Single-stranded DNA binding protein from calf thymus. Purification, properties, and stimulation of the homologous DNA-polymerase-alpha-primase complex

Characterization of exceptionally thermostable single-stranded DNA-binding proteins from Thermotoga maritima and Thermotoga neapolitana

Background

In recent years, there has been an increasing interest in SSBs because they find numerous applications in diverse molecular biology and analytical methods.

Results

We report the characterization of single-stranded DNA binding proteins (SSBs) from the thermophilic bacteria Thermotoga maritima (TmaSSB) and Thermotoga neapolitana (TneSSB). They are the smallest known bacterial SSB proteins, consisting of 141 and 142 amino acid residues with a calculated molecular mass of 16.30 and 16.58 kDa, respectively. The similarity between amino acid sequences of these proteins is very high: 90% identity and 95% similarity. Surprisingly, both TmaSSB and TneSSB possess a quite low sequence similarity to Escherichia coli SSB (36 and 35% identity, 55 and 56% similarity, respectively). They are functional as homotetramers containing one single-stranded DNA binding domain (OB-fold) in each monomer. Agarose mobility assays indicated that the ssDNA-binding site for both proteins is salt independent, and fluorescence spectroscopy resulted in a size of 68 ± 2 nucleotides. The half-lives of TmaSSB and TneSSB were 10 h and 12 h at 100°C, respectively. When analysed by differential scanning microcalorimetry (DSC) the melting temperature (T_m) was 109.3°C and 112.5°C for TmaSSB and TneSSB, respectively.

Conclusion

The results showed that TmaSSB and TneSSB are the most thermostable SSB proteins identified to date, offering an attractive alternative to TaqSSB and TthSSB in molecular biology applications, especially with using high temperature e. g. polymerase chain reaction (PCR).

Saccharomyces cerevisiae replication protein A binds to single-stranded DNA in multiple salt-dependent modes

We have examined the single-stranded DNA (ssDNA) binding properties of the Saccharomyces cerevisiae replication protein A (scRPA) using fluorescence titrations, isothermal titration calorimetry, and sedimentation equilibrium to determine whether scRPA can bind to ssDNA in multiple binding modes. We measured the occluded site size for scRPA binding poly(dT), as well as the stoichiometry, equilibrium binding constants, and binding enthalpy of scRPA-(dT)L complexes as a function of the oligodeoxynucleotide length, L. Sedimentation equilibrium studies show that scRPA is a stable heterotrimer over the range of [NaCl] examined (0.02-1.5 M). However, the occluded site size, n, undergoes a salt-dependent transition between values of n = 18-20 nucleotides at low [NaCl] and values of n = 26-28 nucleotides at high [NaCl], with a transition midpoint near 0.36 M NaCl (25.0 degrees C, pH 8.1). Measurements of the stoichiometry of scRPA-(dT)L complexes also show a [NaCl]-dependent change in stoichiometry consistent with the observed change in the occluded site size. Measurements of the deltaH(obsd) for scRPA binding to (dT)L at 1.5 M NaCl yield a contact site size of 28 nucleotides, similar to the occluded site size determined at this [NaCl]. Altogether, these data support a model in which scRPA can bind to ssDNA in at least two binding modes, a low site size mode (n = 18 +/- 1 nucleotides), stabilized at low [NaCl], in which only three of its oligonucleotide/oligosaccharide binding folds (OB-folds) are used, and a higher site size mode (n = 27 +/- 1 nucleotides), stabilized at higher [NaCl], which uses four of its OB-folds. No evidence for highly cooperative binding of scRPA to ssDNA was found under any conditions examined. Thus, scRPA shows some behavior similar to that of the E. coli SSB homotetramer, which also shows binding mode transitions, but some significant differences also exist.

