Interactions of human replication protein A with oligonucleotides

High-throughput fluorescence spectroscopic analysis of affinity of peptides displayed on bacteriophage

Fluorescence spectroscopy titrations, although widely used to analyze binding affinity, are not an efficient screening method for detecting high-affinity binding among a large number of available ligands, such as during bacteriophage display selections. We hypothesize that a miniaturized, high-throughput fluorescence spectroscopy assay can be used to efficiently analyze selection results by applying the Langmuir equation to the binding data to estimate affinity constants for a large number of ligands, either as synthesized molecules or as displayed on bacteriophage. Here, bacteriophage-display-derived peptides specific for the Thomsen-Friedenreich disaccharide are used to develop a high-throughput fluorescence spectroscopy screening method, which uses one binding partner labeled with a fluorescent dye and different concentrations of a second partner to analyze binding affinity in bacteriophage display selections. The affinity constants derived from binding isotherms prepared using the new system accurately replicate those derived from standard spectroscopy titrations. Furthermore, the technique correctly defined the affinity constant describing binding of a cognate epitope peptide by a monoclonal antibody. Finally, we have applied the technique to analysis of binding affinity by ligands displayed on bacteriophage, which suggests that this technique could be used to monitor bacteriophage enrichment during selections.

Interactions of human replication protein A with single-stranded DNA adducts

Human RPA (replication protein A), a single-stranded DNA-binding protein, is required for many cellular pathways including DNA repair, recombination and replication. However, the role of RPA in nucleotide excision repair remains elusive. In the present study, we have systematically examined the binding of RPA to a battery of well-defined ssDNA (single-stranded DNA) substrates using fluorescence spectroscopy. These substrates contain adducts of (6-4) photoproducts, N-acetyl-2-aminofluorene-, 1-aminopyrene-, BPDE (benzo[a]pyrene diol epoxide)- and fluorescein that are different in many aspects such as molecular structure and size, DNA disruption mode (e.g. base stacking or non-stacking), as well as chemical properties. Our results showed that RPA has a lower binding affinity for damaged ssDNA than for non-damaged ssDNA and that the affinity of RPA for damaged ssDNA depends on the type of adduct. Interestingly, the bulkier lesions have a greater effect. With a fluorescent base-stacking bulky adduct, (+)-cis-anti-BPDE-dG, we demonstrated that, on binding of RPA, the fluorescence of BPDE-ssDNA was significantly enhanced by up to 8-9-fold. This indicated that the stacking between the BPDE adduct and its neighbouring ssDNA bases had been disrupted and there was a lack of substantial direct contacts between the protein residues and the lesion itself. For RPA interaction with short damaged ssDNA, we propose that, on RPA binding, the modified base of ssDNA is looped out from the surface of the protein, permitting proper contacts of RPA with the remaining unmodified bases.

Denaturation of replication protein A reveals an alternative conformation with intact domain structure and oligonucleotide binding activity

Replication protein A (RPA) is a heterotrimeric, multidomain, single-stranded DNA-binding protein. Using spectroscopic methods and methylene carbene-based chemical modification methods, we have identified conformational intermediates in the denaturation pathway of RPA. Intrinsic protein fluorescence studies reveal unfolding profiles composed of multiple transitions, with midpoints at 1.5, 2.7, 4.2, and 5.3 M urea. CD profiles of RPA unfolding are characterized by a single transition. RPA is stabilized with respect to the CD-monitored transition when bound to a dA15 oligonucleotide. However, oligonucleotide binding appears to exert little, if any, effect on the first fluorescence transition. Methylene carbene chemical modification, coupled with MALDI-TOF mass spectrometry analysis, was also used to monitor unfolding of several specific RPA folds of the protein. The unfolding profiles of the individual structures are characterized by single transitions similar to the CD-monitored transition. Each fold, however, unravels with different individual characteristics, suggesting significant autonomy. Based on results from chemical modification and spectroscopic analyses, we conclude the initial transition observed in fluorescence experiments represents a change in the juxtaposition of binding folds with little unraveling of the domain structures. The second transition represents the unfolding of the majority of fold structure, and the third transition observed by fluorescence correlates with the dissociation of the 70- and 32-kD subunits.

Effective combinatorial strategy to increase affinity of carbohydrate binding by peptides

The Thomsen-Friedenreich antigen, a carcinoma-associated disaccharide involved in carcinoma cell homotypic aggregation and increased metastatic potential, has clinical value as a prognostic indicator and a marker of metastasized cells. Hence, it can reasonably be predicted that antigen-binding macromolecules are valuable clinical in vivo diagnostic/therapeutic targeting agents. Recently, we have selected first-generation antigen-binding peptides from a random peptide bacteriophage display library and have applied combinatorial affinity maturation to select functionally-maturated peptides, which target cultured carcinoma cells and inhibit carcinoma cell aggregation. In the current study we hypothesize that a targeted search of sequence space surrounding the antigen-binding consensus sequence will select unpredictable amino acid sequences in the non-consensus portions of the peptides, leading to increased affinity for the carbohydrate and greater solubility in physiological buffers. This comprehensive in vitro analysis demonstrates that preferential evolution of the amino-terminal sequence of the peptides occurred, which correlated, in structure/function studies, with the acquisition of maturated function. The maturated peptides are more soluble than the earlier peptides. Studies of peptide binding to the disaccharide indicate that two maturated peptides (P-30-1, F03) have higher affinity for the antigen and bind with higher intensity to the surface of cultured human carcinoma cells than the first-generation peptides. The results support our hypothesis that affinity maturation can improve carbohydrate binding by peptides and have theoretical importance as the first report of maturation of carbohydrate-binding affinity in a small, soluble peptide.

The N-terminal domain of the large subunit of human replication protein A binds to Werner syndrome protein and stimulates helicase activity

Werner syndrome (WS) is a recessive inherited human disease characterized by the early onset of aging. The gene mutated in WS encodes a DNA helicase that unwinds the double helical structure of DNA in the 3'-->5' direction as well as a 3'-->5' exonuclease. Our previous studies indicated that the activity of Werner syndrome helicase (WRN) could be stimulated by human replication protein A (hRPA), a heterotrimeric single-stranded DNA binding protein. We now localize the interaction between WRN and hRPA by measuring the stimulation of helicase activity and the binding of WRN by hRPA and its derivatives. The large subunit of hRPA (hRPA70) stimulates WRN helicase to the same extent as the hRPA heterotrimer, whereas the dimer of the two smaller subunits (hRPA 32.14) does not stimulate. By examining hRPA70 mutants with progressive deletions from either the C- or N-terminus, we found that the domain responsible for stimulation lies in the N-terminal half of the protein. By using enzyme-linked immunosorbent assay (ELISA) to examine physical interaction between WRN and the same deletion mutants, we found that the WRN-binding motif is located within amino acids 100-300 and overlaps with the single-stranded DNA binding domain (amino acids 150-450). We suggest that hRPA, by engaging in both protein-protein and protein-DNA interactions, facilitates unwinding events catalyzed by WRN helicase during DNA synthetic processes. These data should help further elucidation of the molecular mechanisms of genetic instability and premature aging phenotypes manifested by WS.

