Purification of bacteriophage phi 29 DNA polymerase

Phi29 DNA polymerase residues Tyr59, His61 and Phe69 of the highly conserved ExoII motif are essential for interaction with the terminal protein

Phage Phi29 encodes a DNA-dependent DNA polymerase belonging to the eukaryotic-type (family B) subgroup of DNA polymerases that use a protein as the primer for initiation of DNA synthesis. In one of the most important motifs present in the 3'-->5' exonucleolytic domain of proofreading DNA polymerases, the ExoII motif, Phi29 DNA polymerase contains three amino acid residues, Y59, H61 and F69, which are highly conserved among most proofreading DNA polymerases. These residues have recently been shown to be involved in proper stabilization of the primer terminus at the 3'-->5' exonuclease active site. Here we investigate by means of site-directed mutagenesis the role of these three residues in reactions that are specific for DNA polymerases utilizing a protein-primed DNA replication mechanism. Mutations introduced at residues Y59, H61 and F69 severely affected the protein-primed replication capacity of Phi29 DNA polymerase. For four of the mutants, namely Y59L, H61L, H61R and F69S, interaction with the terminal protein was affected, leading to few initiation and transition products. These findings, together with the specific conservation of Y59, H61 and F69 among DNA polymerases belonging to the protein-primed subgroup, strongly suggest a functional role of these amino acid residues in the DNA polymerase-terminal protein interaction.

Sequence requirements for protein-primed initiation and elongation of phage O29 DNA replication

The double-stranded linear DNA of Bacillus subtilis phage O29 is replicated by a mechanism in which a terminal protein (TP) acts as a primer. The second 3'-terminal nucleotide of the template directs the incorporation of the 5'-terminal nucleotide into the TP, giving rise to the initiation complex TP-dAMP. Elongation then proceeds by a sliding-back mechanism in which the dAMP covalently linked to the TP pairs to the 3'-terminal nucleotide of the template strand to recover full-length DNA. We have studied the sequence requirements for efficient initiation of replication using mutated TP-free double-stranded DNA fragments. Efficient initiation only requires the terminal repetition 5'-AA. The 3'-terminal T, although not used as template, increases the affinity of DNA polymerase for the initiator nucleotide; in addition, although to a minor extent, the third 3'-terminal position also directs the formation of the initiation complex and modulates the initiation rate at the second position. Efficient elongation requires a previous sliding-back, demanding again a repetition of two nucleotides at the 3' end; if the sliding-back is prevented, a residual elongation can proceed directly from the second position or after jumping back from the third to the first position.

An aspartic acid residue in TPR-1, a specific region of protein-priming DNA polymerases, is required for the functional interaction with primer terminal protein

A multiple sequence alignment of eukaryotic-type DNA polymerases led to the identification of two regions of amino acid residues that are only present in the group of DNA polymerases that make use of terminal proteins. (TPs) as primers to initiate DNA replication of linear genomes. These amino acid regions (named terminal region (TPR protein-1 and TPR-2) are inserted between the generally conserved motifs Dx(2)SLYP and Kx(3)NSxYG (TPR-1) and motifs Kx(3)NSxYG and YxDTDS (TPR-2) of the eukaryotic-type family of DNA polymerases. We carried out site-directed mutagenesis in two of the most conserved residues of phi29 DNA polymerase TPR-1 to study the possible role of this specific region. Two mutant DNA polymerases, in conserved residues AsP332 and Leu342, were purified and subjected to a detailed biochemical analysis of their enzymatic activities. Both mutant DNA polymerases were essentially normal when assayed for synthetic activities in DNA-primed reactions. However, mutant D332Y was drastically affected in phi29 TP-DNA replication as a consequence of a large reduction in the catalytic efficiency of the protein-primed reactions. The molecular basis of this defect is a non-functional interaction with TP that strongly reduces the activity of the DNA polymerase/TP heterodimer.

Phage phi 29 DNA polymerase residues involved in the proper stabilisation of the primer-terminus at the 3'-5' exonuclease active site

Three highly conserved amino acid residues have been characterised here as ssDNA ligands at the 3'-5' exonuclease active site of o29 DNA polymerase. The functional role of Tyr59, His61 and Phe69 residues of o29 DNA polymerase (belonging to Exo II motif, previously described as containing an invariant catalytic aspartate residue and two highly conserved ssDNA ligands) was assayed by biochemical analysis of six site-directed mutants at those residues. These studies revealed that the mutations introduced severely affected their ssDNA binding capacity and, as a consequence, the 3'-5' exonuclease activity on ssDNA substrates was also severely impaired, producing drastic defects in the maintenance of replication fidelity. Crystal structures of Klenow fragment of Pol Ik and Thermococcus gorgonarius DNA polymerase complexed with ssDNA at their 3'-5' exonuclease active sites revealed that residues Gln419 of the former, and Tyr209 of the latter, the counterparts of His61 of o29 DNA polymerase, are making contacts with the penultimate phosphodiester bond of ssDNA substrate. Here, the functional role of this residue is described.

