Characterization of the three Arabidopsis thaliana RAD21 cohesins reveals differential responses to ionizing radiation

J. A. da Costa-Nunes¹^,4, A. M. Bhatt¹, S. O'Shea¹, C. E. West², C. M. Bray³, U. Grossniklaus⁴ and H. G. Dickinson¹^,*

¹Department of Plant Sciences, University of Oxford, South Parks Road, Oxford OX1 3RB, UK
²Centre for Plant Sciences, University of Leeds, Leeds LS2 9JT, UK
³School of Biological Sciences, University of Manchester, Oxford Road, Manchester M13 9PT, UK
⁴Institut für Pflanzenbiologie und Zürich–Basel Plant Science Centre, Universität Zürich, Zollikerstrasse 107, CH-8008 Zürich, Switzerland

^* To whom correspondence should be addressed. E-mail: hugh.dickinson{at}plants.ox.ac.uk

Received 28 July 2005; Accepted 4 December 2005

Abstract

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Abstract
Introduction
Materials and methods
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Discussion
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The RAD21/REC8 gene family has been implicated in sister chromatidcohesion and DNA repair in several organisms. Unlike most eukaryotes,Arabidopsis thaliana has three RAD21 gene homologues, and theircloning and characterization are reported here. All three genes,AtRAD21.1, AtRAD21.2, and AtRAD21.3, are expressed in tissuesrich in cells undergoing cell division, and AtRAD21.3 showsthe highest relative level of expression. An increase in steady-statelevels of AtRAD21.1 transcript was also observed, specificallyafter the induction of DNA damage. Phenotypic analysis of theatrad21.1 and atrad21.3 mutants revealed that neither of thesingle mutants was lethal, probably due to the redundancy infunction of the AtRAD21 genes. However, AtRAD21.1 plays a criticalrole in recovery from DNA damage during seed imbibition, priorto germination, as atrad21.1 mutant seeds are hypersensitiveto radiation damage.

Key words: AtRAD21, Arabidopsis, cohesins, DNA-damage, double-strand-break, ionizing radiation, seed

Introduction

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Abstract
Introduction
Materials and methods
Results
Discussion
Accession numbers
Supplementary data
References

The maintenance of genome integrity is dependent on accuratechromosome segregation and repair of DNA damage during the cellcycle. Both processes are essential for the faithful transmissionof the genetic information to daughter cells and for the survivalof the organism. In yeast (Schizosaccharomyces pombe and Saccharomycescerevisiae) and Caenorhabditis elegans, RAD21/SCC1/MCD1/CHO-2(from now on referred as RAD21) is one of the genes involvedin these essential functions since it has been implicated notonly in DNA double-strand break (DSB) repair (Birkenbihl andSubramani, 1992; Boulton et al., 2002) but also in sister chromatidcohesion in mitotic cells (Guacci et al., 1997; Michaelis etal., 1997; Chan et al., 2003; Mito et al., 2003). REC8, themeiotic homologue of RAD21 has also been found to be essentialfor chromosome cohesion and DNA DSB repair in meiotic cells(Molnar et al., 1995; Klein et al., 1999; Watanabe and Nurse,1999). Genes belonging to the RAD21/REC8 gene family have beenidentified in several organisms, from yeast to humans (Birkenbihland Subramani, 1992; Molnar et al., 1995; McKay et al., 1996;Guacci et al., 1997; Michaelis et al., 1997; Heo et al., 1998;Losada et al., 1998; Bhatt et al., 1999; Klein et al., 1999;Watanabe and Nurse, 1999; Warren et al., 2000; Dong et al.,2001; Pasierbek et al., 2001) supporting their central rolein cell division. Unlike most organisms, which have only onemitotic RAD21 gene, Caenorhabditis elegans (C. elegans) (Pasierbeket al., 2001), Arabidopsis thaliana (Arabidopsis; Dong et al.,2001; this study), and rice (Oryza spp.) possess three differentRAD21-like genes. By contrast, both Arabidopsis (Bai et al.,1999; Bhatt et al., 1999; Mercier et al., 2003) and C. elegans(Pasierbek et al., 2001) have only one REC8 gene important forboth sister chromatid cohesion and DNA DSB repair during meiosis.

In several organisms, the RAD21 gene is transcribed and translatedin a cell cycle-regulated fashion since sister chromatid cohesionhas to be established when RAD21 (as part of the cohesion complex)is loaded on to the nascent sister chromatids during S-phasewith the assistance of other proteins; ultimately, the loadingof this cohesin complex maintains cohesion between the two sisterchromatids (Guacci et al., 1997; Michaelis et al., 1997; Uhlmannand Nasmyth, 1998; Skibbens et al., 1999; Tóth et al.,1999; Ciosk et al., 2000; Mayer et al., 2001). In budding yeast,Xenopus, and humans this complex has been shown to contain RAD21,and three other proteins (SMC1, SMC3, and SCC3) (Guacci et al.,1997; Michaelis et al., 1997; Losada et al., 1998, 2000; Tóthet al., 1999; Sumara et al., 2000). In fission yeast the cohesincomplex lacks SCC3 (Tomonaga et al., 2000).

The cohesion between sister chromatids is maintained until themetaphase-to-anaphase transition, when serine residues at theRAD21 cleavage sites are phosphorylated (Alexandru et al., 2001)and targeted for proteolytic cleavage by the separase ESP1 (Ciosket al., 1998; Uhlmann et al., 1999, 2000; Waizenegger et al.,2000; Hauf et al., 2001). The cleavage releases the ties betweenthe two sister chromatids allowing them to be separated to oppositedirections by the mitotic spindle.

In addition to their function in chromosome segregation RAD21,and its meiotic homologue REC8, have also been implicated inDNA double-strand break (DSB) repair (Birkenbihl and Subramani,1992; Klein et al., 1999). The fission yeast rad21-45 mutantis viable under normal growth conditions but is hypersensitiveto DNA damage (Birkenbihl and Subramani, 1992), similarly buddingyeast RAD21 mutants are also sensitive to gamma rays (Heo etal., 1998). Finally, the depletion of cohesins from Xenopuscells and RAD21 from chicken cells also results in the persistenceof chromosomal breaks in gamma ray irradiated cells (Losadaet al., 1998; Sonoda et al., 2001), thus suggesting a role forRAD21 in DNA DSB repair after DSB induction. Further supportfor the role of RAD21 in DNA DSB repair comes from the observationthat in yeast cells RAD21 is specifically recruited to the DNAdamaged sites after induction of DSB in G₂ (Ström et al.,2004; Ünal et al., 2004). Previously, Kim et al. (2002)had also shown that, in human cells, SMC1 (a component of thecohesin complex) is also recruited by DNA repair proteins tothe DNA DSB damaged sites.