Role of protein-protein interactions during herpes simplex virus type 1 recombination-dependent replication

Recombination-dependent replication is an integral part of the process by which double-strand DNA breaks are repaired to maintain genome integrity. It also serves as a means to replicate genomic termini. We reported previously on the reconstitution of a recombination-dependent replication system using purified herpes simplex virus type 1 proteins (Nimonkar A. V., and Boehmer, P. E. (2003) Proc. Natl. Acad. Sci. U. S. A. 100, 10201-10206). In this system, homologous pairing by the viral single-strand DNA-binding protein (ICP8) is coupled to DNA synthesis by the viral DNA polymerase and helicase-primase in the presence of a DNA-relaxing enzyme. Here we show that DNA synthesis in this system is dependent on the viral polymerase processivity factor (UL42). Moreover, although DNA synthesis is strictly dependent on topoisomerase I, it is only stimulated by the viral helicase in a manner that requires the helicase-loading protein (UL8). Furthermore, we have examined the dependence of DNA synthesis in the viral system on species-specific protein-protein interactions. Optimal DNA synthesis was observed with the herpes simplex virus type 1 replication proteins, ICP8, DNA polymerase (UL30/UL42), and helicase-primase (UL5/UL52/UL8). Interestingly, substitution of each component with functional homologues from other systems for the most part did not drastically impede DNA synthesis. In contrast, recombination-dependent replication promoted by the bacteriophage T7 replisome was disrupted by substitution with the replication proteins from herpes simplex virus type 1. These results show that although DNA synthesis performed by the T7 replisome is dependent on cognate protein-protein interactions, such interactions are less important in the herpes simplex virus replisome.

Independent and coordinated functions of replication protein A tandem high affinity single-stranded DNA binding domains

The initial high affinity binding of single-stranded DNA (ssDNA) by replication protein A (RPA) is involved in the tandem domains in the central region of the RPA70 subunit (RPA70AB). However, it was not clear whether the two domains, RPA70A and RPA70B, bind DNA simultaneously or sequentially. Here, using primarily heteronuclear NMR complemented by fluorescence spectroscopy, we have analyzed the binding characteristics of the individual RPA70A and RPA70B domains and compared them with the intact RPA70AB. NMR chemical shift comparisons confirmed that RPA70A and RPA70B tumble independently in solution in the absence of ssDNA. NMR chemical shift perturbations showed that all ssDNA oligomers bind to the same sites as observed in the x-ray crystal structure of RPA70AB complexed to d(C)8. Titrations using a variety of 5'-mer ssDNA oligomers showed that RPA70A has a 5-10-fold higher affinity for ssDNA than RPA70B. Detailed analysis of ssDNA binding to RPA70A revealed that all DNA sequences interact in a similar mode. Fluorescence binding measurements with a variety of 8-10'-mer DNA sequences showed that RPA70AB interacts with DNA with approximately 100-fold higher affinity than the isolated domains. Calculation of the theoretical "linkage effect" from the structure of RPA70AB suggests that the high overall affinity for ssDNA is a byproduct of the covalent attachment of the two domains via a short flexible tether, which increases the effective local concentration. Taken together, our data are consistent with a sequential model of DNA binding by RPA according to which RPA70A binds the majority of DNA first and subsequent loading of RPA70B domain is facilitated by the linkage effect.

The phosphorylation domain of the 32-kDa subunit of replication protein A (RPA) modulates RPA-DNA interactions. Evidence for an intersubunit interaction

Replication protein A (RPA) is a heterotrimeric (subunits of 70, 32, and 14 kDa) single-stranded DNA-binding protein that is required for DNA replication, recombination, and repair. The 40-residue N-terminal domain of the 32-kDa subunit of RPA (RPA32) becomes phosphorylated during S-phase and after DNA damage. Recently it has been shown that phosphorylation or the addition of negative charges to this N-terminal phosphorylation domain modulates RPA-protein interactions and increases cell sensitivity to DNA damage. We found that addition of multiple negative charges to the N-terminal phosphorylation domain also caused a significant decrease in the ability of a mutant form of RPA to destabilize double-stranded (ds) DNA. Kinetic studies suggested that the addition of negative charges to the N-terminal phosphorylation domain caused defects in both complex formation (nucleation) and subsequent destabilization of dsDNA by RPA. We conclude that the N-terminal phosphorylation domain modulates RPA interactions with dsDNA. Similar changes in DNA interactions were observed with a mutant form of RPA in which the N-terminal domain of the 70-kDa subunit was deleted. This suggested a functional link between the N-terminal domains of the 70- and 32-kDa subunits of RPA. NMR experiments provided evidence for a direct interaction between the N-terminal domain of the 70-kDa subunit and the negatively charged N-terminal phosphorylation domain of RPA32. These findings suggest that phosphorylation causes a conformational change in the RPA complex that regulates RPA function.

Critical DNA damage recognition functions of XPC-hHR23B and XPA-RPA in nucleotide excision repair

It has been reported that 80-90% of human cancers may result, in part, from DNA damage. Cell survival depends critically on the stability of our DNA and exquisitely sensitive DNA repair mechanisms have developed as a result. In humans, nucleotide excision repair (NER) protects the DNA against the mutagenic effects of carcinogens and ultraviolet (UV) radiation from sun exposure. By preventing mutations from forming in the DNA, the repair machinery ultimately protects us from developing cancers. DNA damage recognition is the rate-limiting step in repair, and although many details of NER have been elucidated, the mechanisms by which DNA damage is recognized remain to be fully determined. Two primary protein complexes have been proposed as the damaged DNA recognition factor in NER: xeroderma pigmentosum protein A-replication protein A (XPA-RPA) and xeroderma pigmentosum protein C-human homolog of RAD23B (XPC-hHR23B). Here we compare the evidence that supports damage detection by these protein complexes and propose a model for DNA damage recognition in NER based on the current understanding of the roles these proteins may play in the processing of DNA lesions.

Human replication protein A. The C-terminal RPA70 and the central RPA32 domains are involved in the interactions with the 3'-end of a primer-template DNA

Although the mechanical aspects of the single-stranded DNA (ssDNA) binding activity of human replication protein A (RPA) have been extensively studied, only limited information is available about its interaction with other physiologically relevant DNA structures. RPA interacts with partial DNA duplexes that resemble DNA intermediates found in the processes of DNA replication and DNA repair. Limited proteolysis of RPA showed that RPA associated with ssDNA is less protected against proteases than RPA bound to a partial duplex DNA containing a 5'-protruding tail that had the same length as the ssDNA. Modification of both the 70- and 32-kDa subunits, RPA70 and RPA32, respectively, by photoaffinity labeling indicates that RPA can bind the primer-template junction of partial duplex DNAs by interacting with the 3'-end of the primer. The identification of the protein domains modified by the photoreactive 3'-end of the primer showed that domains located in the central part of the RPA32 subunit (amino acids 39-180) and the C-terminal part of the RPA70 subunit (amino acids 432-616) are involved in these interactions.

