Structure of the Escherichia coli primase/single-strand DNA-binding protein/phage G4oric complex required for primer RNA synthesis

Escherichia coli primase/SSB/single-stranded phage G4oric is a simple system to study how primase interacts with DNA template to synthesize primer RNA for initiation of DNA replication. By a strategy of deletion analysis and antisense oligonucleotide protection on small single-stranded G4oric fragments, we have identified the DNA sequences required for binding primase and the critical location of single-strand DNA-binding (SSB) protein. Together with the previous data, we have defined the structure of the primase/SSB/G4oric priming complex. Two SSB tetramers bind to the G4oric secondary structure, which dictates the spacing of 3' and 5' bound adjacent SSB tetramers and leaves SSB-free regions on both sides of the stem-loop structure. Two primase molecules then bind separately to specific DNA sequences in the 3' and 5' SSB-free G4oric regions. Binding of the 3' SSB tetramer, upstream of the primer RNA initiation site, is also necessary for priming. The generation of a primase-recognition target by SSB phasing at DNA hairpin structures may be applicable to the binding of initiator proteins in other single-stranded DNA priming systems. Novel techniques used in this study include antisense oligonucleotide protection and RNA synthesis on an SSB-melted, double-stranded DNA template.     

phi29 DNA polymerase residue Ser122, a single-stranded DNA ligand for 3'-5' exonucleolysis, is required to interact with the terminal protein

Three amino acid residues highly conserved in most proofreading DNA polymerases, a phenylalanine contained in the Exo II motif and a serine and a leucine belonging to the S/TLx2h motif, were recently shown to be critical for 3'-5' exonucleolysis by acting as single-stranded DNA ligands (de Vega, M., Lázaro, J.M., Salas, M. and Blanco, L. (1998) J. Mol. Biol. 279, 807-822). In this paper, site-directed mutants at these three residues were used to analyze their functional importance for the synthetic activities of phi29 DNA polymerase, an enzyme able to start linear phi29 DNA replication using a terminal protein (TP) as primer. Mutations introduced at Phe65, Ser122, and Leu123 residues of phi29 DNA polymerase severely affected the replication capacity of the enzyme. Three mutants, F65S, S122T, and S122N, were strongly affected in their capacity to interact with a DNA primer/template structure, suggesting a dual role during both polymerization and proofreading. Interestingly, mutant S122N was not able to maintain a stable interaction with the TP primer, thus impeding the firsts steps (initiation and transition) of phi29 DNA replication. The involvement of Ser122 in the consecutive binding of TP and DNA is compatible with the finding that the TP/DNA polymerase heterodimer was not able to use a DNA primer/template structure. Assuming a structural conservation among the eukaryotic-type DNA polymerases, a model for the interactions of phi29 DNA polymerase with both TP and DNA primers is presented.     

Phi 29 DNA polymerase active site. Residue ASP249 of conserved amino acid motif "Dx2SLYP" is critical for synthetic activities

phi 29 DNA polymerase shares with other alpha-like DNA polymerases several regions of amino acid sequence similarity and sensitivity to inhibitors of eukaryotic DNA polymerase alpha. In this paper, site-directed mutants in the phi 29 DNA polymerase residues Asp249, Ser252, Leu253, and Pro255 of the conserved amino acid motif "Dx2SLYP" are described. Two mutants, D249E and S252R, were drastically affected in all the synthetic activities, whereas their 3' to 5' exonuclease activity and interaction with the TP primer was normal. Mutant D249E, slightly affected in template-primer binding, was completely inactive in all conditions tested, suggesting that Asp249 could be playing a direct role in catalysis. On the other hand, mutant S252R, strongly affected in template-primer binding, showed some DNA polymerization activity in the presence of Mn2+. Mutants S252G and P255S showed a reduced template-primer binding ability; these mutants, together with mutant L253V, showed metal ion-dependent phenotypes in their synthetic activities and altered sensitivities to the PPi analog phosphonoacetic acid. All these results support the hypothesis that the Dx2SLYP motif forms part of the polymerization active site of the phi 29 DNA polymerase, being the Asp249 residue critical both for protein-primed initiation and DNA polymerization.     

