Genetic Interactions of the Aspergillus nidulans atmAATM Homolog With Different Components of the DNA Damage Response Pathway

doi:10.1534/genetics.107.080879

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Genetic Interactions of the Aspergillus nidulans atmA^ATM Homolog With Different Components of the DNA Damage Response Pathway

Iran Malavazi^*, Joel Fernandes Lima^*, Patrícia Alves de Castro^*, Marcela Savoldi^*, Maria Helena de Souza Goldman and Gustavo Henrique Goldman^*^,1

^* Faculdade de Ciências Farmacêuticas de Ribeirão Preto and Faculdade de Filosofia, Ciências e Letras de Ribeirão Preto, Universidade de São Paulo, São Paulo 14040-903, Brazil

^¹ Corresponding author: Departamento de Ciências Farmacêuticas Faculdade de Ciências Farmacêuticas de Ribeirão Preto, Universidade de São Paulo, Av. do Café S/N, Ribeirão Preto, São Paulo 14040-903, Brazil.
E-mail: ggoldman{at}usp.br

Manuscript received August 22, 2007. Accepted for publication December 12, 2007.

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Ataxia telangiectasia mutated (ATM) is a phosphatidyl-3-kinase-relatedprotein kinase that functions as a central regulator of theDNA damage response in eukaryotic cells. In humans, mutationsin ATM cause the devastating neurodegenerative disease ataxiatelangiectasia. Previously, we characterized the homolog ofATM (AtmA) in the filamentous fungus Aspergillus nidulans. Inaddition to its expected role in the DNA damage response, wefound that AtmA is also required for polarized hyphal growth.Here, we extended these studies by investigating which componentsof the DNA damage response pathway are interacting with AtmA.The AtmA^ATM loss of function caused synthetic lethality whencombined with mutation in UvsB^ATR. Our results suggest thatAtmA and UvsB are interacting and they are probably partiallyredundant in terms of DNA damage sensing and/or repairing andpolar growth. We identified and inactivated A. nidulans chkA^CHK1and chkB^CHK2 genes. These genes are also redundantly involvedin A. nidulans DNA damage response. We constructed several combinationsof double mutants for ${Delta}$ atmA, ${Delta}$ uvsB, ${Delta}$ chkA, and ${Delta}$ chkB. We observeda complex genetic relationship with these mutations during theDNA replication checkpoint and DNA damage response. Finally,we observed epistatic and synergistic interactions between AtmA,and bimE^APC1, ankA^WEE1 and the cdc2-related kinase npkA, atS-phase checkpoint and in response to DNA-damaging agents.

ATAXIA telangiectasia mutated/ataxia telangiectasia and Rad3related (ATM/ATR) are members of the family of phosphoinositide3-kinase-related kinases (PIKKs) and key regulators of the DNAdamage response (CASPARI and CARR 1999; SHILOH and KASTAN 2001;SHILOH 2006; HURLEY and BUNZ 2007). The ATM and ATR proteinkinases share many biochemical and functional similarities.Both activate signal transduction pathways that ultimately interfacewith the Cdk/cyclin machinery (ABRAHAM 2001; SHILOH 2006). Theytrigger responses that promote the maintenance of genome integrityby phosphorylating multiple target proteins, such as p53, c-Abl,Chk2, and Brca1 (BASKARAN et al. 1997; LAVIN and SHILOH 1997;SHAFMAN et al. 1997; BANIN et al. 1998; CANMAN and LIM 1998;CORTEZ et al. 2001; MCKINNON 2004). In mammalian cells, ATMresponds to the presence of double-strand breaks (DSBs). ATRalso responds to DSBs, but more slowly than ATM (SHILOH 2006).In addition, the ATR pathway can respond to agents that interferewith the function of replication forks, such as hydroxyurea(HU), ultraviolet (UV) light, and DNA-alkylating agents suchas methyl methanesulfonate (MMS) (NYBERG et al. 2002; OSBORN et al. 2002).

Mutations in the ATM (ataxia telangiectasia mutated) gene giverise to ataxia telangiectasia (AT) (SAVITSKY et al. 1995; SHILOH 2006).This autosomal recessive disease is characterized by progressivecerebellar ataxia, immunodeficiency, premature aging, gonadaldysgenesis, extreme radiosensitivity, and susceptibility toinfections and tumors (MCKINNON 2004). Studies have shown thatATM is present predominantly within the nucleus of culturedhuman cells with a small fraction present in the cytoplasm (LAKIN et al. 1996;BROWN et al. 1997; WATTERS et al. 1997). In response to DSBs,ATM is autophosphorylated at Ser-1981, which leads to the dissociationof inactive multimeric ATM to initiate ATM signaling (BAKKENIST and KASTAN 2003).ATM works in concert with other factors, among them the MRE11,RAD50, and NBS1 (MRN) complex (for a review, see VAN DEN BOSCH et al. 2003).Activated ATM can directly associate with the MRN complex, andthis interaction can control signaling by influencing the ATMsubstrate choice (LEE and PAULL 2004; PAULL and LEE 2005). Besidesits nuclear role in DNA damage surveillance, in the cytoplasmATM localizes to vesicles and interacts with β-adaptin,one of the components of the AP-2 adaptor complex, which isinvolved in clathrin-mediated endocytosis of receptors (LIM et al. 1998).

The filamentous fungus Aspergillus nidulans possesses a sophisticatedDNA damage response that ensures the maintenance of genome integrity(GOLDMAN et al. 2002; GOLDMAN and KAFER 2004). The ATR homologUvsB^ATR is a central component of this response, where it controlsthe activation of multiple checkpoints, regulates damage-inducedgene expression, and also promotes DNA repair (DE SOUZA et al. 1999;HOFMANN and HARRIS 2000). UvsB^ATR displays an extensive webof genetic interactions with other proteins involved in theDNA damage response, including the Mre11 complex (ScaA^NBS1,MreA^MRE11, and SldI^RAD50), the cdc2-related kinase NpkA, andSepB^CTF4 (FAGUNDES et al. 2004, 2005; GYGAX et al. 2005; MALAVAZI et al. 2005).Recently, we characterized the homolog of ATM (AtmA) in A. nidulans(MALAVAZI et al. 2006, 2007). Here, we investigate genetic interactionsof the A. nidulans atmA^ATM homolog with different componentsof the DNA damage response pathway. We demonstrated that theatmA^ATM loss of function causes synthetic lethality when combinedwith mutation in uvsB^ATR. Furthermore, we identified the A.nidulans CHK1 and CHK2 homologs and showed that these genesare redundantly involved in the DNA damage response. In addition,we characterized genetic interactions between atmA and bimE^APC1,ankA^WEE1, and the cdc2-related kinase npkA, at S-phase checkpointand in response to DNA-damaging agents.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Strains and media methods:
A. nidulans strains used in this work are described in Table 1.The media used were of two basic types, i.e., complete and minimal.The complete media comprised the following three variants: 2%glucose, 0.5% yeast extract, 2% agar, and trace elements (YAG);YAG supplemented with 1.2 g/liter (each) of uracil and uridine(YUU); and liquid YG or YG + UU medium with the same composition(but without agar). The minimal media were a modified minimalmedium (MM) of 1% glucose, original high-nitrate salts, traceelements, and 2% agar, pH 6.5. Expression of atmA under thecontrol of the alcA promoter was regulated by repression onglucose (4%), derepression on glycerol (2%), and induction onthreonine (100 mM) or ethanol (2%). Therefore, MM-G was identicalto MM, except that glycerol and ethanol (2%) or threonine (100mM) were used, instead of glucose as the sole carbon source.Trace elements, vitamins, and nitrate salts were included asdescribed by KAFER (1977). Standard genetic techniques for A.nidulans were used for all strain constructions (KAFER 1977).