Combinatorial evolution of high-affinity peptides that bind to the Thomsen-Friedenreich carcinoma antigen

Thomsen-Friedenreich (TF) antigen occurs on approximately 90% of human carcinomas, is likely involved in carcinoma cell homotypic aggregation, and has clinical value as a prognostic indicator and marker of metastasized cells. Previously, we isolated anti-TF antigen peptides from bacteriophage display libraries. These bound to TF antigen on carcinoma cells but were of low affinity and solubility. We hypothesized that peptide amino acid sequence changes would result in increased affinity and solubility, which would translate into improved carcinoma cell binding and increased inhibition of aggregation. The new peptides were more soluble and exhibited up to fivefold increase in affinity (Kd approximately equal to 60 nM). They bound cultured human breast and prostate carcinoma cells at low concentrations, whereas the earlier peptides did not. Moreover, the new peptides were potent inhibitors of homotypic aggregation. The maturated peptides will have expanded applications in basic studies of the TF antigen and particular utility as clinical carcinoma-targeting agents.

Heterogeneous expression and functional analysis of two distinct replication protein A large subunits from Cryptosporidium parvum

Replication protein A is a single stranded DNA-binding protein that has multiple roles in eukaryotic DNA metabolism. Typically, eukaryotic replication protein A is a stable heterotrimeric complex with three subunits of 70 kDa (RPA1), 32 kDa (RPA2) and 14 kDa (RPA3). We have previously cloned and characterised an RPA1 subunit from Cryptosporidium parvum, which shares high homology with other eukaryotic replication protein A 1 proteins, but lacks an N-terminal domain. Here, we have identified a second replication protein A 1 (termed CpRPA1B) from the ongoing C. parvum genome-sequencing project. The deduced protein sequence to CpRPA1B shows only 16% sequence identity with CpRPA1, indicating that two different types of RPA1 subunits are present in C. parvum. The CpRPA1B gene predicts a 75.5 kDa peptide similar in size to those of higher eukaryotes, but in contrast to the 53.9 kDa N-terminal short-type CpRPA1 protein. However, western blot analysis suggested that, although the entire CpRPA1B open reading frame might be translated, the protein may be cleaved by posttranslational modification, similar to that observed with the replication protein A 1 gene product in Plasmodium falciparum. Indirect immunofluorescence studies indicated a diffused pattern for both proteins in sporozoites. However, differential localisation was observed with CpRPA1 to the anterior region that contains the apical-complex and CpRPA1B to the central region in/or around the nuclei of the sporozoites. Both CpRPA1 and CpRPA1B full-length open reading frames were expressed for functionality assays. The CpRPA1 and CpRPA1B recombinant proteins were expressed in bacterial Escherichia coli as maltose-binding protein fusion proteins and the entire fusion proteins were assayed for their DNA-binding properties. Studies indicate that CpRPA1B binds ssDNA of >or=5 nucleotides (dT), while CpRPA1 only binds ssDNA >or=20 nucleotides (dT). This study indicates that C. parvum possesses two different types of replication protein A large subunits (replication protein A 1), both differing significantly from their hosts.

Scanning confocal fluorescence microscopy for single molecule analysis of nucleotide excision repair complexes

We used scanning confocal fluorescence microscopy to observe and analyze individual DNA- protein complexes formed between human nucleotide excision repair (NER) proteins and model DNA substrates. For this purpose human XPA protein was fused to EGFP, purified and shown to be functional. Binding of EGFP-labeled XPA protein to a Cy3.5-labeled DNA substrate, in the presence and absence of RPA, was assessed quantitatively by simultaneous excitation and emission detection of both fluorophores. Co-localization of Cy3.5 and EGFP signals within one diffraction limited spot indicated complexes of XPA with DNA. Measurements were performed on samples in a 1% agarose matrix in conditions that are compatible with protein activity and where reactions can be studied under equilibrium conditions. In these samples DNA alone was freely diffusing and protein-bound DNA was immobile, whereby they could be discriminated resulting in quantitative data on DNA binding. On the single molecule level approximately 10% of XPA co-localized with DNA; this increased to 32% in the presence of RPA. These results, especially the enhanced binding of XPA in the presence of RPA, are similar to those obtained in bulk experiments, validating the utility of scanning confocal fluorescence microscopy for investigating functional interactions at the single molecule level.

Analysis of the human replication protein A:Rad52 complex: evidence for crosstalk between RPA32, RPA70, Rad52 and DNA

The eukaryotic single-stranded DNA-binding protein, replication protein A (RPA), is essential for DNA replication, and plays important roles in DNA repair and DNA recombination. Rad52 and RPA, along with other members of the Rad52 epistasis group of genes, repair double-stranded DNA breaks (DSBs). Two repair pathways involve RPA and Rad52, homologous recombination and single-strand annealing. Two binding sites for Rad52 have been identified on RPA. They include the previously identified C-terminal domain (CTD) of RPA32 (residues 224-271) and the newly identified domain containing residues 169-326 of RPA70. A region on Rad52, which includes residues 218-303, binds RPA70 as well as RPA32. The N-terminal region of RPA32 does not appear to play a role in the formation of the RPA:Rad52 complex. It appears that the RPA32CTD can substitute for RPA70 in binding Rad52. Sequence homology between RPA32 and RPA70 was used to identify a putative Rad52-binding site on RPA70 that is located near DNA-binding domains A and B. Rad52 binding to RPA increases ssDNA affinity significantly. Mutations in DBD-D on RPA32 show that this domain is primarily responsible for the ssDNA binding enhancement. RPA binding to Rad52 inhibits the higher-order self-association of Rad52 rings. Implications for these results for the "hand-off" mechanism between protein-protein partners, including Rad51, in homologous recombination and single-strand annealing are discussed.

Parvovirus initiator protein NS1 and RPA coordinate replication fork progression in a reconstituted DNA replication system

We show here that the DNA helicase activity of the parvoviral initiator protein NS1 is highly directional, binding to the single strand at a recessed 5' end and displacing the other strand while progressing in a 3'-to-5' direction on the bound strand. NS1 and a cellular site-specific DNA binding factor, PIF, also known as glucocorticoid modulating element binding protein, bind to the left-end minimal replication origin of minute virus of mice, forming a ternary complex. In this complex, NS1 is activated to nick one DNA strand, becoming covalently attached to the 5' end of the nick in the process and providing a 3' OH for priming DNA synthesis. In this situation, the helicase activity of NS1 did not displace the nicked strand, but the origin duplex was distorted by the NS1-PIF complex, as assayed by its sensitivity to KMnO(4) oxidation, and a stretch of about 14 nucleotides on both strands of the nicked origin underwent limited unwinding. Addition of Escherichia coli single-stranded DNA binding protein (SSB) did not lead to further unwinding. However, addition of recombinant human single-stranded DNA binding protein (RPA) to the initiation reaction catalyzed extensive unwinding of the nicked origin, suggesting that RPA may be required to form a functional replication fork. Accordingly, the unwinding mediated by NS1 and RPA promoted processive leading-strand synthesis catalyzed by recombinant human DNA polymerase delta, PCNA, and RFC, using the minimal left-end origin cloned in a plasmid as a template. The requirement for RPA, rather than SSB, in the unwinding reaction indicated that specific NS1-RPA protein interactions were formed. NS1 was tested by enzyme-linked immunosorbent assay for binding to two- or three-subunit RPA complexes expressed from recombinant baculoviruses. NS1 efficiently bound each of the baculovirus-expressed complexes, indicating that the small subunit of RPA is not involved in specific NS1 binding. No NS1 interactions were observed with E. coli SSB or other proteins included as controls.

