Identification and Characterization of the Fourth Single-Stranded-DNA Binding Domain of Replication Protein A

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Molecular and Cellular Biology, December 1998, p. 7225-7234, Vol. 18, No. 12
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Identification and Characterization of the Fourth Single-Stranded-DNA Binding Domain of Replication Protein A

Steven J. Brill^* and Suzanne Bastin-Shanower

Department of Molecular Biology, Center for Advanced Biotechnology and Medicine, Rutgers University, Piscataway, New Jersey 08855

Received 28 April 1998/Returned for modification 28 May 1998/Accepted 9 September 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Replication protein A (RPA), the heterotrimeric single-stranded-DNA (ssDNA) binding protein (SSB) of eukaryotes, containstwo homologous ssDNA binding domains (A and B) in its largestsubunit, RPA1, and a third domain in its second-largest subunit,RPA2. Here we report that Saccharomyces cerevisiae RPA1 containsa previously undetected ssDNA binding domain (domain C) lyingin tandem with domains A and B. The carboxy-terminal portion ofdomain C shows sequence similarity to domains A and B and to theregion of RPA2 that binds ssDNA (domain D). The aromatic residuesin domains A and B that are known to stack with the ssDNA basesare conserved in domain C, and as in domain A, one of these isrequired for viability in yeast. Interestingly, the amino-terminalportion of domain C contains a putative Cys₄-type zinc-bindingmotif similar to that of another prokaryotic SSB, T4 gp32. Wedemonstrate that the ssDNA binding activity of domain C is uniquelysensitive to cysteine modification but that, as with gp32, ssDNAbinding is not strictly dependent on zinc. The RPA heterotrimeris thus composed of at least four ssDNA binding domains and exhibitsfeatures of both bacterial and phageSSBs.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Single-stranded-DNA (ssDNA) binding proteins (SSBs) participate in almost every aspect of DNA metabolism. These proteins bindtightly to ssDNA with little or no sequence specificity and activatessDNA by reducing its secondary structure and by stimulating DNApolymerases and DNA helicases. At first glance, the three well-studiedSSBs encoded by phage T4 (gp32), Escherichia coli (Ecssb), andeukaryotes (replication protein A [RPA]) appear to have evolvedvery different ways of accomplishing this task. Gene 32 proteinis a monomer of 33 kDa that binds ssDNA cooperatively ( $omega$ = 3,800),with a binding-site size of 8 nucleotides (nt) (19, 46). Thestructure of gp32 has been determined by X-ray crystallographyand shown to contain a hydrophobic pocket composed of five $beta$ strandsthat contact the ssDNA bases and an electropositive cleft thatcontacts the phosphate backbone (52). While gp32 is a zinc metalloprotein,zinc is not required for ssDNA binding but is required for cooperativityand stabilization of the structure of the core fragment (19,20, 43). The prototype bacterial SSB, Ecssb, is a tetramerof four identical 19-kDa subunits, or protomers, with at leasttwo well-characterized DNA binding modes (38). At low salt concentrations(<10 mM NaCl) two protomers bind 35 nt of ssDNA with unlimitedcooperativity ( $omega$ = 10⁵) (18, 50), and at high salt concentrations ( $>=$ 0.2 M NaCl)four protomers bind 65 nt of ssDNA with limited cooperativity( $omega$ = 420) (9, 38, 39). This larger binding mode resultsin compaction of the ssDNA due to higher-order binding or wrappingabout the tetramer (10, 12, 23).

The nuclear SSB of eukaryotes, RPA, is a heterotrimeric complex that was originally identified as a Homo sapiens protein (hsRPA)required for simian virus 40 (SV40) DNA replication in vitro (17,59-61). RPA has been identified in numerous species, includingthe yeast Saccharomyces cerevisiae (scRPA), where it is a complexof subunits of 69 (RPA1), 36 (RPA2), and 13 (RPA3) kDa (8).Each subunit of RPA is required for SV40 DNA replication (16,30) and for viability in yeast (7, 26).

RPA1 is known to bind ssDNA on its own and for some time was thought to be the only subunit that binds ssDNA (8, 16,30, 62). Structure-function analysis revealed that the N-terminal18 kDa of RPA1 is dispensable for SV40 DNA replication (21)but that the C terminus, which contains a putative Cys₄-type zinc-bindingdomain, is required for RPA2 binding (21, 35, 36). The centralportion of hsRPA1 (residues 168 to 442) contains a major ssDNAbinding domain (21, 22, 35, 44). The notion that RPA mightcontain additional ssDNA binding domains was suggested by thefact that this domain has a 20-fold lower affinity for ssDNA thandoes the heterotrimer (21) and by the fact that different binding-sitesizes have been reported for RPA. These include an 8-nt bindingmode that is dependent on glutaraldehyde cross-linking (3),a 30-nt binding mode that is obtained by fluorescence quenchingand electrophoretic mobility shift assay (EMSA) (2, 32-34, 41,55), and a 90-nt binding mode that is obtained by fluorescencequenching and electron microscopy (EM) (1). These various sizesmight be explained if RPA has multiple ssDNA binding domains andalternative binding modes like Ecssb (45).