A highly thermostable, homodimeric single-stranded DNA-binding protein from Deinococcus radiopugnans

We report the identification and characterization of the single-stranded DNA-binding protein (SSB) from the mesophile and highly radiation-resistant Deinococcus radiopugnans (DrpSSB). PCR-derived DNA fragment containing the complete structural gene for DrpSSB protein was cloned and expressed in Escherichia coli. The gene consisting of an open reading frame of 900 nucleotides encodes a protein of 300 amino acids with a calculated molecular weight of 32.45 kDa and pI 5.34. The amino acids sequence exhibits 43, 44, 79 and 18% identity with Thermus aquaticus, Thermus thermophilus, Deinococcus radiodurans and E. coli SSBs, respectively. The DrpSSB includes two OB folds per monomer and functions as a homodimer. In fluorescence titrations with poly(dT), DrpSSB bound 24-31 nt depending on the salt concentration, and fluorescence was quenched by about 80%. In a complementation assay in E. coli, DrpSSB took over the in vivo function of EcoSSB. The half-lives of DrpSSB were 120 min at 90 degrees C, 60 min at 95 degrees C and 30 min at 100 degrees C. These results were surprising in the context of half-life of SSB from thermophilic T. aquaticus, which has only 30 s of half-life at 95 degrees C. DrpSSB is the most thermostable SSB-like protein identified to date, offering an attractive alternative for TaqSSB and TthSSB in their applications for molecular biology methods and analytical purposes.

Novel thermostable single-stranded DNA-binding protein (SSB) from Deinococcus geothermalis

To study the biochemical properties of single-stranded DNA-binding (SSB) protein from Deinococcus geothermalis (DgeSSB), we have cloned the ssb gene obtained by PCR and developed an overexpression system. The gene consists of an open reading frame of 900 nucleotides encoding a protein of 300 amino acids with a calculated molecular weight of 32.45 kDa. The amino acid sequence exhibits 43, 44 and 75% identity with Thermus aquaticus, Thermus thermophilus and Deinococcus radiodurans SSBs, respectively. We show that DgeSSB is similar to Thermus/Deinococcus SSB in its biochemical properties. DgeSSB includes two oligonucleotide/oligosaccharide-binding folds per monomer and functions as a homodimer. In fluorescence titrations with poly(dT), DgeSSB bound about 30 nt independent of the salt concentration, and the fluorescence was quenched by about 65%. In a complementation assay in Escherichia coli, DgeSSB took over the in vivo function of EcoSSB. DgeSSB is thermostable with half-lives of 50 min at 70 degrees C and 5 min at 90 degrees C. Hence, DgeSSB offers an attractive alternative for TaqSSB and TthSSB in their applications for molecular biology methods and for analytical purposes.

Initiation of eukaryotic DNA replication: regulation and mechanisms

The accurate and timely duplication of the genome is a major task for eukaryotic cells. This process requires the cooperation of multiple factors to ensure the stability of the genetic information of each cell. Mutations, rearrangements, or loss of chromosomes can be detrimental to a single cell as well as to the whole organism, causing failures, disease, or death. Because of the size of eukaryotic genomes, chromosomal duplication is accomplished in a multiparallel process. In human somatic cells between 10,000 and 100,000 parallel synthesis sites are present. This raises fundamental problems for eukaryotic cells to coordinate the start of DNA replication at each origin and to prevent replication of already duplicated DNA regions. Since these general phenomena were recognized in the middle of the 20th century the regulation and mechanisms of the initiation of eukaryotic DNA replication have been intensively investigated. These studies were carried out to find the essential factors involved in the process and to determine their functions during DNA replication. These studies gave rise to a model of the organization and the coordination of DNA replication within the eukaryotic cell. The elegant experiments carried out by Rao and Johnson (1970) (1), who fused cells in different phases of the cell cycle, showed that G1 cells are competent for replication of their chromosomes, but lack a specific diffusible factor required to activate their replicaton machinery and showed that G2 cells are incompetent for DNA replication. These findings suggested that eukaryotic cells exist in two states. In G1 phase, cells are competent to initiate DNA replication, which is subsequently triggered in S phase. After completion of S phase, cells in G2 are no longer able to initiate DNA replication and they require a transition through mitosis to reenable initiation of DNA replication to take place in the next S phase. The Xenopus cell-free replication system has proved a good model system in which to study DNA replication in vitro as well as the mechanism preventing rereplication within a single cell cycle (2). Studies using this system resulted in the development of a model postulating the existence of a replication licensing factor, which binds to chromatin before the G1-S transition and which is displaced during replication (2, 3). These results were supported by genetic and biochemical experiments in Saccharomyces cerevisiae (budding yeast) and Schizosaccharomyces pombe (fission yeast) (4, 5). The investigation of cell division cycle mutants and the budding yeast origin of replication resulted in the concept of a prereplicative and a postreplicative complex of initiation proteins (6-9). These three individual concepts have recently started to merge and it has become obvious that initiation in eukaryotes is generally governed by the same ubiquitous mechanisms.