UV light-damaged DNA and its interaction with human replication protein A: an atomic force microscopy study

We have imaged a non-damaged and UV-damaged DNA fragment and its complexes with human replication protein A (RPA) using tapping mode atomic force microscopy (AFM). For imaging, molecules were immobilized under nearly physiological conditions on mica surfaces. Quantitative sizing of the 538 bp DNA before and after UV light treatment shows a reduction in the contour and persistence lengths and mean square end-to-end distance as a consequence of UV irradiation. Complexes of the UV-damaged DNA with RPA, an essential component of the initial steps of nucleotide excision repair, can be detected at high resolution with AFM and reveal conformational changes of the DNA related to complex formation. By phase image analysis we are able to discriminate between protein and DNA in the complexes. The DNA molecules are found to 'wrap' around the RPA, which in turn results in a considerable reduction in its apparent contour length.

Functional analysis of the four DNA binding domains of replication protein A. The role of RPA2 in ssDNA binding

Replication Protein A (RPA), the heterotrimeric single-stranded DNA (ssDNA)-binding protein of eukaryotes, contains four ssDNA binding domains (DBDs) within its two largest subunits, RPA1 and RPA2. We analyzed the contribution of the four DBDs to ssDNA binding affinity by assaying recombinant yeast RPA in which a single DBD (A, B, C, or D) was inactive. Inactivation was accomplished by mutating the two conserved aromatic stacking residues present in each DBD. Mutation of domain A had the most severe effect and eliminated binding to a short substrate such as (dT)12. RPA containing mutations in DBDs B and C bound to substrates (dT)12, 17, and 23 but with reduced affinity compared with wild type RPA. Mutation of DBD-D had little or no effect on the binding of RPA to these substrates. However, mutations in domain D did affect the binding to oligonucleotides larger than 23 nucleotides (nt). Protein-DNA cross-linking indicated that DBD-A (in RPA1) is essential for RPA1 to interact efficiently with substrates of 12 nt or less and that DBD-D (RPA2) interacts efficiently with oligonucleotides of 27 nt or larger. The data support a sequential model of binding in which DBD-A is responsible for the initial interaction with ssDNA, that domains A, B, and C (RPA1) contact 12-23 nt of ssDNA, and that DBD-D (RPA2) is needed for RPA to interact with substrates that are 23-27 nt in length.

Replication protein A modulates its interface with the primed DNA template during RNA-DNA primer elongation in replicating SV40 chromosomes

The eukaryal single-stranded DNA binding protein replication protein A (RPA) binds short oligonucleotides with high affinity but exhibits low cooperativity in binding longer templates, opposite to prokaryal counterparts. This discrepancy could reflect the smaller size of the replicative template portion availed to RPA. According to current models, this portion accommodates an RNA-DNA primer (RDP) of <40 nt (nested discontinuity) or a several-fold longer Okazaki fragment (initiation zone). Previous in situ UV-crosslinking revealed that RPA also interacts with nascent DNA, especially growing RDPs. Here we compare nascent SV40 DNA chains UV-crosslinked to the middle and large RPA subunits and use the data to re-examine the two models. The middle subunit interacted with the nascent chains after a few DNA residues were added to the RNA primer while the large subunit became accessible after extension by several more. Upon RDP maturation, the middle subunit disengaged while the large subunit remained accessible during further limited extension. A corresponding shift in preference in favor of the large subunit has been reported for purified RPA and synthetic gapped duplexes upon reduction of the gap from 19 to 9 nt. Combined, these facts support the proposal that the mature RDP faces downstream a correspondingly small gap, possibly created by removal of the RNA primer moiety from an adjacent, previously synthesized RDP (nested discontinuity) but insufficient for continuous elongation of the RDP into an Okazaki fragment (initiation zone).

Stopped-flow kinetic analysis of replication protein A-binding DNA: damage recognition and affinity for single-stranded DNA reveal differential contributions of k(on) and k(off) rate constants

Replication protein A (RPA) is a heterotrimeric protein required for many DNA metabolic functions, including replication, recombination, and nucleotide excision repair (NER). We report the pre-steady-state kinetic analysis of RPA-binding DNA substrates using a stopped-flow assay to elucidate the kinetics of DNA damage recognition. The bimolecular association rate, k(on), for RPA binding to duplex DNA substrates is greatest for a 1,3d(GXG), intermediate for a 1,2d(GpG) cisplatin-DNA adduct, and least for an undamaged duplex DNA substrate. RPA displays a decreased k(on) and an increased k(off) for a single-stranded DNA substrate containing a single 1,2d(GpG) cisplatin-DNA adduct compared with an undamaged DNA substrate. The k(on) for RPA-binding single-stranded polypyrimidine sequences appears to be diffusion-limited. There is minimal difference in k(on) for varying length DNA substrates; therefore, the difference in equilibrium binding affinity is mainly attributed to the k(off). The k(on) for a purine-rich 30-base DNA is reduced by a factor of 10 compared with a pyrimidine-rich DNA of identical length. These results provide insight into the mechanism of RPA-DNA binding and are consistent with RPA recognition of DNA-damage playing a critical role in NER.

Zinc affects the conformation of nucleoprotein filaments formed by replication protein A (RPA) and long natural DNA molecules

Replication protein A is the major single strand DNA binding protein of human cells, composed of three subunits with molecular weights of 70, 32, and 14 kDa. Most of the DNA binding activity of RPA has been mapped to the largest subunit that contains two OB-fold DNA binding domains and a third, OB-like structure in the carboxyterminal domain (CTD). This third domain resembles an OB-fold with a zinc binding domain inserted in the middle of the structure, and has recently been shown to carry a coordinated Zn(II) ion. The bound metal ion is essential for the tertiary structure of the RPA70-CTD, and appears to modulate its DNA binding activity when tested with synthetic oligonucleotides. We show here that zinc strongly affects the conformation of nucleoprotein filaments formed between RPA and long natural DNA molecules. In these experiments, the CTD is dispensable for DNA binding and the unwinding of long double stranded DNA molecules. However, using band shift assays and electron microscopy, we found that RPA-DNA complexes contract at zinc concentrations that do not affect the conformations of complexes formed between DNA and a RPA70 deletion construct lacking the CTD. Our data suggest that nucleoprotein complexes with RPA in its natural, zinc-bearing form may have a compact rather than an extended conformation.

Polarity of human replication protein A binding to DNA

Replication protein A (RPA), the nuclear single-stranded DNA binding protein is involved in DNA replication, nucleotide excision repair (NER) and homologous recombination. It is a stable heterotrimer consisting of subunits with molecular masses of 70, 32 and 14 kDa (p70, p32 and p14, respectively). Gapped DNA structures are common intermediates during DNA replication and NER. To analyze the interaction of RPA and its subunits with gapped DNA we designed structures containing 9 and 30 nucleotide gaps with a photoreactive arylazido group at the 3'-end of the upstream oligonucleotide or at the 5'-end of the downstream oligonucleotide. UV crosslinking and subsequent analysis showed that the p70 subunit mainly interacts with the 5'-end of DNA irrespective of DNA structure, while the subunit orientation towards the 3'-end of DNA in the gap structures strongly depends on the gap size. The results are compared with the data obtained previously with the primer-template systems containing 5'- or 3'-protruding DNA strands. Our results suggest a model of polar RPA binding to the gapped DNA.

