The 32- and 14-kilodalton subunits of replication protein A are responsible for species-specific interactions with single-stranded DNA

Replication protein A (RPA) is a multisubunit single-stranded DNA-binding (ssDNA) protein that is required for cellular DNA metabolism. RPA homologues have been identified in all eukaryotes examined. All homologues are heterotrimeric complexes with subunits of approximately 70, approximately 32, and approximately 14 kDa. While RPA homologues are evolutionarily conserved, they are not functionally equivalent. To gain a better understanding of the functional differences between RPA homologues, we analyzed the DNA-binding parameters of RPA from human cells and the budding yeast Saccharomyces cerevisiae (hRPA and scRPA, respectively). Both yeast and human RPA bind ssDNA with high affinity and low cooperativity. However, scRPA has a larger occluded binding site (45 nucleotides versus 34 nucleotides) and a higher affinity for oligothymidine than hRPA. Mutant forms of hRPA and scRPA containing the high-affinity DNA-binding domain from the 70-kDa subunit had nearly identical DNA binding properties. In contrast, subcomplexes of the 32- and 14-kDa subunits from both yeast and human RPA had weak ssDNA binding activity. However, the binding constants for the yeast and human subcomplexes were 3 and greater than 6 orders of magnitude lower than those for the RPA heterotrimer, respectively. We conclude that differences in the activity of the 32- and 14-kDa subunits of RPA are responsible for variations in the ssDNA-binding properties of scRPA and hRPA. These data also indicate that hRPA and scRPA have different modes of binding to ssDNA, which may contribute to the functional disparities between the two proteins.     

DNA-binding polarity of human replication protein A positions nucleases in nucleotide excision repair

The human single-stranded DNA-binding replication A protein (RPA) is involved in various DNA-processing events. By comparing the affinity of hRPA for artificial DNA hairpin structures with 3'- or 5'-protruding single-stranded arms, we found that hRPA binds ssDNA with a defined polarity; a strong ssDNA interaction domain of hRPA is positioned at the 5' side of its binding region, a weak ssDNA-binding domain resides at the 3' side. Polarity appears crucial for positioning of the excision repair nucleases XPG and ERCC1-XPF on the DNA. With the 3'-oriented side of hRPA facing a duplex ssDNA junction, hRPA interacts with and stimulates ERCC1-XPF, whereas the 5'-oriented side of hRPA at a DNA junction allows stable binding of XPG to hRPA. Our data pinpoint hRPA to the undamaged strand during nucleotide excision repair. Polarity of hRPA on ssDNA is likely to contribute to the directionality of other hRPA-dependent processes as well.     

Solution structure of the DNA-binding domain of a human papillomavirus E2 protein: evidence for flexible DNA-binding regions

The three-dimensional structure of the DNA-binding domain of the E2 protein from human papillomavirus-31 was determined by using multidimensional heteronuclear nuclear magnetic resonance (NMR) spectroscopy. A total of 1429 NMR-derived distance and dihedral angle restraints were obtained for each of the 83-residue subunits of this symmetric dimer. The average root mean square deviations of 20 structures calculated using a distance geometry-simulated annealing protocol are 0.59 and 0.90 angstroms for the backbone and all heavy atoms, respectively, for residues 2-83. The structure of the human virus protein free in solution consists of an eight-stranded beta-barrel and two pairs of alpha-helices. Although the overall fold of the protein is similar to the crystal structure of the bovine papillomavirus-1 E2 protein when complexed to DNA, several small but interesting differences were observed between these two structures at the subunit interface. In addition, a beta-hairpin that contacts DNA in the crystal structure of the protein-DNA complex is disordered in the NMR structures, and steady-state 1H-15N heteronuclear NOE measurements indicate that this region is highly mobile in the absence of DNA. The recognition helix also appears to be flexible, as evidenced by fast amide exchange rates. This phenomenon has also been observed for a number of other DNA-binding proteins and may constitute a common theme in protein/DNA recognition.     

The product of the lexC gene of Escherichia coli is single-stranded DNA-binding protein

Extracts from lexC113 cells could not support phage G4 DNA-dependent replication unless supplemented with single-stranded DNA-binding protein. Purified lexC113 binding protein supported synthesis in a reconstituted replication assay, using purified proteins at 30 but not at 42 degrees C, indicating that the product of the lexC113 gene is an altered single-stranded DNA-binding protein.     