It is currently thought that the RAD21 DNA DSB repair activityis due to its cohesin function ensuring correct chromosome topologyand physical proximity of the sister chromatids (in the S andG₂ phases), hence facilitating DNA repair, rather than to acatalytic function of RAD21 in DNA repair. This is supportedby data from Sjögren and Nasmyth (2001) showing that RAD21per se attached to the DNA of non-joined sister chromatids isnot enough to repair DNA DSB. Despite these associations betweenRAD21 and DNA repair, very few reports have been published onhow RAD21 expression responds to DNA damaging agents. Accordingto McKay et al. (1996) expression of the human RAD21 gene isnot enhanced by exposure of diploid fibroblasts to DNA damagingagents like gamma radiation.

In this study, the cloning of three different RAD21 cDNAs fromArabidopsis, their expression profile and differential responseto DNA damage are described as well as reporting the phenotypeof the atrad21.1 mutant after exposure to ionizing radiation.

Materials and methods

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Abstract
Introduction
Materials and methods
Results
Discussion
Accession numbers
Supplementary data
References

Plant material
The ap1-1/cal-1 double mutant (Landsberg erecta) and T-DNA linessalk_044851 and salk_076116 (Alonso et al., 2003) were obtainedfrom the Nottingham Arabidopsis Stock Centre (http://nasc.nott.ac.uk/).Seedlings were grown on germination medium plates (GM; Gibco-BRL)in a growth cabinet (Sanyo Gallenkamp PLC Fi-Totron TC) witha light cycle of 16 h at 22.5 °C alternating with 8 h ofdarkness at 19.5 °C; seedling tissue was collected 7 d aftergermination. For the remaining samples, tissue was collectedfrom plants grown on soil (1:1 v:v mixture of compost and vermiculite;Levington Universal Extra Compost, Levington, UK, and SilvaperlVermiperl medium grade, respectively) and grown in a Sanyo GallenkampPLC growth cabinet in 16 h of light at 20 °C alternatingwith 8 h of darkness at 15 °C. Plant transformation wascarried out by dipping inflorescences (Clough and Bent, 1998)in Agrobacterium tumefaciens GV3101 containing pMP90RK. Planttransformants were selected on GM medium containing 30 µgml^–1 hygromycin.

DNA damage assays (ionizing radiation and UV)
Arabidopsis plants at 23-d-old were irradiated with 30 krad(300 Gy at a rate of 2.6 Gy min^–1) of gamma rays using¹³⁷Ce (RX30 55M Irradiation, Graviton Industries Lda.). Arabidopsisimbibed and stratified seeds and 5-d-old seedlings grown onGM medium were irradiated with 0, 50, 100, and 150 Gy (3.6 Gymin^–1) of X-rays using tungsten (Müller MG 150, PhilipsPW 2184/00, Monitor SN4). Aerial tissues were collected 1 hafter irradiation and used for RNA extraction as described inDoutriaux et al. (1998). UV-B irradiation of 3–4-week-oldplants was carried out as in West et al. (2000). Hypersensitivityof plants to bleomycin was assayed as described in West et al.(2002).

RNA extraction
Total RNA was extracted using guanidine hydrochloride (Logemannet al., 1987), Trizol (Gibco-BRL) or a RNeasy Plant Qiagen totalRNA extraction kit. Poly(A) RNA was purified from inflorescencesusing the PolyATract® mRNA Isolation System IV (Promega).

Cloning of AtRAD21 cDNAs
General molecular biology protocols were used as described inSambrook et al. (1989). Primers for amplifying and sequencingAtRAD21 cDNAs were based on the gene predictions obtained fromthe Arabidopsis sequencing consortium, Genscan (http://bioweb.pasteur.fr/seqanal/interfaces/genscan.html)and NetGene2 programs (http://genome.cbs.dtu.dk). Total RNAwas treated with RNase free DNase I (Gibco-BRL) and 1 µgof total RNA was used for cDNA synthesis as described in themanufacturer's protocols (AMV Reverse transcription: Promega;Superscript^TM II Gibco-BRL). Full-length cDNAs for AtRAD21.1,AtRAD21.2, and AtRAD21.3 were amplified (35 cycles) with Taq/Pwousing primers CR1 (5'-ATGTTTTACTCGCATTGTCTAG) and CR10 (5'-GACACATATACTTTAGATCGTC)for AtRAD21.1, primers ACO5 (5'-ATGTTTTATTCACATACGCTTTTGG) andACO3 (5'-TCACGTTTGAACCTTAGAAAAAAG) for AtRAD21.2, and primersAtRAD21-3-5 (5'-AGGAATGTTTTATTCGCAGTTTATA) and ATRAD21-3-3 (5'-ACCAAACTAGCTATCTGCAACTATATG)for AtRAD21.3, respectively. An aliquot of each PCR reactionwas reamplified, using the same primers, to increase the amountof PCR product, which were subsequently cloned in the pGEM-TEasy (Promega) vector and sequenced. Sequence data was assembledfrom overlapping PCR products, spanning the entire length ofthe cDNA. PCR products used to sequence the junction betweenthe 9th intron and the 10th exon in the two variants of AtRAD21.1were amplified with 35 PCR cycles using primers CR11 (5'-CAAGCTTTTTGTGGTCTGGA)and CR22 (5'-CCACAGGAACCCCTAAAGATA). The products of the AtRAD21.1splice variants were cloned in the pGEM-T Easy (Promega) vector,and sequenced.

