DSpace at VNU: A UVB-hypersensitive mutant in Arabidopsis thaliana is defective in the DNA damage response

SUMMARY To investigate UVB DNA damage response in higher plants, we used a genetic screen to isolate Arabidopsis thaliana mutants that are hypersensitive to UVB irradiation, and isolated

A UVB-hypersensitive mutant in Arabidopsis thaliana is

defective in the DNA damage response

Ayako N Sakamoto1,*, Vo Thi Thuong Lan1,†, Vichai Puripunyavanich1,‡, Yoshihiro Hase1, Yuichiro Yokota1,

Naoya Shikazono1,2, Mayu Nakagawa1, Issay Narumi1and Atsushi Tanaka1

1

Radiation-Applied Biology Division, Japan Atomic Energy Agency, Watanuki-machi 1233, Takasaki, Gumma 370-1292, Japan, and

2Advanced Science Research Center, Japan Atomic Energy Agency, 2–4 Shirakata-Shirane, Tokai, Ibaraki 319-1195, Japan

Received 6 April 2009; revised 20 June 2009; accepted 29 June 2009; published online 11 August 2009.

*

For correspondence (fax +81 27 346 9688; e-mail sakamoto.ayako@jaea.go.jp).

†

Present address: Hanoi University of Science, Hanoi, Vietnam.

‡

Present address: Thailand Institute of Nuclear Technology, Bangkok, Thailand.

SUMMARY

To investigate UVB DNA damage response in higher plants, we used a genetic screen to isolate Arabidopsis

thaliana mutants that are hypersensitive to UVB irradiation, and isolated a UVB-sensitive mutant, termed suv2

(for sensitive to UV 2) that also displayed hypersensitivity to c-radiation and hydroxyurea This phenotype is

reminiscent of the Arabidopsis DNA damage-response mutant atr The suv2 mutation was mapped to the

bottom of chromosome 5, and contains an insertion in an unknown gene annotated as MRA19.1 RT-PCR

analysis with specific primers to MRA19.1 detected a transcript consisting of 12 exons The transcript is

predicted to encode a 646 amino acid protein that contains a coiled-coil domain and two instances of predicted

PIKK target sequences within the N-terminal region Fusion proteins consisting of the predicted MRA19.1 and

DNA-binding or activation domain of yeast transcription factor GAL4 interacted with each other in a yeast

two-hybrid system, suggesting that the proteins form a homodimer Expression of CYCB1;1:GUS gene, which

encodes a labile cyclin:GUS fusion protein to monitor mitotic activity by GUS activity, was weaker in the suv2

plant after c-irradiation than in the wild-type plants and was similar to that in the atr plants, suggesting that

the suv2 mutant is defective in cell-cycle arrest in response to DNA damage Overall, these results suggest that

the gene disrupted in the suv2 mutant encodes an Arabidopsis homologue of the ATR-interacting protein

ATRIP

Keywords: checkpoint, cell cycle, ultraviolet light, ATR, DNA damage, hydroxyurea

INTRODUCTION

Plants are continuously exposed to environmental stresses

that may damage the integrity of the genome For example,

the UVB (290–320 nm) component of sunlight induces

vari-ous types of DNA damage, such as formation of cyclobutane

pyrimidine dimers (CPD) or 6-4 photoproducts (6-4PP),

which prevent DNA replication and/or cell proliferation, and

cause mutations (Britt, 1999) Plants encodes various DNA

repair enzymes, e.g photolyases (Ahmad et al., 1997;

Nak-ajima et al., 1998), DNA endonucleases (Gallego et al., 2000;

Liu et al., 2001) or DNA glycosylases (Gao and Murphy, 2001;

Garcı´a-Ortiz et al., 2001), that remove the DNA damage and

support continuous growth in harmful environments

To survive in a stressful environment, it is also important

for plants to coordinate DNA-repair activities with cell-cycle

progression Unrepaired DNA damage occurring in S phase can result in mutagenic replication, while incomplete DNA repair prior to M phase can cause chromosome loss Many eukaryotes have ‘cell-cycle checkpoint’ systems that verify whether the processes at each phase of the cell cycle have been accurately completed before progression to the next phase The majority of these checkpoint responses, which appear to be highly conserved throughout eukaryotes, are triggered by activation of two major sensor proteins, ATM (ataxia-telangiectasia-mutated) and ATR (ataxia-telangiecta-sia- and Rad3-related) ATM primary responds to DNA double-strand breaks, whereas ATR primary responds to DNA damage or agents that block DNA replication The checkpoint signals are then transferred to mediator proteins,

such as checkpoint kinase 1 or 2 (CHK1 or CHK2), through

protein phosphorylation cascades that directly regulate

cell-cycle progression

Homologues of ATM and ATR have been previously

identified in Arabidopsis thaliana (Garcia et al., 2000;

