The evolutionarily conserved zinc finger motif in the largest subunit of human replication protein A is required for DNA replication and mismatch repair but not for nucleotide excision repair

Zinc finger of replication protein A, a non-DNA binding element, regulates its DNA binding activity through redox

Eukaryotic replication protein A (RPA) is a single-stranded DNA-binding protein with multiple functions in DNA replication, repair, and genetic recombination. RPA contains an evolutionarily conserved 4-cysteine-type zinc finger motif (X(3)CX(2-4)CX(12-15)CX(2)C) that has a potential role in regulation of DNA replication and repair (Dong, J., Park, J-S., and Lee, S-H. (1999) Biochem. J. 337, 311-317 and Lin, Y.-L., Shivji, M. K. K., Chen, C., Kolodner, R., Wood, R. D., and Dutta, A. (1998) J. Biol. Chem. 273, 1453-1461), even though the zinc finger itself is not essential for its DNA binding activity (Kim, D. K., Stigger, E., and Lee, S.-H. (1996) J. Biol. Chem. 271, 15124-15129). Here, we show that RPA single-stranded DNA (ssDNA) binding activity is regulated by reduction-oxidation (redox) through its zinc finger domain. RPA-ssDNA interaction was stimulated 10-fold by the reducing agent, dithiothreitol (DTT), whereas treatment of RPA with oxidizing agent, diazene dicarboxylic acid bis[N,N-dimethylamide] (diamide), significantly reduced this interaction. The effect of diamide was reversed by the addition of excess DTT, suggesting that RPA ssDNA binding activity is regulated by redox. Redox regulation of RPA-ssDNA interaction was more effective in the presence of 0.2 M NaCl or higher. Cellular redox factor, thioredoxin, was able to replace DTT in stimulation of RPA DNA binding activity, suggesting that redox protein may be involved in RPA modulation in vivo. In contrast to wild-type RPA, zinc finger mutant (cysteine to alanine mutation at amino acid 486) did not require DTT for its ssDNA binding activity and is not affected by redox. Together, these results suggest a novel function for a putative zinc finger in the regulation of RPA DNA binding activity through cellular redox.

Cryptosporidium parvum possesses a short-type replication protein A large subunit that differs from its host

Replication protein A (RPA) consisting of three subunits is a eukaryotic single-stranded DNA (ssDNA)-binding protein involved in DNA replication, repair and recombination. We report here the identification and characterization of a RPA large subunit (CpRPA1) gene from the apicomplexan Cryptosporidium parvum. The CpRPA1 gene encodes a 53.9-kDa peptide that is remarkably smaller than that from other eukaryotes (i.e. approximately 70 kDa) and is actively expressed in both free sporozoites and parasite intracellular stages. This short-type RPA large subunit has also been characterized from one other protist, Crithidia fasciculata. Three distinct domains have been identified in the RPA large subunit of humans and yeasts: an N-terminal protein interaction domain, a central ssDNA-binding area, and a C-terminal subunit-interacting region. Sequence analysis reveals that the short-type RPA large subunit differs from that of other eukaryotes in that only the domains required for ssDNA binding and heterotrimer formation are present. It lacks the N-terminal domain necessary for the binding of proteins mainly involved in DNA repair and recombination. This major structural difference suggests that the mechanism for DNA repair and recombination in some protists differs from that of other eukaryotes. Since replication proteins play an essential role in the cell cycle, the fact that RPA proteins of C. parvum differ from those of its host suggests that RPA be explored as a potential chemotherapeutic target for controlling cryptosporidiosis and/or diseases caused by other apicomplexans.

Eukaryotic DNA mismatch repair

Eukaryotic mismatch repair (MMR) has been shown to require two different heterodimeric complexes of MutS-related proteins: MSH2-MSH3 and MSH2-MSH6. These two complexes have different mispair recognition properties and different abilities to support MMR. Alternative models have been proposed for how these MSH complexes function in MMR. Two different heterodimeric complexes of MutL-related proteins, MLH1-PMS1 (human PMS2) and MLH1-MLH3 (human PMS1) also function in MMR and appear to interact with other MMR proteins including the MSH complexes and replication factors. A number of other proteins have been implicated in MMR, including DNA polymerase delta, RPA (replication protein A), PCNA (proliferating cell nuclear antigen), RFC (replication factor C), Exonuclease 1, FEN1 (RAD27) and the DNA polymerase delta and epsilon associated exonucleases. MMR proteins have also been shown to function in other types of repair and recombination that appear distinct from MMR. MMR proteins function in these processes in conjunction with components of nucleotide excision repair (NER) and, possibly, recombination.