The alpha-helical rod domain of human lamins A and C contains a chromatin binding site

We examined regions of human lamins A and C involved in binding to surfaces of mitotic chromosomes. An Escherichia coli expression system was used to produce full-length lamin A and lamin C, and truncated lamins retaining the central alpha-helical rod domain (residues 34-388) but lacking various amounts of the amino-terminal 'head' and carboxy-terminal 'tail' domains. We found that lamin A, lamin C and lamin fragments lacking the head domain and tail sequences distal to residue 431 efficiently assembled into paracrystals and strongly associated with mitotic chromosomes. Furthermore, the lamin rod domain also associated with chromosomes, although efficient chromosome coating required the pH 5-6 conditions needed to assemble the rod into higher order structures. Biochemical assays showed that chromosomes substantially reduced the critical concentration for assembly of lamin polypeptides into pelletable structures. Association of the lamin rod with chromosomes was abolished by pretrypsinization of chromosomes, and was not seen for vimentin (which possesses a similar rod domain). These data demonstrate that the alpha-helical rod of lamins A and C contains a specific chromosome binding site. Hence, the central rod domain of intermediate filament proteins can be involved in interactions with other cellular structures as well as in filament assembly.     

Studies of the interaction between Rad52 protein and the yeast single-stranded DNA binding protein RPA

The RFA1 gene encodes the large subunit of the yeast trimeric single-stranded DNA binding protein replication protein A (RPA), which is known to play a critical role in DNA replication. A Saccharomyces cerevisiae strain carrying the rfa1-44 allele displays a number of impaired recombination and repair phenotypes, all of which are suppressible by overexpression of RAD52. We demonstrate that a rad52 mutation is epistatic to the rfa1-44 mutation, placing RFA1 and RAD52 in the same genetic pathway. Furthermore, two-hybrid analysis indicates the existence of interactions between Rad52 and all three subunits of RPA. The nature of this Rad52-RPA interaction was further explored by using two different mutant alleles of rad52. Both mutations lie in the amino terminus of Rad52, a region previously defined as being responsible for its DNA binding ability (U. H. Mortenson, C. Beudixen, I. Sunjeuaric, and R. Rothstein, Proc. Natl. Acad. Sci. USA 93:10729-10734, 1996). The yeast two-hybrid system was used to monitor the protein-protein interactions of the mutant Rad52 proteins. Both of the mutant proteins are capable of self-interaction but are unable to interact with Rad51. The mutant proteins also lack the ability to interact with the large subunit of RPA, Rfa1. Interestingly, they retain their ability to interact with the medium-sized subunit, Rfa2. Given the location of the mutations in the DNA binding domain of Rad52, a model incorporating the role of DNA in the protein-protein interactions involved in the repair of DNA double-strand breaks is presented.     

The chi psi subunits of DNA polymerase III holoenzyme bind to single-stranded DNA-binding protein (SSB) and facilitate replication of an SSB-coated template

A complex of the chi and psi proteins is required to confer resistance to high levels of glutamate on the DNA polymerase III holoenzyme-catalyzed reaction (Olson, M., Dallmann, H. G., and McHenry, C. (1995) J. Biol. Chem. 270, 29570-29577). We demonstrate that this salt resistance also requires templates to be coated with the Escherichia coli single-stranded DNA-binding protein (SSB). We show that this is the result of a direct chipsi-SSB interaction that is strengthened approximately 1000-fold when SSB is bound to DNA. On model oligonucleotide templates, DNA polymerase III core is inhibited by SSB. We show that the minimal polymerase assembly that will synthesize DNA on SSB-coated templates is polymerase III-tau-psi chi. gamma, the alternative product of the dnaX gene, will not replace tau in this reaction, indicating that tau's unique ability to bind to DNA polymerase III holding chipsi in the same complex is essential. All of our findings are consistent with chipsi strengthening DNA polymerase III holoenzyme interactions with the SSB-coated lagging strand at the replication fork, facilitating complex assembly and elongation.     

The solution structure of the human retinoic acid receptor-beta DNA-binding domain

Parkinsonism is a feature not only of Parkinson's disease but also of many other diseases affecting basal ganglia function. Functional imaging (PET and SPECT) can demonstrate the various resting patterns of disruption of regional cerebral blood flow, metabolism, and neuropharmacology associated with different parkinsonian disorders. 18F-dopa PET also has the potential to detect subclinical dysfunction of dopaminergic terminals in at-risk subjects. Finally, functional imaging can help us understand the nature of the networks involved in performing different motor tasks, and can reveal how these networks malfunction in the presence of bradykinesia or parkinsonian tremor.     

The human S mu bp-2, a DNA-binding protein specific to the single-stranded guanine-rich sequence related to the immunoglobulin mu chain switch region

We have cloned the cDNA encoding the human homologue of S mu bp-2, which binds to single-stranded DNA with 5'-phosphorylated guanine-rich sequences related to the immunoglobulin mu chain switch (S mu) region. The deduced amino acid sequences of the mouse and human S mu bp-2 are 76.5% homologous and contain motifs conserved among helicases. We have identified a domain essential for DNA binding at residues 638-786. The binding domain is less conserved (63% homologous) than the putative catalytic domain of N-terminal half containing most of the helicase motifs (85% homologous). The human and mouse S mu bp-2 have similar, although slightly different, binding specificities. Although the mouse S mu bp-2 preferentially binds to the mouse S mu motif (GGGGT), the human S mu bp-2 binds equally well to the human (GGGCT) and mouse S mu motifs. The human S mu bp-2 gene was mapped to chromosome 11 q13.2-q13.4 by in situ hybridization.     

