells arrested at 37 C to obtain phosphorylated, inactive protein. We first confirmed that treatment of isolated Yen1 with recombinant Cdc14 caused dephosphorylation and that subsequent treatment with purified Cdk1 (Clb2-Cdc28) restored phosphorylation, based on gel mobility (Figure S5C). Pretreatment of Yen1-3FLAG with Cdc14 strongly enhanced cleavage of the fluorescent HJ substrate into nicked duplex products (Figure 5A). This effect was suppressed by sodium tungstate, a potent inhibitor of Cdc14. We next isolated Yen1-3FLAG from cycling cells without using phosphatase inhibitors and found that it was highly active (Figure 5B). Pretreatment with Cdk1 completely inhibited HJ resolution, and additional treatment of the Cdk-inhibited Yen1 with Cdc14 restored activity. These results demonstrate that Cdc14 and Cdk directly activate and inhibit Yen1 resolvase activity, respectively. We next tested whether the cluster 2 or 3 mutations affected Yen1 enzymatic activity and response to Cdc14. First, we compared Yen1, Yen1c2D, and Yen1c3D purified from asynchro86 Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc.

nous cultures without phosphatase inhibitors (Figure 5C). Yen1 and Yen1c3D displayed statistically indistinguishable activity, but Yen1c2D activity was significantly lower, suggesting that phosphorylation of the cluster 2 Cdk sites might inhibit Yen1. Consistent with this, Yen1c2D was much less responsive to Cdc14-induced activation compared to Yen1 and Yen1c3D when isolated from the inactivating conditions of cdc14-1 cells (Figure 5D). Finally, we examined the Ala mutants isolated from cdc14-1 cells at restrictive temperature. Whereas Yen1c3A behaved similar to wild-type Yen1, exhibiting low basal activity and strong stimulation upon Cdc14 treatment, Yen1c2A was highly active in the absence of Cdc14 treatment and only slightly more active after Cdc14 treatment (Figure 5E). These results suggest that Cdk and Cdc14 primarily control Yen1 enzymatic activity by regulating the phosphorylation status of one or more sites within cluster 2, and that the cluster 3 sites that regulate nuclear localization do not influence activity. Cluster 1 mutations had a very minor effect on activity compared to cluster 2 (data not shown). Activation of Yen1 by Cdc14 Influences Chromosome Segregation during Mitosis Matos et al. proposed that activation of Yen1 during mitosis might be important to resolve persistent recombination intermediates that had escaped noncrossover (NCO) HR repair pathways and thereby ensure all sister chromatids can be segregated during anaphase (Matos et al., 2011). In support of this idea, mus81D yen1D cells exhibit a significantly elevated rate of sister chromatid nondisjunction that is largely dependent on HR (Ho et al., 2010). We tested whether expression of the nonfunctional Yen1c2D mutant that mimics constitutive cluster 2 Cdk phosphorylation would also cause elevated sister chromatid nondisjunction using this same assay (Figure 6A). The

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

A

DIC

GFP

DAPI 23O C pre-mitosis

23O C late anaphase

YEN1-GFP

37O C late anaphase yen1c3A-GFP

B

DIC

GFP

DAPI

23O C early anaphase

YEN1-GFP

C yen1c2A-GFP

DIC

GFP

DAPI 37O C late anaphase

Figure 4. Cdc14 Is Required for Nuclear Accumulation of Yen1 in Anaphase (A) cdc14-1 cells containing a CEN plasmid expressing Yen1-GFP or Yen1c3A-GFP from PGPD were grown in selective medium at 23 C. Where indicated, growth temperature was shifted to 37 C for 4 hr. Cells were briefly fixed and stained with 40 ,6-diamidino-2-phenylindole (DAPI) prior to microscopic imaging. At 37 C, less than 5% of cells expressing Yen1-GFP exhibited detectable nuclear fluorescence above the cytoplasmic signal. Greater than 90% of cells expressing Yen1c3A-GFP exhibited strong accumulation of nuclear fluorescence (n > 100). (B) Select images from cultures used in (A) showing cells in early anaphase with nuclear accumulation of Yen1-GFP signal. (C) Similar to (A), cdc14-1 cells expressing Yen1c2A-GFP were arrested at 37 C and imaged. Less than 10% of cells exhibited detectable nuclear signal (n > 65). See also Figure S4.

