From the Cellular and Molecular Biology Group, The University of South Dakota, Vermillion, South Dakota 57069
Received for publication, March 28, 2003
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ABSTRACT |
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INTRODUCTION |
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Nucleotide excision repair is a common repair pathway that is employed to repair UV damage by both prokaryotes and eukaryotes. The evidence that plants have a repair system similar to nucleotide excision repair in human and yeast mainly comes from identification of many Arabidopsis homologues of the known yeast and human repair proteins (3). So far, mutations in only a few of these genes have been isolated and correlated with repair defects in Arabidopsis (4).
Chlamydomonas reinhardtii is a single-celled, photosynthesizing alga, which is widely used as a model system for plants. Many UV-sensitive and DNA-repair-deficient mutants of C. reinhardtii have been isolated (5, 6), but with the exception of DNA photolyase (7), none of the relevant genes have been cloned. Our goal in this project was to clone a gene that was involved in a light-independent repair pathway. Here, we report cloning of a novel gene, which is required for resistance to both UV and methyl methanesulphonate (MMS).1 Because the gene is required for the excision of cyclobutane pyrimidine dimers (CPD), we have named the gene REX1 (Required for Excision 1).
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EXPERIMENTAL PROCEDURES |
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Determination of Exon-Intron BoundariesExpressed sequence tags 1031103D12 and 1024010H12.x2 defined part of exon 1, exon 2, part of exons 3 and 6, and exons 7 and 8. The boundaries of exons 36 were determined by sequencing the PCR product obtained using a cDNA library (available at the Chlamydomonas Genetic Center, www.biology.duke.edu/chlamy_genome/) as template and exon 3 sense primer (CGGACTTGGACGAAACAACGCTCCTCAT) and exon 6 antisense primer (ATCGCCTCCTTCACGGCCGCTTCAT). The 5'-untranslated region (5'-UTR) was obtained by again using the cDNA library as template and the reverse universal sequencing primer and exon 3 antisense primer (CCGCATGAAG-GCCTTGTGTCCCA). The resulting product was re-amplified using the reverse sequencing primer and exon 2 antisense primer (TGCACGATATACACCTTGGT). All sequencing was done by the Iowa State University Sequencing Center, Ames, Iowa.
Isolation of the Genomic Regions Flanking the ble InsertFlanking regions of the ble insert in the UV-sensitive mutant 72E2 were mapped by Southern blot analysis. Genomic DNA (11) was digested with various restriction enzymes and probed with ble cDNA. Both regions flanking the insert were isolated by preparing bookshelf libraries (12) based on the restriction map and screening the resulting colonies with the ble probe. One probe from each flanking region was prepared and used for screening a Chlamydomonas BAC (bacterial artificial chromosome) genomic library, which is provided as a high density filter array. Filters are available from Clemson University (www.genome.clemson.edu).
Complementation AssaysThe UV-sensitive mutant, 72E2, was crossed with an arginine requiring strain (arg7, mating type plus) to isolate 72E2 arg7. The resulting 72E2 arg7 strain was co-transformed with 13 µg of pUC ARG7.8 and up to 18 µg of BAC DNA or up to 5 µg of the constructs shown in Fig. 1 for rescuing the UV-sensitive phenotype. The plasmid pUC ARG7.8 was derived from pARG7.8 (13) by ligation of a 7.8-kb SalI-BamHI fragment into pUC119.
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Survival CurvesCell cultures were normalized to an OD of 0.30 at 700 nm. 7 ml of cells was UV-irradiated in a 9-cm diameter Petri dish using a germicidal lamp. After appropriate dilutions, the cells were spread on tris-acetate-phosphate plates using the starch embedding method, which enhances the plating efficiency of cell wall-deficient cells (14). Plates were wrapped in aluminum foil and kept in the dark for 18 h, then grown under fluorescent light until colonies grew big enough to count. Percent survival was calculated comparing the number of colonies survived after UV exposure to the number of colonies formed by unirradiated cells.
Spot Test for Survival after UV or MMS Treatment10 µl aliquots of 1 to 3 serial dilutions of each culture grown to approximately the same cell density were spotted on either normal plates or a plate supplemented with 1.5 mM MMS. One plate was exposed to 100 J/m2 UV light and kept in the dark for 18 h before growing in the light.