Genetic and biochemical analysis in yeast revealed that the major ssDNA binding domain of yeast RPA1 is composed of two homologoussubdomains, A and B, with weak sequence similarity to Ecssb (45).Both domains are required for viability, and domain A can functionallyreplace domain B. Based on a model of ssDNA binding by Ecssb (11),a pair of conserved aromatic residues in each domain was identifiedby amino acid sequence alignment and proposed to stack with thessDNA. One of these, F238, is likely to be important for ssDNAbinding since it was the only residue in scRPA1 that was individuallyrequired for viability. Portions of this model have been confirmedby the crystal structure of residues 181 to 422 of hsRPA1 (RPA1_181-422)bound to ssDNA (5). Bochkarev and colleagues (5) showedthat the central ssDNA binding domain of hsRPA1 is composed oftwo structurally homologous subdomains, or "OB folds" (42) (foroligonucleotide oligosaccharide binding folds), and that bindingby each domain involves a number of hydrogen bonds as well asthe stacking of ssDNA bases with a pair of aromatic residues,one of which is F238. To closely resemble Ecssb, however, twoadditional ssDNA binding domains must exist in the RPA heterotrimer.One of these is in the middle subunit, since it was demonstratedthat RPA2 can bind ssDNA as part of the heterotrimer (45) oras part of the RPA2-RPA3 subcomplex of hsRPA (6). Binding bythe RPA2-RPA3 subcomplex of hsRPA is stimulated by the C terminusof RPA1, suggesting that this domain might contain another ssDNAbinding activity (6). RPA3 was proposed to serve as a bindingdomain; however, no direct evidence has yet been obtained to supportthis idea (45).

Here we show that the fourth ssDNA binding domain of RPA lies in the C terminus of RPA1, adjacent to domains A and B. Thisresult confirms that both cellular SSBs, Ecssb and RPA, have atleast four ssDNA binding domains. Curiously, the new domain inthe C terminus of RPA1 has several features in common with thephage SSB gp32. This suggests that these very different SSBs arelikely to have a common mechanism of function, if not a commonorigin.

	MATERIALS AND METHODS

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DNA constructions. Fragments of the RFA1 gene encoding scRPA1 were isolated on NdeI/BamHI cassettes by 12 rounds of amplification with Vent DNApolymerase and pJM136 (45) as the template. Fragments were ligatedinto pET11a to produce the following E. coli expression plasmids:pJM163 (M1 to K180), pJM158 (M, T181 to N294), pJM159 (M, V295to D415), pJM165 (M, S416 to A485), pJM164 (M, S416 to N511),pJM157 (M, F481 to S601), pJM155 (M, F481 to A621), and pJM185(M, S416 to A621). Point mutations were introduced by two roundsof oligonucleotide-directed PCR mutagenesis, and the mutated sequenceswere ligated into pET11a for E. coli expression or into a yeastshuttle vector to test genetic complementation. The followingdomain C mutation expression plasmids were identical to pJM185except for the indicated mutations: pJM174 (M, S416 to S601, witha C-terminal truncation of 20 amino acids in domain C) and pJM186(C505A and C508A). To test whether an RFA1 gene with point mutationscould complement an RFA1 deletion, we placed the mutations inthe context of an intact RFA1 gene by using the "domain swap"vector pDS1 (45) to produce pDS1.13 (F238A), pDS1.28 (F269A),pDS1.14 (W360A), and pDS1.29 (F385A). Plasmid pDS1C was constructedfor placing domain C mutations into RFA1 by introducing a SalIsite just downstream of the Cys₄ motif (resulting in the aminoacid changes T510V and N511D) and a BglII site near the end ofdomain C (resulting in the amino acid change Y594S). Plasmid pDS1Cwas shown to confer wild-type activity by a complementation testand was used to place mutations in RFA1, which resulted in thefollowing plasmids: pJM183 (C505A and C508A), pDS1C.9 (F537A),and pDS1C.10 (F563A). Complementation with the RPA2 F143A mutationwas tested with pJM243 (45), and complementation with the RPA2W101A mutation was tested with pJM254 (W101A), which was constructedin pDS2 (45). Maltose binding protein (MBP) fusions were constructedin the vector pMAL-c2 (New England Biolabs) by inserting BamHIfragments that were generated by PCR as described above into theunique BamHI site of the vector. Plasmid pJM410 expresses theMBP-A domain fusion (T181 to N294), pJM411 expresses the MBP-Bfusion (V295-D415), and pJM412 expresses the MBP-C fusion (G418-A621).Genetic complementation of the rfa1-1::TRP1 and rfa2-1::TRP1 nullmutations was performed as described previously (45).