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TABLE 1 A. nidulans strains used in this work

For the UV light viability assays, conidiospores (dormant ina quiescent G₁ state; BERGEN and MORRIS 1983) were suspendedin 0.2% Tween-20 and plated out on YUU plates ( $~$ 100 conidia/plate).The plates were then immediately irradiated with UV light usinga UV Stratalinker 1800 (Stratagene, La Jolla, CA) and incubatedat 30° for 48 hr to determine UV light sensitivity of nondividingcells. To determine UV light survival of dividing cells, conidiosporeson YUU plates were first allowed to germinate for 4.5 hr at30°. By this time the germinated conidia had entered thecell cycle and were about to undergo the first mitosis. Thesegermlings were UV irradiated on the plates and then similarlyincubated at 30° for 48 hr. Viability was determined asthe percentage of colonies on treated plates compared to untreatedcontrols.

To establish the polarization kinetics, conidia were incubatedin YG + 50 mM HU for 5 hr at 37°. Germlings were releasedfrom cell-cycle arrest by three sequential washes in prewarmedYG, followed by transfer to a new petri dish containing freshprewarmed YG. Following release, samples were taken at 30-minintervals over the next 150 min. A conidium was counted as polarizedif it possessed a germ tube readily detectable as small protuberanceson the spherical shape of conidium surface. For the septationexperiments, asexual spores were inoculated on coverslips inthe presence or the absence of DNA-damaging agent 4-nitroquinoline1-oxide (4-NQO). After 8–12 hr incubation at 30°,the percentage of germlings possessing septum was scored.

To evaluate the statistical differences among the strains usedfor growth in the presence of DNA-damaging agents, mitosis,and UV light assays, we used one-way ANOVA and the Student–Newman–Keulsmulticomparison test as a post hoc test. The data shown arethe average of three independent experiments and means ±standard deviations are shown in the tables and figures. Analyseswere performed using the software package Sigma Stat 3.1 (Systat)and the statistical significance was set at ${alpha}$ = 0.05. In theepistasis grouping, P-values >0.05 and <0.05 were usedto discriminate between epistatic and synergistic interactions,respectively.

Mitosis assay:
Conidiospores were inoculated on coverslips in YG + UU mediumcontaining 0, 6, or 100 mM of HU. After 5–7 hr incubationat 37°, coverslips with adherent germlings were transferredto fixative solution and stained with 4',6-diamidino-2-phenyylindole(DAPI) as described below. The number of nuclei was assessedand germlings that had two or more nuclei after the HU incubationwere scored as having a nonfunctional checkpoint response incomparison to the wild-type strain.

Staining and microscopy:
For germling nuclear and septum staining, conidia were inoculatedon coverslips. After incubation at the appropriate conditionsfor each experiment, coverslips with adherent germlings weretransferred to fixative solution (3.7% formaldehyde, 50 mM sodiumphosphate buffer pH 7.0, 0.2% Triton X-100) for 30 min at roomtemperature. Then, they were briefly rinsed with PBS buffer(140 mM NaCl, 2 mM KCl, 10 mM NaHPO₄, 1.8 mM KH₂PO₄, pH 7.4)and incubated for 5 min in a solution with 100 ng/ml of DAPI(Sigma Chemical, St. Louis) and/or 100 ng/ml of calcofluor (fluorescentbrightener, Sigma Chemical). After incubation with the dyes,they were washed with PBS buffer for 10 min at room temperatureand then rinsed in distilled water, mounted, and visualizedin an epifluorescence microscope. Slides were viewed using aCarl Zeiss (Oberkochen, Germany) microscope, using a 100x magnificationoil immersion objective lens (EC Plan-Neofluar, NA 1.3) equippedwith a 100-W HBO mercury lamp epifluorescence module. Phasecontrast for the brightfield images and fluorescent images wascaptured with a AxioCan camera (Carl Zeiss), processed usingthe AxioVision software version 3.1, and saved as tiff files.Further processing was performed using Adobe Photoshop 7.0 (AdobeSystems, San Jose, CA). The living cells were visualized atroom temperature in a confocal microscope. For cell imagingof atmA^ATM protein fused to GFP, conidiospores were grown inglass-bottom dishes (Mattek, Ashland, MA) in 2 ml of MM-G and/orethanol plus supplements for 15 hr at 30°. Germlings werefixed for 10 min in a fixative solution containing 1x PBS, 5%DMSO, 3.7% formaldehyde, and 10% methanol. The nucleus was DAPIstained as described above. Images were analyzed using the LeicaTCS SP5 spectral laser scanning confocal microscope (Leica Microsystems,Heidelberg, Germany) (Laboratory of Confocal Microscopy, FMRP,University of São Paulo, São Paulo, Brazil), usinga 63x magnification water immersion objective lens, using laserline 488 nm for GFP and 405 nm for DAPI. Images were capturedby direct acquisition with the Z step ranging from 0.5 to 2µm with the Leica LAS AF software (Leica Microsystems)and additional processing was carried out using Adobe Photoshop7.0 (Adobe Systems).

RNA isolation:
A total of 1.0 x 10⁷ conidia/ml were used to inoculate 50 mlof liquid cultures that were incubated in a reciprocal shakerat 37° for 16 hr. When necessary, mycelia were asepticallytransferred to fresh YG medium in the presence or the absenceof DNA-damaging agent indicated for each experiment. RNA extraction,RNAse free DNAse treatment, and real-time RT–PCR experimentswere performed as previously described (SEMIGHINI et al. 2002).Table 2 describes the primers and Lux fluorescent probes (Invitrogen,San Diego) used in this work.