5'-RACE and 3'-RACE products
cDNA synthesis for 5'-RACE and 3'-RACE was carried out accordingto the manufacturer's instructions (GIBCO-BRL 5'-RACE kit version2.0 or 5'/3'-RACE Kit Roche-Boehringer Mannheim). 5'-RACE ofAtRAD21.1 was performed using the Abridged Anchor Primer (5'-GGCCACGCGTCGACTAGTACGGGIIGGGIIGGGIIG; GIBCO-BRL) and 5HOM1 (5'-GCTGCATCTCTTCGCAACTTG). A secondPCR was performed using Abridged Universal Amplification Primerprimer (AUAP; 5'-GGCCACGCGTCGACTAGTAC) and 5HOM2 (5'-CTCTTCCATGTCAAACCTTTCC).3'-RACE of AtRAD21.1 was obtained with the Adaptor primer (5'-GACTCGAGTCGACATCGATTTTTTTTTTTTTT)and 3HOM1 (5'-GGAAAGGTTTGACATGGAA), followed by a second PCRwith 3HOM2 (5'-CATGAGACTTTCTCTACCA) and the same adaptor primer.5'-RACE of AtRAD21.2 was carried out with the oligo d(T) anchorprimer (5'-GACCACGCGTATCGATGTCGACTTTTTTTTTTTTTTTV) and 5CO-1.5primer (5'-CCAAGTCGAACTCGTCCAGAT). The PCR products were usedfor a second PCR using the adaptor primer (5'-GACCACGCGTATCGATGTCGAC)and 5CO-2 (5'-GCTTGAGGCAAAGTAACAGAC). A third PCR reaction wasrequired with the 5CO-4 primer (5'-GGAAACATTATATTATCAACAGTG)and the adaptor primer. 3'-RACE of AtRAD21.2 was performed asfollows, cDNA was synthesized using oligo-dT Anchor primer (5'-GACCACGCGTATCGATGTCGACTTTTTTTTTTTTTTTV),subsequently 3'-RACE cDNA was amplified using the adaptor primer(5'-GACCACGCGTATCGATGTCGAC) and 3CO-1 (5'-CTGGAGGTAGGTGGCAATTC),the amplification products were subjected to a second PCR with3CO-2 (5'-GGGAGAGCAAGAGCCTTGG) and the adaptor primer (5'-GACCACGCGTATCGATGTCGAC).These products were cloned in the pGEM-T Easy (Promega) vector,and sequenced. Similarly, the 5' and 3'-UTR of AtRAD21.3 wereamplified using the following gene-specific primers 5AT3-1 (5'-GGCACCTCAACTAATCCAGG),5AT3-2 (5'-GCAAGATCTTCAACCTGCTCT) and 5AT3-3 (5'-GCGTTGTGATCAATACCTGGA)for 5'-RACE, and 3AT3-1 (5'-GGGAGACAATGATGAAATGGATA) and 3AT3-2(5'-GCACATGACACAGGATTTTTGA) for 3'-RACE.

Predicted protein analysis
Protein sequence prediction and analysis was carried out withthe Translate tool from Expasy (http://www.expasy.ch/tools/dna.html),PSORT (http://psort.nibb.ac.jp/), PROSITE (http://www.expasy.ch//tools/scanprosite),and PESTfind (https://emb1.bcc.univie.ac.at/content/view/21/45).Protein alignment was carried out with the program ClustalX1.8(Person et al., 1997). Phylogenetic trees were constructed withthe program Phylip 3.5 (Felsenstein, 1993).

Northern analysis
Total RNA was subjected to electrophoresis on a 1.2% formaldehydeagarose gel, blotted onto Hybond-NX membrane (Amersham Pharmacia)and crosslinked by UV at 70 000 µjoules cm^–2. cDNAprobes (PCR products) specific for the AtRAD21.1, AtRAD21.2,AtRAD21.3, AtRAD51, and ß-tubulin gene family wereradiolabelled with ${alpha}$ -³²P dCTP by random priming, and RNA filterswere sequentially hybridized with AtRAD21.1, AtRAD21.3, and,finally, ß-tubulin probe, with AtRAD51 followed bythe ß-tubulin probe, or AtRAD21.2 and the ß-tubulinprobe. All filters were washed at high stringency and hybridizationsignals were detected by autoradiography with Kodak X-Omat X-rayfilm (Kodak).

Knock-out lines genotyping
T-DNA SALK line salk_044851 was genotyped using the primersLBa1 (5'-TGGTTCACGTAGTGGGCCATCG) (Alonso et al., 2003) and 51L(5'-GAGATGGTCACACAGAGAATTTAG), RBa1 (5'-GTGCAATCCATCTTGTTCAATCATG)and 51R (5'-CTCCTCTCAGGACAGTCAGTATG). The T-DNA line salk_076116was genotyped using the primers LBa1 and 16L (5'-CTGTGTCATGTGCATTTTCCATGG),RB1 (5'-ATTAGGCACCCCAGGCTTTACACTTTATG) (McElver et al., 2001),and 16R (5'-CCGTGTAGAGGATTTACAGGTTG). Plant DNA was extractedusing the Edwards et al. (1991) method.

Expression analysis by semi-quantitative RT-PCR
1 µg of total RNA (DNase I-treated) was used for the cDNAsynthesis using gene-specific primers for each AtRAD21 gene.10 µl of the (1:10 dilution of the) cDNA synthesis reactionwas added to the 40 µl of the PCR mix and the PCR reactioncarried out for 25 amplification cycles (20 cycles for the ß-tubulingene family amplification). AtRAD21-1 498 bp PCR product amplifiedwith primers: CR1 and 5HOM2; AtRAD21.2 530 bp PCR product amplifiedwith primers: ACO5 and 5-CO6 (5'-GGTTCTGTTGATTGGTCGAC); AtRAD21.3701 bp PCR product amplified with primers: ATRAD21-3–5and AT5 (5'-GATCTTCAACCTGCTCTTC); ß-tubulin-specificPCR products were amplified as controls with primers: TUB-R(5'-GTGAACTCCATCTCGTCCAT); TUB-L (5'-CCTGATAACTTCGTCTTTGG) (Knightet al., 1999). 30 µl of each PCR reaction was used forSouthern analysis, and the hybridization signals were analysedusing a Phosphorimager (Bio-Rad). For each tissue, four independenttotal RNA samples were used to synthesize the four independentcDNA synthesis reactions (RT-PCR analysis). In addition to thePhosphorimager analysis, autoradiography was also performedusing Kodak X-Omatxray film (Kodak).

RT-PCR analysis of knock-out mutants
Expression analysis of the mutants was carried out with thefollowing primers for T-DNA line salk_044851; upstream of T-DNAinsertion: CR1 and CR4 (5'-TCTAGAGTACTCATCTCAGG); downstreamof T-DNA insertion: CR11 and CR22. For the T-DNA line salk_076116the following primers were used; Upstream of T-DNA insertion:ATRAD21-3-5 and ATUP (5'-GGCTTCAGAGACTCCTTCCATCG); downstreamof T-DNA insertion: ATRAD21-3-3 and ATDW (5'-CGTCTTCTAGAAAACAGTGGATGG).TUB-L and TUB-R primers were also used. 4 µl of the (1:1dilution of the) cDNA synthesis reaction was added to the 21µl of the PCR mix and the PCR reaction carried out for28 amplification cycles (30 cycles for the AtRAD21.1 gene).