Molecular phylogeny of phi29-like phages and their evolutionary relatedness to other protein-primed replicating phages and other phages hosted by gram-positive bacteria

The phi29-like phage genus of Podoviridae family contains phages B103, BS32, GA-1, M2, Nf, phi15, phi29, and PZA that all infect Bacillus subtilis. They have very similar morphology and their genomes consist of linear double-stranded DNA of approximately 20 kb. The nucleotide sequences of individual genomes or their parts determined thus far show that these phages evolved from a common ancestor. A terminal protein (TP) that is covalently bound to the DNA 5'-end primes DNA replication of these phages. The same mechanism of DNA replication is used by the Cp-1 related phages (also members of the Podoviridae family) and by the phage PRD1 (member of the Tectoviridae family). Based on the complete or partial genomic sequence data of these phages it was possible to analyze the evolutionary relationship within the phi29-like phage genus as well as to other protein-primed replicating phages. Noncoding regions containing origins of replication were used in the analysis, as well as amino acid sequences of DNA polymerases, and with the phi29-like phages also amino acid sequences of the terminal proteins and of the gene 17 protein product, an accessory component of bacteriophage DNA replicating machinery. Included in the analysis are also results of a comparison of these phage DNAs with the prophages present in the Bacillus subtilis genome. Based on this complex analysis we define and describe in more detail the evolutionary branches of phi29-like phages, one branch consisting of phages BS32, phi15, phi29, and PZA, the second branch composed of phages B103, M2, and Nf, and the third branch having phage GA-1 as its sole member. In addition, amino acid sequences of holins, proteins involved in phage lysis were used to extend the evolutionary study to other phages infecting Gram-positive bacteria. The analysis based on the amino acid sequences of holins showed several weak points in present bacteriophage classification.     

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

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

Functional domains of Escherichia coli single-stranded DNA binding protein as assessed by analyses of the deletion mutants

A series of C- and N-terminal deletion mutants of Escherichia coli single-stranded DNA binding protein (SSB) was constructed, purified, and characterized in terms of ability to self-multimerize and to bind to DNA. High-performance gel filtration chromatography revealed that the amino acids 89-105 play a key role in the maintenance of homotetramer for native SSB of 177 amino acids. Interestingly, all of the N-terminal deletion mutants studied here were eluted as octamers, indicating that the N-terminal 11 residues are involved in the prevention of the formation of octamers. The binding of SSB and its deletion mutant proteins to single-stranded d(T)n was examined by gel mobility shift assay and circular dichroism spectroscopy. C-terminal deletion mutant proteins, SSB1-135 and SSB1-115, maintained high affinity and may be wrapped by single-stranded DNA (ssDNA) in the same way as in the case of native SSB. In contrast, deletion of the C-terminal region (residues 89-115) or N-terminal region (residues 1-11) caused a dramatic decrease in the binding affinity. Furthermore, two different stoichiometries of SSB in the complexes with d(T)64, but not with d(T)32, were observed for native SSB, SSB1-135, SSB1-115, and SSB37-177, suggesting that the (SSB)65 and (SSB)35 binding modes, as previously demonstrated [Lohman, T. M., & Overman, L. B. (1985) J. Biol. Chem. 260, 3594-3603; Bujalowski, W., & Lohman, T. M. (1986) Biochemistry 25, 7799-7802], occurred at lower and higher SSB concentrations, respectively. A functional map for SSB molecule was presented and discussed.     

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

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

Effects of Xenopus laevis mitochondrial single-stranded DNA-binding protein on primer-template binding and 3'-->5' exonuclease activity of DNA polymerase gamma

Mitochondrial DNA (mtDNA) is replicated by DNA polymerase gamma by a strand displacement mechanism involving mitochondrial single-stranded DNA-binding protein (mtSSB). mtSSB stimulates the overall rate of DNA synthesis on singly-primed M13 DNA mainly by stimulating the processivity of DNA synthesis rather than by stimulating primer recognition. We used electrophoretic mobility shift methods to study the effects of mtSSB on primer-template recognition by DNA pol gamma. Preliminary experiments showed that single mtSSB tetramers bind tightly to oligo(dT) single strands containing 32 to 48 residues. An oligonucleotide primer-template was designed with an 18-mer primer annealed to the 3'-portion of a 71-mer template containing 40 dT residues at its 5'-end as a binding site for mtSSB. DNA pol gamma bound to this primer-template either in the absence or presence of mtSSB in complexes that remained intact and enzymatically active following native gel electrophoresis. Association of mtSSB with the 5'-dT40-tail in the 18:71-mer primer-template reduced the binding of DNA polymerase gamma and the efficiency of primer extension. Binding of mtSSB to single-stranded DNA was also observed to block the action of the 3'-->5' exonuclease of DNA polymerase gamma. The size of fragments protected from 3'-->5' exonuclease trimming increases with increasing ionic strength in a manner consistent with the known salt dependence of the binding site size of Escherichia coli SSB.     