Identification and characterization of single-stranded-DNA-binding proteins from Thermus thermophilus and Thermus aquaticus - new arrangement of binding domains

Single-stranded-DNA-binding proteins (SSBs) play essential roles in DNA replication, recombination and repair in bacteria, archaea and eukarya. This paper reports the identification and characterization of the SSB-like proteins of the thermophilic bacteria Thermus thermophilus and Thermus aquaticus. These proteins (TthSSB and TaqSSB), in contrast to their known counterparts from mesophilic bacteria, archaea and eukarya, are homodimers, and each monomer contains two ssDNA-binding domains with a conserved OB (oligonucleotide/oligosaccharide-binding) fold, as deduced from the sequence analysis. The N-terminal domain is located in the region from amino acid 1 to 123 and the C-terminal domain is located between amino acids 124 and 264 or 266 in TthSSB and TaqSSB, respectively. Purified TthSSB or TaqSSB binds only to ssDNA and with high affinity. The binding site size for TaqSSB and TthSSB protein corresponds to 30-35 nucleotides. It is concluded that the SSBs of thermophilic and mesophilic bacteria, archaea and eukarya 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.

Novel thermostable ssDNA-binding proteins from Thermus thermophilus and T. aquaticus-expression and purification

Single-stranded DNA-binding proteins (SSBs) play essential roles in DNA replication, recombination, and repair in bacteria, archaea, and eukarya. We report here the identification, expression, and purification of the SSB-like proteins of the thermophilic bacteria Thermus thermophilus and T. aquaticus. The nucleotide (nt) sequence revealed that T. thermophilus SSB (TthSSB) and T. aquaticus (TaqSSB) consist of 264 and 266 amino acids, respectively, and have a molecular weight of 29.87 and 30.03kDa, respectively. The homology between these protein, is very high-82% identity and 90% similarity. They are the largest known prokaryotic SSB proteins. TthSSB and TaqSSB monomers have two putative ssDNA-binding sequences: N-terminal (located in the region from amino acids 1 to 123) and C-terminal (located between amino acids 124 and 264 or 266 in TthSSB and TaqSSB, respectively). PCR-derived DNA fragment containing the complete structural gene for TthSSB or TaqSSB protein was cloned into an expression vector. The clones expressing SSB-like proteins were selected and cloned DNA fragments were verified to be authentic by sequencing several clones. The purification was carried out using reduction of contamination by the host protein with heat treatment, followed by QAE-cellulose and ssDNA-cellulose column chromatography. We found our expression and purification system to be quite convenient and efficient, and will use it for production of thermostable SSB-proteins for crystallography study. We have applied the use of TthSSB and TaqSSB protein to increase the amplification efficiency with a number of diverse templates. The use of SSB protein may prove to be generally applicable in improving the PCR efficiency.

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.

Protein-protein interactions of the primase subunits p58 and p48 with simian virus 40 T antigen are required for efficient primer synthesis in a cell-free system

DNA polymerase alpha-primase (pol-prim, consisting of p180-p68-p58-p48), and primase p58-p48 (prim(2)) synthesize short RNA primers on single-stranded DNA. In the SV40 DNA replication system, only pol-prim is able to start leading strand DNA replication that needs unwinding of double-stranded (ds) DNA prior to primer synthesis. At high concentrations, pol-prim and prim(2) indistinguishably reduce the unwinding of dsDNA by SV40 T antigen (Tag). RNA primer synthesis on ssDNA in the presence of replication protein A (RPA) and Tag has served as a model system to study the initiation of Okazaki fragments on the lagging strand in vitro. On ssDNA, Tag stimulates whereas RPA inhibits the initiation reaction of both enzymes. Tag reverses and even overcompensates the inhibition of primase by RPA. Physical binding of Tag to the primase subunits and RPA, respectively, is required for these activities. Each subunit of the primase complex, p58 and p48, performs physical contacts with Tag and RPA independently of p180 and p68. Using surface plasmon resonance, the dissociation constants of the Tag/pol-prim and Tag/primase interactions were 1.2 x 10(-8) m and 1.3 x 10(-8) m, respectively.

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.

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.