Southern analysis
Agarose gels were blotted to Hybond NX (Amersham Pharmacia)and DNA was crosslinked with UV at 70 000 µjoules cm^–2,as described in Sambrook et al. (1989). Southern blot membraneswere hybridized with the radiolabelled AtRAD21 gene-specificprobes and the ß-tubulin probe. Hybridization andwashes were carried out at high stringency.

DIF1 promoter–uidA fusion
A 535 nucleotide PCR product corresponding to the 520 nucleotidesof the DIF1 promoter and codons for the first five amino acidsof DIF1/SYN1 was cloned upstream of the uidA gene, replacingthe CaMV 35S promoter of pSLJ4D4 (Jones et al., 1992) to generatea DIF1–uidA translational fusion. The PCR amplificationintroduced a NcoI site, and also altered an alternative splicesite identified in DIF1/SYN1 (Bai et al., 1999). The promoter–uidAfusion was subcloned into the binary vector pVKH18 (Batoko etal., 2000) and introduced into Arabidopsis plants by the inflorescencedip method (Clough and Bent, 1998). 26 independent transformantswere analysed for uidA expression as described in Jeffersonet al. (1987) and Rodrigues-Pousada et al. (1993).

Results

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Abstract
Introduction
Materials and methods
Results
Discussion
Accession numbers
Supplementary data
References

Arabidopsis has three AtRAD21 genes
Three genes homologous to REC8/RAD21 were identified by BLASTsearches of the Arabidopsis thaliana genome sequence (http://www.kazusa.or.jp/kaos/and http://www.mips.gsf.de/thal/db) (The Arabidopsis GenomeInitiative, 2000) queried with the Arabidopsis REC8 homologue.Two of the RAD21 homologues are on chromosome V, AtRAD21.1 (At5g40840)and AtRAD21.3 (At5g16270), while the third, AtRAD21.2 (At3g59550)is on chromosome III. The genomic sequences of AtRAD21.1, AtRAD21.2,and AtRAD21.3 cDNA span the nucleotides 34060–38168 fromthe P1 clone MHK7 (accession number AB011477), 20212–23446of the BAC T16L24 clone (accession number AL138659), and 60806–66353of BAC clone T21H19 (accession number AL391148), respectively.

The predicted sequence of AtRAD21.1 (wild type, Col-0) was confirmedby cloning and sequencing the full-length cDNAs, and two variantswere identified which differ by a single amino acid due to anextra codon at the junction of the 9th intron and the 10th exon(variant 1; accession number AF400126). The extra codon insertsa glutamine at position 716 (⁷¹⁶Q) in the longer AtRAD21.1 variant.Both transcripts are represented equally in both open and unopenedflower RNA as approximately 50% of the clones sequenced areof each class. The adjacent 5'-untranslated region (5'-UTR)and 3’-UTR sequences were also cloned and sequenced (70bp and 184 bp, respectively). Both AtRAD21.1 variants ORF contain13 exons, spanning 2430 bp (variant 2–2427 bp) and encodea predicted protein of 810 amino acids (aa) (variant 2–809aa) (Fig. 1).

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Fig. 1. Schematic representations of AtRAD21.1, AtRAD21.2, and AtRAD21.3 genes. Exons are shown as open boxes, and introns are shown as thick black lines. The 5'- and 3'-UTR of the three RAD21 genes is shown by a thick grey line. Black arrowheads represent primers used for expression analysis by RT-PCR (CR1, ACO5, ATRAD21-3-5, 5HOM2, 5CO-6, AT5). The T-DNA insertion sites in the AtRAD21 genes, atrad21.1 (salk_ 044851) and atrad21.3 (salk_076116) is shown by a large black triangle. The filled circles identify the putative separase target consensus sequence (S/D/xExxRx) (Hauf et al., 2001

) in AtRAD21.1 that are predicted to be cleaved by the putative Arabidopsis separase. The numbers in the sequences depict the amino acid residue number in the protein sequence.

The cDNAs corresponding to AtRAD21.2 and AtRAD21.3 (Col-0) werealso cloned and sequenced, along with their 5'- and 3'-UTR sequences.AtRAD21.2 has a 208 bp long 5'-UTR and a 185 bp 3-'UTR, andcontains 12 exons and is 2079 bp long. AtRAD21.2 encodes a predictedprotein of 693 aa (accession number AF400128) (Fig. 1).

AtRAD21.3 (Col-0) has a 227 bp long 5'-UTR and a 281 bp long3'-UTR and is encoded by 15 exons and is 3093 bp long. AtRAD21.3encodes a predicted protein of 1031 aa (accession number AF400129)(Fig. 1).

Sequence analysis of AtRAD21 proteins
The two variants of AtRAD21.1 differ by a single amino acidthat does not significantly alter their predicted properties.PSORT analysis of AtRAD21.1 identified two potential nuclearlocalizing signals (NLS) (⁴⁶⁰RKRK⁴⁶³ and ⁴⁹⁰KRRNVPHTDCPERRTKRF⁵⁰⁷).AtRAD21.2 has two predicted NLS (³⁵⁵RKRK³⁵⁸ and ³⁸³RKRKK³⁸⁷)(PSORT). The largest of the three Arabidopsis RAD21 homologues,AtRAD21.3, has a single predicted NLS (⁵⁴⁶KRLRSAPRSTATKRKVL⁵⁶²;PSORT analysis). All three proteins have several phosphorylationsites each (PROSITE). These characteristics are in agreementwith the putative cohesion function of these proteins. However,none of the AtRAD21 proteins identified here have predictedserine phosphorylation sites important for cohesin cleavage(Alexandru et al., 2001). Phosphorylation of serine residuesin the ESP1 cleavage motif is necessary for the RAD21 cleavagethat precedes loss of sister chromatid cohesion (Alexandru etal., 2001). Although it was possible to identify putative consensusESP1 cleavage motifs in AtRAD21.1 (¹⁴⁸SxExxRx¹⁵⁴; ¹⁹⁵DxExxRx²⁰¹,and ²¹⁸SxExxRx²²⁴) (Hauf et al., 2001) and in the meiotic cohesinhomologue DIF1/SYN1 (Bai et al., 1999; Bhatt et al., 1999) (¹²⁴DxExxRx¹³⁰),similar putative ESP1 cleavage motifs were not identified inAtRAD21.2 and AtRAD21.3. If, however, the consensus sequencefor ESP1 cleavage has diverged at the first amino acid S/T/D/Iin the cleavage motif–/T/D/IxExxRx, there are severalputative ESP1 cleavage motifs in AtRAD21.2 and AtRAD21.3. AllAtRAD21 proteins have several PEST sequences (Rechsteiner andRogers, 1996), suggesting that these proteins are likely tobe unstable (Rao et al., 2001).