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TABLE 2 Primers and probes used in this work

DNA manipulations, chkA and chkB deletion strains isolation, and construction of an alcA::gfp::atmA strain:
These are described in supplemental Materials and Methods athttp://www.genetics.org/supplemental/.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

The atmA^ATM loss of function causes synthetic lethality when combined with mutation in uvsB^ATR:
To investigate possible interactions between the atmA^ATM anduvsB^ATR genes, we tried to construct double mutants either bycrossing single mutants or by deleting both genes by DNA-mediatedtransformation. After several trials, we were unable to observeany segregant or transformant carrying both mutations. Theseresults suggested that the loss of function of both genes causessynthetic lethality. Thus, we decided to construct a conditionaldouble mutant with alcA::gfp::atmA uvsB101. As first step, wevalidate the alcA::atmA construction in the wild-type strain(Figure 1). The alcA promoter is induced to high levels by glycerol,ethanol, and L-threonine and repressed by glucose (FLIPPHI et al. 2002).The construction (p)alcA::gfp::atmA^1kb was transformed intothe wild-type strain and several transformants were obtainedin which the plasmid had integrated homologously (as verifiedby PCR) and produced a functional Gfp::AtmA when derepressedwith glycerol (Figure 1A). Figure 1, A and B, shows wild-typehyphae that were grown in the presence of glycerol and exposedfor 2 hr to 10 µg/ml of phleomycin (PHLEO). The Gfp::AtmAwas detected along the hyphae and barely detected in the nucleiof untreated wild-type hyphae; however, it was clearly and mostabundantly present within nuclei of hyphae exposed to PHLEO(Figure 1, A and B). When the wild-type strain harboring thealcA::gfp::atmA construct was grown in the presence of eitherglucose or glycerol as single carbon sources and 50 µMof camptothecin (CPT), this strain was sensitive and resistantto CPT, respectively (Figure 1C; compare with the growth andinhibition of the wild-type and ${Delta}$ atmA mutant strains in the presenceof CPT in both carbon sources). When grown on glucose as a singlecarbon source, the alcA::atmA strain behaves identically tothe ${Delta}$ atmA strain in terms of drug sensitivity (data not shown).We have observed the same results for two independent transformantsobtained for each treatment (data not shown). These resultsvalidated our alcA::atmA construction and showed that apparentlyAtmA has increased localization to nuclei in response to DNAdamage (i.e., DSBs).

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FIGURE 1.— AtmA localizes to nuclei in response to DNA damage. (A) Conidiospores from the alcA::gfp::atmA strain were grown in MM-G and ethanol plus supplements for 15 hr at 30°. In one of the treatments, 10 µg/ml phleomycin was added for 2 hr at 30°. Bar, 5 µm. (B) Higher magnification of the nuclei surrounded by a dashed white circle in A. (C) Growth phenotypes of the wild-type, ${Delta}$ atmA, and alcA::gfp::atmA strains grown in YUU (4% glucose) or in MM + G or in both media in the presence of 50 µM CPT.

As next step, the ASH270 (uvsB101) strain was crossed with IM69-1[(p)alcA::gfp::AtmA] and we have identified several segregants[(p)alcA::gfp::AtmA uvsB101] that produced Gfp::AtmA when inducedwith glycerol (data not shown). We have grown the wild-type,alcA::gfp::atmA, ${Delta}$ atmA, uvsB101, and one of these segregant alcA::gfp::atmAuvsB101 mutant strains in the presence of glucose, glycerol,or glycerol plus threonine as single carbon sources. As predicted,the combination of atmA mRNA repression with the mutation uvsB101caused synthetic lethality (Figure 2A, first lane). The sameresults were observed when a double mutant alcA::gfp::atmA ${Delta}$ uvsB^ATRwas constructed (data not shown). These strains were also incubatedin the presence of different concentrations or dosages of severalDNA-damaging agents (such as CPT, bleomycin (BLEO), 4-NQO, MMS,and UV light) and the atmA gene was either repressed or overexpressed.As expected, when the atmA gene is repressed, the double-inactivationmutant is highly sensitive to these DNA-damaging agents. However,interestingly, when atmA is overexpressed, it confers resistanceto 0.001% MMS (Figure 2A). An increase in survival was alsoobserved when the double mutant was grown in the presence ofdifferent MMS concentrations (supplemental Figure S3 at http://www.genetics.org/supplemental/).This effect was not observed for the other DNA-damaging agentstested (data not shown).

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FIGURE 2.— (A) Growth phenotypes of the wild-type, alcA::gfp::atmA, ${Delta}$ atmA, uvsB101, and alcA::gfp::atmA uvsB101 mutant strains grown in the presence of either YUU (4% glucose) or MM + 2% glycerol + 100 mM threonine with or without 0.001% MMS. (B) Conidia from the same strains from A were grown for 8 hr at 37° in YUU + 4% glucose and DAPI stained. Arrows indicate multiple polar axes. Bar, 10 µm.

We compared the nuclear division kinetics (number of nucleiper cell compartment) and the polar growth of the wild-type,alcA::gfp::atmA, uvsB101, and ${Delta}$ atmA mutant strains (Figure 2B).As previously shown by MALAVAZI et al. (2006, 2007), the ${Delta}$ atmAmutant strain has an accelerated rate of proliferation, i.e.,increased nuclear kinetics, when compared to the wild-type strain(Figure 2B, first and second lanes). The double mutant showedan increased number of nuclei that was comparable to the ${Delta}$ atmAmutant strain (Figure 2B, third lane). Interestingly, the double-mutantstrain displayed germlings with more polarity axes than thewild-type and the ${Delta}$ atmA mutant strains (Figure 2B, third lane).Taken together, these results suggest that atmA and uvsB areinteracting and they are probably partially redundant in termsof DNA damage sensing and/or repairing and polar growth. Interestingly,the data also suggest that uvsB101 may be partially suppressingthe ${Delta}$ atmA polarity defects (see Figure 2B) and that, at leastwith respect to polarity defects, the two kinases are not merelyredundant.