Culli-gan et al., 2004) Mutant atm plants show hypersensitivity to

c-rays, but not to UVB, aphidicolin or hydroxyurea (HU),

suggesting functional conservation of the ATM-dependent

pathway in higher plants (Garcia et al., 2003) Similarly, atr

mutants show hypersensitivity to all of these agents, which

is reminiscent of the phenotype of ATR-deficient

mamma-lian cells (Culligan et al., 2004) These results suggest that

the function of ATR is conserved in higher plants, at least in

part Interestingly, however, the atr mutant plants are viable,

in contrast to ATR knockout mice Accumulation of

CY-CB1;1:GUS fusion protein in the c-ray-irradiated wild-type

plants but not in the ATR knockout plant suggested that

the checkpoint signal regulated by ATR is transferred to the

cyclin/CDK complex (through the ATR activity) in

Arabidop-sis (Culligan et al., 2006)

In Arabidopsis, a downstream target of AtATM kinase,

AtNBS1, has been identified, and is suggested to be

involved in the signal transduction pathway triggered by

double-strand breaks (Waterworth et al., 2007) However,

there is little information about the pathway downstream of

AtATR, as homologues of neither CHK1 nor CHK2 have

been found in Arabidopsis so far Thus, the ATR-mediated

checkpoint signal pathway is largely unknown in higher

plants

Here we report the isolation and characterization of a

novel UVB-, c-ray- and HU-sensitive mutant suv2 (sensitive

to UV 2) The gene disrupted in suv2 is predicted to encode a

protein that displays similarity to mammalian

ATR-interact-ing protein (ATRIP) or fission yeast Rad26 The presence of

the potential target sequence of

phosphoinositole-3-kinase-related protein kinases (PIKKs) revealed that this protein

could be a substrate of ATR Thus, we named this gene

AtATRIP Further detailed characterization of the AtATRIP

protein could provide novel information of the checkpoint

pathway in higher plants

RESULTS AND DISCUSSION

The suv2-1 mutant is hypersensitive to DNA-damaging

agents

To isolate novel genes involved in the UV response in

higher plants, approximately 3000 M2 lines of ion

beam-irradiated Arabidopsis plants were screened for UVB

hypersensitivity under dark conditions (Sakamoto et al.,

2003) Six independent mutants isolated from this

screen-ing were tentatively named suv (sensitive to UV) The

suv2-1 mutation, the focus of this paper, mapped to the

bottom of chromosome 5, and was a single-site recessive

mutation (data not shown)

To determine the function of the gene disrupted in suv2-1,

we exposed the mutant plants to various DNA-damaging agents and observed their responses Three-day-old seed-lings were exposed to various doses of UVB or c-rays, or transplanted to new plates supplemented with various concentrations of mitomycin C (MMC) Root growth after exposure/transplantation was then measured and plotted When the plants were exposed to UVB, the root growth of suv2-1 plants was more severely inhibited than that of wild-type plants under both dark and light conditions (Fig-ure 1a,b) Similarly, the c-ray expos(Fig-ure and MMC treatment had more severe effects on suv2-1 plants than on wild-type plants (Figure 1c,d) These results suggest that the gene disrupted in suv2-1 is involved in a pathway responding to various kinds of DNA damage rather than specific DNA-repair pathways such as photoDNA-repair or excision-DNA-repair pathways

Identification of the gene responsible for the suv2 mutation

To identify the mutation present in suv2-1, we performed fine mapping by the SSLP or CAPS methods Approximately

300 UVB-sensitive F2 lines derived from a cross between suv2-1 and Ler were investigated Among the markers examined, markers on K2N11, MRA19 and K15I22 showed

no recombination in 608 chromosomes, while markers on K9E15 or MCL19 showed one or two recombination events (Figure 2a) As ion-beam irradiation often induces large chromosome rearrangements such as inversions and/or translocations (Sakamoto et al., 2003; Kitamura et al., 2004; Shikazono et al., 2005; Rahman et al., 2006), we first exam-ined whether the chromosome region surrounding these markers showed a large structural change We obtained the P1 clones MRA19 and MCL19 from Kazusa DNA Research Institute and BAC clone K15I22 from the Arabidopsis Bio-logical Resource Center (Figure 2a), and used the whole P1

or BAC DNA as a probe for genomic DNA blotting Probe MRA19 detected a band of approximately 5.3 kb that was present in the wild-type but not in suv2-1 (Figure 2b,e) Four pairs of PCR primers covering the 5.3 kb fragment were designed to test whether each sub-fragment was amplified

or not One primer pair failed to amplify the expected band, suggesting that the corresponding region was altered in the suv2-1 (Figure 2c) To identify the exact position of the rearrangement, TAIL-PCR was performed using nine sets of specific (SP) primers (Figure S1) and arbitrary degenerated (AD) primers Sequencing analysis of TAIL-PCR products revealed the structure of the chromosomal rearrangement that occurred in suv2-1 In particular, the suv2-1 chromo-some had an insertion within the region corresponding to MRA19 (Figures 2d and 3, and S1) The inserted DNA appears to have originated from two sites on chromo-some 5: a 1114 bp fragment from MHJ24 and a 996 bp fragment from MDC12 were fused and inserted into the region corresponding to MRA19 PCR analysis revealed that