rate of sister chromatid nondisjunction in yen1c2D-TAP cells was indistinguishable from yen1D and significantly higher than in YEN1-TAP and yen1c2A-TAP cells (Figure 6B). This result

reveals that activation of Yen1 by Cdc14 contributes to genome stability by ensuring complete segregation of sister chromatids during mitosis. mus81D yen1D cells exhibit a defect in bulk DNA segregation and an associated G2/M cell-cycle delay when grown in low concentrations of MMS (Blanco et al., 2010). If Cdc14 is critical for Yen1 activation, then a similar effect should be observed in mus81D cdc14-1 cells at the restrictive temperature. To test this, we released G1-arrested cells at 37 C in the presence of 0.001% MMS and monitored DNA segregation cytologically by 40 ,6-diamidino-2-phenylindole (DAPI) staining (Figures 6C and 6D). We used the cdc15-2 background for comparison due to its similar late mitotic arrest at 37 C. All strains released and reached G2/M as large-budded cells with similar kinetics, although slower than at lower temperatures (data not shown). At 4 and 5 hr postrelease, the cdc14-1, cdc15-2, and cdc15-2 mus81D strains exhibited statistically indistinguishable fractions of cells with clearly segregated DNA masses. In contrast, a much smaller fraction of cdc14-1 mus81D cells had fully segregated DNA masses (Figure 6D). This difference was highly significant, and was eliminated by expression of a Yen1c2A_c3A mutant containing Ala substitutions at all six C-terminal Ser-Pro sequences that should be constitutively active and nuclear based on the experiments described above. We interpret this phenomenon as failure to properly resolve MMS-induced damage repair intermediates, leading to a persistent DNA damage checkpoint, a physical barrier to segregation, or a combination of both. This provides additional evidence that Cdc14 function is required for Yen1 activation and proper chromosome segregation. Constitutively Active Yen1 Increases the Crossover Frequency during Mitotic DSB Repair We predicted that the combined Yen1c2A_c3A mutant might result in constitutive Yen1 function that could influence the crossover (CO) outcome of DSB repair by HR. To address the roles of the Yen1 Cdk site mutants in DSB-induced recombination, we used a well-characterized system to monitor CO formation between dispersed chromosomal repeats (Agmon et al., 2011; Mazo´n et al., 2012). A haploid strain expressing a galactoseinducible HO endonuclease was used to monitor repair by recombination between a DSB generated at the HO endonuclease cut site (HOcs) inserted within the URA3 locus on chromosome (Ch) V and a 5.6 kb URA3 donor sequence containing the HO-resistant HOcs-inc sequence inserted at the LYS2 locus on Ch II (Figure 7A). After galactose induction, a DSB is continuously generated at the Ch V locus until repair by gene conversion transfers HOcs-inc from the donor to the recipient locus. CO products can be monitored and quantified physically by using asymmetrically located restriction sites flanking both the URA3 regions on Ch V and Ch II. As described previously, the Yen1 effect on CO formation can only be seen in a mus81D background (Mazo´n et al., 2012). We therefore evaluated CO levels and plating efficiency (competence to repair the DSB) in mus81D yen1D complemented by YEN1-TAP or mutant derivatives (Figures 7B and 7C). Expression of yen1c2D only partially complemented the decreased CO level, whereas yen1c2D_c3D completely failed to complement the mus81D yen1D CO defect (6.8% and 4.3% CO, Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc. 87

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

Cdc14: Tungstate:

+

-

+ +

-

+ + +

- + + - - +

Cdk1: Cdc14:

D Cdc14:

- + - + - +

20 10 0

*

*

*

* 20 16 12 8 4 0

Yen1WT Yen1c2A Yen1c3A Cdc14:

Neg

α-FLAG

- + - + - +

Neg

α-FLAG

16

Adj. Res. (%)

Adj. Res. (%)

30

E

Yen1WT Yen1c2D Yen1c3D

α-FLAG

Adj. Res. (%)

* Resolution (%)

Resolution (%)

*

30 25 20 15 10 5 0

D

C

c2

B

-

Ye n1 Ye WT n Ye 1 c3D n1

A Yen1-3FLAG:

12 8 4 0

Yen1WT

Yen1c2D Yen1c3D

5 4 3 2 1 0

Yen1WT Yen1c2A Yen1c3A

Figure 5. Cdc14 and Cdk1 Directly Control Yen1 Endonuclease Activity In all panels, Yen1-3FLAG resin was added to reactions containing the fluorescent synthetic HJ substrate (see Figure S5). Yield differences in independent Yen1 preparations likely account for apparent fluctuations in activity between panels; however, all activities of Yen1 variants within the panels are appropriately normalized to recovered protein levels. Products were resolved by native PAGE and quantified by fluorescence imaging. (A) Yen1-3FLAG was isolated from cdc14-1 cells arrested at 37 C. Equal fractions of Yen1-bound resin were either untreated or treated with recombinant Cdc14 (±sodium tungstate) prior to HJ resolution assays. (B) Yen1-3FLAG isolated under permissive conditions without phosphatase inhibitors was treated with purified Cdk1. Half of the Cdk1-treated resin was washed and additionally treated with recombinant Cdc14. (C) The indicated proteins were prepared as in (B). Anti-FLAG immunoblots of reaction mixtures were used to normalize product levels and account for differences in protein recovery (shown as adjusted resolution % in the bottom graph). The graph shows averages of three trials with standard deviations. (D) Yen1-3FLAG and Asp variants were isolated as in (A). Prior to reactions, Yen1-bound resins were divided and one half was treated with recombinant Cdc14. Signals were normalized as in (C). Results for Yen1c1D were cropped (black line). (E) Same as (D), comparing Yen1-3FLAG and Ala variants.

respectively). These results are mostly consistent with the lack of function of the Asp mutants in the DNA damage sensitivity assays. In contrast, expression of both yen1c2A and yen1c2A_c3A not only fully complemented the CO defect but resulted in a modest, but statistically significant, elevation in CO levels compared to the strain complemented with YEN1 (10.3% and 10.7% CO, respectively, compared to 7.7% CO; p = 0.044 and p = 0.028, respectively). 88 Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc.

DISCUSSION A Function for Cdc14 in DNA Repair A daunting challenge in the functional characterization of kinases and phosphatases is the identification of bona fide physiological substrates. For Ser/Thr phosphatases, this problem is exacerbated by the structural complexity of phosphatase families and lack of strong active site specificity. Cdc14

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

A

B

C

D

Figure 6. Activation of Yen1 by Cdc14 Helps Prevent Chromosome Segregation Defects (A) Schematic of the sister chromatid cosegregation assay (Ho et al., 2010). Spontaneous recombination between the direct repeats of ade2 alleles in the ade250 ::URA3::ade2-30 construct on one sister generates a chromatid pair with URA3 and ADE2 markers that are monitored for cosegregration on medium lacking uracil and adenine. (B) Cosegregation of sister chromatids in strain LSY2307-2C harboring integrated YEN1-TAP, yen1c2A-TAP, and yen1c2D driven by PYEN1 was monitored using the assay from (A). The method of the median was used to calculate cosegregation rates, and data are the average of three independent experiments. Error bars are standard deviations. The asterisk and p value indicate a statistically significant difference compared to the YEN1-TAP-complementing strain determined using a Student’s t test. (C) Representative fields of view of the indicated strains collected by either DIC or fluorescence microscopy 4 hr after release from G1 arrest at 37 C in the presence of 0.001% MMS. White arrows show examples of fully segregated DNA. (D) Quantification of images from experiments in (C) at 4 and 5 hr after release. A minimum of 120 cells was counted for each strain at each time point. Asterisks indicate a significant difference compared to both cdc14-1 and cdc14-1 mus81D + yen1c2A_c3A in a c2 test (p < 0.0001).