Genetic interactions of AtmA^ATM, UvsB^ATR, and ChkA^CHK1 and ChkB^CHK2:
Chk1 and Chk2 are serine/threonine kinases that are requiredfor cell-cycle arrest in response to DNA damage. As downstreamkinases, they are phosphorylated by ATM/ATR-dependent processesand may additionally undergo autophosphorylation that potentiatesphosphorylation of downstream targets (NYBERG et al. 2002).A BLASTp search of the A. nidulans genome database (http://www.broad.mit.edu/annotation/fungi/aspergillus/)using human CHK1 and CHK2 as queries revealed two single openreading frames with significant similarity. The potential homologs,AN5494.3 (chkA) and AN4279.3 (chkB), are predicted 534- and648-amino-acid proteins that possessed homology to the Homosapiens CHK1 and CHK2 (e-value 7e-46 and 2e-63; 47 and 55% similarityand 30 and 36% identity), respectively. A. nidulans ChkA andChkB also showed high identity with its Neurospora crassa homologsNCU08346.1 (e-value 2e-155; 63% similarity and 49% identity)and pdr-4, recently shown as a regulatory link between the circadianand cell cycles (e-value 0.0; 67% similarity and 52% identity;PREGUEIRO et al. 2006). The serine/threonine active-site signaturesfor ChkA and ChkB are located at residues 395–407 and139–151 for ChkA and ChkB, respectively. There is a singleforkhead-associated (FHA) domain in the ChkB located at residues186–238. The FHA domain is a putative nuclear signalingdomain found in a variety of otherwise unrelated proteins; thisdomain comprises $~$ 55–75 amino acids and contains threehighly conserved blocks separated by divergent spacer regions(PROSITE entry PS50006, www.expasy.org). To characterize thefunction of ChkA and ChkB, ORF deletions were generated usinga fusion PCR-based approach (see MATERIALS AND METHODS). Protoplastsof A. nidulans strain TNO2A3 were transformed using the fusionPCR products, and several transformants were obtained by theirability to grow in YAG. Allelic replacement of chkA and chkBwas verified in several transformants as confirmed by the analysisof Southern blots (data not shown). One of these transformantsfor each gene was crossed with the wild-type UI224 strain toeliminate the ${Delta}$ nkuA mutation; accordingly the deletion strainsare wild type for these loci. These allelic replacements ofchkA and chkB were also confirmed by the analysis of Southernblots (Figure 3), thereby generating the ${Delta}$ chkA and ${Delta}$ chkB strainsnamed JFL3 and JFL4, respectively.

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FIGURE 3.— Schematic illustration for the chkA/chkB deletion strategy. (A) Genomic DNA from both wild-type and ${Delta}$ chkA strains was isolated and cleaved with the enzyme HindIII; a 2.0-kb 5'-upstream chkA DNA fragment was used as a hybridization probe. This fragment recognizes two DNA bands ( $~$ 3.5 and 2.0 kb) in the wild-type strain and two DNA bands ( $~$ 1.6 and 2.0 kb) in the ${Delta}$ chkA mutant strain as shown in the Southern blot analysis. Growth phenotypes of the wild-type and chkA deletion mutant strains grown either in YUU or in YUU + 10 mM HU for 48 hr at 37° are shown. (B) Genomic DNAs from both wild-type and ${Delta}$ chkB strains were isolated and cleaved with the enzyme EcoRI; a 2.0-kb 5'-upstream chkB DNA fragment was used as a hybridization probe. This fragment recognizes two DNA bands ( $~$ 2.0 and 5.5 kb) in the wild-type strain and two DNA bands ( $~$ 2.0 and 2.4 kb) in the ${Delta}$ chkB mutant strain as shown in the Southern blot analysis.

Two approaches were used as initial tests of ChkA and ChkB functionin the DNA damage response: we examined (i) the growth of the ${Delta}$ chkA and ${Delta}$ chkB strains in the presence of DNA-damaging agentsand (ii) how the mRNA expression of these genes is affectedby these agents by using real-time RT–PCR. In the firsttest, the ${Delta}$ chkA strain was more sensitive only to HU while the ${Delta}$ chkB strain showed a comparable sensitivity to the wild-typestrain in 4-NQO, BLEO, CPT, HU, and MMS (Figure 3A and datanot shown). All these phenotypes were identical in media eithersupplemented with UU or not.

To accomplish the second test, A. nidulans wild type was grownin the absence of any drug and transferred to a specific concentrationof a DNA-damaging agent for 30, 60, 120, and 240 min, and thenRNA was isolated and analyzed for the expression of these genes(Figure 4). The chkA gene expression was increased 2–3times after 30–240 min growth in the presence of CPT, $~$ 11 times after 240 min growth in the presence of MMS, 2–5times after 30–240 min of growth in the presence of BLEO,and 2–4 times after 30–120 min growth in the presenceof 4-NQO. The chkB gene expression was increased 3 and 4 timesafter 30 and 120 min growth in the presence of CPT; $~$ 11 and 2times after 60, 120, and 240 min growth in the presence of MMS,respectively; 13 and 2 times after 60–120 min of growthin the presence of BLEO; and 3–6 times after 60 and 120min growth in the presence of 4-NQO. Thus, these results indicatethat chkA and chkB genes transcriptionally respond to DNA-damagingagents.

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FIGURE 4.— Fold increase in chkA/chkB RNA levels in response to DNA-damaging agents. Mycelia were grown either in the absence of any drug or in the presence of 25 µM CPT, 0.003% MMS, 0.6 µg/ml BLEO, or 0.25 µg/ml 4-NQO for 30, 60, 120, and 240 min. Real-time RT–PCR was the method used to quantify the mRNA. The measured quantity of the chkA/chkB mRNA in each of the treated samples was normalized using the C_T values obtained for the tubC RNA amplifications run in the same plate. The relative quantitation of chkA/chkB and tubulin gene expression was determined by a standard curve (i.e., C_T values plotted against the logarithm of the DNA copy number). Results of four sets of experiments were combined for each determination; means ± standard deviations are shown. The values represent the number of times the genes are expressed compared to the wild-type control grown without any drug (represented absolutely as 1.00).

We also constructed a double-mutant ${Delta}$ chkA ${Delta}$ chkB and investigatedits sensitivity to DNA-damaging agents. We have observed thatboth ${Delta}$ chkA and ${Delta}$ chkB mutants have increased sensitivity to UVlight as quiescent conidia (Figure 5A, left; P $≤$ 0.03). However,only the ${Delta}$ chkA mutant strain has increased sensitivity to UVlight as germinating conidia (Figure 5A, right; P < 0.001).Accordingly, the double-mutant ${Delta}$ chkA ${Delta}$ chkB showed comparable sensitivityto UV light as quiescent conidia, suggesting that ${Delta}$ chkA was epistaticto ${Delta}$ chkB (Figure 5B, left). Interestingly, the double-mutant ${Delta}$ chkA ${Delta}$ chkB was more sensitive to UV light as germinating conidiathan the ${Delta}$ chkA and ${Delta}$ chkB mutant strains (P $≤$ 0.02). The double-mutant ${Delta}$ chkA ${Delta}$ chkB showed the same sensitivity to 4-NQO, MMS, and CPTas the wild-type strain (data not shown) and it was as sensitiveto HU as was ${Delta}$ chkA (Figure 6A).