ª 2009 The Authors

the authentic chromosome regions corresponding to MHJ24

and MDC12 were intact in suv2-1 (Figure 2d) This is

probably due to duplication of DNA fragments during the

repair process after ion-beam irradiation

The chromosome rearrangement in suv2-1 disrupted a

gene annotated as MRA19.1 (At5g45610) The MRA19.1 gene

originally annotated consisted of 11 exons, encoding an

unknown protein To confirm the nucleotide sequence of

MRA19.1 transcripts, we performed RT-PCR with total RNA

from wild-type plants, and determined the cDNA sequence

As a result, we found that the MRA19.1 transcript had an

additional short exon between the originally predicted

exon 1 and exon 2 The resulting new ORF consists of 12

exons encoding a 646 amino acid protein (Figure 3a) A

homology search with the amino acid sequence indicated no

significant homology to any previously reported proteins

However, analysis using a coiled-coil region prediction

program (Lupas et al., 1991) revealed that the region

surrounding the novel exon 2 had a high score for

coiled-coil structure Helical wheel analysis of the amino acid

sequence predicted a typical amphipathic helix structure

in this region, which could make a solid protein–protein

interaction surface (data not shown) In addition, the amino

acid sequence contained two SQ sequences that are known

targets of PIKK kinases These characteristics are

reminis-cent of mammalian ATR-interacting protein ATRIP or fission

yeast Rad26, both of which are involved in the damage checkpoint pathway (Figure 3b) Phylogenic analysis of this gene product and other ATRIP/Rad26 family proteins sug-gests a close relationship between them (Sweeney et al., 2009)

MRA19.1 cDNA complements the suv2 mutants

To confirm whether the disruption of the MRA19.1 gene is responsible for the suv2 phenotype, we studied another mutant line suv2-2 (SALK_077978; Figure 3a) We examined the UVB sensitivity of suv2-1, suv2-2 and their F1progeny (suv2-1/suv2-2) We found that the root growth of the suv2-1, suv2-2 and suv2-1/suv2-2 plants was indistinguishable from each other, and that these roots were shorter than those of the wild-type plants (data not shown)

To confirm whether the isolated MRA19.1 cDNA includes

a full ORF and is sufficient to complement the suv2 phenotype, the cDNA was introduced into the suv2-2 lines under the control of the 35S promoter The homozygous transgenic 35S:MRA19.1 line was isolated and examined for UVB hypersensitivity by a root-bending assay (see Experi-mental procedures) Root growth of the transgenic plants was indistinguishable from that of wild-type plants, and was significantly greater than that of the parental suv2-2 plants This result suggests that the MRA19.1 cDNA is functional and sufficient to complement the UVB sensitivity of the suv2 mutant (Figure 4)

According to publicly available microarray data [for example, the Arabidopsis eFP browser (http://bar.utoronto ca/efp/cgi-bin/efpWeb.cgi) or Genevestigator (https://www genevestigator.com/gv/user/serveApplet.jsp)], the MRA19.1 gene (At5g45610) is expressed constantly throughout the developmental stages and in various tissues When 3-day-old seedlings were exposed to 100 Gy of c-rays or

3 kJ m)2 of UVB, the MRA19.1 mRNA level was slightly increased (data not shown and Figure S2c) In addition, long-term UVB irradiation of 3-week-old plants also increased the MRA19.1 mRNA level (Figure S2c)

suv2 is reminiscent of the atr mutant The characteristics of the MRA19.1 protein suggests that this gene may be involved in cell-cycle checkpoint regulation and possibly associated with AtATR in Arabidopsis To compare the phenotype of AtATR-disrupted plants with that

of suv2, we obtained a T-DNA insertion mutant of ATR (atr-5; SALK_083543) Semi-quantitative RT-PCR analysis revealed that the level of AtATR transcripts was strongly reduced in atr-5 (Figure 2), suggesting that the AtATR gene is inacti-vated in this line

First, we examined the responses of atr-5 and suv2-1 plants to HU When the suv2-1 seedlings were transplanted onto plates including 0.25 or 0.5 mMHU, the root growth of suv2-1 seedlings was severely inhibited compared to wild-type plants (Figure 5) The growth inhibition level of suv2-1

(d) (c)

Figure 1 Sensitivity of suv2-1 to UVB, c-rays and MMC.