The Schizosaccharomyces pombe rad11+ gene encodes the large subunit of replication protein A

Replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein present in all eukaryotes. In vitro studies have implicated RPA in simian virus 40 DNA synthesis and nucleotide excision repair, but little direct information is available about the in vivo roles of the protein. We report here the cloning of the largest subunit of RPA (rpa1+) from the fission yeast Schizosaccharomyces pombe. The rpa1+ gene is essential for viability and is expressed specifically at S phase of the cell cycle. Genetic analysis revealed that rpa1+ is the locus of the S. pombe radiation-sensitive mutation rad11. The rad11 allele exhibits pleiotropic effects consistent with an in vivo role for RPA in both DNA repair and DNA synthesis. The mutant is sensitive to both UV and ionizing radiation but is not defective in the DNA damage-dependent checkpoint, consistent with the hypothesis that RPA is part of the enzymatic machinery of DNA repair. When incubated in hydroxyurea, rad11 cells initially arrest with a 1C DNA content but then lose viability coincident with reentry into S phase, suggesting that DNA synthesis is aberrant under these conditions. A significant fraction of the mutant cells subsequently undergo inappropriate mitosis in the presence of hydroxyurea, indicating that RPA also plays a role in the checkpoint mechanism that monitors the completion of S phase. We propose that RPA is required to maintain the integrity of replication complexes when DNA replication is blocked. We further suggest that the rad11 mutation leads to the premature breakdown of such complexes, thereby preventing recovery from the hydroxyurea arrest and eliminating a signal recognized by the S-phase checkpoint mechanism.     

Human xeroderma pigmentosum group A protein interacts with human replication protein A and inhibits DNA replication

Human replication protein A (RPA; also known as human single-stranded DNA binding protein, or HSSB) is a multisubunit complex involved in both DNA replication and repair. While the role of RPA in replication has been well studied, its function in repair is less clear, although it is known to be involved in the early stages of the repair process. We found that RPA interacts with xeroderma pigmentosum group A complementing protein (XPAC), a protein that specifically recognizes UV-damaged DNA. We examined the effect of this XPAC-RPA interaction on in vitro simian virus 40 (SV40) DNA replication catalyzed by the monopolymerase system. XPAC inhibited SV40 DNA replication in vitro, and this inhibition was reversed by the addition of RPA but not by the addition of DNA polymerase alpha-primase complex, SV40 large tumor antigen, or topoisomerase I. This inhibition did not result from an interaction between XPAC and single-stranded DNA (ssDNA), or from competition between RPA and XPAC for DNA binding, because XPAC does not show any ssDNA binding activity and, in fact, stimulates RPA's ssDNA binding activity. Furthermore, XPAC inhibited DNA polymerase alpha activity in the presence of RPA but not in RPA's absence. These results suggest that the inhibitory effect of XPAC on DNA replication probably occurs through its interaction with RPA.     

Viability and preliminary in vivo characterization of site-directed mutants of Escherichia coli single-stranded DNA-binding protein

Site-directed mutations involving selected amino acids of Escherichia coli single-stranded DNA-binding protein (SSB) were tested for their in vivo functionality when introduced into a chromosomal ssb deletion strain on a plasmid. All mutants complemented the ssb deletion for viability when present on a pSC101 derivative. The generation time with ssbW54S doubled in comparison to the ssb+ control, and both the ssbW54S- and ssbH55K-containing strains exhibited temperature sensitivity. ssbH55K, ssbW54S, ssbW88T, and ssbH55Y (ssb-1) strains displayed reduced survival to ultraviolet irradiation, while ssbW40T and ssbF60L strains were comparable to the ssb+ control strain. This study represents the first investigation of the in vivo properties of ssb mutations constructed for in vitro analysis of DNA binding by SSB.     

A common core for binding single-stranded DNA: structural comparison of the single-stranded DNA-binding proteins (SSB) from E. coli and human mitochondria

The crystal structure of the DNA-binding domain of E. coli SSB (EcoSSB) has been determined to a resolution of 2.5 A. This is the first reported structure of a prokaryotic SSB. The structure of the DNA-binding domain of the E. coli protein is compared to that of the human mitochondrial SSB (HsmtSSB). In spite of the relatively low sequence identity between them, the two proteins display a high degree of structural similarity. EcoSSB crystallises with two dimers in the asymmetric unit, unlike HsmtSSB which contains only a dimer. This is probably a consequence of the different polypeptide chain lengths in the EcoSSB heterotetramer. Crucial differences in the dimer-dimer interface of EcoSSB may account for the inability of EcoSSB and HsmtSSB to form cross-species heterotetramers, in contrast to many bacterial SSBs.