The 60-residue C-terminal region of the single-stranded DNA binding protein of herpes simplex virus type 1 is required for cooperative DNA binding

ICP8 is the major single-stranded DNA (ssDNA) binding protein of the herpes simplex virus type 1 and is required for the onset and maintenance of viral genomic replication. To identify regions responsible for the cooperative binding to ssDNA, several mutants of ICP8 have been characterized. Total reflection X-ray fluorescence experiments on the constructs confirmed the presence of one zinc atom per molecule. Comparative analysis of the mutants by electrophoretic mobility shift assays was done with oligonucleotides for which the number of bases is approximately that occluded by one protein molecule. The analysis indicated that neither removal of the 60-amino-acid C-terminal region nor Cys254Ser and Cys455Ser mutations qualitatively affect the intrinsic DNA binding ability of ICP8. The C-terminal deletion mutants, however, exhibit a total loss of cooperativity on longer ssDNA stretches. This behavior is only slightly modulated by the two-cysteine substitution. Circular dichroism experiments suggest a role for this C-terminal tail in protein stabilization as well as in intermolecular interactions. The results show that the cooperative nature of the ssDNA binding of ICP8 is localized in the 60-residue C-terminal region. Since the anchoring of a C- or N-terminal arm of one protein onto the adjacent one on the DNA strand has been reported for other ssDNA binding proteins, this appears to be the general structural mechanism responsible for the cooperative ssDNA binding by this class of protein.

DNA replication but not nucleotide excision repair is required for UVC-induced replication protein A phosphorylation in mammalian cells

Exposure of mammalian cells to short-wavelength light (UVC) triggers a global response which can either counteract the deleterious effect of DNA damage by enabling DNA repair or lead to apoptosis. Several stress-activated protein kinases participate in this response, making phosphorylation a strong candidate for being involved in regulating the cellular damage response. One factor that is phosphorylated in a UVC-dependent manner is the 32-kDa subunit of the single-stranded DNA-binding replication protein A (RPA32). RPA is required for major cellular processes like DNA replication, and removal of DNA damage by nucleotide excision repair (NER). In this study we examined the signal which triggers RPA32 hyperphosphorylation following UVC irradiation in human cells. Hyperphosphorylation of RPA was observed in cells from patients with either NER or transcription-coupled repair (TCR) deficiency (A, C, and G complementation groups of xeroderma pigmentosum and A and B groups of Cockayne syndrome, respectively). This exclude both NER intermediates and TCR as essential signals for RPA hyperphosphorylation. However, we have observed that UV-sensitive cells deficient in NER and TCR require lower doses of UV irradiation to induce RPA32 hyperphosphorylation than normal cells, indicating that persistent unrepaired lesions contribute to RPA phosphorylation. Finally, the results of UVC irradiation experiments on nonreplicating cells and S-phase-synchronized cells emphasize a major role for DNA replication arrest in the presence of UVC lesions in RPA UVC-induced hyperphosphorylation in mammalian cells.

RPA subunit arrangement near the 3'-end of the primer is modulated by the length of the template strand and cooperative protein interactions

To analyze the interaction of human replication protein A (RPA) and its subunits with the DNA template-primer junction in the DNA replication fork, we designed several template-primer systems differing in the size of the single-stranded template tail (4, 9, 13, 14, 19 and 31 nt). Base substituted photoreactive dNTP analogs-5-[ N -(2-nitro-5-azidobenzoyl)- trans -3-amino-propenyl-1]-2'-deoxyuridine-5'-triphosphate (NAB-4-dUTP) and 5-[ N -[ N -(2-nitro-5-azidobenzoyl)glycyl]- trans -3-aminopropenyl-1]-2'-deoxyuridine-5'-triphosphate (NAB-7-dUTP)-were used as substrates for elongation of radiolabeled primer-template by DNA polymerases in the presence or absence of RPA. Subsequent UV crosslinking showed that the pattern of p32 and p70 RPA subunit labeling, and consequently their interaction with the template-primer junction, is strongly dependent on the template extension length at a particular RPA concentration, as well as on the ratio of RPA to template concentration. Our results suggest a model of changes in the RPA configuration modulating by the length of the template extension in the course of nascent DNA synthesis.

Detection of proteins binding to short RNA.DNA hybrids or short antisense oligonucleotides in Xenopus laevis oocytes and human macrophage cell extracts by photoaffinity radiolabeling

Using a 12 base pair RNA.DNA hybrid, substituted with bromouracil on either the RNA or DNA strand, we have detected by photoaffinity radiolabeling a limited set of proteins able to bind to RNA.DNA hybrids in both Xenopus oocyte extracts and human macrophage extracts. Resulting patterns of crosslinked proteins were highly dependent on the strand (DNA or RNA) that was substituted. With one exception, none of the proteins investigated in competition experiments was found to be absolutely specific for RNA.DNA hybrids, as at least one other nucleic acid, either single-stranded DNA or single-stranded RNA, was found to compete efficiently. None of the proteins detected in this assay correspond to the size expected for RNases H. Using the same methodology, we have detected proteins that bind to short oligodeoxyribonucleotides. Although we have essentially detected in Xenopus oocytes one prominent protein of approximately 75 kDa, corresponding to replication protein A (RPA) whatever the oligonucleotide used, the patterns obtained with extracts of human macrophages were more complex and dependent on the oligonucleotide used. If a protein corresponding to RPA was observed most of the time, other crosslinks of similar or sometimes higher intensity were also detected. Interestingly, among these, one protein of 35 kDa appears paradoxically to bind and crosslink to a dodecamer but not to an octadecamer containing the same sequence placed either at its 3'-end or 5'-end.

Recognition of nonhybridizing base pairs during nucleotide excision repair of DNA

Nondistorting C4' backbone adducts serve as molecular tools to analyze the strategy by which a limited number of human nucleotide excision repair (NER) factors recognize an infinite variety of DNA lesions. We have constructed composite DNA substrates containing a noncomplementary site adjacent to a nondistorting C4' adduct to show that the loss of hydrogen bonding contacts between partner strands is an essential signal for the recruitment of NER enzymes. This specific conformational requirement for excision is mediated by the affinity of xeroderma pigmentosum group A (XPA) protein for nonhybridizing sites in duplex DNA. XPA recognizes defective Watson-Crick base pair conformations even in the absence of DNA adducts or other covalent modifications, apparently through detection of hydrophobic base components that are abnormally exposed to the double helical surface. This recognition function of XPA is enhanced by replication protein A (RPA) such that, in combination, XPA and RPA constitute a potent molecular sensor of denatured base pairs. Our results indicate that the XPA-RPA complex may promote damage recognition by monitoring Watson-Crick base pair integrity, thereby recruiting the human NER system preferentially to sites where hybridization between complementary strands is weakened or entirely disrupted.