Protein expression, purification, and ssDNA binding assay. Recombinant RPA1 proteins were expressed in strain BL21 (DE3) by using the T7 expression system (54). Cells were grown inLuria-Bertani medium at 37°C in the presence of ampicillin andinduced for 16 h by the addition of 0.4 mM IPTG (isopropyl- $beta$ -D-thiogalactopyranoside).Cells were harvested and lysed as described previously (45),and the insoluble pellet from 6 ml of culture was resuspendedin 0.3 ml of 10 M urea. The sample was then diluted with 0.3 mlof 2× buffer A (25 mM Tris [pH 7.5], 1 mM EDTA, 0.01% NonidetP-40, 10% glycerol, 0.1 mM phenylmethylsulfonyl fluoride, 1 mMdithiothreitol [DTT]) containing 200 mM NaCl, and the sample wascentrifuged 15 min at 4°C. The soluble portion was then sequentiallydialyzed to 2, 1, 0.5, and 0 M urea in dialysis buffer consistingof buffer A and 100 mM NaCl, 10 mM MgCl₂, and 20 µM ZnSO₄. Eachdialysis step was carried out for 8 to 16 h. Precipitates wereremoved by centrifugation, and the soluble sample, typically 0.3mg of recombinant protein per ml, was stored at $-$ 80°C. Proteinconcentrations were determined by comparison to known standardson Coomassie blue-stained sodium dodecyl sulfate (SDS)-polyacrylamidegels.

MBP fusion proteins were expressed in strain XL1-Blue grown in Luria-Bertani medium with 0.2% glucose and 0.1 mg of ampicillinper ml. A 1-liter culture was induced for 2 h with 0.3 mM IPTG,and the cells were collected by centrifugation and resuspendedin buffer A containing 50 mM NaCl and 1 mg of lysozyme per ml.All buffers for MBP-C also contained 20 µM ZnSO₄ throughout thepurification. All steps were performed either on ice or at 4°C.Following a 15-min incubation on ice, the samples were subjectedto one freeze-thaw cycle and four sonication cycles (15 s each).The lysate was clarified by centrifugation, diluted fivefold withbuffer A containing 50 mM NaCl, and applied to a 15-ml amylose-affinityresin. The resin was washed with 8 column volumes of buffer Acontaining 300 mM NaCl, and the MBP fusion proteins were elutedin a step with buffer A containing 50 mM NaCl and 10 mM maltose.Peak fractions were identified by the Bradford assay, pooled,and loaded onto a Mono Q column. This column was washed with 3ml of buffer A containing 50 mM NaCl and eluted with an 8-ml gradientfrom 50 mM to 1 M NaCl. The peak fractions (0.15 M NaCl) wereidentified by SDS-polyacrylamide gel electrophoresis (PAGE), pooled,and dialyzed to buffer A containing 50 mMNaCl.

Typically, 10 µl of ssDNA binding reaction mixtures containing protein extracts from E. coli were incubated with a 10,000cpm (2 fmol) of ³²P-labeled 17-base oligonucleotide (universal sequencing primer)in the following solution: 10 mM HEPES (pH 7.5)-0.5 mM DTT-10µg of sheared salmon sperm DNA per ml. Reaction mixtures werecross-linked and analyzed as described previously (45). Bindingreactions for MBP fusion proteins were carried out under identicalconditions except that they were UV cross-linked at 500 J/m² to minimize the time of UV exposure. Gels were analyzed witha phosphorimager, and the intensities of the bound and free probeswere quantitated with IP-Lab Gel software. The K_d for each bindingreaction was then determined by fitting the data to the Langmuirequation.

Amino acid sequence analysis. The amino acid sequences of the four domains shown in Fig. 3 were initially aligned with the PILEUP program. This alignmentidentified the absolutely conserved aspartic acid as well as theinvariant N-terminal aromatic residue in all four domains. Anaromatic residue corresponding to the C-terminal stacking residuewas found to be conserved within each of the four domains butwas not aligned between domains. The residues at this positionin domains A and B were aligned with each other based on the structuralalignment of hsRPA1_181-422 (5), which consisted of shiftingthe stacking residue of domain B three residues upstream. Thearomatic residue in domain D had aligned with this residue indomain B and was similarly shifted three residues. The aromaticresidue of domain C was shifted three residues downstream. ThePHD structure prediction program has been described previously(47-49).

PMPS inactivation and reactivation. p-Hydroxymercuriphenylsulfonate (PMPS) treatment was performed essentially as described previously (15, 20). All buffersand water were first passed over 30 ml of Chelex-100 resin (Bio-Rad),and the pH was adjusted with NaOH. Extracts were prepared withoutzinc and dialyzed twice against 1,000 volumes of buffer A lackingDTT and containing 10 mM EDTA. Concentrations of samples weremade to be 2.5 mM in PMPS (Sigma) for 1 h on ice and adjustedto 50 mM in EDTA. Sensitivity to PMPS was determined by assayingthe sample as usual, except that the assay buffer did not containDTT. Reactivation was performed by dialyzing the PMPS-treatedsample against TNG buffer (25 mM Tris [pH 7.5], 0.2 M NaCl, 5%glycerol) containing 1 mM EDTA to remove unreacted PMPS. The sampleswere then incubated with 0.1 M $beta$ -mercaptoethanol and increasingconcentrations of zinc sulfate for 30 min on ice. Samples wereassayed in the absence ofDTT.