Immunoassay for Detection of Removal of CPDsChlamydomonas cell cultures were normalized to an OD reading of 0.850 at 700 nm. For each cell line tested, 25 ml of liquid culture in a 14-cm diameter Petri dish was irradiated with 30 J/m2 using a germicidal UV lamp. 3 ml was removed at zero time, 6 h, and 18 h for DNA extraction (11). UV irradiation, incubations, and DNA extraction were all done under non-photoreactivating conditions. The DNA was suspended in 50 µl of 10 mM Tris and 1 mM EDTA, pH 8, plus 50 µg/ml RNase A and incubated for 1 h at 37 °C to hydrolyze RNA. DNA was reprecipitated and resuspended in 200 µl water. DNA concentration of the samples was quantitated based on fluorescence in the presence of 0.2 µg/ml ethidium bromide using a Chemi-Imager 4000 (Alpha Innotech Corp.). Known concentrations of DNA were used as standards. DNA (125 ng) in 200 µl denaturation buffer (1.5 M NaCl, 0.5 M NaOH) was spotted on a nylon transfer membrane (Nytran supercharge, Schleicher & Schuell) pretreated with 2x SSC. The membrane was treated with neutralization solution (1 M Tris, 2 M NaCl, pH 5) and baked at 80 °C, then incubated for one hour with anti-thymine dimerspecific mouse monoclonal antibody KTM53 (Kamiya Biomedical Co.) at a 1:2500 dilution, followed with one-hour incubation with horseradish peroxidase-conjugated secondary anti-mouse antibody (Bio-Rad) at a 1:2500 dilution. Chemiluminescence (ECL+plus Western blot Detection System, Amersham Biosciences) was used for detection of the primary antibodies. The signal intensity was quantitated using a ChemiImager 4000 (Alpha Innotech Corp.).
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RESULTS |
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We used a probe from the ble gene to map the flanking regions of the insert and subsequently used the bookshelf library technique (12) to isolate both flanking regions (Fig. 1). Based on the linkage analysis, the disrupted gene must be located in the proximity of the insert. Therefore, we used probes isolated from both flanking regions to screen a Chlamydomonas BAC genomic library. We found a BAC, 29e18, which contained both of the flanking regions (Fig. 1). An arginine requiring strain of 72E2 was co-transformed with pUC ARG7.8 and BAC 29e18 DNA. From multiple transformations, 27% of the transformants were UV-resistant (data not shown). Transformation with just pUC ARG7.8 plasmid gave no UV-resistant transformants. Thus, this BAC contains the gene that was disrupted or deleted in 72E2. Therefore, we used BAC 29e18 to isolate this gene. Starting with the right flanking region (arbitrarily designated as shown in Fig. 1), we did a small-scale chromosome walk toward the left flanking region. The chromosome walk revealed that the insert had caused an unusually large deletion, 57.6 kb, in 72E2. Despite such a large deletion, which eliminated 12 or 13 predicted proteins, the mutant grows at about the same rate as wild-type strains in the absence of DNA damaging agents (data not shown). We eventually isolated a 6.7 kb KpnI-EcoRV fragment (2944, Fig. 1) that was able to confer UV resistance to 72E2 (Fig. 2, A and B).
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Determining the Exon-Intron BoundariesWe have found expressed sequence tags that mapped to this 6.7-kb region. We determined the exon-intron boundaries of the gene by using the available expressed sequence tags and doing PCR using a cDNA library. As shown in Fig. 1, the gene has 8 exons and 7 introns. The predicted transcript from this region surprisingly has two open reading frames (ORFs), which are separated from each other by 50 bp. The ORF nearest to the 5' end of the transcript encodes a putative protein of 78 amino acids (8.9 kDa), whereas the other ORF encodes a protein of 305 amino acids (31.8 kDa). We called the putative proteins REX1-S (small protein) and REX1-B (big protein).
Complementation Analysis of Deletion ConstructsTo more clearly define the region required for rescue of the UV-sensitive mutant 72E2, we made a series of constructs as outlined at the bottom of Fig. 1. These constructs were transformed into 72E2 and tested for complementation by the UV spot test. The subclone 2945, which lacks exon 1 and the promoter region, did not complement the mutant cells (data not shown). Construct 2949 complements as well as 2944 (Fig. 2B). Construct 2948 is the smallest subclone that confers UV resistance to 72E2, although this complementation is only partial (Fig. 2, A and B). Subclone 2948 includes the entire ORF for REX1-S but includes only the first 7 amino acids for REX1-B (Fig. 1). This result shows that REX1-S is required for UV resistance. However, the fact that the complementation by 2948 was partial relative to the complementation by 2944, which includes both ORFs, raised some questions. Construct 2948 is missing about 500 bp at the 5' end relative to 2949, which might be important for full promoter activity. Construct 2948 also lacks the 3' UTR, which contains the polyadenylation signal that might result in an unstable mRNA. To address these questions we made a deletion construct, 2950, which has the same 5' upstream region as 2949 and also includes 283 bp of the 3'-UTR containing the polyadenylation signal but deletes the REX1-B coding region except for the first 37 amino acids. Complementation with 2950 conferred partial UV resistance to 72E2 similar to 2948 (Fig. 2B), which indicated that lack of full complementation by 2948 was not due to an incomplete promoter region or lack of a poly(A) tail. These results indirectly suggest that expression of both REX1-S and REX1-B may be necessary for the full complementation of the repair defect.