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

The largest subunit of the replication protein A (RPA) contains an evolutionarily conserved zinc finger motif that lies outside of the domains required for binding to single-stranded DNA or forming the RPA holocomplex. In previous studies, we showed that a point mutation in this motif (RPAm) cannot support SV40 DNA replication. We have now investigated the role of this motif in several steps of DNA replication and in two DNA repair pathways. RPAm associates with T antigen, assists the unwinding of double-stranded DNA at an origin of replication, stimulates DNA polymerases alpha and delta, and supports the formation of the initial short Okazaki fragments. However, the synthesis of a leading strand and later Okazaki fragments is impaired. In contrast, RPAm can function well during the incision step of nucleotide excision repair and in a full repair synthesis reaction, with either UV-damaged or cisplatin-adducted DNA. Two deletion mutants of the Rpa1 subunit (eliminating amino acids 1-278 or 222-411) were not functional in nucleotide excision repair. We report for the first time that wild type RPA is required for a mismatch repair reaction in vitro. Neither the deletion mutants nor RPAm can support this reaction. Therefore, the zinc finger of the largest subunit of RPA is required for a function that is essential for DNA replication and mismatch repair but not for nucleotide excision repair.

Role of protein-protein interactions in the function of replication protein A (RPA): RPA modulates the activity of DNA polymerase alpha by multiple mechanisms

Replication Protein A (RPA) from human cells is a stable complex of 70-, 32-, and 14-kDa subunits that is required for multiple processes in DNA metabolism. RPA binds with high affinity to single-stranded DNA and interacts with multiple proteins, including proteins required for the initiation of SV40 DNA replication, DNA polymerase alpha and SV40 large T antigen. We have used a series of mutant derivatives of RPA to map the regions of RPA required for specific protein-protein interactions and have examined the roles of these interactions in DNA replication. T antigen, DNA polymerase alpha and the activation domain of VP16 all have overlapping sites of interaction in the N-terminal half (residues 1-327) of the 70-kDa subunit of RPA. In addition, the interaction site for DNA polymerase alpha is composed of two functionally distinct regions, one (residues 1- approximately 170) which stimulates polymerase activity and a second (residues approximately 170-327) which increases polymerase processivity. In the latter, both the direct protein-protein interaction and ssDNA-binding activities of RPA were needed for RPA to modulate polymerase processivity. We also found that SV40 T antigen inhibited the ability of RPA to increase processivity of DNA polymerase alpha, suggesting that this activity of RPA may be important for elongation but not during the initiation of DNA replication. DNA polymerase alpha, but not T antigen also interacted with the 32- and/or 14-kDa subunits of RPA, but these interactions did not seem to effect polymerase activity.

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.

Functional domains of the 70-kilodalton subunit of human replication protein A

Human replication protein A (RPA) is a single-stranded DNA-binding protein that is composed of subunits of 70, 32, and 14 kDa. This heterotrimeric complex is required for multiple processes in DNA metabolism including DNA replication, DNA repair, and recombination. Previous studies have suggested that the 616 amino acid, 70-kDa subunit of RPA (RPA 70) is composed of multiple structural/functional domains. We used a series of N-terminal deletions of RPA70 to define the boundaries of these domains and elucidate their functions. Mutant RPA complexes missing residues 1-168 of RPA70 bound ssDNA with high affinity and supported SV40 replication in vitro. In contrast, deletions extending beyond residue 168 showed a decreased affinity for ssDNA and were inactive in SV40 DNA replication. When residues 1-381 were deleted, the resulting truncated RPA70 was unable to bind ssDNA but still formed a stable complex with the 32- and 14-kDa subunits of RPA. Thus, the C-terminal domain of RPA70 is both necessary and sufficient for RPA complex formation. These data indicate that RPA70 is composed of three functional domains: an N-terminal domain that is not required for ssDNA binding or SV40 replication, a central DNA-binding domain, and a C-terminal domain that is essential for subunit interactions. For all mutant complexes examined, both phosphorylation of the 32-kDa subunit of RPA and the ability to support T antigen-dependent, origin-dependent DNA unwinding correlated with ssDNA binding activity.

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.