enzymes, members of the protein tyrosine phosphatase family despite their pSer specificity, do not share this problem. Cdc14 phosphatases function independent of accessory or regulatory subunits. Importantly, as shown here and previously (Bremmer et al., 2012; Gray et al., 2003), the Cdc14 active site region imposes strict substrate selection requirements on the enzyme. This includes Ser as the phospho-amino acid, a +1 Pro, and a +3 Lys (or to a lesser extent Arg). Absence of any one of these features renders a substrate nearly unreactive in vitro using phosphopeptides. We used this strict enzymatic specificity to predict optimal Cdc14 substrates in silico and identified a role for Cdc14 in activating the DNA repair

enzyme Yen1 that contributes to genome stability. Such an approach may be a useful companion tool to substrate trap methodologies to facilitate direct substrate identification, or even as a stand-alone approach to identification of substrates in metazoan systems where very little is known about Cdc14 functions. Cdc14 has been implicated in both DNA damage checkpoint signaling and repair in several model systems (Bassermann et al., 2008; Dı´az-Cuervo and Bueno, 2008; Mocciaro et al., 2010; Wei et al., 2011). Consistent with this, several Cdc14 orthologs are activated by nucleolar release upon genotoxic stress (Bassermann et al., 2008; Broadus and Gould, Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc. 89

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

A Ch. II

B

P

B

A

mus81∆ yen1∆ background

ura3-HOinc

YEN1

A

P

Ch. V

0

ura3-HO

2 24

yen1 c2D

yen1 c2A

0

0

2 24

2 24

yen1 c2D_c3D yen1 c2A_c3A 0

2 24

0

2 24

h post HO

- Ch. II B

P NCO

P

CO

12.3kb

ura3-HOinc B

A

- Ch. V + NCO 7 kb A

ura3-HOinc

or B

P CO

P

- DSB 8.6 kb A

ura3-HOinc B

10.7 kb A

ura3-HOinc

CO 24h (%)

C

*

mus81∆ yen1∆

yen1 c2A_c3A -TAP

10.7 ± 1.2

CO NCO

yen1c2D_c3D -TAP

*

yen1 c2A -TAP

4.3 ± 0.6 10.3 ± 1.0

yen1 c2D -TAP

6.8 ± 1.7

YEN1-TAP

7.7 ± 0.8

mus81∆ yen1∆

4.3 ± 0.9

mus81∆

7.1 ± 1.3

Wild-type

8.3 ± 0.5

0

20

40

60

80

Distribution of recombinants (%) Figure 7. Misregulation of Cdk Sites on Yen1 Influences CO Formation (A) Schematic of the ectopic recombination assay used to monitor CO formation between ura3 repeats (Mazo´n et al., 2012). P and A mark the PvuII and ApaLI restriction sites used to monitor CO formation by Southern blot, respectively, and the solid triangle indicates the HO cut site. (B) CO products are detected as ApaLI/PvuII restriction fragments of 10.7 and 8.6 kb in Southern blot analysis of DNA extracted from cells after HO endonuclease induction. The chromosome V band represents entirely NCO products by 24 hr. Only the larger of the two DSB fragments is present under the gel conditions used. (C) Quantitation of CO and NCO products from gels in (B) normalized to the plating efficiency of the indicated strains. Values for the raw estimate of % COs at 24 hr are shown and are averages of at least three independent trials. Error bars and values are standard deviations. The asterisks indicate p < 0.05 from a Student’s t test comparing COs to that from the YEN1-TAP strain.

