Replication Protein A (RPA1a) Is Required for Meiotic and Somatic DNA Repair But Is Dispensable for DNA Replication and Homologous Recombination in Rice

Replication protein A (RPA), a highly conserved single-stranded DNA-binding protein in eukaryotes, is a stable complex comprising three subunits termed RPA1, RPA2, and RPA3. RPA is required for multiple processes in DNA metabolism such as replication, repair, and homologous recombination in yeast (Saccharomyces cerevisiae) and human. Most eukaryotic organisms, including fungi, insects, and vertebrates, have only a single RPA gene that encodes each RPA subunit. Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa), however, possess multiple copies of an RPA gene. Rice has three paralogs each of RPA1 and RPA2, and one for RPA3. Previous studies have established their biochemical interactions in vitro and in vivo, but little is known about their exact function in rice. We examined the function of OsRPA1a in rice using a T-DNA insertional mutant. The osrpa1a mutants had a normal phenotype during vegetative growth but were sterile at the reproductive stage. Cytological examination confirmed that no embryo sac formed in female meiocytes and that abnormal chromosomal fragmentation occurred in male meiocytes after anaphase I. Compared with wild type, the osrpa1a mutant showed no visible defects in mitosis and chromosome pairing and synapsis during meiosis. In addition, the osrpa1a mutant was hypersensitive to ultraviolet-C irradiation and the DNA-damaging agents mitomycin C and methyl methanesulfonate. Thus, our data suggest that OsRPA1a plays an essential role in DNA repair but may not participate in, or at least is dispensable for, DNA replication and homologous recombination in rice.In a population of organisms, it is crucial to maintain the integrity of genome among individuals as well as shuffle genetic information at the population level. To maintain such genetic integrity, cells have evolved elaborate mechanisms such as base excision repair (BER; Hegde et al., 2008), nucleotide excision repair (NER; Shuck et al., 2008), homologous recombination (HR; Li and Heyer, 2008) repair, and nonhomologous end joining (Weterings and Chen, 2008) pathways to repair diverse types of DNA damage. To allow for variation, however, organisms utilize meiosis to shuffle genetic material so as to increase genetic diversity in populations and in the species.DNA double-strand break (DSB) repair is particularly important in maintaining the integrity of genome among individuals and shuffling genetic information among population, because DSBs are generated not only in meiotic cells but also from the action of certain endogenous or exogenous DNA-damaging agents and during repair of other kinds of DNA lesions by NER or BER (West et al., 2004; Bleuyard et al., 2006). The past decade has witnessed an explosion in understanding of this complex process by using yeast (Saccharomyces cerevisiae) as a model organism (Aylon and Kupiec, 2004). Cells can repair DSBs by the relatively inaccurate process of rejoining the two broken ends directly (i.e. nonhomologous end joining) or much more accurately by HR (Bleuyard et al., 2006; Wyman and Kanaar, 2006). These two pathways appear to compete for DSBs, but the balance between them differs widely among species, between different cell types of a single species, and during different cell cycle phases of a single cell type (Shrivastav et al., 2008). According to the current general model for meiotic DSB repair (Bishop and Zickler, 2004; Ma, 2006; San Filippo et al., 2008), when DSBs occur the MRN complex (composed of Mre11, Rad50, and NBS1) resects the DSBs to generate 5′→3′ single-stranded DNA (ssDNA) ends. Subsequently, the replication protein A (RPA) protein complex binds to the ssDNA ends to protect them from attack by endogenous exonucleases; then, in concert with catalysis by Rad52, Rad55, and Rad57, the recombinase Rad51 displaces RPA, resulting in the generation of a Rad51 nucleoprotein filament that in turn catalyzes the search and invasion into the recombination partner with the help of proteins belonging to the RAD52 epistasis group to form a D loop that accompanies DNA synthesis. Thereafter, at least two competing mechanisms may come into play. One is the DSB repair pathway, in which the capture of the second DSB end and additional DNA synthesis result in an intermediate that harbors two Holliday junctions. The subsequent resolution of Holliday junctions results in the formation of crossovers. Alternatively, in the synthesis-dependent strand annealing pathway, the D loop dissociates and the invading single strand with newly synthesized DNA reanneals with the other DSB end, followed by gap-filling DNA synthesis and ligation, forming only noncrossover products (Ma, 2006; San Filippo et al., 2008).RPA is comprised of three subunits of RPA1, 2, and 3, alternatively termed as RPA70, 32, and 14, respectively, according to their apparent M_rs (Wold, 1997; Iftode et al., 1999). RPA is an essential protein in various DNA metabolism pathways such as DNA replication, repair, and HR (Wold, 1997; Iftode et al., 1999). In these pathways, the most basic function of RPA is binding to ssDNA to protect it from exonucleases, and its general roles in DNA metabolism depend on its interactions with other proteins in various pathways (Wold, 1997; Iftode et al., 1999). For example, in human NER pathway, RPA binds to damaged DNA and interacts with xeroderma pigmentosum damage-recognition protein, XPA, in the damage recognition step, and then the endonucleases XPG and ERCC1/XPF are recruited to the RPA-XPA-damaged DNA complex in the excision step (He et al., 1995). Interactions of RPA with those proteins are critical in this process (Wold, 1997; Iftode et al., 1999). A great deal of protein dynamics research has indicated that the interactions between RPA and other DNA-metabolism proteins are choreographed on the ssDNA to recruit the required protein present at the proper time (Fanning et al., 2006).Human, animals, and fungi have single copy for each subunit of RPA (http://www.ncbi.nlm.nih.gov/sutils/genom_table.cgi). Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa), however, have multiple genes for most RPA subunits (Ishibashi et al., 2006; Shultz et al., 2007). Most of them have not unveiled exact function up to now. To elucidate the molecular basis of meiosis in rice, we performed a large-scale screen for sterile mutants using our T-DNA insertion mutant library (Wu et al., 2003). Previously, we reported the cloning of OsPAIR3, a novel gene required for homologous chromosome pairing and synapsis in rice (Yuan et al., 2009). Here we report the characterization of another sterile mutant with a T-DNA insertion in OsRPA1a. Our results indicate that OsRPA1a is essential for DNA repair but may play redundant roles in DNA replication and recombination in rice.