Proteolytic mapping of human replication protein A: evidence for multiple structural domains and a conformational change upon interaction with single-stranded DNA

Replication protein A (RPA) is multisubunit single-stranded DNA-binding protein required for multiple processes in DNA metabolism including DNA replication, DNA repair, and recombination. Human RPA is a stable complex of three subunits of 70, 32, and 14 kDa (RPA70, RPA32, and RPA14, respectively). We examined the structure of both wild-type and mutant forms of human RPA by mapping sites sensitive to proteolytic cleavage. For all three subunits, only a subset of the possible protease cleavage sites was sensitive to digestion. RPA70 was cleaved into multiple fragments of defined lengths. RPA32 was cleaved rapidly to a approximately 28-kDa polypeptide containing the C-terminus that was partially resistant to further digestion. RPA14 was refractory to digestion under the conditions used in these studies. The digestion properties of a complex of RPA32 and RPA14 were similar to those of the native heterotrimeric RPA complex, indicating that the structure of these subunits is similar in both complexes. Epitopes recognized by monoclonal antibodies to RPA70 were mapped, and this information was used to determine the position of individual cleavage events. These studies suggest that RPA70 is composed of at least two structural domains: an approximately 18-kDa N-terminal domain and a approximately 52-kDa C-terminal domain. The N-terminus of RPA70 was not required for single-stranded DNA-binding activity. Multiple changes in the digestion pattern were observed when RPA bound single-stranded DNA: degradation of the approximately 52-kDa domain of RPA70 was inhibited while proteolysis of RPA32 was stimulated. These data indicate that RPA undergoes a conformational change upon binding to single-stranded DNA.

Rpa4, a homolog of the 34-kilodalton subunit of the replication protein A complex

Replication protein A (RPA) is a complex of three polypeptides of 70, 34, and 13 kDa isolated from diverse eukaryotes. The complex is a single-stranded DNA-binding protein essential for simian virus 40-based DNA replication in vitro and for viability in the yeast Saccharomyces cerevisiae. We have identified a new 30-kDa human protein which interacts with the 70- and 13-kDa subunits of RPA, with a yeast two-hybrid/interaction trap method. This protein, Rpa4, has 47% identity with Rpa2, the 34-kDa subunit of RPA. Rpa4 associates with the 70- and 13-kDa subunits to form a trimeric complex capable of binding to single-stranded DNA. Rpa4 is preferentially expressed in placental and colon mucosa tissues. In the placenta, Rpa4 is more abundant than the 70-kDa Rpa1 subunit and is not associated with either Rpa1 or with any other single-stranded DNA-binding protein. In proliferating cells in culture, Rpa4 is considerably less abundant than Rpa1 and Rpa2. Northern (RNA) blot analysis suggest that there are alternatively processed forms of the RPA4 mRNA, and Southern blot analysis indicates that beside RPA4 there may be other members of the RPA2 gene family.

Structural analysis of human replication protein A. Mapping functional domains of the 70-kDa subunit

Replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein that is essential for DNA metabolism. Human RPA is composed of subunits of 70, 32, and 14 kDa with intrinsic DNA-binding activity localized to the 616-amino acid, 70-kDa subunit (RPA70). We have made a series of C-terminal deletions to map the functional domains of RPA70. Deletion of the C terminus resulted in polypeptides that were significantly more soluble than RPA70 but were unable to form stable complexes with the other two subunits of RPA. These data suggest that the C-terminal region of RPA70 may be important for complex formation. The DNA-binding domain was localized to a region of RPA70 between residues 1 and 441. A mutant containing residues 1-441 bound oligonucleotides with an intrinsic affinity close to wild-type RPA complex. This mutant also appeared to bind with reduced cooperativity. We conclude that the C terminus of RPA70 and the 32- and 14-kDa subunits are not involved directly with interactions with DNA but may have a role in cooperativity of RPA binding. RPA70 deletion mutants were not able to support DNA replication even in the presence of a complex of the 32- and 14-kDa subunits, suggesting that the heterotrimeric complex is essential for DNA replication. The putative zinc finger in the C terminus of RPA70 is not required for single-stranded DNA-binding activity.