Identification and characterization of the fourth single-stranded-DNA binding domain of replication protein A

Replication protein A (RPA), the heterotrimeric single-stranded-DNA (ssDNA) binding protein (SSB) of eukaryotes, contains two homologous ssDNA binding domains (A and B) in its largest subunit, RPA1, and a third domain in its second-largest subunit, RPA2. Here we report that Saccharomyces cerevisiae RPA1 contains a previously undetected ssDNA binding domain (domain C) lying in tandem with domains A and B. The carboxy-terminal portion of domain C shows sequence similarity to domains A and B and to the region of RPA2 that binds ssDNA (domain D). The aromatic residues in domains A and B that are known to stack with the ssDNA bases are conserved in domain C, and as in domain A, one of these is required for viability in yeast. Interestingly, the amino-terminal portion of domain C contains a putative Cys4-type zinc-binding motif similar to that of another prokaryotic SSB, T4 gp32. We demonstrate that the ssDNA binding activity of domain C is uniquely sensitive to cysteine modification but that, as with gp32, ssDNA binding is not strictly dependent on zinc. The RPA heterotrimer is thus composed of at least four ssDNA binding domains and exhibits features of both bacterial and phage SSBs.

Replication factor C disengages from proliferating cell nuclear antigen (PCNA) upon sliding clamp formation, and PCNA itself tethers DNA polymerase delta to DNA

Replication factor C (RF-C) and proliferating cell nuclear antigen (PCNA) assemble a complex, called sliding clamp, onto DNA. The clamp in turn loads DNA polymerases (pol) delta and epsilon to form the corresponding holoenzymes, which play an essential role in replication of eukaryotic chromosomal DNA and in several DNA repair pathways. To determine the fate of RF-C after loading of PCNA onto DNA, we tagged the RF-C subunit p37 with a protein kinase A recognition motif, so that the recombinant five-subunit RF-C complex could be 32P-labeled and quantitatively detected in femtomolar amounts. Nonspecific binding of RF-C to DNA was minimized by replacing the p140 subunit with an N-terminally truncated p140 subunit lacking the previously identified nonspecific DNA binding domain. Neither of these modifications impaired the clamp loading activity of the recombinant RF-C. Using gel filtration techniques, we demonstrated that RF-C dissociated from the DNA after clamp loading or pol delta holoenzyme assembly, while PCNA or PCNA.pol delta complex remained bound to DNA. PCNA catalytically loaded onto the template-primer was sufficient by itself to tether pol delta and stimulate DNA replication. The readdition of RF-C to the isolated PCNA.DNA complex did not further stimulate pol delta DNA synthesis. We conclude that pol delta holoenzyme consists of PCNA and pol delta core and that RF-C serves only to load PCNA clamp.

Replication errors: cha(lle)nging the genome

Since the discovery of a link between the malfunction of post-replicative mismatch correction and hereditary non-polyposis colon cancer, the study of this complex repair pathway has received a great deal of attention. Our understanding of the mammalian system was facilitated by conservation of the main protagonists of this process from microbes to humans. Thus, biochemical experiments carried out with Escherichia coli extracts helped us to identify functional human homologues of the bacterial mismatch repair proteins, while the genetics of Saccharomyces cerevisiae aided our understanding of the phenotypes of human cells deficient in mismatch correction. Today, mismatch repair is no longer thought of solely as the mechanism responsible for the correction of replication errors, whose failure demonstrates itself in the form of a mutator phenotype and microsatellite instability. Malfunction of this process has been implicated also in mitotic and meiotic recombination, drug and ionizing radiation resistance, transcription-coupled repair and apoptosis. Elucidation of the roles of mismatch repair proteins in these transduction pathways is key to our understanding of the role of mismatch correction in human cancer. However, in order to unravel all the complexities involved in post-replicative mismatch correction, we need to know the cast and the roles of the individual players. This brief treatise provides an overview of our current knowledge of the biochemistry of this process.

Replication protein A stimulates long patch DNA base excision repair

Two pathways for completion of DNA base excision repair (BER) have recently emerged. In one, called short patch BER, only the damaged nucleotide is replaced, whereas in the second, known as long patch BER, the monobasic lesion is removed along with additional downstream nucleotides. Flap endonuclease 1, which preferentially cleaves unannealed 5'-flap structures in DNA, has been shown to play a crucial role in the long patch mode of repair. This nuclease will efficiently release 5'-terminal abasic lesions as part of an intact oligonucleotide when cleavage is combined with strand displacement synthesis. Further gap filling and ligation complete repair. We reconstituted the final steps of long patch base excision repair in vitro using calf DNA polymerase epsilon to provide strand displacement synthesis, human flap endonuclease 1, and human DNA ligase I. Replication protein A is an important constituent of the DNA replication machinery. It also has been shown to interact with an early component of base excision repair: uracil glycosylase. Here we show that human replication protein A greatly stimulates long patch base excision repair.