Three-day-old seedlings were irradiated with UVB (a, b) or c-rays (c) or

transplanted onto new plates supplemented with MMC (d) The seedlings

were grown for another 3 days under continuous white light (a, c, d) or in the

dark (b) The root growth after irradiation or transplantation was measured

using NIH Image, and expressed as a percentage of the mean length of

non-irradiated wild-type roots or wild-type roots on non-supplemented plates.

Each value is the mean  SD of 15–25 measurements.

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was very similar to that of atr-5 plants Moreover, the growth

of an atr-5 suv2-1 double mutant was indistinguishable from

that of 1 and atr-5 single mutants In addition, the

suv2-1 plants were hypersensitive to aphidicolin, similar to atr-5

plants (data not shown) These results are consistent with

the possibility that the gene disrupted in suv2 is involved in

the same pathway as AtATR for tolerance of replication

inhibitors

To investigate the possible roles of the gene disrupted in

suv2, we introgressed the CYCB1;1:GUS gene construct, a

marker of G2/M progression (Colo´n-Carmona et al., 1999),

into the suv2-1 and atr-5 backgrounds Transgenic plants in

wild-type, suv2-1 or atr-5 background were treated with

c-rays, and GUS expression was observed 2–24 h after

treat-ment When the wild-type background plants were treated

with 100 Gy of c-rays, several cells in the root tip started to

accumulate CYCB1;1:GUS protein at 2 h, resulting in spotted

patterns of GUS staining (Figure 6a) At 4 h, the GUS

staining became uniform and spread to throughout the root

tip This staining pattern was still seen even at 24 h,

suggesting G2 cell-cycle arrest in almost all cells in the

wild-type root tip at 24 h post-irradiation In contrast, the staining patterns in the suv2-1 and atr-5 background were significantly weaker than those in the wild-type background (Figure 6a) The staining in suv2-1 and atr-5 roots was reduced 6–24 h after the c-ray treatment when wild-type roots still showed uniform staining These results suggest that many of the cells in the suv2-1 and atr-5 root meristems failed to arrest in G2in the presence of double-strand breaks

In addition, we observed the GUS expression patterns of aphidicolin-treated plants Similar to c-radiation treatment, the suv2-1 and atr-5 plants displayed less overall GUS staining than observed in wild-type plants (Figure 6b) Taken together, these results strongly support the possibility that the gene disrupted in suv2 is involved in a pathway that regulates cell-cycle progression when DNA is damaged or when replication is disturbed

By contrast, GUS expression after UVB treatments was not significantly different among wild-type, suv2-1 and

atr-5 (Figure 6c), which is inconsistent with the severe root growth inhibition of suv2-1 and atr-5 by UVB irradiation The relatively weak GUS staining in wild-type roots could

(a)

(b)

(c)

Figure 2 Mapping analysis and detection of the chromosomal rearrangement.

(a) Mapping analysis of the suv2-1 mutation suv2-1 was mapped to the bottom of chromo-some 5 An approximately 700 kb region of chromosome 5 (positions 18 300 000–

19 000 000) and major BACs (filled arrows) are shown, as well as the recombination frequencies (numbers) No recombination was observed for the K2N11, MRA19 and K15I22 markers (b) Restriction map of MRA19 The vertical lines show the restriction sites for EcoO109 I The numbers show the size of major fragments The 5.3 kb fragment that was absent in the Southern blotting analysis with suv2-1 DNA was analyzed further.

(c) PCR analysis of suv2-1 The horizontal and vertical lines show the 5.3 kb fragment and the restriction sites of EcoO109 I, respectively The horizontal arrows indicate the two annotated ORFs present in this region The filled rectangles indicate the regions amplified by PCR with

suv2-1 DNA The open rectangle indicates the region that was not amplified by PCR with suv2-1 DNA (d) Chromosome rearrangement in the suv2-1 mutant Two DNA fragments from the regions corresponding to MDC12 and MHJ24 were dupli-cated and inserted into a site in MRA19 Arrows indicate the direction of the fragments The diagram is not drawn to scale.

(e) Southern blot analysis with wild-type (Col) and suv2-1 DNA The genomic DNA was digested with EcoO109 I and hybridized with a probe prepared from P1 clone MRA19 The 5.3 kb band (asterisk) present in the Col DNA was absent in suv2-1, and a band of approximately 6 kb appeared instead (arrow).