ClustalX1.8 alignment of the three AtRAD21 sequences with thoseof RAD21 proteins from other organisms show that the N and Ctermini are the most conserved (see supplementary Figs I andII at JXB online), as previously observed for RAD21 proteinsidentified in Arabidopsis and other organisms (McKay et al.,1996; Bai et al., 1999; Bhatt et al., 1999; Watanabe and Nurse,1999; Warren et al., 2000). The conserved N and C terminal sequencesof selected available plant, yeast, and animal REC8 and RAD21were aligned with ClustalX1.8, and the data were used to generatea parsimony rooted tree with Phylip using AtSPO11-1 as the outgroup(see supplementary Fig. III at JXB online). Phylogenetic analysisof the three Arabidopsis RAD21 genes revealed that AtRAD21.2(21AR2) and AtRAD21.3 (21AR3) both have closely related sequencesin the rice genome, 21ORYZ3 and 21ORYZKAA, respectively, andoccupy a position separate from DIF1/SYN1 (8AR) and the animaland yeast REC8 sequences. However, the relationship of AtRAD21.1(21AR1) sequence to other RAD21 or REC8 protein sequences wasnot clear. Finally, the increase in number of RAD21 genes inrelation to other model organisms is a common feature of bothmonocot and dicot genomes.

The three AtRAD21 genes are expressed in a wide variety of tissues
In order to determine and compare the expression profile ofthe three AtRAD21 genes, their expressions in different planttissues were analysed. RT-PCR analysis of the three AtRAD21genes shows that all three are expressed in tissues rich incells undergoing mitosis, namely 7-d-old seedlings, unopenedflower buds, open flower buds, and the rapidly proliferatinginflorescence meristem of the ap1-1/cal-1 double mutant (Bowman,1994) (Fig. 2). Although all three AtRAD21 genes show overlappingpatterns of expression, their relative levels of expressionare not similar. In plants grown under normal growth conditionsAtRAD21.3 has the highest transcript level. It was possibleto detect AtRAD21.3 transcripts in 5 µg of total RNA fromtissues of untreated (non-irradiated) seedlings (Fig. 3), whereasAtRAD21.1 mRNA could only be detected in poly-A RNA samplesof untreated inflorescences (not shown). A weak signal correspondingto the AtRAD21.2 transcript could be detected when 10 µgof total RNA from seedlings was used for northern blot analysis(Fig. 3).

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Fig. 2. RT-PCR expression analysis of the three AtRAD21 genes. AtRAD21 genes are expressed in vegetative and reproductive tissues containing dividing cells, but at different levels of expression. Autoradiograph representing the expression of all three genes, as analysed by RT-PCR using RNA extracted from 7-d-old seedlings (S), unopened flower buds (UB), open flowers (OB), and cauliflower-1/apetala1-1 inflorescence meristem tissue (C); a water control was also included in the analysis (H₂O) and two independent products for each tissue are shown. Primers specific for AtRAD21.1, AtRAD21.2, AtRAD21.3, and the RT-PCR control – ß-tubulin (Oppenheimer et al., 1988

; Snustad et al., 1992

; Knight et al., 1999

) were used to amplify the corresponding cDNAs (Fig. 1) and 30 µl of each PCR reaction was loaded per well; these products were subsequently used for Southern hybridization with the corresponding radiolabelled probes to produce the autoradiographs shown. The analysis was performed with RT-PCR products from eight independent cDNA samples and a representative result is shown; each autoradiograph was exposed to the RT-PCR products for different periods.

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Fig. 3. Transcript levels of AtRAD21.1 increase in plants exposed to ionizing radiation. The steady-state mRNA levels of AtRAD21.1 increase 1 h after ionizing radiation treatment, while AtRAD21.3 transcript levels remains mostly unchanged and AtRAD21.2 transcript levels are reduced. Autoradiographs show the steady-state RNA levels of AtRAD21.1 (a), AtRAD21.2 (b), AtRAD21.3 (c), AtRAD51 (d), and ß-tubulin (e–g) in the aerial parts of 3-week-old seedlings exposed to 300 Gy of gamma rays ( ${gamma}$ -rays) and in unexposed controls. Wild-type plants from Columbia-0 (C) and Landsberg erecta (L) ecotype were used for the analysis, and the ethidium bromide-stained gels showing equal loading are shown in (h)–(j). 5 µg of total RNA sample was loaded in each well, except for AtRAD21.2, for which 10 µg total RNA was used. RNA samples were extracted from aerial part of 3-week-old plants that had the following treatments: C, wild type Columbia ecotype (Col-0) non-irradiated; L, wild-type Landsberg ecotype (Lands.) non-irradiated; ${gamma}$ -rays C, Col-0 irradiated once with 300 Gy of gamma radiation; ${gamma}$ -rays L, Lands. irradiated once with 300 Gy of gamma radiation. The molecular weight marker (M) used was a 0.24–9.5 kb Gibco BRL RNA ladder. Autoradiographs for AtRAD21.1, AtRAD21.2, AtRAD21.3, and AtRAD51 were developed after exposure for 16 h, 14 d, 3 d and 16 h, respectively.

Ionizing radiation enhances AtRAD21.1 gene expression
Exposure of plants to DNA damage is known to increase transcriptlevels of genes implicated in DNA repair, and as rad21 mutantsidentified for several different organisms are also sensitiveto ${gamma}$ -rays (Birkenbihl and Subramani, 1992

; Heo et al., 1998

;Losada et al., 1998

; Sonoda et al., 2001

), it was tested if ${gamma}$ -rays (and X-rays), expected to induce DNA DSB damage, couldalso alter the expression levels of any of the RAD21 genes inArabidopsis.

There were specific differences in the expression of differentAtRAD21 genes after exposure to ionizing radiation. Steady-statemRNA levels for AtRAD21.1 increase in the aerial tissues ofwild-type plants 1 h after irradiation with ionizing radiation( ${gamma}$ -rays and X-rays) (Figs 3 and 4, respectively). The increasein AtRAD21.1 transcript after irradiation with ${gamma}$ -rays parallelsthe increased transcript levels of AtRAD51, a gene involvedin the homologous recombination of broken double-stranded DNA(Klimyuk and Jones, 1997; Doutriaux et al., 1998). By contrast,steady-state mRNA levels for AtRAD21.2 were reduced in ${gamma}$ -rayirradiated plants, while the AtRAD21.3 expression pattern wasnot significantly altered after exposure to ${gamma}$ -rays (300 Gy).To determine if the response of AtRAD21.1 was specific to DNADSB and not a broader response to DNA damage (ionizing radiation,X-rays and ${gamma}$ -rays, ultimately causes both double and single DNAstrand breaks via oxidative stress), wild-type Arabidopsis plantswere exposed to ultraviolet (UV-B) radiation. UV-B indirectlycauses single-strand DNA breaks (rather than DSBs) through theformation of pyrimidine dimers and oxidative damage productswhich are substrates for excision repair pathways (Britt, 1999).It was found that AtRAD21.1 expression was not altered afterplants were exposed to UV-B radiation (data not shown). Thissuggests that the increase in steady-state mRNA levels of AtRAD21.1was a specific response to DSB DNA damage induced by ionizingradiation.