2012; Dı´az-Cuervo and Bueno, 2008; Mocciaro et al., 2010). However, little evidence exists directly linking Cdc14 to specific DNA repair functions. Aside from a report that Cdc14 activates the anaphase-promoting complex to facilitate DNA damage checkpoint arrest in human cells (Bassermann et al., 2008), the direct targets of Cdc14 in the DDR and DNA repair are not known. Yen1 therefore represents an important connection between Cdc14 function and DNA repair in budding yeast. The evidence for Cdc14 involvement in the repair of DNA damage in budding yeast, fission yeast, and metazoans suggests that it may be a conserved function for this phosphatase family. 90 Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc.

Cdc14 Enzymatic Specificity and the DDR Cdk phosphorylation is required for an effective DDR, but also must be suppressed to prevent cell-cycle progression until damage is repaired (Trovesi et al., 2013). Although Cdk is a positive regulator of CO pathways of HR in budding yeast (Trovesi et al., 2011), our work suggests it suppresses the CO-promoting activity of Yen1. How the pro- and anti-HR effects of Cdk (and likely other kinases) are coordinated to yield an appropriate DDR is unclear. Phosphatase specificity may be one contributing factor. The strict specificity of Cdc14 for a distinct class of Cdk substrates could act to selectively reverse phosphorylation on optimal substrates at times when overall Cdk activity is high.

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

This would be an effective strategy to selectively activate repair proteins that are otherwise kept dormant in the absence of DNA damage. It also may underlie Cdc14 substrate selection in late mitosis as cells execute the ordered dephosphorylation of Cdk substrates to coordinate chromosome segregation, mitotic exit, and cytokinesis (Bouchoux and Uhlmann, 2011). Yen1 Is a Regulatory Target of the FEAR Network Yen1 appears to be a target of the transient nuclear pool of Cdc14 activated by the FEAR network in anaphase, as it was independent of the other major Cdc14 activation pathway, the mitotic exit network (Figure 2H). The timing of Yen1 activation is consistent with it being a FEAR target, because FEAR signaling originates at the metaphase-anaphase transition when separase is activated via proteolysis of its inhibitor, securin, to promote nucleolar release of Cdc14 (Azzam et al., 2004; Stegmeier et al., 2002; Sullivan and Uhlmann, 2003). FEAR-released Cdc14 selectively dephosphorylates a handful of Cdk substrates to ensure proper spindle function and chromosome segregation during anaphase (Stegmeier and Amon, 2004). Because cells expressing the Yen1c2D phosphomimetic mutant exhibited a sister chromatid segregation defect similar to yen1D strains (Figure 6B), dephosphorylation of Yen1 by Cdc14 represents another mechanism by which the FEAR pathway promotes faithful chromosome segregation and safeguards genome integrity. Strict Regulation of Yen1 Function Contributes to Genome Stability Yen1 was identified as an HJ resolvase several years ago, along with its human ortholog GEN1, based on detection of its enzymatic activity (Ip et al., 2008). Since then, several studies have shown that the HJ cleavage activity of Yen1 functions in HRbased repair of DSBs during mitosis (Agmon et al., 2011; Blanco et al., 2010; Ho et al., 2010; Tay and Wu, 2010). Cells lacking YEN1 seem to be mostly proficient for DNA repair, and strong phenotypes are typically only observed in combination with deletion of other structure-selective endonucleases. However, yen1D cells do exhibit a modest defect in the repair of replication-derived DSBs by sister chromatid recombination (Mun˜ozGalva´n et al., 2012). Collectively, these studies suggest that Yen1 function in resolving HR intermediates overlaps heavily with other structure-selective nucleases and implies a highly robust network of repair pathways that ensure genome integrity during cell division. Yen1 was proposed to serve as a last line of defense against sister chromatid nondisjunction caused by unresolved recombination intermediates that arise during the repair of DSBs (Matos et al., 2011). The phosphoinhibition of Yen1 from S phase through early mitosis would encourage NCO pathways of DSB repair, which are preferred during mitotic divisions to limit loss of heterozygosity. In support of the model of Matos et al., our results show that Cdc14-mediated dephosphorylation of Yen1 promotes faithful chromosome segregation, likely by removing residual branched structures that would otherwise prevent sister chromatid disjunction. Furthermore, lack of Cdk phosphorylation on Yen1 results in constitutive activity and elevates the fraction of HR repair events resulting in CO formation (Figure 7), potentially leading to an increase in loss of heterozygosity. This pheno-