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be due to cell-cycle arrest that occurs before G2 (i.e in

S phase)

The MRA19.1 gene product dimerizes through the

coiled-coil domain

The presence of a coiled-coil domain in the MRA19.1

protein suggested that this protein might form a multimer

inside the cell To examine this possibility, we used a yeast two-hybrid system A full-length or partial MRA19.1 cDNA was sub-cloned into two types of destination vector (pDEST22 or pDEST32) to express the cDNA as fusion proteins with a DNA-binding domain (BD) or activation domain (AD) When the full-length sequence of MRA19.1 cDNA was inserted into both plasmids, yeast cells harboring both plasmids (BD-F and AD-F) could survive on the selection medium, suggesting the presence of a pro-tein–protein interaction between the MRA19.1 proteins (Figure 7) When the N-terminal part of MRA19.1 covering the coiled-coil region was fused with AD (AD-NT) and combined with BD-F, yeast cells harboring both plasmids also survived on the selection medium, although growth was slower compared to the cells carrying BD-F and AD-F However, the yeast cells carrying AD-NT2 or AD-C, which lacked the coiled-coil domain, together with BD-F could not survive on the selection medium (Figure 7) In addition, the combination of BD-NT and AD-NT also allowed the yeast to survive on the selection medium (data not shown) These results suggest that the MRA19.1 protein forms multimers in yeast cells through the coiled-coil domain However, the more vigorous growth of yeast cells carrying BD-F and AD-F than those carrying BD-F and AD-NT suggests that domains other than the coiled-coil domain may contribute to stronger subunit interactions (Figure 7)

AtATRIP is a member of ATRIP/Rad26 protein family Human ATRIP has been identified as an ATR-interacting protein that co-localizes with ATR in intra-nuclear foci

(a)

(b)

Figure 3 Structure of the MRA19.1 gene and comparison of the MRA19.1

protein with proteins of the ATRIP/Rad26 family.

(a) Structure of the MRA19.1 gene, predicted ORF and insertions in suv2-1 and

suv2-2 The MRA19.1 gene consists of 11 originally annotated exons (open

boxes) and one newly identified exon (exon 2, filled box), which encodes a

646 amino acid protein (bottom) The region predicted to form a coiled-coil is

shaded The stars indicates putative target sites of PIKK The suv2-1 mutant

has an insertion of a 2110 bp fragment in intron 7, while suv2-2 has a T-DNA

insertion in exon 10.

(b) Comparison of the predicted MRA191 protein with ATRIP/Rad26 family

proteins The structures of Homo sapience (human) ATRIP (NP_569055),

Drosophila melanogaster (fly) MUS304 (NP_524135), Saccharomyces

cerevisiae (budding yeast) DDC2 (LCD1; NP_010787) and

Schizosaccharo-myces pombe (fission yeast) Rad26 (CAA54058) are compared with that of

MRA19.1 The region predicted to form a coiled-coil is shaded The stars

indicate the positions of SQ/TQ motifs.

Figure 4 UVB sensitivities of wild-type, suv2 and suv2 carrying the

35S:MRA19.1 gene.

Three-day-old seedlings were irradiated with 2 kJ m)2of UVB and grown for

another 3 days under continuous white light The root growth after the

irradiation was measured using NIH Image Each value is the mean  SD of 8–

20 measurements.

Figure 5 HU sensitivities of wild-type, atr, suv2 and the atr suv2 double mutant.

Three-day-old seedlings were transplanted onto new plates supplemented with 0.125–0.5 m M HU The seedlings were grown for another 3 days under continuous white light The root growth after transplantation was measured using NIH Image, and expressed as a percentage of the mean length of wild-type roots on the non-supplemented plates Each value is the mean  SD of 18–20 measurements.

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following DNA damage or inhibition of replication (Cortez

et al., 2001) Reducing ATRIP and consequently ATR levels

by the use of small interfering RNAs resulted in the loss of a

checkpoint response to DNA damage, suggesting that ATRIP

and ATR are mutually dependent partners in cell-cycle

checkpoint signaling pathways (Cortez et al., 2001) Mec1

and Rad3 are homologues of ATR in Schizosaccharomyces

pombe and Saccharomyces cerevisiae, respectively (Bentley

et al., 1996), and their respective partners, Ddc2 and Rad26,

are also thought to be homologues of ATRIP (Figure 3b)

ATRIP dimerizes through the coiled-coil motif (Itakura et al.,

2005), and interacts with ATR with its N-terminal region

(Itakura et al., 2004a) ATRIP is phosphorylated in an

ATR-dependent manner (Itakura et al., 2004b) Likewise, Rad26 or

Ddc2 are phosphorylated in a Rad3- or Mec1-dependent

manner, respectively (Edward et al., 1999; Paciotti et al.,

2000) The serine residues in the conserved TQ/SQ sequence

are targets for direct modification by ATR in vitro (Itakura

et al., 2004b) Activated ATR phosphorylates a number of

proteins, including mediators or effector kinases, through the TQ/SQ sequences (Bao et al., 2001; Zhao and Piwnica-Worms, 2001), which transmits the checkpoint signal to the cell-cycle regulators