	RESULTS

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Identification of a new ssDNA binding domain in RPA1. A UV-cross-linking EMSA was previously used to characterize the ssDNA binding activity of domains A and B of scRPA1 (45).In this method, an oligonucleotide ³²P labeled at its 5' end is incubated with an extract made fromE. coli expressing a defined fragment of RPA protein and the mixtureis irradiated with UV light to covalently link bound protein tothe oligonucleotide. Activity is then detected by gel shift assayon a denaturing polyacrylamide gel. The experiments describedhere use the 17-nt universal sequencing primer to minimize thenumber of multiple protein-ssDNA interactions, but similar resultswere obtained with oligo(dT)₄₀.

To search for additional ssDNA binding domains within the RPA1 subunit, fragments of the yeast gene encoding RPA1 were clonedinto an E. coli expression vector such that the entire RPA1 proteincould be expressed as several protein fragments (Fig. 1). Uponinduction and cell lysis, each RPA1 fragment was found in theinsoluble fraction. These proteins were solubilized in urea andrefolded by stepwise dialysis. SDS-PAGE revealed that all RPA1fragments were soluble and present in nearly equal amounts exceptfor the smallest one (fragment 4), which was about fourfold lessconcentrated (data not shown). Portions of each extract were thensubjected to the UV EMSA, and as was shown previously (45),fragments encompassing domains A and B resulted in a clear mobilityshift (Fig. 1). At least two background bands were observed withall extracts, including extracts of E. coli expressing the vectoralone (lane V). A strong mobility shift was also seen in assaysof fragment 8, which encompasses residues 416 to 621. Assays ofsmaller fragments within this region (fragments 4 to 7) did notresult in binding; however, we cannot rule out the possibilityof a signal comigrating with the background bands. It should benoted that the RPA binding activities in this assay resulted ina corresponding decrease in the signal of the major backgroundband (Fig. 1). This effect was due to limiting amounts of probeused in this experiment and was not observed when the ratio ofprobe to extract was increased (data not shown, but see Fig. 2).We also note that the signal obtained in the UV EMSA depends onboth a protein's ssDNA binding affinity and its efficiency ofcross-linking, which may differ between proteins. The new bindingdomain located in the 206 amino acids C terminal to domain B ishereafter referred to as domain C. The ssDNA binding domain inRPA2 (6, 45) is here renamed domain D.

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FIG. 1. Identification of a new ssDNA binding domain in RPA1. Fragments of the scRPA1 protein were expressed in E. coli and tested for ssDNA binding activity by the UV EMSA. At the top is a schematic of the scRPA1 protein illustrating the locations of the three ssDNA binding domains and the eight protein fragments (numbered horizontal black bars) that were tested in this assay. Numbers above the schematic refer to the amino acid numbers of the scRPA1 protein. For each protein fragment, a portion of extract containing approximately 0.3 µg of recombinant protein was incubated with a 17-nt oligonucleotide ³²P labeled at its 5' end (P) and cross-linked with UV light. Products were resolved on a 6% denaturing polyacrylamide gel. V, extract made from E. coli expressing the vector alone; A*, B*, and C*, RPA1 domains A, B, and C; bkg, background band.

To determine the specificity of domain C binding, UV EMSAs were performed on extracts of E. coli expressing domains A, B,and C in the presence of competitor nucleic acid. As shown previously,binding by domains A and B is competed by the presence of unlabeledssDNA but not by the presence of unlabeled double-stranded DNA(dsDNA) (Fig. 2; e.g., compare lanes 2 and 3 to lanes 4 and 5).The ssDNA binding activity of these two domains is also resistantto added RNA as the competitor (e.g., compare lanes 1 and 6).Domain C shows an identical pattern: it is specifically competedby ssDNA but not by dsDNA or RNA (lanes 13 to 18).

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FIG. 2. RPA1 domain C binds ssDNA specifically. Extracts of E. coli containing approximately 0.3 µg of recombinant protein were assayed in the presence of the indicated competitor, namely, 0.5 or 3 µg of unlabled lambda DNA before (double stranded [DS]) or after (single stranded [SS]) boiling or 3 µg of yeast tRNA (RNA). V, extract of E. coli expressing the vector alone or competed with 3 µg of ssDNA. A*, B*, and C*, RPA1 domains A, B, and C.

Amino acid sequence analysis of domain C. To identify residues of domain C that might contribute to its ssDNA binding activity, the amino acid sequences of domainsA, B, C, and D (RPA2) from a number of species were compared (Fig.3). The alignment of domains A and B was anchored by using thestructural comparison of hsRPA1_181-422 described by Bochkarevet al. (5), and presented at the top of the alignment is aschematic of the corresponding secondary structure of this region.As described previously, this structure is an OB fold which consistsof five strands of $beta$ -sheet with an $alpha$ -helix connecting the thirdand fourth strands (42). A pair of aromatic residues in hsRPA1domains A and B (one at the end of strand 3 and one in the loopbetween strands 4 and 5) make stacking interactions with the DNAbases. Several nonconserved residues in $beta$ -strands 1 and 2 (a structuretermed the $beta$ -hairpin) make hydrogen bonds with the phosphate backboneand the DNA bases. A very similar structure in gp32 indicatedthat the ssDNA binding pocket of gp32 is also an OB fold (5,52).