type is modest, (although statistically significant), likely because mechanisms exist to limit COs associated with homologydirected repair of DSBs during mitotic cell divisions. Multiple Mechanisms of Yen1 Inhibition by Cdk The opposing activities of Cdk and Cdc14 enforce specific activation of Yen1 at anaphase by two independent mechanisms. Cdk phosphorylation of the cluster 2 Cdk sites directly inhibits Yen1 enzymatic activity, whereas phosphorylation of the cluster 3 sites near the C-terminal NLS restricts Yen1 to the cytoplasm. FEAR network-released Cdc14 dephosphorylates Yen1 to allow its accumulation in the nucleus in a fully active state. The existence of two independent regulatory mechanisms may be necessary to completely silence Yen1 function until anaphase onset. Phosphorylated Yen1 may retain minimal catalytic activity or interfere with other repair factors or pathways if not sequestered in the cytoplasm. On the other hand, Yen1 may actively shuttle between the cytoplasm and nucleus, with phosphorylation status shifting the equilibrium between export and import. The small amount of Yen1 present at any given time in the nucleus prior to anaphase could potentially function in repair without inhibition of its enzymatic activity. Our observation that Yen1c2A leads to increased COs (Figure 7), despite a normal localization pattern, is consistent with this idea. The mechanism by which the cluster 2 Cdk sites contribute to Yen1 inhibition remains an open question. These sites are distant from the catalytic domain in the primary sequence, but may interact with it in the folded, native protein. The West laboratory found evidence that phosphorylation at Yen1 Cdk sites inhibits binding to its DNA substrates (Blanco et al., 2014), and the region around cluster 2 may be important for recognition of HJs and other DNA structures that Yen1 acts on. Another possibility is that cluster 2 sites regulate interaction with another protein that influences Yen1 activity. Additional experiments will be required to define the detailed molecular mechanism of Yen1 inhibition by Cdk. EXPERIMENTAL PROCEDURES Reagents Yeast strains are listed in Table S5 and plasmids are in Table S6. Phosphopeptides were synthesized by New England Peptide. Phos-tag reagent was from Wako Pure Chemical Industries. Enzyme and Interaction Assays Phosphatase assays were conducted as described (Bremmer et al., 2012). The synthetic X0 Holliday junction (Figure S5) and resolution assay conditions were described previously (Ip et al., 2008). CoIP experiments were performed as described (Bremmer et al., 2012). Fluorescence Microscopy Fluorescence and differential interference contrast (DIC) images were acquired using a 1003 oil objective on an Olympus BX51 microscope equipped with a Hamamatsu Orca-R2 digital camera. Functional Assays Cell doubling times were calculated as described (Bernstein et al., 2009). DNA damage sensitivity was measured by spotting serial culture dilutions on YPD plates with 40 mM HU or 0.0025% MMS and incubating at 30 C for 48 or 72 hr. Rates of sister chromatid cosegregation were measured as described (Ho et al., 2010). Recombination assays were performed as described (Mazo´n et al., 2012).

Molecular Cell 54, 80–93, April 10, 2014 ª2014 Elsevier Inc. 91

Molecular Cell Regulation of Yen1 by Cdk and Cdc14

Molecular Modeling Homology modeling, docking, and MD simulations were conducted using Prime 3.3 and Glide 6.0 (Schro¨dinger) and Desmond Molecular Dynamics System 3.5 (D.E. Shaw Research). Detailed methods are provided in Supplemental Experimental Procedures.

Dı´az-Cuervo, H., and Bueno, A. (2008). Cds1 controls the release of Cdc14-like phosphatase Flp1 from the nucleolus to drive full activation of the checkpoint response to replication stress in fission yeast. Mol. Biol. Cell 19, 2488–2499.