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Fig. 4. Characterization of the atrad21.1 and atrad21.3 mutant lines. T-DNA insertions in both atrad21.1 and atrad21.3 homozygous mutants truncate corresponding atrad21 transcripts. (a) PCR products indicating insertion of the T-DNA into the gene AtRAD21.3 (primer pair LB 16L) and AtRAD21.1 (primer pair LB 51L). The truncated atrad21.3 transcript detected in mutant atrad21.3 plants includes part of the T-DNA sequence. (b) top panel: Expression of the truncated atrad21.1 transcript is still increased after exposure of the atrad21.1 mutant to 100 Gy of ionizing radiation (X-rays), but this truncated transcript contains only sequences upstream of the T-DNA insertion site. The reduced expression detected downstream of the mutant atrad21.1 gene could be caused by a cryptic T-DNA promoter. Bottom panel: PCR control reaction with primers specific to the AtRAD21.3 gene showing that an equivalent amount of template from each sample was used in all four PCR reactions. (c) The atrad21.3 mutant expresses a truncated atrad21.3 transcript that includes sequences up to, and upstream of the T-DNA insertion site, but does not include sequences downstream of the T-DNA insertion site. ß-tubulin primers used as control. In (a), (b), and (c) the arrow indicates the (top) contaminant genomic band. (d) Schematic representation of the T-DNA insertions and of the primers. LB and RB – T-DNA left and right border, respectively (in bold); primers for T-DNA left and right border (LB, RB); primers specific to AtRAD21.1 –CR1, CR4, 51L, 51R, CR22, CR11; primers specific to AtRAD21.3–ATRAD21-3-5, ATUP, 16L, 16R, ATDW, ATR21-3-3; primers for ß-tubulin gene family (control) –TUBL, TUBR. Samples: genomic samples (GEN); cDNA of 5-d-old seedlings in (a) and (b); cDNA samples of inflorescences in (c). 1 (atrad21.1 homozygous mutant), 3 (atrad21.3 homozygous mutant); C (Columbia-0 plants). 0G and 100G (5-d-old seedlings samples non-irradiated and irradiated with 100 Gy of ionizing radiation (X-rays), respectively).

Mutants of AtRAD21.1, but not AtRAD21.3, are sensitive to ionizing radiation
To assess the function provided by the AtRAD21 genes, lineswith T-DNA insertions (Alonso et al, 2003

) in AtRAD21.1 andAtRAD21.3 were characterized. The insertion mutant for AtRAD21.1(salk_044851) has a T-DNA inserted in the 6th exon of the gene,likely to disrupt expression of AtRAD21.1. However, despitethis insertion, atrad21.1 mutants have no obvious developmentalphenotype. atrad21.1 mutant plants are fertile, produce viableseeds and undergo normal vegetative growth. Sequencing of theleft and right borders of the T-DNA insertion site showed thatthe T-DNA insert is (Fig. 1) accompanied by an 8 bp deletionin the 6th exon of AtRAD21.1. Furthermore, AtRAD21.1 expressionanalysis in the homozygous mutant shows that the T-DNA insertionprevents expression of the full-length AtRAD21.1 transcript(Fig. 4). As AtRAD21.1 mRNA levels are increased after ionizingirradiation, it seems possible that AtRAD21.1 could have a rolein repairing DNA damage and, consequently, loss of AtRAD21.1may make mutant plants hypersensitive to DNA DSB damage. Thereforeatrad21.1 mutants were exposed to DNA damage by growing seedlingson GM containing 1 µg ml^–1 and 2 µg ml^–1of bleomycin (which causes single- and double-strand breaksin DNA), but did not observe any increase in sensitivity (datanot shown). The radiation sensitivity of atrad21.1 and wild-typeplants was also tested by exposing plants to X-rays at two differentstages of development, either as seeds or as 5-d-old seedlings.Both seeds and seedlings were exposed to several different dosesof X-rays (0, 50, 100, and 150 Gy) and their growth responsewas analysed after a fixed period. A hypersensitive responsewas consistently observed in atrad21.1 seeds exposed to sub-lethaldoses of X-rays (Fig. 5); plants grown from irradiated atrad21.1seeds also displayed a decrease in the number of true leavesand therefore showed a slight developmental delay when comparedwith seedlings germinated from wild-type irradiated seeds (seesupplementary Fig. IV at JXB online). Surprisingly, when 5-d-oldseedlings of atrad21.1 mutants were irradiated, rather thanseeds, they did not show an increased sensitivity to radiation,compared with wild-type seedlings. This suggests that the functionof AtRAD21.1 in DNA DSB repair is essential in seeds duringimbibing/germination, but not in germinated seedlings.

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Fig. 5. Radiation hypersensitive phenotype of atrad21.1 mutants. Seeds of wild-type Columbia (Col-0) plants, and atrad21.1, and atrad21.3 mutants were irradiated (100 Gy) and germinated on GM medium. Growth of the irradiated seeds was compared to unirradiated samples (0 Gy) 15 and 30 d after treatment. No differences are seen 15 d after irradiation of w.t. Col (Col-0) and the two different atrad21 mutants, apart from the general delay in development of irradiated plants. However, a phenotype was evident when plants were allowed to grow longer, and analysed 30 d after irradiation, it was clear that atrad21.1 mutants were clearly more sensitive to irradiation than either atrad21.3 or Col-0, which supports a role for AtRAD21.1 in DNA DSB repair.

As AtRAD21.3 has the highest steady-state mRNA levels amongstall three AtRAD21 genes, it seemed likely that it might providean essential mitotic function. Hence, a T-DNA insertion in AtRAD21.3from the SALK T-DNA population (salk_076116) was also characterized.It was confirmed that the insertion of the T-DNA (with two leftborders) in the 11th exon of AtRAD21.3 (Fig. 1) is associatedwith a 9 bp deletion. This insertion also disrupts AtRAD21.3transcript integrity (Fig. 4). The loss of AtRAD21.3 functiondoes not result in lethality or infertility, but mutant plantsdevelop slightly slower than wild type and, consequently, startto flower (bolting) a bit later than the wild type (data notshown). As AtRAD21.3 transcript persists after irradiation with ${gamma}$ -rays, atrad21.3 plants were also tested for sensitivity toDNA damage by exposing them (seeds and seedlings) to X-rays,or to 1 µg ml^–1 and 2 µg ml^–1 of bleomycin,respectively, and no difference was found in the bleomycin andradiation sensitivity of wild-type and mutant plants (Fig. 5)(data not shown for the bleomycin assay).