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FIGURE 5.— The double-mutant ${Delta}$ chkA ${Delta}$ chkB showed increased sensitivity to UV light. Viability of the wild-type, ${Delta}$ chkA, ${Delta}$ chkB (A), ${Delta}$ chkA ${Delta}$ chkB (B), ${Delta}$ atmA ${Delta}$ chkA (C), ${Delta}$ atmA ${Delta}$ chkB (D), ${Delta}$ uvsB ${Delta}$ chkA (E), and ${Delta}$ uvsB ${Delta}$ chkB (F) germlings was scored after exposure to UV light of quiescent and germinating conidiospores. Viability was determined as the percentage of colonies on treated plates compared to untreated controls. The results were expressed by the average of three independent experiments and means ± standard deviations are shown. The ${Delta}$ chkA and ${Delta}$ chkA ${Delta}$ chkB strains were significantly different from the wild-type and ${Delta}$ chkB strains in germinating conidiospores, P < 0.02.

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FIGURE 6.— Growth phenotypes of the wild type, ${Delta}$ chkA, ${Delta}$ chkB, and ${Delta}$ chkA ${Delta}$ chkB mutant strains grown in YUU with or without 2.5 and 5.0 mM HU (A); of ${Delta}$ chkA, ${Delta}$ atmA, and ${Delta}$ atmA ${Delta}$ chkA grown in YUU with or without 0.005% MMS and 5.0 mM HU (B); and of ${Delta}$ chkB, ${Delta}$ atmA, and ${Delta}$ atmA ${Delta}$ chkB grown in YUU with or without 0.1 µg/ml 4-NQO (C).

We were not able to observe any defect in the sexual cycle inboth A. nidulans chkA and chkB inactivation strains (data notshown). However, the mRNA accumulation of both genes was increasedduring the sexual cycle (supplemental Figure S2 at http://www.genetics.org/supplemental/).

We also constructed double mutants ${Delta}$ atmA^ATM with ${Delta}$ chkA and ${Delta}$ chkBand ${Delta}$ uvsB^ATR with ${Delta}$ chkA and ${Delta}$ chkB. The double-mutant ${Delta}$ atmA^ATM ${Delta}$ chkAshowed an increased sensitivity to MMS and HU (Figure 6B). The ${Delta}$ chkB mutation partially suppressed the ${Delta}$ atmA^ATM sensitivity to0.1 µg/ml of 4-NQO (Figure 6C). The ${Delta}$ atmA and ${Delta}$ chkA mutationsare in epistasis during exposure to UV light of quiescent conidiaof single and double mutants at 50–150 J/m² (Figure 5C,left, P > 0.05). The ${Delta}$ atmA and ${Delta}$ chkA mutations are synergisticduring UV light exposure of germinating single and double mutants(Figure 5C, right, P < 0.05). The ${Delta}$ atmA and ${Delta}$ chkB mutationsare not interacting when quiescent germlings are exposed toUV light (Figure 5D, left); however, there is a synergisticinteraction when ${Delta}$ atmA ${Delta}$ chkB mutant germinating conidia are exposedto UV light (Figure 5D, right, P < 0.001). We have observedthat there is no interaction between ${Delta}$ uvsB and ${Delta}$ chkA when quiescentand germinating conidia from the single and double mutants wereexposed to UV light (Figure 5E); and also there is no interactionbetween ${Delta}$ uvsB and ${Delta}$ chkB when germinating conidia from the singleand double mutants were exposed to UV light (Figure 5F, right).However, the ${Delta}$ chkB mutation is suppressing the ${Delta}$ uvsB sensitivityto UV light (Figure 5F, left).

An important survival function when DNA damage occurs is theinhibition of the cell cycle through the activation of cell-cyclecheckpoints. HU is an inhibitor of ribonucleoside diphosphatereductase, the rate-limiting enzyme in deoxyribonucleotide (dNTP)biosynthesis. Depletion of dNTPs activates the DNA replicationcheckpoint, which slows progression through S phase (DESANY et al. 1998).Furthermore, initiation of DNA replication in the presence ofhigh levels of HU causes DSBs (MERRILL and HOLM 1999). HU isan effective inhibitor of DNA synthesis in A. nidulans (BERGEN and MORRIS 1983).We examined the ability of the ${Delta}$ atmA, ${Delta}$ uvsB, ${Delta}$ chkA, and ${Delta}$ chkB single-and double-mutant strains to replicate DNA during a transientperiod of growth in the presence of HU. A mitosis assay wasused to verify if DNA replication checkpoint response is impairedin mutant strains (FAGUNDES et al. 2004). This assay monitorsmitosis in mutant and wild-type strains incubated in 0, 6, or100 mM of HU for 5–7 hr. The number of nuclei was assessedby DAPI staining, and if germlings had two or more nuclei afterthe HU incubation, they were scored as defective in mitoticarrest (Table 3). This assay measures the state of the replicationcheckpoint response. The atmA and uvsB inactivation strainshad significant defects in the mitosis assay at 6 mM and 100mM (Table 3). Interestingly, the ${Delta}$ chkA and ${Delta}$ chkB mutant strainshad an intact replication checkpoint at both 6 and 100 mM, butthe double-mutant strain ${Delta}$ chkA ${Delta}$ chkB had defects only at 6 mM(Table 3). Curiously, the ${Delta}$ chkA and ${Delta}$ chkB mutations suppressedboth ${Delta}$ atmA and ${Delta}$ uvsB defects in the intra-S-phase checkpoint.

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TABLE 3 Mitosis assay from A. nidulans wild-type and mutant strains

We also evaluated the polar growth of the ChkA and ChkB inactivationmutants by following the same methodology described above, i.e.,the HU-block-release assay. As was previously seen (MALAVAZI et al. 2006,2007, and this work), the ${Delta}$ atmA mutant strain showed decreasedpolar growth when compared to the wild-type strain (Table 4).The ${Delta}$ chkA and ${Delta}$ chkB mutant strains have not displayed polar growthdefects while the double-mutant ${Delta}$ chkA ${Delta}$ chkB had decreased polargrowth. Interestingly, all the double mutants with ${Delta}$ chkA and ${Delta}$ chkB, and with ${Delta}$ atmA and ${Delta}$ uvsB, showed to different extents intensificationof the polar growth defect (Table 4). Notably, the most pronouncedeffect was observed for the double-mutant ${Delta}$ atmA ${Delta}$ chkB (3% of polargrowth at 150 min after HU release; Table 4, last row). Takentogether, these data indicate that ChkA and ChkB are redundantlyinvolved in the DNA damage response in A. nidulans.