Identification and characterization of a single-stranded DNA-binding protein from the archaeon Methanococcus jannaschii

Single-stranded DNA-binding proteins (SSBs) play essential roles in DNA replication, recombination, and repair in bacteria and eukarya. We report here the identification and characterization of the SSB of an archaeon, Methanococcus jannaschii. The M. jannaschii SSB (mjaSSB) has significant amino acid sequence similarity to the eukaryotic SSB, replication protein A (RPA), and contains four tandem repeats of the core single-stranded DNA (ssDNA) binding domain originally defined by structural studies of RPA. Homologous SSBs are encoded by the genomes of other archaeal species, including Methanobacterium thermoautotrophicum and Archaeoglobus fulgidus. The purified mjaSSB binds to ssDNA with high affinity and selectivity. The apparent association constant for binding to ssDNA is similar to that of RPA under comparable experimental conditions, and the affinity for ssDNA exceeds that for double-stranded DNA by at least two orders of magnitude. The binding site size for mjaSSB is approximately 20 nucleotides. Given that RPA is related to mjaSSB at the sequence level and to Escherichia coli SSB at the structural level, we conclude that the SSBs of archaea, eukarya, and bacteria share a common core ssDNA-binding domain. This ssDNA-binding domain was presumably present in the common ancestor to all three major branches of life.

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.

Chromatin association of replication protein A

Replication protein A (RPA) is the major single strand-specific DNA-binding protein in eukaryotic cells. We have investigated the distribution of RPA in nuclei of proliferating HeLa cells and found that only one-third of the detectable RPA appeared to be bound to DNA in chromatin, whereas the remainder was free in the nucleosol. This distribution did not significantly change when cells were released from a double thymidine block into the S phase of the cell cycle. Single strand-specific endonucleases failed to mobilize RPA bound to chromatin in G1 phase and S phase HeLa cells. In contrast, brief treatments with pancreatic DNase I or with micrococcal nuclease sufficed to release RPA from its chromatin-binding sites. Sucrose gradient analysis of soluble micrococcal nuclease digests showed that the released RPA sedimented free of mono- or oligonucleosomal chromatin fragments, possibly indicating that most of the detectable RPA may be associated with chromatin sites, which are more open to nuclease attack than bulk chromatin. The surprising conclusion is that the majority of the detectable RPA is, either directly or indirectly, associated with double-stranded DNA regions in chromatin from HeLa cells in G1 phase and in S phase.

The middle subunit of replication protein A contacts growing RNA-DNA primers in replicating simian virus 40 chromosomes

The eukaryotic single-stranded DNA binding protein replication protein A (RPA) participates in major DNA transactions. RPA also interacts through its middle subunit (Rpa2) with regulators of the cell division cycle and of the response to DNA damage. A specific contact between Rpa2 and nascent simian virus 40 DNA was revealed by in situ UV cross-linking. The dynamic attributes of the cross-linked DNA, its size distribution, its RNA primer content, and its replication fork polarity were determined [corrected]. These data suggest that Rpa2 contacts the early DNA chain intermediates synthesized by DNA polymerase alpha-primase (RNA-DNA primers) but not more advanced products. Possible signaling functions of Rpa2 are discussed, and current models of eukaryotic lagging-strand DNA synthesis are evaluated in view of our results.

The DNA replication fork in eukaryotic cells

Replication of the two template strands at eukaryotic cell DNA replication forks is a highly coordinated process that ensures accurate and efficient genome duplication. Biochemical studies, principally of plasmid DNAs containing the Simian Virus 40 origin of DNA replication, and yeast genetic studies have uncovered the fundamental mechanisms of replication fork progression. At least two different DNA polymerases, a single-stranded DNA-binding protein, a clamp-loading complex, and a polymerase clamp combine to replicate DNA. Okazaki fragment synthesis involves a DNA polymerase-switching mechanism, and maturation occurs by the recruitment of specific nucleases, a helicase, and a ligase. The process of DNA replication is also coupled to cell-cycle progression and to DNA repair to maintain genome integrity.

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.

Mutants with changes in different domains of yeast replication protein A exhibit differences in repairing the control region, the transcribed strand and the non-transcribed strand of the Saccharomyces cerevisiae MFA2 gene

We have analysed the removal of UV-induced cyclobutane pyrimidine dimers (CPDs) at nucleotide resolution from the MFA2 gene of wild-type Saccharomyces cerevisiae and in strains harbouring mutations in one of the yeast replication protein A (RPA) genes, RFA1. This gene codes for the 70 kDa subunit of RPA and it has previously been shown to have a role in nucleotide excision repair. Here two RFA1 mutants were examined: rfa1-M2 which is mutated in the protein interaction domain and rfa1-M4 which is mutated in the DNA-binding domain. A distinct difference in the removal of CPDs from the MFA2 sequence of these two mutants was observed. Compared to the parental strain, there was no defect in CPD removal in the rfa1-M2 mutant. Contrarily, the rfa1-M4 mutant was totally defective in the global repair of CPDs from the non-transcribed strand and the non-transcribed portions of the strand containing the transcribed sequence, yet it was able to perform reduced transcription coupled repair of the transcribed strand. These results indicate that the role of the DNA-binding domain of RPA is different for global repair versus transcription coupled nucleotide excision repair.

The RPA32 subunit of human replication protein A contains a single-stranded DNA-binding domain

Replication protein A (RPA) is a conserved nuclear single-stranded DNA (ssDNA)-binding protein. Human RPA (hRPA) comprises three subunits of approximately 70, 32, and 14 kDa (hRPA70, hRPA32 and hRPA14). RPA is known to bind ssDNA through two ssDNA-binding domains in the RPA70 subunit. Here, we demonstrate that the complex of hRPA32 and hRPA14 has an ssDNA-binding domain. Limited proteolysis of the hRPA14.32 complex defined a core dimer composed of the central region of hRPA32 (amino acids 43-171) and RPA14. The core dimer bound ssDNA with an affinity of approximately 10-50 microM, which is at least 100-fold more avid than the DNA-binding affinity of the intact dimer. Analysis of the predicted secondary structure of hRPA32 suggests that amino acids 63-150 of hRPA32 form an ssDNA-binding domain similar in structure to each of those in hRPA70. The complex of hRPA14 and hRPA32-(43-171) in turn formed a trimeric complex with the C-terminal region of hRPA70 (amino acids 436-616). The ssDNA-binding affinity of this trimeric complex was 3 to 5-fold higher than hRPA14.32-(43-171) alone, suggesting a role for the C terminus of hRPA70 in ssDNA binding.

Subunits of human replication protein A are crosslinked by photoreactive primers synthesized by DNA polymerases

Human replication protein A (huRPA) is a multisubunit protein which is involved in DNA replication, repair and recombination processes. It exists as a stable heterotrimer consisting of p70, p32 and p14 subunits. To understand the contribution of huRPA subunits to DNA binding we applied the photoaffinity labeling technique. The photoreactive oligonucleotide was synthesized in situ by DNA polymerases. 5-[N-(2-nitro-5-azidobenzoyl)-trans -3-aminopropenyl-1]deoxyuridine-5'-triphosphate (NABdUTP) was used as substrate for elongation of a radiolabeled primer logical ortemplate either by human DNA polymerase alpha primase (polalpha), human DNA polymerase beta (polbeta) or Klenow fragment of Escherichia coli DNA polymerase I (KF). The polymerase was incubated with NABdUTP and radiolabeled primer-template in the presence or absence of huRPA. The reaction mixtures were then irradiated with monochromatic UV light (315 nm) and the crosslinked products were separated by SDS-PAGE. The results clearly demonstrate crosslinking of the huRPA p70 and p32 subunits with DNA. The p70 subunit appears to bind to the single-stranded part of the DNA duplex, the p32 subunit locates near the 3'-end of the primer, while the p14 subunit locates relatively far from the 3'-end of the primer. This approach opens new possibilities for analysis of huRPA loading on DNA in the course of DNA replication and DNA repair.