The phenotype of the suv2 mutant suggests a close functional interaction with AtATR and involvement in the checkpoint pathway The suv2 mutant showed reduction of

G2/M arrest after c-ray exposure or aphidicolin treatment, similar to atr mutants Both suv2 and atr single mutants and the double mutant displayed indistinguishable sensitivity to UVB and HU Moreover, MRA19.1 (SUV2) proteins dimerize

in yeast cells through the coiled-coil domains The amino acid sequence of MRA19.1 has two instances of the SQ sequence that is a potential target of PIKKs, including ATR The amino acid sequence surrounding the two SQs is well conserved among plant cell-cycle-related genes (Table 1), suggesting that this motif is functional in the signal transduction pathway in plants These lines of evidence strongly suggest that the protein encoded by MRA19.1 is a member of the ATRIP/Rad26 family Thus, we renamed this gene AtATRIP Root growth arrest and checkpoint response

After exposure to the DNA-damaging agents or replication inhibitors, the root growth rate of wild-type plants was slightly reduced compared to that of non-treated plants (Figures 1 and 5) In agreement with this, abundant accumulation of CYCB1;1:GUS in c-irradiated or aphidico-lin-treated wild-type roots was observed, suggesting that a correct checkpoint response occurred in the meristematic tissues (Figure 6a,b) Thus, reduced root growth in the wild-type root is thought to be due to temporal arrest

of the cell cycle by checkpoint responses Similarly, the root growth of atr and suv2 plants treated with the

(b)

(a)

(c)

Figure 6 Expression of CYCB1;1:GUS after c-ray, UVB or aphidicolin

treatment.

Wild-type (Columbia), atr or suv2 seedlings carrying the CYCB1;1:GUS gene

were either exposed to UVB or c-rays, or placed in liquid medium containing

aphidicolin After treatment and growth, the seedlings were fixed with 90%

acetone and stained in X-Gluc solution.

(a) Expression of CYCB1;1:GUS after c-ray exposure Irradiated (100 Gy) or

mock-irradiated (0 Gy) seedlings were grown under continuous white light for

the indicated period, then fixed and stained.

(b) Expression of CYCB1;1:GUS after aphidicolin treatment Seedlings were

placed in liquid medium supplemented with 0.1% DMSO (0 lg ml)1) or 12 lg

ml)1aphidicolin dissolved in DMSO (12 lg ml)1) for 24 h, then fixed and

stained.

(c) Expression of CYCB1;1:GUS after UVB exposure Irradiated (2 kJ m)2) or

mock-irradiated (0 kJ m)2) seedlings were grown under continuous white

light for 6 h, then fixed and stained.

Figure 7 Dimer formation of MRA19.1 proteins in yeast cells.

Full-length (F) MRA19.1 cDNA was used to prepare a bait plasmid Full-length (F) MRA19.1 cDNA, the N-terminal region containing the putative coiled-coil region (NT), the C-terminal region (CT) and the N-terminal region without the putative coiled-coil region (NT2) were used to prepare prey plasmids Combinations of bait and prey plasmids were introduced into yeast cells to express fusion proteins At least three independent clones were chosen randomly and grown on non-selection medium (NSM) or selection medium (SM) to examine the interaction between the fusion proteins.

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DNA-damaging agents or replication inhibitors was also

inhibited compared to non-treated plants (Figures 1 and

5) In these mutants, CYCB1;1:GUS accumulation, induced

by c-irradiation or aphidicolin, was less than that in

wild-type plants (Figure 6a,b) At first glance, this may seem

consistent with the view that disruption of ATR or AtATRIP

allows the root cells to grow without cell-cycle arrest

However, this is a paradoxical situation because the root

growth was actually more severely inhibited by

DNA-damaging agents or replication inhibitors in those

mutants than in wild-type

There are several possible explanations for this One

possibility is that the some cells fail to arrest at G2/M but

instead are arrested at G1/S in the atr and suv2 plants It has been suggested that HU treatment induces G1arrest in addition to G2arrest in atr mutant plants (Culligan et al., 2004) It is possible that the c-irradiated atr and suv2 plants may be arrested at G1phase, and recovery from this arrest may be delayed Another possibility is that the cells that failed to arrest at G2/M accumulate DNA damage and/or chromosome defects, resulting in inactivated cells (which exit the cell cycle) or cell death Culligan et al (2004) reported that cell death occurs in aphidicolin-treated atr plants In addition, Curtis and Hays (2007) detected inactivated cells in UVB-irradiated wild-type roots by propidium iodide staining These lines of evidence support the view that cell inactivation or death may cause root growth inhibition in atr and suv2 plants