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TABLE 4 Polar growth upon HU-block-release experiments

Genetic interactions of the AtmA^ATM with other components of the DNA damage response:
We investigated possible genetic interactions between atmA andseveral genes with known roles in the regulation of the A. nidulansDNA damage response, including npkA, ankA^WEE1, bimE^APC1, sldI^RAD50,and mreA^MRE11. Accordingly, we constructed the following doublemutants: ${Delta}$ atmA ${Delta}$ npkA (strain IM69-3), ${Delta}$ atmA ankA (strain IM69-35), ${Delta}$ atmA bimE7 (strain IM69-228), and ${Delta}$ atmA mreA::pyr4 (strain IM69-RE).

The double-mutant strain ${Delta}$ atmA ${Delta}$ npkA was more sensitive to HUand 4-NQO while ${Delta}$ atmA ankA was more sensitive to MMS, 4-NQO,and CPT than the corresponding parental strains (Figure 7 andsupplemental Figure S1 at http://www.genetics.org/supplemental/).Our results suggest that AtmA functions in a different pathwayfrom either NpkA or AnkA for the repair of DNA damage causedby these agents. By contrast, AtmA appears to display epistaticinteractions with BimE and MreA under all tested conditions.Interestingly, the double-mutant ${Delta}$ atmA ankA has a reduced growthrate in the absence of any DNA-damaging agent and poorly conidiateswhen compared to parental strains (Figure 7, supplemental FigureS1, and data not shown), providing more evidence for a geneticinteraction between these two mutations.

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FIGURE 7.— Growth phenotypes of the wild-type, ${Delta}$ atmA, ${Delta}$ npkA, ${Delta}$ atmA ${Delta}$ npkA, ankA, and ${Delta}$ atmA ankA strains. Strains GR5 (wild type), IM69 ( ${Delta}$ atmA), MV3 ( ${Delta}$ npkA), IM69-3 ( ${Delta}$ atmA ${Delta}$ npkA), APK35 (ankA), and IM69-35 ( ${Delta}$ atmA ankA) were grown for 72 hr at 37° in YUU medium in the presence or absence of 10 mM HU, 0.0025% MMS, 0.05 µg/ml 4-NQO, and 25 µM CPT.

We checked UV sensitivities of nondividing (quiescent) and dividing(germinating) double mutants with the aim of identifying possibleinteractions between these genes. Germinating conidia from thedouble ${Delta}$ atmA ${Delta}$ npkA strain were more sensitive to UV light thanthe corresponding parental strains (Figure 8A; P < 0.001).Notably, the sldI^RAD50::pyrG mutation suppresses the UV sensitivityof quiescent (200 and 250 J/m²) and germinating ${Delta}$ atmA conidia(Figure 8B), thereby suggesting that AtmA and SldI may act inparallel to mediate checkpoint responses. The double-mutant ${Delta}$ atmA ankA was also more sensitive when UV irradiation was appliedto quiescent and germinating conidia than the correspondingparental strains (Figure 8C; P < 0.001). These results suggestthat atmA and ankA function in parallel UV repair pathways forboth quiescent and germinating conidia, whereas atmA and npkAfunction in parallel pathways only when germinating conidiaare exposed to UV light. By contrast, epistasis was observedbetween ${Delta}$ atmA and bimE7 when quiescent conidia were exposed to50–150 J/m² of UV light (Figure 8D). We were unable totest the UV-light sensitivity of the double-mutant ${Delta}$ atmA mreA^MRE11because this strain cannot conidiate (data not shown).

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FIGURE 8.— Sensitivity to UV light. Quiescent and germinating conidiospores from wild type, ${Delta}$ atmA, ${Delta}$ npkA, and ${Delta}$ atmA ${Delta}$ npkA (A); ${Delta}$ atmA, sldI^RAD50, and ${Delta}$ atmA sldI^RAD50 (B); ${Delta}$ atmA, ankA, and ${Delta}$ atmA ankA (C); and ${Delta}$ atmA, bimE7, and ${Delta}$ atmA bimE7 (D) were exposed to UV light, and viability was scored after exposure to this DNA-damaging agent. Viability was determined as in Figure 5. The results were expressed by the average of four independent experiments and means ± standard deviations are shown.

We also tested if the DNA replication checkpoint response wasintact in these double-mutant strains (Table 5). As previouslyreported, the bimE7, ${Delta}$ npkA, sldI^RAD50::pyrG, and ankA mutantshave impaired checkpoint response at 6 mM (FAGUNDES et al. 2004;MALAVAZI et al. 2005). During the mitosis assay at 100 mM ofHU, there was a synergistic interaction between ankA and ${Delta}$ atmA(Table 5). There was a suppression of the DNA replication checkpointin the ${Delta}$ atmA mutation by ${Delta}$ sldI^RAD50 (at both 6 and 100 mM of HU), ${Delta}$ npkA (at 6 mM HU), and bimE7 (at 6 mM HU) mutations (Table 5).Accordingly, we were also not able to perform the mitosis assayfor the ${Delta}$ atmA mreA^MRE11 mutant due to the conidiation defect.These data indicate that atmA has a complex genetic relationshipwith these genes during the DNA replication checkpoint and supportthe notion that there are genetic interactions between atmA^ATMand ankA^WEE1, npkA, and bimE^APC1 during the DNA damage responsein A. nidulans.

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TABLE 5 Mitosis assay from A. nidulans wild-type and mutant strains

	DISCUSSION

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

The atmA^ATM loss of function causes synthetic lethality when combined with mutation in uvsB^ATR:
ATM and ATR are paralogous PIKKs that orchestrate the DNA damageresponse in eukaryotic cells (SHILOH and KASTAN 2001; MCKINNON 2004).These kinases possess both overlapping and distinct roles inthe regulation of this response. ATM and ATR respond to differenttypes of signals and they were assigned to independent pathwaysthat were parallel in structure, but with distinct inputs andoutputs (HURLEY and BUNZ 2007). Recently, it was shown thatATR responds to DSBs and that this response is ATM dependent(ADAMS et al. 2006; CUADRADO et al. 2006; JAZAYERI et al. 2006;MYERS and CORTEZ 2006). STIFF et al. (2006) showed that UV lightand HU also activate ATM and that this activation is ATR dependent.Thus, it seems these two regulatory kinases can have some degreeof communication as if they belong to an integrated molecularcircuit that can process diverse types of signals linking DNAreplication with the DNA damage response pathway (HURLEY and BUNZ 2007).In A. nidulans, we have previously shown that UvsB^ATR regulatesthe DNA damage checkpoint response, inhibits septation in predivisionalhyphae that have experienced DNA damage, and controls both theexpression and the localization of proteins involved in theprocessing and repair of DNA damage (HARRIS and KRAUS 1998;HOFMANN and HARRIS 2000; FAGUNDES et al. 2005). Recently, wecharacterized the homolog of ATM (AtmA) in A. nidulans (MALAVAZI et al. 2006,2007). In addition to its expected role in the DNA damage response,we found that AtmA is also required for polarized hyphal growth.Here, we present an analysis of the genetic interactions ofdifferent components of the A. nidulans DNA damage responsepathway with the atmA^ATM.