Characterization of strand exchange activity of yeast Rad51 protein

The Saccharomyces cerevisiae RAD51 gene product takes part in genetic recombination and repair of DNA double strand breaks. Rad51, like Escherichia coli RecA, catalyzes strand exchange between homologous circular single-stranded DNA (ssDNA) and linear double-stranded DNA (dsDNA) in the presence of ATP and ssDNA-binding protein. The formation of joint molecules between circular ssDNA and linear dsDNA is initiated at either the 5' or the 3' overhanging end of the complementary strand; joint molecules are formed only if the length of the overhanging end is more than 1 nucleotide. Linear dsDNAs with recessed complementary or blunt ends are not utilized. The polarity of strand exchange depends upon which end is used to initiate the formation of joint molecules. Joint molecules formed via the 5' end are processed by branch migration in the 3'-to-5' direction with respect to ssDNA, and joint molecules formed with a 3' end are processed in the opposite direction.

Denaturation of the simian virus 40 origin of replication mediated by human replication protein A

The initiation of simian virus 40 (SV40) replication requires recognition of the viral origin of replication (ori) by SV40 T antigen, followed by denaturation of ori in a reaction dependent upon human replication protein A (hRPA). To understand how origin denaturation is achieved, we constructed a 48-bp SV40 "pseudo-origin" with a central 8-nucleotide (nt) bubble flanked by viral sequences, mimicking a DNA structure found within the SV40 T antigen-ori complex. hRPA bound the pseudo-origin with similar stoichiometry and an approximately fivefold reduced affinity compared to the binding of a 48-nt single-stranded DNA molecule. The presence of hRPA not only distorted the duplex DNA flanking the bubble but also resulted in denaturation of the pseudo-origin substrate in an ATP-independent reaction. Pseudo-origin denaturation occurred in 7 mM MgCl2, distinguishing this reaction from Mg2+-independent DNA-unwinding activities previously reported for hRPA. Tests of other single-stranded DNA-binding proteins (SSBs) revealed that pseudo-origin binding correlates with the known ability of these SSBs to support the T-antigen-dependent origin unwinding activity. Our results suggest that hRPA binding to the T antigen-ori complex induces the denaturation of ori including T-antigen recognition sequences, thus releasing T antigen from ori to unwind the viral DNA. The denaturation activity of hRPA has the potential to play a significant role in other aspects of DNA metabolism, including DNA repair.

The binding-site sizes of Escherichia coli single-stranded-DNA-binding protein and mammalian replication protein A are 65 and >/= 54 nucleotides respectively

The electrophoretic mobilities of complexes formed with single-stranded (ss) DNA and tetrameric Escherichia coli ssDNA-binding protein (EcoSSB) or mammalian replication protein A (RPA) were analysed. The electrophoretic mobilities of the complexes in a native polyacrylamide gel increased as the lengths of the DNA increased from 28 to 70 nt, thus revealing paradoxical 'descending-staircase' patterns. Increases in the electrophoretic mobilities of EcoSSB.ssDNA complexes were observed when the lengths of the bound DNA were increased by 1 nt. Quantitative analyses of the complexes suggested that the binding-sites sizes of EcoSSB and RPA were 65 and >=54 nt respectively. The binding-site size for RPA is at least 24 nt larger than previously reported.

Replication protein A. Characterization and crystallization of the DNA binding domain

Replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein in eukaryotic cells. The DNA binding activity of human RPA has been previously localized to the N-terminal 441 amino acids of the 70-kDa subunit, RPA70. We have used a combination of limited proteolysis and mutational analysis to define the smallest soluble fragment of human RPA70 that retains complete DNA binding activity. This fragment comprises residues 181-422. RPA181-422 bound DNA with the same affinity as the 1-441 fragment and had a DNA binding site of 8 nucleotides or less. RPA70 fragments were subjected to crystal trials in the presence of single-stranded DNA, and diffraction quality crystals were obtained for RPA181-422 bound to octadeoxycytidine. The RPA181-422 co-crystals belonged to the P2(1)2(1)2(1) space group, with unit cell dimensions of a = 34.3 A, b = 78.0 A, and c = 95.4 A and diffracted to a resolution of 2.1 A.

Structural features of phi29 single-stranded DNA-binding protein. II. Global conformation of phi29 single-stranded DNA-binding protein and the effects of complex formation on the protein and the single-stranded DNA

The strand-displacement mechanism of Bacillus subtilis phage phi29 DNA replication occurs through replicative intermediates with high amounts of single-stranded DNA (ssDNA). These ssDNA must be covered by the viral ssDNA-binding protein, phi29 SSB, to be replicated in vivo. To understand the characteristics of phi29 SSB-ssDNA complex that could explain the requirement of phi29 SSB, we have (i) determined the hydrodynamic behavior of phi29 SSB in solution and (ii) monitored the effect of complex formation on phi29 SSB and ssDNA secondary structure. Based on its translational frictional coefficient (3.5 +/- 0.1) x 10(8) gs(-1), and its rotational correlation time, 7.0 +/- 0.5 ns, phi29 SSB was modeled as a nearly spherical ellipsoid of revolution. The axial ratio (p = a/b) could range from 0.8 to 1.0 (oblate model, a < b) or 1.0 to 3.2 (prolate model, a > b). Far-UV CD spectra, indicated that phi29 SSB is highly organized within a wide range of temperatures (15 to 50 degrees C), being mainly constituted by beta-sheet elements (approximately 50%, at pH 7). Complex formation with ssDNA, although inducing minimal changes on the global conformation of phi29 SSB, had a clear stabilizing effect against pH and temperature increase of the solution samples. On the other hand, phi29 SSB binding leads to non-conservative changes of the near-UV CD spectra of ssDNA, which are consistent with different nearest-neighbor interactions of the nucleotide bases upon complex formation. The above results will be compared to those reported for other SSBs and discussed in terms of the functional roles of phi29 SSB.

Replication protein A: a heterotrimeric, single-stranded DNA-binding protein required for eukaryotic DNA metabolism

Replication protein A [RPA; also known as replication factor A (RFA) and human single-stranded DNA-binding protein] is a single-stranded DNA-binding protein that is required for multiple processes in eukaryotic DNA metabolism, including DNA replication, DNA repair, and recombination. RPA homologues have been identified in all eukaryotic organisms examined and are all abundant heterotrimeric proteins composed of subunits of approximately 70, 30, and 14 kDa. Members of this family bind nonspecifically to single-stranded DNA and interact with and/or modify the activities of multiple proteins. In cells, RPA is phosphorylated by DNA-dependent protein kinase when RPA is bound to single-stranded DNA (during S phase and after DNA damage). Phosphorylation of RPA may play a role in coordinating DNA metabolism in the cell. RPA may also have a role in modulating gene expression.