Although the root growth of wild-type plants was inhib-ited by irradiation with 2 kJ m)2 of UVB (Figure 1a,b), induction of CYCB1;1:GUS accumulation by UV- rradiation was much weaker than that caused by c-irradiation or aphidicolin treatment (Figure 1c and data not shown) This could be because the UV-irradiated cells are arrested at a different phase to G2/M It is known that UV irradiation arrests the cell cycle at various stages in other organisms (Siede et al., 1994; Orren et al., 1995; Heffernan et al., 2002) Thus, UVB treatment may bring about cell-cycle arrest at G1

or S phase rather than, or in addition to, G2phase in wild-type plants, although it is still unclear why more severe growth inhibition was seen in the atr and suv2 roots versus wild-type plants Further analysis with various cell-cycle markers is required to evaluate the mechanism of cell-cycle checkpoints in higher plants

EXPERIMENTAL PROCEDURES Plant materials and mutant isolation

The wild-type plant used in this study was Arabidopsis thaliana Columbia (Col) The suv2-1 mutant (Col) was isolated from the carbon ion-irradiated M 2 seed stocks described previously (Sakamoto et al., 2003) The suv2-2 (SALK_077978) and atr-5 (SALK_083543) mutants were provided by Arabidopsis Biological Resource Center.

Mapping analysis and segregation test

The suv2-1 plant was crossed with the Landsberg erecta (Ler) eco-type to obtain an F 2 genetic mapping population F 2 plants from this cross were grown, and DNA was extracted from individual plants for genetic marker analysis The individual plants were then allowed to self-pollinate to obtain F 3 seeds (F 2 line seed pool) Approximately ten F 3 seedlings from each F 2 line were examined for UVB sensitivity using a root-bending assay (Britt et al., 1993) F 2 lines for which all seedlings displayed a UVB-hypersensitive phenotype (and there-fore homozygous for suv2-1) were used to establish the genetic mapping population of 304 lines To determine the genetic map location of suv2-1, this mapping population was analyzed using SSLP (Bell and Ecker, 1994) or CAPS (Konieczny and Ausubel, 1993) genetic markers The sequences of these PCR-based markers

Table 1 Conserved SQ/TQ sequence in plant cell-cycle-related

proteins

Protein

Position

Rice hypothetical

protein (Indica)

Rice hypothetical

protein

(Japonica)

et al (2007)

et al (2004)

et al (2004)

et al (2004)

et al (2007)

275, 278 EDISSMSQDSQFGEINR

et al (2005)

ª 2009 The Authors

are listed in the TAIR database (http://www.Arabidopsis.org/) or in

Table S1.

The suv2-1 plant was back-crossed with the parent Columbia, and

approximately 100 F 2 plants derived from this cross were grown

and self-pollinated to produce F 2 lines More than 20 seedlings per

F 2 line were examined for UVB sensitivity, and the lines in which all

seedlings showed UV sensitivity were identified as homozygous

UV-sensitive lines The number of UV-sensitive lines and other lines

was examined by v2test.

Isolation of MRA19.1 cDNA and complementation test

To isolate the full-length MRA19.1 cDNA, total RNA was extracted

from wild-type plants and used in RT-PCR reactions with primers

RT-F1 (5¢-AACCAAGGTCTTCAAATTTACA-3¢) and RT-R1

(5¢-TACT-ATGCTCCTTCAATCAAAAT-3¢) The RT-PCR products were

sub-cloned into pGEM-T vectors (Promega, http://www.promega.com/)

and sequenced The original full-length cDNA contained four PCR

errors, which were removed by digesting the fragment with

restriction enzymes and replacing them with independently

ampli-fied short PCR products.

To transfer the MRA19.1 cDNA into the entry vector, the cDNA

was re-amplified using primers

5¢-CACCATGGCGAAGGACGACA-ATAA-3¢ and 5¢-TCATATAGTATTATCACC-3¢, and transferred into

the pENTR/D-TOPO vector (Invitrogen, http://www.invitrogen.com/).

For the complementation test, the inserts were transferred into

binary vector pB7WG2 (Karimi et al., 2002), and used to transform

Agobacterium strain GV3101 The suv2-2 plants were infected with

pB7WG2-transformed Agrobacterium, and T 1 plants were selected

on selection medium (1 · MS, 1 · B5 vitamin mix, 2.5% sucrose,

0.2% gellan gum, 0.02 mg ml)1of glufosinate ammonium, pH 6.3).

Coiled-coil region prediction and helical wheel analysis

Prediction of coiled-coil regions was performed at http://www.

ch.embnet.org/software/COILS_form.html (Lupas et al., 1991)

Heli-cal wheel analysis was done according to the Schiffer-Edmundson

wheel model (Schiffer-Edmundson, 1967).