In Saccharomyces cerevisiae, the double-mutant tel1 mec1 (theATM and ATR homologs, respectively) is viable (MORROW et al. 1995).Furthermore, Tel1p appears to have a role in the repair of DNAdamage that is functionally redundant with that of Mec1p becausetel1 mec1 double-mutant strains are more sensitive to DNA-damagingagents than are mec1 strains (MORROW et al. 1995; SANCHEZ et al. 1996;USUI et al. 2001) and an extra copy of TEL1 partially suppressesthe DNA damage sensitivity of mec1 strains (MORROW et al. 1995).Differently from S. cerevisiae, we have shown that the doubleA. nidulans inactivation mutant atmA uvsB is nonviable. Here,we provided several examples that strongly suggest these genesare interacting and are probably partially redundant in termsof DNA damage sensing and/or repairing and polar growth. Wewere not able to introduce either a copy of the atmA gene intoa uvsB mutant or a copy of uvsB into a atmA mutant (data notshown). However, surprisingly, when atmA is overexpressed inthe uvsB101 background, the strain becomes more resistant onlyto 0.001% MMS. We are currently investigating the possible causesfor this phenomenon.

ATM function has never been linked to the establishment or themaintenance of cell polarity in yeast cells. However, recentlyENSERINK et al. (2006) and SHI et al. (2007) showed that Rad53^CHK2was involved in polar growth in S. cerevisiae and Candida albicans,respectively. We have also observed a role in these morphogeneticevents for C. albicans Mec1 but not for Atm inactivation strains(I. MALAVAZI and G. H. GOLDMAN, unpublished results). We werenot able to observe any polar growth defect in A. nidulans uvsB^ATR,chkA^CHK1, and chkB^CHK2 inactivation strains. However, everydouble mutant constructed with ${Delta}$ atmA and ${Delta}$ chkB displayed delayedpolar growth, suggesting that these two genes are importantfor coordinating morphogenetic events with DNA replication andDNA damage response during growth. But, we cannot eliminatethe possibility that endogenous DNA damage response exacerbatesthe polarization defects of AtmA mutants. Interestingly, thedouble-mutant ${Delta}$ atmA ${Delta}$ uvsB germlings have an increased number ofpolarity axes. These results once more suggest a redundant rolefor AtmA and UvsB during early morphogenetic events.

Molecular characterization of the chkA and chkB genes:
ATM and ATR are central to entire DNA damage response and directlyregulate at least two effector kinases, Chk1 and Chk2 that areresponsible for relaying the checkpoint signals (BARTEK and LUKAS 2003;AHN et al. 2004; YINHUAI and SANCHEZ 2004). These kinases arestructurally unrelated serine/threonine kinases activated inresponse to several DNA-damaging insults that regulate fundamentalcellular functions such as DNA replication and cell-cycle progression,chromatin restructuring, and apoptosis (BARTEK and LUKAS 2003).We have characterized the A. nidulans chkA^CHK1 and chkB^CHK2homologs. The A. nidulans ChkA is the first CHK1 homolog characterizedin filamentous fungi. Both A. nidulans inactivation strainsare viable. Mammalian Chk2 shares many of the Chk1 substratesand seems to function to support the role of Chk1 in the responseto genotoxic stress in addition to its role in the regulationof apoptosis in response to ionizing radiation (IR) (CHEN and SANCHEZ 2004).Yeast Chk1 responds to DNA damage that occurs in late S or G2but is inert to damage that occurs in S phase or replicationblocks; in contrast, mammalian Chk1 has much broader roles inthe response to all forms of genotoxic stress (CHEN and SANCHEZ 2004).

Our results suggest that A. nidulans ChkA and ChkB have conservedand specific biological roles during the DNA damage response.Furthermore, they display an intense level of redundancy; i.e.,when both genes were inactivated, the double mutant showed increaseddefects or epistatic relationship during the DNA damage responsedepending on its triggering agent. Actually, the model proposedby BARTEK and LUKAS (2003, p. 426) that the "‘biologicalmission’ (of Chk1 and Chk2) is one of mutual complementationand intimate cooperation, a partnership where Chk1 operatesas workhorse, while Chk2 contributes decisively yet only undercircumstances that cause DSBs," is applicable to the A. nidulansChkA and ChkB genes. However, we were not able to observe aninvolvement of ChkB in DSBs, except for its mRNA accumulationwhen A. nidulans is challenged with BLEO and CPT. Additionally,the fact that the S-phase replication checkpoint is intact at100 mM HU suggests that possibly a third kinase or a differentrelay pathway is involved in the S-phase checkpoints. Thereare still a large number of issues to be addressed before acomplete view of the A. nidulans ChkA and ChkB functions inthe DNA damage response can be understood.

It has been proposed that Chk1 is primarily regulated by ATRin response to replication blocks and UV treatment, while Chk2is regulated by ATM in response to IR-induced DSBs. This viewneeds to be modified if we consider recent studies showing thatChk1 is activated by the ATM pathway (GATEI et al. 2003) andthe phosphorylation of Chk2 in response to UV light and HU doesnot require ATM (MATSUOKA et al. 2000; WANG et al. 2006). Inresponse to DNA damage or replication stress, Chk1 is phosphorylatedand activated by ATR and/or ATM in yeasts, Xenopus, and mammals(CHEN and SANCHEZ 2004). To investigate the genetic relationshipamong AtmA and UvsB, and ChkA and ChkB, we constructed severaldouble-inactivation mutants and observed genetic interactionsamong them when these strains were tested in the presence ofgenotoxins and/or UV light. Surprisingly, we determined thatthe presence of either a ${Delta}$ chkA or a ${Delta}$ chkB mutation was enoughto suppress the intra-S-phase DNA replication checkpoint inthe ${Delta}$ atmA or ${Delta}$ uvsB mutations. Suppression of a null allele isexpected to be due to downstream mutations that activate thepathway independent of the original (suppressed) gene product(PRELICH 1999). Thus, it is possible that ChkA and ChkB arepositioned downstream of AtmA^ATM and UvsB^ATR in the intra-S-phasecheckpoint pathway, like in other organisms. However, the resultsimply that atmA and uvsB negatively control chkA and chkB forthe intra-S checkpoint (Figure 9). Our results revealed a verycomplex web of interactions in A. nidulans among the apicalprotein kinases AtmA^ATM and UvsB^ATR and the signal relay proteinkinases ChkA^CHK1 and ChkB^CHK2. It seems these proteins displayvery redundant and complementary functions during the A. nidulansDNA damage response.