Phosphorylation of DNA polymerase alpha-primase by cyclin A-dependent kinases regulates initiation of DNA replication in vitro

DNA polymerase alpha-primase is the only known eukaryotic enzyme that can start DNA replication de novo. In this study, we investigated the regulation of DNA replication by phosphorylation of DNA polymerase alpha-primase. The p180 and the p68 subunits of DNA polymerase alpha-primase were phosphorylated using Cyclin A-, B- and E- dependent kinases. This phosphorylation did not influence its DNA polymerase activity on activated DNA, but slightly stimulated primase activity using poly(dT) single-stranded DNA (ssDNA) without changing the product length of primers. In contrast, site-specific initiation of replication on plasmid DNA containing the SV40 origin is affected: Cyclin A-Cdk2 and Cyclin A-Cdc2 inhibited initiation of SV40 DNA replication in vitro, Cyclin B-Cdc2 had no effect and Cyclin E-Cdk2 stimulated the initiation reaction. DNA polymerase alpha-primase that was pre-phosphorylated by Cyclin A-Cdk2 was completely unable to initiate the SV40 DNA replication in vitro; Cyclin B-Cdc2-phosphorylated enzyme was moderately inhibited, while Cyclin E-Cdk2-treated DNA polymerase alpha-primase remained fully active in the initiation reaction.     

Changes in the subcellular localization of replication initiation proteins and cell cycle proteins during G1- to S-phase transition in mammalian cells

DNA replication in eukaryotic cells is restricted to the S-phase of the cell cycle. In a cell-free replication model system, using SV40 origin-containing DNA, extracts from G1 cells are inefficient in supporting DNA replication. We have undertaken a detailed analysis of the subcellular localization of replication proteins and cell cycle regulators to determine when these proteins are present in the nucleus and therefore available for DNA replication. Cyclin A and cdk2 have been implicated in regulating DNA replication, and may be responsible for activating components of the DNA replication initiation complex on entry into S-phase. G1 cell extracts used for in vitro replication contain the replication proteins RPA (the eukaryotic single-stranded DNA binding protein) and DNA polymerase alpha as well as cdk2, but lack cyclin A. On localizing these components in G1 cells we find that both RPA and DNA polymerase alpha are present as nuclear proteins, while cdk2 is primarily cytoplasmic and there is no detectable cyclin A. An apparent change in the distribution of these proteins occurs as the cell enters S-phase. Cyclin A becomes abundant and both cyclin A and cdk2 become localized to the nucleus in S-phase. In contrast, the RPA-34 and RPA-70 subunits of RPA, which are already nuclear, undergo a transition from the uniform nuclear distribution observed during G1, and now display a distinct punctate nuclear pattern. The initiation of DNA replication therefore most likely occurs by modification and activation of these replication initiation proteins rather than by their recruitment to the nuclear compartment.     

Functional features of an ssi signal of plasmid pGKV21 in Escherichia coli

A single-strand initiation (ssi) signal was detected on the Lactococcus lactis plasmid pGKV21 containing the replicon of pWV01 by its ability to complement the poor growth of an M13 phage derivative (M13 delta lac182) lacking the complementary-strand origin in Escherichia coli. This ssi signal was situated at the 229-nucleotide (nt) DdeI-DraI fragment and located within the 109 nt upstream of the nick site of the putative plus origin. SSI activity is orientation specific with respect to the direction of replication. We constructed an ssi signal-deleted plasmid and then examined the effects of the ssi signal on the conversion of the single-stranded replication intermediate to double-stranded plasmid DNA in E. coli. The plasmid lacking an ssi signal accumulated much more plasmid single-stranded DNA than the wild-type plasmid did. Moreover, deletion of this region caused a great reduction in plasmid copy number or plasmid maintenance. These results suggest that in E. coli, this ssi signal directs its lagging-strand synthesis as a minus origin of plasmid pGKV21. Primer RNA synthesis in vitro suggests that E. coli RNA polymerase directly recognizes the 229-nt ssi signal and synthesizes primer RNA dependent on the presence of E. coli single-stranded DNA binding (SSB) protein. This region contains two stem-loop structures, stem-loop I and stem-loop II. Deletion of stem-loop I portion results in loss of priming activity by E. coli RNA polymerase, suggesting that stem-loop I portion is essential for priming by E. coli RNA polymerase on the SSB-coated single-stranded DNA template.     