The DIF1 promoter drives expression in reproductive and vegetative tissues
DIF1/SYN1, the Arabidopsis RAD21 homologue essential only formeiosis, has been shown by RT-PCR to be expressed not only inflowers but also in vegetative tissue, namely seedlings (Baiet al., 1999; Bhatt et al., 1999). Therefore, in order to determineif DIF1 expression in seedlings correlates with actively dividingmitotic cells, and hence if its expression overlaps with thatexpected of the other AtRAD21 genes, the expression patternof the 520 bp upstream sequence of DIF1 fused to the uidA reportergene, encoding ß-glucuronidase (GUS) was investigated.This fragment contains the 5'-end of the DIF1/SYN1 transcriptthat overlaps with a flanking divergently transcribed ORF ofa glycoamidase-like gene (Bai et al., 1999), and hence it islikely that this 520 bp promoter fragment retains elements importantfor DIF1 expression. 26 independent transformants were generatedand the tissue- and stage-specific expression of this reporterwas examined in a subset of these, of which a representativesample is shown in Fig. 6. Of these 26 transformants, 11 stainedin the young anther and root tips, 19 in the emerging lateralroots, and 21 in the shoot apical meristem region. Nine displayeda puntacted-staining pattern in the basal part of the youngleaves. As expected from its function during meiosis in anthersand ovules, reporter gene expression controlled by the DIF1promoter was seen in the anthers of flower buds at stages 7–10(staging according to Smyth et al., 1990) (Fig. 6a, b), however,it was not possible to detect reporter expression in ovules.In addition to the expression in reproductive organs, GUS expressionwas also seen in the root tips (Fig. 6c), in emerging lateralroots (Fig. 6d) and at the shoot apex (Fig. 6e). The reportergene was also expressed in a punctuate pattern in developingleaves (Fig. 6e). This suggests that DIF1 expression may beassociated with dividing cells in the shoot apexes and vegetativetissue, and may possibly overlap with the expression of theAtRAD21 homologues.

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Fig. 6. DIF1 promoter–uidA expression pattern is not restricted to flowers. The DIF1 promoter–-uidA fusion was detected using a chromogenic substrate. The reporter gene was expressed in buds at inflorescences stages 7–10 (a), specifically in the anthers (b); expression was also seen in the root-tip (c) and in emerging lateral roots (d) of 7-d-old transgenic seedlings. The ß-glucuronidase protein encoded by the uidA reporter gene was also detected in young leaves (e) and around the shoot apex (e) of 7–10-d-old seedlings. Expression of DIF1 could hence overlap the expression of the AtRAD21 genes in vegetative meristematic tissues.

AtRAD21.1 and AtRAD21.3 share redundant functions
Since two of the AtRAD21 genes appear to be at least partiallyredundant for normal growth, attempts were made to isolate adouble mutant to determine if this would result in a vegetativeor reproductive phenotype, or affect the viability of a atrad21.1atrad21.3 double mutant. However, the atrad21.1 atrad21.3 doublemutants are normal in all aspects of their development and arefully fertile with normal seed set (data not shown). Thus, tounmask the mitotic function of RAD21 genes in Arabidopsis mayrequire the generation of plants mutant for three or more RAD21/REC8genes.

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Structural features of the three Arabidopsis AtRAD21 proteins
Most organisms have been reported to have two RAD21 homologousgenes, a meiotic and a mitotic one (Birkenbihl and Subramani,1992; Molnar et al., 1995; McKay et al., 1996; Guacci et al.,1997; Michaelis et al., 1997; Heo et al., 1998; Losada et al.,1998; Klein et al., 1999; Watanabe and Nurse, 1999; Warren etal., 2000). In this study, it is shown that A. thaliana, likeC. elegans (Pasierbek et al., 2001) and rice, has three RAD21homologues in addition to the meiotic REC8 homologue (Bai etal., 1999; Bhatt et al., 1999; Pasierbek et al., 2001).

All three AtRAD21 proteins have NLS, as would be expected ofproteins likely to be involved in cohesion of sister chromatids(Birkenbihl and Subramani, 1995; Uhlmann and Nasmyth, 1998;Losada and Hirano, 2001). All three AtRAD21 proteins are alsoexpected to be unstable as they have potential PEST sequencesand are predicted to have several phosphorylation sites thatmay be important for their function. In yeast, RAD21 is hyperphosphorylatedand is subsequently rapidly degraded to release sister chromatidcohesion (Birkenbihl and Subramani, 1995; Uhlmann et al., 1999,2000; Tomonaga et al., 2000). In addition to these sites, thepresence of putative separase cleavage sites in AtRAD21.1, originallyidentified for SCC1 (a RAD21 homologue) (Uhlmann et al., 2000;Hauf et al., 2001), suggests that AtRAD21.1 may also be subjectedto regulation via an ESP1 cleavage pathway. Although consensusESP1 cleavage sites were not identified in the AtRAD21.2 andAtRAD21.3 proteins, it is possible that these plant RAD21 proteinsmay have a slightly different ESP1 cleavage site from thosebased on the animal and yeast consensus sequences (Fig. 1).As Arabidopsis has a putative ESP1 homologue (Jones and Sgouros,2001; At4g22970), it is speculated that the protease-mediatedputative cleavage of Arabidopsis RAD21 proteins is also likelyto be a feature involved in the regulation of their function.Thus, the mechanism of chromosome cohesion release via ESP1cleavage of cohesion which is conserved in other organisms couldalso be conserved in Arabidopsis.

The AtRAD21.1 protein is involved in DSB DNA repair and may share redundant functions with other family members during cell division
In Arabidopsis, RT-PCR analysis of the expression for threeAtRAD21 genes shows that all three (AtRAD21.1 to AtRAD21.3)are expressed in tissues with dividing cells (Fig. 2), as wouldbe expected for genes predicted to be involved in chromosomecohesion. As DIF1/SYN1 (REC8 homologue) is expressed in vegetativeand reproductive cells (Bai et al., 1999; Bhatt et al., 1999),the overlapping expression pattern of the REC8/RAD21 genes inArabidopsis could thus provide redundancy in one or more functionsat different stages of development, namely in meristematic tissue.This appears be the case as the atrad21.1 atrad21.3 double mutantdevelops normally and is fully fertile, as would be expectedfor genes that are at least partially redundant.