Interactions of human replication protein A with oligonucleotides

Replication protein A (RPA) is a heterotrimeric, single-stranded DNA binding protein that is essential for eukaryotic DNA replication. In order to gain a better understanding of the interactions between RPA and DNA, we have examined the interactions of human RPA with single-stranded oligonucleotides. Our analysis of RPA.DNA complexes demonstrated that RPA binds as a heterotrimer. Stoichiometric binding reactions monitored by fluorescence quenching indicated that the binding site size of human RPA is 30 nucleotides and that between 20-30 nucleotides of DNA directly interact with RPA. The binding of RPA to DNA of different lengths was systematically examined using deoxythymidine-containing oligonucleotides. We found that the binding affinity of RPA for short oligonucleotides was length dependent. The apparent association constant of RPA varied over 200-fold from approximately 7 x 10(7) M-1 for oligo(dT)10 to approximately 1.5 x 10(10) M-1 for oligo(dT)50. Human RPA binds to oligonucleotides with low cooperativity; the cooperativity parameter (omega) for RPA binding was estimated to be approximately 15.

Human replication protein A binds single-stranded DNA in two distinct complexes

Human replication protein A, a single-stranded DNA (ssDNA)-binding protein, is a required factor in eukaryotic DNA replication and DNA repair systems and has been suggested to function during DNA recombination. The protein is also a target of interaction for a variety of proteins that control replication, transcription, and cell growth. To understand the role of hRPA in these processes, we examined the binding of hRPA to defined ssDNA molecules. Employing gel shift assays that "titrated" the length of ssDNA, hRPA was found to form distinct multimeric complexes that could be detected by glutaraldehyde cross-linking. Within these complexes, monomers of hRPA utilized a minimum binding site size on ssDNA of 8 to 10 nucleotides (the hRPA8-10nt complex) and appeared to bind ssDNA cooperatively. Intriguingly, alteration of gel shift conditions revealed the formation of a second, distinctly different complex that bound ssDNA in roughly 30-nucleotide steps (the hRPA30nt complex), a complex similar to that described by Kim et al. (C. Kim, R. O. Snyder, and M. S. Wold, Mol. Cell. Biol. 12:3050-3059, 1992). Both the hRPA8-10nt and hRPA30nt complexes can coexist in solution. We speculate that the role of hRPA in DNA metabolism may be modulated through the ability of hRPA to bind ssDNA in these two modes.

Human replication protein A binds single-stranded DNA in two distinct complexes

Human replication protein A, a single-stranded DNA (ssDNA)-binding protein, is a required factor in eukaryotic DNA replication and DNA repair systems and has been suggested to function during DNA recombination. The protein is also a target of interaction for a variety of proteins that control replication, transcription, and cell growth. To understand the role of hRPA in these processes, we examined the binding of hRPA to defined ssDNA molecules. Employing gel shift assays that "titrated" the length of ssDNA, hRPA was found to form distinct multimeric complexes that could be detected by glutaraldehyde cross-linking. Within these complexes, monomers of hRPA utilized a minimum binding site size on ssDNA of 8 to 10 nucleotides (the hRPA8-10nt complex) and appeared to bind ssDNA cooperatively. Intriguingly, alteration of gel shift conditions revealed the formation of a second, distinctly different complex that bound ssDNA in roughly 30-nucleotide steps (the hRPA30nt complex), a complex similar to that described by Kim et al. (C. Kim, R. O. Snyder, and M. S. Wold, Mol. Cell. Biol. 12:3050-3059, 1992). Both the hRPA8-10nt and hRPA30nt complexes can coexist in solution. We speculate that the role of hRPA in DNA metabolism may be modulated through the ability of hRPA to bind ssDNA in these two modes.

Purification and characterisation of dRP-A: a single-stranded DNA binding protein from Drosophila melanogaster

Replication protein A (RP-A) is an essential single-stranded DNA binding protein (SSB) involved in the initiation and elongation phases of eukaryotic DNA replication. It has the ability to bind single-stranded DNA extremely tightly and possesses a characteristic hetero-trimeric structure. Here we present a method for the purification of RP-A from Drosophila melanogaster embryos. Drosophila RP-A (dRP-A) has subunits of about 66, 31 and 8 kDa, in line with analogues from other species. It binds single-stranded DNA very tightly via the large subunit. The complete protein has at least a 10- to 20-fold preference for single-stranded DNA over double-stranded DNA and it appears that binding is only weakly co-operative. Band shift experiments suggest that it has an approximate site covering the size of 16 nucleotides or less, however, it shows a greater affinity for long oligonucleotides than for short ones. We also demonstrate that dRP-A can stimulate the activity of its homologous DNA polymerase alpha in excess of 20 fold. Analysis of the protein's abundance during embryo development indicates that it varies in a manner akin to other replication proteins.