SUPPLEMENTAL INFORMATION

Gallivan, J.P., and Dougherty, D.A. (2000). A computational study of cation
p interactions vs salt bridges in aqueous media: implications for protein engineering. J. Am. Chem. Soc. 122, 870–874.

Supplemental Information includes Supplemental Experimental Procedures, five figures, and six tables and can be found with this article online at http:// dx.doi.org/10.1016/j.molcel.2014.02.012. ACKNOWLEDGMENTS We acknowledge support from the Purdue Center for Cancer Research small grants and shared resource funding programs and the NIH (R01 GM041784 and R01 GM094386 to L.S.S.). C.L.E. was supported by fellowships from the Purdue Research Foundation and Purdue Graduate School. We thank Harry Charbonneau for helpful comments on the project and manuscript, Scott Briggs for plate reader access, and Laurie Parker and Frank Ankudey for help with peptide synthesis. We thank Hana Hall, Wai Kit Ma, Chris Petell, Ryan Chaparian, and Nikki Lautensack for technical help. Received: October 29, 2013 Revised: January 17, 2014 Accepted: February 3, 2014 Published: March 13, 2014 REFERENCES Agmon, N., Yovel, M., Harari, Y., Liefshitz, B., and Kupiec, M. (2011). The role of Holliday junction resolvases in the repair of spontaneous and induced DNA damage. Nucleic Acids Res. 39, 7009–7019. Azzam, R., Chen, S.L., Shou, W., Mah, A.S., Alexandru, G., Nasmyth, K., Annan, R.S., Carr, S.A., and Deshaies, R.J. (2004). Phosphorylation by cyclin B-Cdk underlies release of mitotic exit activator Cdc14 from the nucleolus. Science 305, 516–519. Bassermann, F., Frescas, D., Guardavaccaro, D., Busino, L., Peschiaroli, A., and Pagano, M. (2008). The Cdc14B-Cdh1-Plk1 axis controls the G2 DNAdamage-response checkpoint. Cell 134, 256–267. Bernstein, K.A., Shor, E., Sunjevaric, I., Fumasoni, M., Burgess, R.C., Foiani, M., Branzei, D., and Rothstein, R. (2009). Sgs1 function in the repair of DNA replication intermediates is separable from its role in homologous recombinational repair. EMBO J. 28, 915–925. Bishop, A.C., Ubersax, J.A., Petsch, D.T., Matheos, D.P., Gray, N.S., Blethrow, J., Shimizu, E., Tsien, J.Z., Schultz, P.G., Rose, M.D., et al. (2000). A chemical switch for inhibitor-sensitive alleles of any protein kinase. Nature 407, 395–401. Blanco, M.G., Matos, J., Rass, U., Ip, S.C., and West, S.C. (2010). Functional overlap between the structure-specific nucleases Yen1 and Mus81-Mms4 for DNA-damage repair in S. cerevisiae. DNA Repair (Amst.) 9, 394–402. Blanco, M.G., Matos, J., and West, S.C. (2014). Dual control of Yen1 nuclease activity and cellular localization by Cdk and Cdc14 prevents genome instability. Mol. Cell 54, this issue, 94–106. Bouchoux, C., and Uhlmann, F. (2011). A quantitative model for ordered Cdk substrate dephosphorylation during mitotic exit. Cell 147, 803–814. Bremmer, S.C., Hall, H., Martinez, J.S., Eissler, C.L., Hinrichsen, T.H., Rossie, S., Parker, L.L., Hall, M.C., and Charbonneau, H. (2012). Cdc14 phosphatases preferentially dephosphorylate a subset of cyclin-dependent kinase (Cdk) sites containing phosphoserine. J. Biol. Chem. 287, 1662–1669. Broadus, M.R., and Gould, K.L. (2012). Multiple protein kinases influence the redistribution of fission yeast Clp1/Cdc14 phosphatase upon genotoxic stress. Mol. Biol. Cell 23, 4118–4128.

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