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FIG. 3. Amino acid sequence alignment of the four ssDNA binding domains of RPA. The amino acid sequences of the indicated proteins were aligned with the PILEUP program and optimized as described in Materials and Methods. The secondary structure of hsRPA1_181-422, presented at the top of the sequences, was taken from Bochkarev et al. (5). Highly conserved residues are indicated in white type on a black background, and the putative zinc-binding domain in domain C is shaded. Numbers to the right of the protein designations refer to amino acid numbers. Note that 14 amino acids are deleted from the scRPA2 sequence at residue 115. Hs, H. sapiens; Xl, Xenopus laevis; Sc, S. cerevisiae; Sp, Schizosaccharomyces pombe; Os, Oryza sativa; Cf, Crithidia fasiculata; Ce, Caenorhabditis elegans.

Highlighted in Fig. 3 are three residues that are conserved in all four ssDNA binding domains. One residue is an absolutelyconserved aspartic acid that lies at the end of the $beta$ 2 strand.This residue was previously noted for being conserved in domainsA and B (45), and mutation of this residue produces phenotypesin yeast when it is mutated in domains A (53), B (45), andD (RPA2) (40, 51). Approximately 10 residues downstream ofthe conserved aspartic acid is an invariant aromatic residue thatlies at the end of the $beta$ 3 strand and is homologous to the N-terminalstacking residue, F238, of hsRPA1A. Approximately 30 residuesfurther downstream is another aromatic residue which is conservedin all domains except RPA4 (31). This aromatic residue liesin the loop between strands $beta$ 4 and $beta$ 5 and is homologous to theC-terminal stacking residue F269 ofhsRPA1A.

While domains A and B of all species probably consist of OB folds like their human homologs, the alignment in Fig. 3 impliesthat domains C and D (RPA2) are also OB folds. With domain C,however, it cannot be so simple, since the $beta$ 1 strand is replacedby the C-terminal portion of the Cys₄ motif (Fig. 3). But theposition of the Cys₄ motif relative to the positions of the remainingsecondary structures is similar to that of the zinc-binding proteingp32. Specifically, the $beta$ -hairpin of gp32 was shown to be interruptedby the zinc-binding domain (5, 52). This may be the casein domain C aswell.

A secondary-structure prediction program was used to determine whether the sequences of domains C and D were consistent withthat of an OB fold. This program accurately predicted the OB folddomains of gp32 as determined by its crystal structure (52).Further, the secondary structures of all species of RPA1 domainC were found to be similar to each other, and the results forthe yeast and human proteins are presented in Fig. 4A. In bothspecies, a $beta$ -sheet is predicted immediately upstream of the Cys₄motif and may be the $beta$ 1 strand of an OB fold. Directly followingthe Cys₄ motif is another $beta$ strand ( $beta$ 2) followed by a third shorter $beta$ strand ( $beta$ 3) and an $alpha$ -helix. A $beta$ -sheet is predicted near residues580 and is proposed to be $beta$ 5. A discrepancy between this analysisand the OB fold of gp32 is that an $alpha$ -helix is predicted to existwhere $beta$ 4 is expected. Thus, domain C may not be a typical OB fold.With domain D, the secondary-structure prediction contained allfive $beta$ -sheets and the $alpha$ -helix (Fig. 4B) (6). It is worth notingthat all the components of the hypothetical OB fold in domainD lie within the minimal region of scRPA2 that is required forviability in yeast (residues 40 to 173) (45). What is remarkableabout both secondary-structure predictions is that each of theconserved residues identified in Fig. 3 lies at the expected positionrelative to the secondary structures of the OB folds in hsRPA1:the invariant aspartic acid closely follows $beta$ 2, the first aromaticclosely follows a shorter $beta$ 3, and the second aromatic lies inthe loop between $beta$ 4 and $beta$ 5. Although this loop is predicted tobe helical in domain C, so also were helices predicted in the $beta$ 4- $beta$ 5 loop of yeast and human domains A (data not shown).

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FIG. 4. Secondary-structure predictions of domains C and D are consistent with an OB fold. Amino acid sequences of domains C and D from yeast and humans were analyzed by the Predict Protein program, European Molecular Biology Laboratory, Heidelberg, Germany (48). The predicted secondary structures of domains C (A) and D (B) are displayed above the yeast (scRPA1C and scRPA2, respectively) and below the human (hsRPA1C and hsRPA2, respectively) sequences. The sequence of the Cys₄ motif (A) and the three highly conserved residues within each amino acid sequence (A and B) are highlighted in white type on a black background. The proposed $beta$ strands of the OB fold are indicated. H, helix; E, extended $beta$ -sheet.

Mutational analysis of domain C. The sequence analysis described above makes predictions regarding the roles of the Cys₄ motif and potential stacking residuesin domain C function. To test these predictions, mutations weregenerated in domain C and the mutant proteins were expressed inE. coli and assayed for ssDNA binding activity. Wild-type domainC and domain C with a C-terminal truncation of 20 amino acidsare active in ssDNA binding, indicating that the extreme C terminusis not required for binding (Fig. 5). But, changing cysteines505 and 508 to alanine resulted in a recombinant protein thatcould no longer bind ssDNA. Similar mutations in the Cys₄ motifof hsRPA are known to reduce or eliminate RPA activity in SV40DNA replication (35, 36) and mismatch repair (37). Consistentwith the role of RPA in these essential processes, complementationanalysis revealed that the C505A-C508A double mutation is lethalin yeast (Table 1).