A hierarchy of SSB protomers in replication protein A

Replication Protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein (SSB) found in all eukaryotic cells. RPA is known to be required for many of the same reactions catalyzed by the homotetrameric SSB of bacteria, but its origin, subunit functions, and mechanism of binding remain a mystery. Here we show that the three subunits of yeast RPA contain a total of four domains with weak sequence similarity to the Escherichia coli SSB protomer. We refer to these four regions as potential ssDNA-binding domains (SBDs). The p69 subunit, which is known to bind ssDNA on its own, contains two SBDs that together confer stable binding to ssDNA. The p36 and p13 subunits each contain a single SBD that does not bind stably, but corresponds to the minimal region required for viability in yeast. Photocross-linking of recombinant protein to ssDNA indicates that an SBD consists of approximately 120 amino acids with two centrally located aromatic residues. Mutation of these aromatic residues inactivates ssDNA binding and is a lethal event in three of the four domains. Finally, we present evidence that the p36 subunit binds ssDNA, as part of the RPA complex, in a salt-dependent reaction similar to the wrapping of ssDNA about E. coli SSB. The results are consistent with the notion that RPA arose by duplication of an ancestral SSB gene and that tetrameric ssDNA-binding domains and higher order binding are essential features of cellular SSBs.

Single-stranded-DNA binding alters human replication protein A structure and facilitates interaction with DNA-dependent protein kinase

Human replication protein A (hRPA) is an essential single-stranded-DNA-binding protein that stimulates the activities of multiple DNA replication and repair proteins through physical interaction. To understand DNA binding and its role in hRPA heterologous interaction, we examined the physical structure of hRPA complexes with single-stranded DNA (ssDNA) by scanning transmission electron microscopy. Recent biochemical studies have shown that hRPA combines with ssDNA in at least two binding modes: by interacting with 8 to 10 nucleotides (hRPA8nt) and with 30 nucleotides (hRPA30nt). We find the relatively unstable hRPA8nt complex to be notably compact with many contacts between hRPA molecules. In contrast, on similar lengths of ssDNA, hRPA30nt complexes align along the DNA and make few intermolecular contacts. Surprisingly, the elongated hRPA30nt complex exists in either a contracted or an extended form that depends on ssDNA length. Therefore, homologous-protein interaction and available ssDNA length both contribute to the physical changes that occur in hRPA when it binds ssDNA. We used activated DNA-dependent protein kinase as a biochemical probe to detect alterations in conformation and demonstrated that formation of the extended hRPA30nt complex correlates with increased phosphorylation of the hRPA 29-kDa subunit. Our results indicate that hRPA binds ssDNA in a multistep pathway, inducing new hRPA alignments and conformations that can modulate the functional interaction of other factors with hRPA.

Replication protein A is a component of a complex that binds the human metallothionein IIA gene transcription start site

Previous studies revealed that sequences surrounding the initiation sites in many mammalian and viral gene promoters, called initiator (Inr) elements, may be essential for promoter strength and for determining the actual transcription start sites. DNA sequences in the vicinity of the human metallothionein IIA (hMTIIA) gene transcription start site share homology with some of the previously identified Inr elements. However, in the present study we have found by in vitro transcription assays that the hMTIIA promoter does not contain a typical Inr. Electrophoretic mobility shift assays identified several DNA-protein complexes at the hMTIIA gene transcription start site. A partially purified protein fraction containing replication protein A (RPA) binds to the hMTIIA gene transcription start site and represses transcription from the hMTIIA promoter in vitro. In addition, overexpression of the human 70-kDa RPA-1 protein represses transcription of a reporter gene controlled by the hMTIIA promoter in vivo. These findings suggest that hMTIIA transcription initiation is controlled by a mechanism different from most mammalian and viral promoters and that the previously identified RPA may also be involved in transcription regulation.

Purification, gene cloning, and reconstitution of the heterotrimeric single-stranded DNA-binding protein from Schizosaccharomyces pombe

We have purified a single-stranded DNA-binding protein (SSB) from Schizosaccharomyces pombe (Sp) and have shown that it is composed of three subunits of 68, 30, and 12 kDa. The SpSSB supports T antigen-dependent unwinding of SV40 ori containing DNA, but is not functional in the SV40 in vitro replication reaction. All three genes that encode the SpSSB subunit have been isolated. The cloned cDNA of the ssb1(+), encoding the p68 subunit, contains 609 amino acids (68.3 kDa), while that of the ssb2(+), encoding the p30 subunit, contains a 279 amino acids (30.3 kDa). The genomic DNA clone of the p12 subunit gene (ssb3(+)) has 2 introns and an open reading frame of 104 amino acids (11.8 kDa). Significant homology is observed among the largest and middle subunits of eukaryotic SSBs, but there is poor homology among the smallest subunits. In addition, we have reconstituted the SpSSB complex by coexpression of all three subunits in Escherichia coli. The reconstituted complex is active in single-stranded DNA binding and the T antigen-dependent unwinding of SV40 ori DNA. Finally, we observed a cell cycle-dependent phosphorylation pattern of the p30 subunit of SpSSB, which is similar to that observed for the human and Saccharomyces cerevisiae SSB.

Phosphorylation of human replication protein A by the DNA-dependent protein kinase is involved in the modulation of DNA replication

The single-stranded DNA-binding protein, Replication Protein A (RPA), is a heterotrimeric complex with subunits of 70, 32 and 14 kDa involved in DNA metabolism. RPA may be a target for cellular regulation; the 32 kDa subunit (RPA32) is phosphorylated by several cellular kinases including the DNA-dependent protein kinase (DNA-PK). We have purified a mutant hRPA complex lacking amino acids 1-33 of RPA32 (rhRPA x 32delta1-33). This mutant bound ssDNA and supported DNA replication; however, rhRPA x 32delta1-33 was not phosphorylated under replication conditions or directly by DNA-PK. Proteolytic mapping revealed that all the sites phosphorylated by DNA-PK are contained on residues 1-33 of RPA32. When wild-type RPA was treated with DNA-PK and the mixture added to SV40 replication assays, DNA replication was supported. In contrast, when rhRPA x 32delta1-33 was treated with DNA-PK, DNA replication was strongly inhibited. Because untreated rhRPA x 32delta1-33 is fully functional, this suggests that the N-terminus of RPA is needed to overcome inhibitory effects of DNA-PK on other components of the DNA replication system. Thus, phosphorylation of RPA may modulate DNA replication indirectly, through interactions with other proteins whose activity is modulated by phosphorylation.

Dissection of functional domains of the human DNA replication protein complex replication protein A

Replication protein A (RPA) is a mammalian single-stranded DNA binding factor essential for DNA replication, repair, and recombination. It is composed of three subunits of 70, 34, and 13 kDa (Rpa1, Rpa2, and Rpa3, respectively). Deletion mapping of the Rpa2 subunit identified the domain required for interaction with Rpa1 and Rpa3 which does not include the N-terminal domain that is phosphorylated during S phase. Deletion mapping of Rpa1 defined three domains. The C-terminal third of the Rpa1 polypeptide binds Rpa2 which itself forms a bridge between Rpa1 and Rpa3. The N-terminal third of Rpa1 bound single-stranded DNA under low stringency conditions only (0.1 M NaCl), while a central domain binds to single-stranded DNA under both low and high stringency conditions (0.5 M NaCl). Binding to p53 requires the N-terminal third of Rpa1 with some contribution from the C-terminal third. The evolutionarily conserved putative zinc finger near the C terminus of Rpa1 was not required for binding to single-stranded DNA, Rpa2, or p53. However, all three subdomains of Rpa1 and the zinc finger were essential for supporting DNA replication in vitro. These experiments are a first step toward defining peptide components responsible for the many functions of the RPA protein complex.