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FIGURE 9.— The diagram is based on data from this article, YE et al. (1996), FAGUNDES et al. (2004, 2005), and MALAVAZI et al. (2005). The DNA damage response was divided into DNA replication checkpoint (DRC, left) and DNA repair pathways (DRP, right). As in other eukaryotic cells, the DNA damage checkpoint in A. nidulans functions via phosphorylation of the NimX^Cdc2 Y15 (YE et al. 1997). YE et al. (1996) have shown the existence of two S-phase checkpoint regulatory systems that control initiation in mitosis. One, which involves Y15 phosphorylation of both NimX^Cdc2 and BimE, prevents initiation of mitosis when DNA replication is arrested and the other restrains mitosis via Y15 phosphorylation of NimX^Cdc2 when DNA replication is slowed. Our work showed that AtmA and UvsB as well as ChkA and ChkB played redundant roles during both DRC and DRP (dashed lines). Other interactions can also be observed during DRC. BimE interacts with AtmA and the Mre11 complex (Mre11 comp.) as well as with NpkA, a Cdc2-related kinase that plays a role in cell-cycle progression during S phase in A. nidulans (FAGUNDES et al. 2004). NimX^Cdc2 (AnkA) is interacting with AtmA in the DRC but not in the same pathway. The underlined genes had increased mRNA accumulation in the DRP (right). In the DRP, AtmA interacts with the Mre11 complex and BimE interacts with both AtmA and UvsB. NpkA and AnkA^Cdc2 are interacting with AtmA in the DRP but not in the same pathway.

Genetic interactions of the AtmA^ATM with other components of the DNA damage response:
We investigated the possible genetic interactions between atmAand three other genes, bimE^APC1 (that encodes a subunit of theanaphase-promoting complex), the kinase ankA^WEE1, and the S-phasecdc-2-related kinase npkA, by constructing double mutants ${Delta}$ atmAbimE^APC1, ${Delta}$ atmA ankA, and ${Delta}$ atmA ${Delta}$ npkA, respectively. In most ofthe investigated phenotypes, we observed consistent epistaticrelationship between ${Delta}$ atmA and bimE and synergistic interactionsbetween atmA and npkA, and ankA mutations. Figure 9 summarizesthese interactions. At this moment, we can only speculate onthe molecular basis of these interactions. The interaction between ${Delta}$ atmA and bimE could reveal a relationship between DSBs and themitotic spindle checkpoint. LOBACHEV et al. (2004) have shownthat the Mre11 complex is required in vivo to hold the two endsof a broken chromosome together throughout DSB repair. The sameauthors have shown that a mutation in the Rad50 Zn-hook structureresulted in DNA ends that are dispersed in $~$ 10–20% of cells.The Mre11 complex holds broken ends together and counteractsmitotic spindle forces that can be destructive to damaged chromosomes(LOBACHEV et al. 2004). MALAVAZI et al. (2005) have shown epistaticand synergistic interactions between sldI^RAD50 and bimE^APC1at S-phase checkpoints and in response to HU and UV light. Duringmitosis in undamaged wild-type cells, the sister chromatidsare separated after proteolytic cleavage of cohesin by the pullingforces of the centromere-attached mitotic spindle (UHLMANN 2004).The cohesion of the sister chromatids is established by thecohesion protein complex during DNA replication and persistsuntil chromosome segregation (HAERING and NASMYTH 2003). Thespindle checkpoint ensures the high-fidelity transmission bythe controlled proteolytic cleavage of a subunit of the cohesioncomplex, Scc1, by separase, destroying the cohesion betweenthe sister chromatids and triggering the onset of anaphase (fora review, see YU 2002). The separase proteolytic activity isblocked by securin, and the APC in association with one of itssubstrate cofactors tags the securin proteins with polyubiquitinchains (PETERS 2002). Finally, degradation of the ubiquitinatedsecurin activates the separase (YU 2002). TRITARELLI et al. (2004)showed that ATM is involved in p53 localization to the centrosomesin mitosis and that the ATM-dependent association of p53 tocentrosomes is strictly linked to the postmitotic checkpointresponse to spindle disruption. Thus, it is possible that theobserved interaction between the atmA-inactivated strain andthe bimE7 mutant reflects an interaction between this proteinkinase and the microtubule-mediated forces through the spindlecheckpoint that would affect the transition from DSBs to chromosomebreaks.

Cell-cycle progression is coupled with the sequential activationof cyclin-dependent kinases (CDKs) (PINES 1999). ATM and ATRalso activate CHK1 and CHK2, which negatively regulate CDK1and CDK2 kinases, via the Cdc25 phosphatase family, thus enforcingthe cell-cycle arrest signal (NYBERG et al. 2002). The synergisticinteractions between atmA and npkA, and ankA mutations couldreflect the fact that critical molecular events involved inthe cell-cycle checkpoint upon DNA damage are disregulated andthus cannot inhibit the advance of the cell cycle. Recently,MAUDE and ENDERS (2005) reported that inhibitors of Cdk1/2 resultedin disparate effects on the Chk1 and Chk2 pathways. Chk1 expressionis reduced, and this effect contributed to a broad DNA damageresponse marked by activation of ATM and Chk2. These authorssupport a model where Cdk inhibitors produce DNA damage andsensitize cells to DNA-damaging agents. Thus, these resultscould explain the synergistic effects observed in the double-mutant ${Delta}$ atmA ankA. It is interesting to emphasize the synergistic interactionwith the npkA deletion mutant. NpkA appears to be a componentof the ATM/ATR signaling pathway because (i) npkA gene expressionis dependent on uvsB^ATR in the presence of camptothecin, (ii)the npkA deletion can partially suppress the HU sensitivityof the uvsB^ATR and uvsD^ATRIP mutants, and (iii) the double-mutant ${Delta}$ npkA ankA is more sensitive to genotoxins that interfere withthe function of replication forks (FAGUNDES et al. 2004). Thesynergistic effects observed between ${Delta}$ atmA and ${Delta}$ npkA indicatesthat NpkA plays a broader role in A. nidulans DNA damage response,interacting not only with uvsB^ATR but also with atmA.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

We thank José Luiz Cappelaro for technical assistancein some of the A. nidulans crosses, the two anonymous reviewersfor their suggestions, and the Laboratory of Confocal Microscopy,Faculdade de Medicina de Ribeirão Preto, University ofSão Paulo, Brazil, for the use of the confocal microscope.This research was supported by the Fundação deAmparo à Pesquisa do Estado de São Paulo, ConselhoNacional de Desenvolvimento Científico e Tecnológico,Brazil, and the John Simon Guggenheim Memorial Foundation.

LITERATURE CITED

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

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