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FIG. 5. ssDNA binding activity of domain C requires the Cys₄ motif. Extracts of E. coli expressing domain C of scRPA1 with the indicated mutations were assayed by UV EMSA. Vector is an extract of E. coli expressing the vector alone. $Delta$ C20 is domain C with a C-terminal truncation of 20 amino acids. WT, wild type.

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TABLE 1. Mutational analysis of conserved residues in RPA

To further analyze the role of the Cys₄ motif in ssDNA binding, domain C activity was tested for sensitivity to the reversiblecysteine-modifying reagent PMPS (15, 20, 27). Unlike domainsA and B, treatment of domain C with PMPS abolished ssDNA bindingactivity (Fig. 6A). Ecssb was resistant to PMPS treatment, aswas the background binding present in the extract. This resultis consistent with genetic and biochemical evidence supportinga role for this domain in RPA function (35-37).

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FIG. 6. Domain C binding activity is sensitive to cysteine modification. (A) Extracts of E. coli expressing the indicated domains of scRPA1 or purified Ecssb (ssb) were incubated in the presence or absence of 2.5 mM PMPS for 1 h, made 50 mM in EDTA, and assayed for ssDNA binding activity by UV EMSA. (B) An extract of E. coli expressing domain C was treated with 2.5 mM PMPS for 1 h, made 50 mM in EDTA, and dialyzed against Chelex-100-treated TNG buffer containing 1 mM EDTA. The modified protein was then treated with the indicated reagents for 30 min before assay by UV EMSA. $beta$ ME, $beta$ -mercaptoethanol; bkg, background.

To test whether a divalent metal was required for binding by domain C, the PMPS-modified protein was treated with high concentrationsof EDTA and extensively dialyzed to remove all metals. The proteinmodification was then reversed with the reducing agent $beta$ -mercaptoethanol.As before, the PMPS-modified protein was inactive and could notbe stimulated by the presence of 1 mM zinc sulfate (Fig. 6B).However, reversal of the modification with $beta$ -mercaptoethanol restoredssDNA binding activity even in the absence of added zinc. Titrationof zinc sulfate into the reaction mixture had only a slight stimulatingeffect on binding. These results indicate that while recombinantdomain C protein is sensitive to cysteine modification, zinc isnot strictly required for ssDNAbinding.

The role of the proposed stacking residues in RPA function in vivo was tested by mutation and complementation analysis inyeast. The N-terminal stacking residue of each domain, analogousto F238 in the $beta$ 3- $alpha$ -helix interval of hsRPA1A, was mutated toalanine. This mutation was found to be lethal in domains A andC but not in domains B and D (Table 1). The proposed C-terminalstacking residues were similarly tested. None of these C-terminalmutations had any noticeable effect on viability or growth ratewhen they were tested for complementation in yeast (Table 1).Thus, with respect to viability, the phenotypes of correspondingmutations in domains A and C are identical. Remarkably, of over60 point mutations that we have made in scRPA1, only F238 andF537 were individually essential for viability. The fact thatthese residues are conserved by amino acid sequence alignmentsuggests that they perform the same function in ssDNAbinding.

Quantitation of ssDNA binding affinity. In order to measure the affinity of ssDNA binding by domains A, B, and C, we attempted to purify them from the E. coli extract.Unfortunately, fractionation of the refolded proteins caused themto precipitate quantitatively. To facilitate the recovery of solubleprotein, we fused each of the RPA domains to MBP and purifiedthem by affinity and ion-exchange chromatography. Figure 7A showsan SDS-PAGE analysis of the purified proteins which were estimatedto be 95% pure. The MBP-C fusion appears as a ladder of bands.This pattern was obtained on multiple purifications and was insensitiveto the amount of zinc sulfate present during purification. Weassume that these bands arise from limited proteolytic degradation.

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FIG. 7. ssDNA binding activity of MBP-RPA fusion proteins. (A) Two micrograms of each purified MBP fusion protein was resolved by SDS-10% PAGE and stained with Coommassie blue. (B) Increasing amounts of the indicated MBP fusion protein or native MBP were incubated with a fixed amount of probe, UV cross-linked, and resolved by denaturing gel electrophoresis. Protein titrations are 0.1, 0.3, 1, 3, and 10 µg in 15-µl binding reaction mixtures.