Analysis of plant sensitivities to UVB, c-rays, MMC and HU

Seeds were set on nutritive agar plates (2% sucrose, 1.5% agar,

0.1% v/v commercial nutrient Hyponex (Hyponex Corporation,

http://www.hyponex.co.jp/link/index.html) and grown vertically

under continuous white light (approximately 40 mE m)2s)1) for

3 days at 23C For analysis of UVB sensitivity, seedlings were

exposed to UVB from a UV lamp (CSL-30B; COSMO BIO Co Ltd,

http://www.cosmobio.co.jp/index_e.asp) at a dose rate of

approxi-mately 0.25 kJ m)2min)1 To test c-ray sensitivity, 3-day-old

seed-lings were irradiated with c-rays from a 60 Co irradiation facility

(Japan Atomic Energy Agency, http://www.jaea.go.jp/english/

index.shtml) with a dose rate of 100 Gy h)1 To test MMC or HU

sensitivity, 3-day-old seedlings were transplanted to the surface of

nutritive agar plates supplemented with MMC or HU After

irradi-ation or transplantirradi-ation, the plates were immediately positioned

vertically so that the new root growth was at right angles to the

previous growth The plants were then incubated in the dark or

under continuous white light for 3 days at 23C, and new root

growth was measured using NIH Image version 1.62 (http://rsb.

info.nih.gov/nih-image/).

Expression of CYCB1;1:GUS

The CYCB1;1:GUS construct was introgressed to the atr-5 or suv2-1

background by genetic crossing each mutant to a

CYCB1;1:GUS-containing Columbia line To detect GUS expression after DNA

damage or cell-cycle inhibition, 3-day-old seedlings were exposed

to UVB or c-rays or put into liquid medium (2% sucrose, 0.1% v/v commercial nutrient) containing 12 lg ml)1aphidicolin After the indicated period, the plants were fixed with 90% acetone for 30 min, washed with 0.1 M sodium phosphate buffer (pH 7.2), and soaked overnight in X-Gluc solution [0.1 M sodium phosphate buffer (pH 7.2) with 0.1% Triton X-100, 0.05% sodium azide, 0.5 m M potassium hexacyanoferrate (III), 0.5 m M potassium hexacyanoferrate (II) tri-hydrate and 0.95 m M 5-bromo-4-chloro-3-indoxyl-b- D- glucuronic acid cyclohexylammonium salt) Seedlings were then washed in 70% ethanol overnight to clear the tissue, and GUS expression in the root tip was observed under light microscopy.

Yeast two-hybrid assay

Dimer formation of MRA19.1 was examined using the Pro-Quest two-hybrid system (Invitrogen) Full-length or partial-length MRA19.1 cDNAs were amplified using PfuTurbo DNA polymerase (Agilent Technologies, http://www.home.agilent.com) and cloned into pENTR/D-TOPO or pENTR/SD/D-TOPO (Invitrogen) The inserts were then transferred to pDEST22 or pDEST32 using Gateway LR Clonase II (Invitrogen) to prepare bait and prey plasmids Yeast strain MaV203 was transformed with a pairwise combination of bait and prey plasmids, and screened on SC-Leu-Trp medium according

to the instructions in the ProQuest Two-hybrid System (Invitrogen).

To detect the interaction between two fusion proteins, the yeast clone harbouring two plasmids were grown in liquid medium for

20 h, and the cells were harvested and resuspended in water Yeast cell suspension (5 ll at an absorbance at 600 nm of approximately 0.2) was dropped on selection medium (SC-Leu-Trp-His supple-mented with 25–50 m M 3-aminotriazole) or non-selection medium (SC-Leu-Trp), and incubated at 30C for 3 days.

ACKNOWLEDGEMENTS

We thank Anne B Britt (University of California, Davis) and Kevin M Culligan (University of New Hampshire) for critical reading of this manuscript We also thank Chihiro Suzuki and Akari Nakasone for their technical assistance, and Yutaka Oono for helpful comments.

We acknowledge Peter Doerner (University of Edinburgh) for pro-viding CYCB1;1:GUS transgenic plants, the Arabidopsis Biological Resources Center for providing the Arabidopsis T-DNA insertion mutants and BAC clones, and Kazusa DNA Research Institute for providing the P1 clones MRA19 and MCL19 This work was partially supported by a grant from the Japan Society for Promotion of Science (19570049) to A.N.S.

SUPPORTING INFORMATION

Additional Supporting Information may be found in the online version of this article:

Figure S1 Detection of the insertion in the suv2-1 mutant Figure S2 Structure of the AtATR gene and semi-quantitative RT-PCR analysis of AtATR and MRA19.1.

Table S1 Nucleotide sequences for PCR primers.

Table S2 PCR primers to detect chromosome rearrangement Table S3 Specific primer for TAIL-PCR.

Please note: Wiley-Blackwell are not responsible for the content or functionality of any supporting materials supplied by the authors Any queries (other than missing material) should be directed to the corresponding author for the article.

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The Genbank accession number for the AtATRIP mRNA is AB492859

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