Fig. 2B illustrates that the mutant 72E2 is not only sensitive to UV but is also sensitive to the methylating agent, MMS. The recovery of resistance to MMS by 72E2 transformed with the constructs shown in Fig. 1 parallel closely the results found using UV as the damaging agent; i.e. 2944 gives nearly complete resistance, whereas constructs 2948 and 2950, which encode only REX1-S, give only partial complementation. Thus, the REX1 gene is required for resistance to both UV and MMS.
In the initial characterization of the mutant, 72E2, we monitored the repair of CPDs by alkaline agarose gel electrophoresis analysis of the DNA after digestion with T4 endonuclease V, which specifically cleaves next to CPDs (data not shown). These results showed that 72E2 was severely deficient in the rate of removal of CPDs in the dark. Using a more quantitative antibody spot test, we confirm this deficiency and show that 72E2 transformed with the constructs shown in Fig. 1 (except 2945) recover the ability to repair CPDs in the dark (Fig. 3). These results correlate very well with the survival results in that 2944 transformants, which give nearly wild-type resistance to UV, show a rate of removal of CPDs close to that of wild-type. The constructs 2948 and 2950, which encode only REX1-S, give partial UV resistance and have a rate of removal of CPDs slower than wild-type or 2944 transformants.
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Homologues of REX1 Proteins in Other OrganismsA BLAST analysis using the REX1-S protein shows that it has homologues in many organisms, including Arabidopsis, Drosophila, S. cerevisiae, mouse, and human (Fig. 4A). Surprisingly, it does not have homology to any known repair protein. REX1-B protein also has homology to Arabidopsis and rice proteins of unknown function (Fig. 4B) and lower homology to human and mouse proteins. Interestingly, there is no S. cerevisiae homologue of REX1-B. In the middle of REX1-B there is a long stretch of mainly repetitive amino acids, which is not present in Arabidopsis and rice homologues.
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DISCUSSION |
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Whether REX1-S and -B proteins have any relationship in terms of function, stability, or regulation of each other is an intriguing question. Currently, we do not have any evidence addressing this question, other than the data showing that subclones lacking REX1-B cannot complement as well as a subclone (2944), which includes the coding regions for both proteins (Figs. 2 and 3). We do not know what the precise function of REX1 might be in DNA repair. Nevertheless, we know that, whatever its function is, it must be before the excision step of the CPDs as our assays show that the mutant 72E2 cannot remove CPDs under non-photoreactivating conditions (Fig. 3, A and B). CPDs are known to be repaired by the nucleotide excision repair pathway in well studied species such as human, S. cerevisiae, and Escherichia coli (16). The yeast, S. cerevisiae, without doubt has been the most intensively studied model eukaryotic system. Recently, an international consortium has systematically deleted up to 95% of the known ORFs (17). A systematic screening of about 5000 of these deletion mutants has identified 103 genes that are required for resistance to MMS (18). A similar screen identified 31 genes that conferred sensitivity to UVC when deleted (19). The S. cerevisiae REX1 homolog is one of the about 5% of the ORFs that were not deleted in this project. Obviously, the effect on S. cerevisiae of deleting this gene will be of considerable interest. We believe that the REX1 homologs may prove to be of general importance in DNA repair.
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FOOTNOTES |
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* This work was supported by National Institutes of Health Grant 1-R15-GM059857. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Present address: Eppley Institute for Research in Cancer and Allied Diseases, University of Nebraska Medical Center, 986805 Nebraska Medical Center, Omaha, NE 68198-6805.
To whom correspondence should be addressed: Cellular and Molecular Biology Group, University of South Dakota, 414 East Clark St., Vermillion, SD 57069. Tel.: 605-677-5129; Fax: 605-677-6381; E-mail: gsmall{at}usd.edu.
1 The abbreviations used are: MMS, methyl methanesulphonate; BAC, bacterial artificial chromosome; ORF, open reading frame; UTR, untranslated region.
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ACKNOWLEDGMENTS |
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REFERENCES |
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