Increasing amounts of each MBP fusion protein were incubated with a fixed amount of probe and UV cross-linked, and the productswere resolved by denaturing gel electrophoresis. As expected,the MBP-A, MBP-B, and MBP-C fusion proteins possessed a ssDNAbinding activity that was not present in purified MBP alone (Fig.7B). Note that at high levels of MBP-A a slower-moving band whichmay represent multiple proteins binding to a single oligonucleotideis observed. To confirm that the binding of these proteins tossDNA was specific, we performed two additional experiments. First,a fixed amount of each MBP fusion protein was incubated with increasingamounts of probe to test whether the binding could be saturatedwith ssDNA substrate. As shown in Fig. 8A, increasing amountsof probe resulted in increasing amounts of DNA binding until thesignal reached a plateau at 50 pmol of input oligonucleotide (3-to 10-fold molar excess). Second, we tested that the binding ofMBP fusion proteins to ssDNA was in equilibrium by reversing theprobe-binding with unlabeled ssDNA. Following a standard incubationof MBP fusion protein with probe, unlabeled oligonucleotide wasadded and a second incubation was performed. The products werethen subjected to UV cross-linking and gel electrophoresis. Thepresence of increasing amounts of competitor oligonucleotide resultedin decreased levels of probe binding by each MBP fusion protein,indicating that the binding of all MBP fusion proteins was specific(Fig. 8B). Again, no binding was seen by MBP alone. The amountsof free and bound probes present in protein titrations of MBPfusion proteins were quantitated by phosphorimaging, and dissociationconstants were calculated. Based on these calculations we findthat the binding affinities of MBP-A and MBP-B are approximatelyequal and two to three times greater than that of MBP-C.

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FIG. 8. ssDNA binding activities of MBP-RPA fusion proteins are saturable and reversible. (A) Increasing amounts of input DNA were incubated with 0.3 µg of MBP-A (5.4 pmol), 0.3 µg of MBP-B (5.4 pmol), or 1 µg of MBP-C (15 pmol) and assayed by UV EMSA. MPB-C values correspond to the 1/20th scale on the right. oligo, oligonucleotide. (B) One microgram of each MBP fusion protein was preincubated with probe (10 fmol) and then incubated with 0, 1, 3, 10, 30, 100, and 300 pmol of unlabeled oligonucleotide. MBP alone was incubated with 0, 100, and 300 pmol unlabeled oligonucleotide. The last lane is a control lacking protein.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

RPA, like its prokaryotic homologs, is involved in multiple aspects of DNA metabolism (58, 60), including roles in DNAreplication (17, 59, 61), DNA repair (13, 24), and geneticrecombination (25, 53). While the role of the RPA complexin these processes is well documented, the functions of RPA'sindividual subunits are not well understood. It has been notedthat RPA resembles Ecssb in that both cellular SSBs are multimericcomplexes; RPA is a heterotrimer and Ecssb is a homotetramer.The identification of ssDNA binding domains A and B in RPA1 anda third domain in RPA2 (5, 6, 45) suggested that RPA mightcontain a fourth ssDNA binding domain analogous to that in Ecssb.The identification of a new ssDNA binding domain in the C terminusof RPA1 supports the idea that cellular SSBs require multiplessDNA binding domains to carry out their essentialfunction.

The putative zinc-binding domain in the C terminus of RPA1 has long been recognized and compared to that in gp32 (16, 26),but its role in RPA function was not obvious. C-terminal truncationsof RPA1 are known to eliminate SV40 DNA replication and the RPA1-RPA2interaction but to only slightly reduce the ssDNA binding activityof the 70-kDa subunit (21, 22, 35, 36). The essentialrole of the RPA1 C terminus in SV40 DNA replication may thereforebe explained by its effect on trimer formation rather than onssDNA binding activity. However, the fact that point mutationsin the Cys₄ motif do not disrupt the RPA1-RPA2 interaction butstill eliminate SV40 DNA replication in vitro (35, 36) suggeststhat it is the ssDNA binding activity of this domain that is importantfor function. Indeed, the role of the Cys₄ motif in the ssDNAbinding activity of domain C was confirmed both with point mutationsand by chemical modification (Fig. 5 and 6). We conclude thatthe ssDNA binding activity of this domain is essential for RPAfunction and that the C-terminal region of RPA1 is required forboth ssDNA binding and complex formation. The dual role of theRPA1 C terminus might explain why the secondary structure of thisdomain was predicted to have an $alpha$ -helix where the $beta$ 4 strand ofthe OB fold was expected. Experiments to test whether this helixcontributes to the additional activity of binding RPA2 are inprogress.

Having demonstrated that the Cys₄ motif is essential for domain C activity, we were surprised to find that zinc is not requiredfor ssDNA binding. While the possibility of trace metal contaminationcannot be ruled out in this experiment, precautions were takento avoid such impurities. For example, all buffers were treatedwith Chelex-100 resin, which removes divalent metals (15, 27),and different preparations of water and $beta$ -mercaptoethanol gaveidentical results. The Cys₄ motif of domain C may therefore functionlike the zinc-binding domain of gp32, which does not require zincfor ssDNA binding but for cooperativity of binding (19, 43).It has been shown that apo-gp32, which lacks zinc, binds a single-sitesubstrate with the same affinity as metallo-gp32 (19). In contrast,the binding affinity of metallo-gp32 was higher than that of apo-gp32on larger substrates due to an increase in cooperativity. Thebinding-site size of the 206-amino-acid domain C protein has notbeen determined, but it is possible that the small stimulationof binding by zinc seen in Fig. 6B is due to enhanced cooperativityof binding to the 17-nt substrate used in this study. Confirmationof a role for zinc in this process awaits further experimentswith largersubstrates.