For one of the Arabidopsis RAD21 genes, AtRAD21.1, an increasein expression is specifically induced by both ionizing radiation(this study) and radiation mimic agents (West et al., 2004),suggesting a role in DNA DSB repair. Furthermore, expressiondata from microarray (Affymetrix25K – www.arabidopsis.org/servletsmicroarray database) Genevestigator (https://www.genevestigator.ethz.ch/;Zimmermann et al., 2004), and AtGenExpress (http://web.uni-frankfurt.de/fb15/botanik/mcb/AFGN/atgenex.htm)emphasize that the increase in AtRAD21.1 gene expression afterexposure to ionizing radiation is probably induced directlyby DNA DSB damage rather than by oxidative damage (caused byionizing radiation) or other types DNA damage; exposure to oxidativestress per se, UV-A, UV-B, and UV-A+B do not lead to an increaseof AtRAD21.1 gene expression.

Although this study's analysis does not demonstrate that theincrease in AtRAD21.1 transcript results in a correspondingincrease in the pool of AtRAD21.1 protein at sites of DNA damage,similar to that described in yeast (Ünal et al., 2004;Ström et al., 2004), the hypersensitivity of atrad21.1mutants to ionizing radiation inducing DNA DSB damage and itsexpression enhancement as an emergency response to ionizing(and ionizing mimicking agents) suggest a role for AtRAD21.1in DNA repair, possibly by facilitating repair between homologoussister chromatids. As the radiation-hypersensitive phenotypewas only observed in atrad21.1 plants that developed from irradiatedseeds, but not in mutant plants that were irradiated after germination,it is speculated that expression of AtRAD21.1 in the irradiatedseeds is critical for a normal response to DNA damage. It isknown that seed desiccation results in genome damage, whichrequires DNA repair during the seed imbibing/germination stage(Britt, 1996; Dandoy et al., 1987). Finally, during embryogenesisthere is a 5–10-fold increase in gene expression of AtRAD21.1while the amounts of the other AtRAD21 transcripts remain unalteredin the later stages of embryo development (microarray data fromAtGenExpress: http://web.uni-frankfurt.de/fb15/botanik/mcb/AFGN/atgenex.htm);these data, taken in conjunction with the radiation-hypersensitivephenotype of atrad21.21 mutants and the increase in AtRAD21.1transcripts by radiation damage, support such a role for AtRAD21.1in the repair of DNA damage specifically during seed imbibing/germination.Irradiated atrad21.1 seedlings fail to show radiation hypersensitivity,possibly because one of the other RAD21 homologues could provideredundancy at this stage.

The increase in steady-state mRNA levels of AtRAD21.1 after ${gamma}$ -irradiation of Arabidopsis is not unique, as it has also beenobserved for several other genes like MIM, AtLigIV, AtGR1, AtRAD51,AtBRCA1, and AtKu80 after exposure to DNA DSB inducing agents(Klimyuk and Jones, 1997; Doutriaux et al., 1998; Mengiste etal., 1999; Deveaux et al., 2000; Hanin et al., 2000; West etal., 2000; Friesner and Britt, 2003; Gallego et al., 2003; Lafargeand Montané, 2003). These genes are involved in eitherhomologueous recombination (HR) or non-homologous end joining(NHEJ) DNA repair of DNA DSB. Of these, mutants for MIM, AtLigIV,AtKu80, like atrad21.1 mutants, display a hypersensitive phenotypeafter exposure to DSB-inducing agents.

Apart from the slower bolting phenotype of the atrad21.3 mutants(salk_076116) no other vegetative, or reproductive defects couldbe identified, probably due to the function provided by thetwo other AtRAD21 genes, or that of the REC8 homologue DIF1/SYN1in vegetative tissues. Since AtRAD21.3 is expressed at highlevels and is not altered by radiation, it may be involved inbasic structural roles, perhaps associated with the nuclearmatrix and/or sister chromatid cohesion (Sadano et al., 2000).If this is the case, its possible role in chromosome structuralmaintenance could explain the general delay in development,especially the delayed bolting phenotype of the atrad21.3 mutant.

Our analysis of atrad21.1 and atrad21.3 single and double mutantssuggests that the functions provided by these two AtRAD21 genesare redundant with that of other RAD21/REC8 family members forvegetative development and fecundity of Arabidopsis. It is possiblethat, apart from these two AtRAD21 genes, either AtRAD21.2,or the REC8 homologue DIF1/SYN1, both of which are expressedin overlapping domains with AtRAD21.1 and AtRAD21.3 could providesuch redundant function (Bai et al., 1999; Bhatt et al., 1999;Dong et al., 2001). However, AtRAD21.1 does have a specificfunction in DNA repair, evident only after mutant seeds areexposed to ionizing radiation, which is not compensated forby the expression of AtRAD21.3. This is in accordance with thefact that it was not possible to identify a vegetative phenotypein atrad21.1 atrad21.3 double mutants. The analysis of ArabidopsisRAD21 genes in mitosis may require the generation of plantsmutant for all three RAD21 genes and/or a quadruple mutant deficientin RAD21 and REC8 functions. This should reveal if indeed AtRAD21proteins have any role in sister chromatid cohesion during mitosisor meiosis.

Accession numbers

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The sequences of the AtRAD21 genes (Col-0) have the followingNCBI accession numbers: AF400126 (AtRAD21.1 variant 1), AF400127(AtRAD21.1 variant 2), AF400128 (AtRAD21.2), and AF400129 (AtRAD21.3).

Supplementary data

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Supplementary data are available at JXB online.

Acknowledgements

We are most thankful to Dr I Moore (for advice), Professor DrP Cook ( ${gamma}$ -rays source; University of Oxford, UK), Drs S Ferrariand M El-Shemerly (X-ray source; University of Zürich,Switzerland), and to Dr P Talhinhas (ISA, Lisboa, Portugal)for his help on phylogeny tree construction. We are also gratefulto the program PRAXIS XXI (Portugal) for providing the funding(scholarship PRAXIS XXI/BD/9484/96) to JA da C-N. Funding inHGD's laboratory is provided by the Biotechnology and BiologicalSciences Research Council, UK, and in UG's laboratory is providedby the Swiss National Science Foundation and the Universityof Zürich.

References

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Characterization of the three Arabidopsis thaliana RAD21 cohesins reveals differential responses to ionizing radiation