Domains of DnaA protein involved in interaction with DnaB protein, and in unwinding the Escherichia coli chromosomal origin

DnaA protein of Escherichia coli is a sequence-specific DNA-binding protein required for the initiation of DNA replication from the chromosomal origin, oriC. It is also required for replication of several plasmids including pSC101, F, P-1, and R6K. A collection of monoclonal antibodies to DnaA protein has been produced and the primary epitopes recognized by them have been determined. These antibodies have also been examined for the ability to inhibit activities of DNA binding, ATP binding, unwinding of oriC, and replication of both an oriC plasmid, and an M13 single-stranded DNA with a proposed hairpin structure containing a DnaA protein-binding site. Replication of the latter DNA is dependent on DnaA protein by a mechanism termed ABC priming. These studies suggest regions of DnaA protein involved in interaction with DnaB protein, and in unwinding of oriC, or low-affinity binding of ATP.     

The effects of antioxidant supplementation during Percoll preparation on human sperm DNA integrity

Adenovirus DNA polymerase is one of three viral proteins and two cellular proteins required for replication of the adenovirus genome. During initiation of viral DNA synthesis the viral DNA polymerase transfers dCMP onto the adenovirus preterminal protein, to which it is tightly bound. The domain structure of the 140 kDa DNA polymerase has been probed by partial proteolysis and the sites of proteolytic cleavage determined by N-terminal sequencing. At least four domains can be recognised within the DNA polymerase. Adenovirus preterminal protein interacts with three of the four proteolytically derived domains. This was confirmed by cloning and expression of each of the individual domains. These data indicate that, like other members of the pol alpha family of DNA polymerases, the adenovirus DNA polymerase has a multidomain structure and that interaction with preterminal protein takes place with non-contiguous regions of the polypeptide chain over a large surface area of the viral DNA polymerase.     

A C-terminal helicase domain of the human papillomavirus E1 protein binds E2 and the DNA polymerase alpha-primase p68 subunit

The human papillomavirus (HPV) E1 and E2 proteins bind cooperatively to the viral origin of replication (ori), forming an E1-E2-ori complex that is essential for initiation of DNA replication. All other replication proteins, including DNA polymerase alpha-primase (polalpha-primase), are derived from the host cell. We have carried out a detailed analysis of the interactions of HPV type 16 (HPV-16) E1 with E2, ori, and the four polalpha-primase subunits. Deletion analysis showed that a C-terminal region of E1 (amino acids [aa] 432 to 583 or 617) is required for E2 binding. HPV-16 E1 was unable to bind the ori in the absence of E2, but the same C-terminal domain of E1 was sufficient to tether E1 to the ori via E2. Of the polalpha-primase subunits, only p68 bound E1, and binding was competitive with E2. The E1 region required (aa 397 to 583) was the same as that required for E2 binding but additionally contained 34 N-terminal residues. In confirmation of these differences, we found that a monoclonal antibody, mapping adjacent to the N-terminal junction of the p68-binding region, blocked E1-p68 but not E1-E2 binding. Sequence alignments and secondary-structure prediction for HPV-16 E1 and other superfamily 3 (SF3) viral helicases closely parallel the mapping data in suggesting that aa 439 to 623 constitute a discrete helicase domain. Assuming a common nucleoside triphosphate-binding fold, we have generated a structural model of this domain based on the X-ray structures of the hepatitis C virus and Bacillus stearothermophilus (SF2) helicases. The modelling closely matches the deletion analysis in suggesting that this region of E1 is indeed a structural domain, and our results suggest that it is multifunctional and critical to several stages of HPV DNA replication.