Novel homologs of replication protein A in archaea: implications for the evolution of ssDNA-binding proteins

In Bacteria and Eukarya, ssDNA-binding proteins are central to most aspects of DNA metabolism. Until recently, however, no counterpart of an ssDNA-binding protein had been identified in the third domain of life, Archaea. Here, we report the discovery of a novel type of ssDNA-binding protein in the genomes of several archaeons. These proteins, in contrast to all known members of this protein family, possess four conserved DNA-binding sites within a single polypeptide or, in one case, two polypeptides. This peculiar structural organization allows us to propose a model for the evolution of this class of proteins.

Chromosomal rearrangements occur in S. cerevisiae rfa1 mutator mutants due to mutagenic lesions processed by double-strand-break repair

Three temperature-sensitive S. cerevisiae RFA1 alleles were found to cause elevated mutation rates. These mutator phenotypes resulted from the accumulation of base substitutions, frameshifts, gross deletions (8 bp-18 kb), and nonreciprocal translocations. A representative rfa1 mutation exhibited a growth defect in conjunction with rad51, rad52, or rad10 mutations, suggesting an accumulation of double-strand breaks. rad10 and rad52 mutations eliminated deletion and translocation formation, whereas a rad51 mutation increased the frequency of these events and revealed a new class of genetic rearrangements--loss of a portion of a chromosome arm combined with telomere addition. The breakpoints of the translocations and deletions were flanked by imperfect direct repeats of 2-20 bp, similar to the breakpoint structures observed at translocations and gross deletions, including LOH events, underlying human cancer and other hereditary diseases.

Relationship of the xeroderma pigmentosum group E DNA repair defect to the chromatin and DNA binding proteins UV-DDB and replication protein A

Cells from complementation groups A through G of the heritable sun-sensitive disorder xeroderma pigmentosum (XP) show defects in nucleotide excision repair of damaged DNA. Proteins representing groups A, B, C, D, F, and G are subunits of the core recognition and incision machinery of repair. XP group E (XP-E) is the mildest form of the disorder, and cells generally show about 50% of the normal repair level. We investigated two protein factors previously implicated in the XP-E defect, UV-damaged DNA binding protein (UV-DDB) and replication protein A (RPA). Three newly identified XP-E cell lines (XP23PV, XP25PV, and a line formerly classified as an XP variant) were defective in UV-DDB binding activity but had levels of RPA in the normal range. The XP-E cell extracts did not display a significant nucleotide excision repair defect in vitro, with either UV-irradiated DNA or a uniquely placed cisplatin lesion used as a substrate. Purified UV-DDB protein did not stimulate repair of naked DNA by DDB- XP-E cell extracts, but microinjection of the protein into DDB- XP-E cells could partially correct the repair defect. RPA stimulated repair in normal, XP-E, or complemented extracts from other XP groups, and so the effect of RPA was not specific for XP-E cell extracts. These data strengthen the connection between XP-E and UV-DDB. Coupled with previous results, the findings suggest that UV-DDB has a role in the repair of DNA in chromatin.

Genetic analysis of yeast RPA1 reveals its multiple functions in DNA metabolism

Replication protein A (RPA) is a single-stranded DNA-binding protein identified as an essential factor for SV40 DNA replication in vitro. To understand the in vivo functions of RPA, we mutagenized the Saccharomyces cerevisiae RFA1 gene and identified 19 ultraviolet light (UV) irradiation- and methyl methane sulfonate (MMS)-sensitive mutants and 5 temperature-sensitive mutants. The UV- and MMS-sensitive mutants showed up to 10(4) to 10(5) times increased sensitivity to these agents. Some of the UV- and MMS-sensitive mutants were killed by an HO-induced double-strand break at MAT. Physical analysis of recombination in one UV- and MMS-sensitive rfa1 mutant demonstrated that it was defective for mating type switching and single-strand annealing recombination. Two temperature-sensitive mutants were characterized in detail, and at the restrictive temperature were found to have an arrest phenotype and DNA content indicative of incomplete DNA replication. DNA sequence analysis indicated that most of the mutations altered amino acids that were conserved between yeast, human, and Xenopus RPA1. Taken together, we conclude that RPA1 has multiple roles in vivo and functions in DNA replication, repair, and recombination, like the single-stranded DNA-binding proteins of bacteria and phages.