The data presented here lead to a revised model of RPA (45). This model proposes that the RPA heterotrimer consists of atleast four ssDNA binding domains that are each essential for RPAactivity and likely to serve distinct roles in RPA function. DomainsA, B, and C lie within RPA1, and domain D lies within RPA2. Thethree domains of RPA1 constitute a very strong binding site andmay bind ssDNA simultaneously at low concentrations of salt. At250 mM NaCl, domain D is capable of binding ssDNA as well (45).Since domain D lies within another subunit, it is possible thathigher-order binding or wrapping results from the interactionof ssDNA with domain D, leading to compaction of the ssDNA. WhileEM has provided some evidence for ssDNA wrapping by yeast RPA(1) and salt-dependent compaction of ssDNA by human RPA (56),investigators in the latter study suspected that factors otherthan wrapping were the cause ofcompaction.

This model may explain the discrepancy in ssDNA binding-site sizes that have been reported for RPA. Given that RPA is a complexof at least four different binding domains, it is reasonable toexpect multiple binding-site sizes, perhaps similar to that ofEcssb. EM studies of hsRPA bound to oligonucleotides suggestedthat the 8-nt binding mode, which is identified by glutaraldehydecross-linking (3), is an initial event that subsequently resolvesinto a stable 30-nt mode (4). Based on the known interactionof domains A and B with 8 nt of ssDNA (5), it is likely thatthis weak initial mode arises by cross-linking of ssDNA to thesetwo domains (28). The current model then suggests that interactionof ssDNA with domains A, B, and C leads to the stable 30-nt mode,which was observed to have a distinctly elongated appearance byEM (4, 28). As described above, interactions between ssDNAand all four domains may account for the 90-nt mode in the presenceof high concentrations of salt (1). Alternatively, it is possiblethat the 8- and 30-nt binding modes represent interactions withdomain A and the A-B pair, respectively. The 90-nt mode mightthen arise from the binding of the C-D pair. Further experimentswill be needed to distinguish between the multiple possibilitiesarising from these redundant domains. These studies will alsoneed to address the role of metals in binding-site size and cooperativityof ssDNA binding byRPA.

If RPA is truly a structural and functional homolog of Ecssb, then the analysis of RPA provides a unique opportunity to studythe role of higher-order binding in DNA metabolism. Since eachof the four protomers of Ecssb are equivalent, it is not possibleto ask if each of them is essential to SSB function, or whetherthey perform specific functions in the homotetramer. With RPA,each of the four protomers is distinct and each has now been shownto be required for yeast viability (45) and for SV40 DNA replicationin vitro (22, 30, 35, 36). While there is some evidencefor functional redundancy in RPA (domain A can substitute fordomain B), each domain may have a specific function since domainB cannot substitute for domain A (45) and preliminary experimentsin this lab indicate that domains A, B, and D cannot functionin place of domain C in yeast. Recently, a detailed mutagenesisof the RPA1 subunit in yeast revealed that point mutations placedthroughout its length can differentially affect its multiple functionsin DNA metabolism (58). Such a result would be expected if thedomains of RPA1 have specific functions. Other mutant studiesindicate that conditional-lethal alleles of RPA2 are defectivein replication fork movement at the nonpermissive temperature(40, 51). The ssDNA binding activity of RPA2 may thereforebe critical to RPA function in the elongation phase of DNA replication.Further in vitro experiments are needed to reconcile the differentresults in studies of higher-order binding by RPA and to testwhether domains C and D play a role in wrappingssDNA.

What advantage could a multimeric SSB have over a monomeric one? A clue may be found by comparing the efficiencies of variousSSBs in T-antigen-catalyzed unwinding (29) and unwinding ofa pseudo-origin template (28). It is curious that most replicativeSSBs that work in these assays (RPA, Ecssb, adenovirus DBP, andherpesvirus ICP8) are known to bind ssDNA in a multimerized fashion.RPA and Ecssb are now known to be multimers, and it has been shownthat DBP uses a C-terminal hook to multimerize (57) and drivestrand displacement synthesis (14). While the mechanism of ssDNAbinding by ICP8 has not been determined, it is possible that thislarge protein of 128 kDa also contains multiple ssDNA bindingdomains. gp32 and T7 gp2.5, which bind ssDNA with high affinity,being monomers, do not function in these unwinding assays (28,29), and mutant RPA complexes lacking one or more ssDNA bindingdomains are capable of only minor levels of unwinding (21).These findings suggest that the multiple domains of RPA play animportant role in denaturing double-stranded DNA. It will be ofinterest to test this idea and determine whether RPA domains Cand D regulate this process in eukaryoticcells.

	ACKNOWLEDGMENTS

Thanks go to Alexey Bochkarev and Aled Edwards for suggesting the use of the secondary-structure prediction program, to JohnDiffley for advice on PMPS treatment, and to David Norris andJan Mullen for comments on themanuscript.

This work was supported by NIH grantGM55583.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Molecular Biology, Center for Advanced Biotechnology and Medicine, 679Hoes Lane, Rutgers University, Piscataway, NJ 08855. Phone: (732)235-4197. Fax: (732) 235-4880. E-mail: brill{at}mbcl.rutgers.edu.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
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