Compartmentalization of phage phi29 DNA replication: interaction between the primer terminal protein and the membrane-associated protein p1

The bacteriophage phi29 replication protein p1 (85 amino acids) is membrane associated in Bacillus subtilis-infected cells. The C-terminal 52 amino acid residues of p1 are sufficient for assembly into protofilament sheet structures. Using chemical cross-linking experiments, we demonstrate here that p1DeltaC43, a C-terminally truncated p1 protein that neither associates with membranes in vivo nor self-interacts in vitro, can interact with the primer terminal protein (TP) in vitro. Like protein p1, plasmid-encoded protein p1DeltaC43 reduces the rate of phi29 DNA replication in vivo in a dosage-dependent manner. We also show that truncated p1 proteins that retain the N-terminal 42 amino acids, when present in excess, interfere with the in vitro formation of the TP.dAMP initiation complex in a reaction that depends on the efficient formation of a primer TP-phi29 DNA polymerase heterodimer. This interference is suppressed by increasing the concentration of either primer TP or phi29 DNA polymerase. We propose a model for initiation of in vivo phi29 DNA replication in which the viral replisome attaches to a membrane-associated p1-based structure.

Differential functional behavior of viral phi29, Nf and GA-1 SSB proteins

DNA replication of phi29 and related phages takes place via a strand displacement mechanism, a process that generates large amounts of single-stranded DNA (ssDNA). Consequently, phage-encoded ssDNA-binding proteins (SSBs) are essential proteins during phage phi29-like DNA replication. In the present work we analyze the helix-destabilizing activity of the SSBs of phi29 and the related phages Nf and GA-1, their ability to eliminate non-productive binding of phi29 DNA polymerase to ssDNA and their stimulatory effect on replication by phi29 DNA polymerase in primed M13 ssDNA replication, a situation that resembles type II replicative intermediates that occur during phi29-like DNA replication. Significant differences have been appreciated in the functional behavior of the three SSBs. First, the GA-1 SSB is able to display helix-destabilizing activity and to stimulate dNTP incorporation by phi29 DNA polymerase in the M13 DNA replication assay, even at SSB concentrations at which the phi29 and Nf SSBs do not show any effect. On the other hand, the phi29 SSB is the only one of the three SSBs able to increase the replication rate of phi29 DNA polymerase in primed M13 ssDNA replication. From the fact that the phi29 SSB, but not the Nf SSB, stimulates the replication rate of Nf DNA polymerase we conclude that the different behaviors of the SSBs on stimulation of the replication rate of phi29 and Nf DNA polymerases is most likely due to formation of different nucleoprotein complexes of the SSBs with the ssDNA rather than to a specific interaction between the SSB and the corresponding DNA polymerase. A model that correlates the thermodynamic parameters that define SSB-ssDNA nucleoprotein complex formation with the functional stimulatory effect of the SSB on phi29-like DNA replication has been proposed.

Specific recognition of parental terminal protein by DNA polymerase for initiation of protein-primed DNA replication

The linear genome of Bacillus subtilis phage phi29 has a protein covalently linked to the 5' ends, called parental terminal protein (TP), and is replicated using a free TP as primer. The initiation of phage phi29 DNA replication requires the formation of a DNA polymerase/TP complex that recognizes the replication origins located at the genome ends. The DNA polymerase catalyzes the formation of the initiation complex TP-dAMP, and elongation proceeds coupled to strand displacement. The same mechanism is used by the related phage Nf. However, DNA polymerase and TP from phi29 do not initiate the replication of Nf TP-DNA. To address the question of the specificity of origin recognition, we took advantage of the initiation reaction enhancement in the presence of Mn(2+), allowing us to detect initiation activity in heterologous systems in which DNA polymerase, TP, and template TP-DNA are not from the same phage. Initiation was selectively stimulated when DNA polymerase and TP-DNA were from the same phage, strongly suggesting that specific recognition of origins is brought through an interaction between DNA polymerase and parental TP.

Structural and functional comparative study of the complexes formed by viral ø29, Nf and GA-1 SSB proteins with DNA

Single-stranded DNA-binding proteins have in common their crucial roles in DNA metabolism, although they exhibit significant differences in their single-stranded DNA binding properties. To evaluate the correlation between the structure of different nucleoprotein complexes and their function, we have carried out a comparative study of the complexes that the single-stranded DNA-binding proteins of three related bacteriophages, ø29, Nf and GA-1, form with single-stranded DNA. Under the experimental conditions used, ø29 and Nf single-stranded DNA-binding proteins are stable monomers in solution, while GA-1 single-stranded DNA-binding protein presents a hexameric state, as determined in glycerol gradients. The thermodynamic parameters derived from quenching measurements of the intrinsic protein fluorescence upon single-stranded DNA binding revealed (i) that GA-1 single-stranded DNA-binding protein occludes a larger binding site (n=51 nt/oligomer) than ø29 and Nf SSBs (n=3.4 and 4.7 nt/monomer, respectively); and (ii) that it shows a higher global affinity for single-stranded DNA (GA-1 SSB, K(eff)=18.6 x 10(5) M(-1); o29 SSB, K(eff)=2.2 x 10(5) M(-1); Nf SSB, K(eff)=2.9 x 10(5) M(-1)). Altogether, these parameters justify the differences displayed by the GA-1 single-stranded DNA-binding protein and single-stranded DNA complex under the electron microscope, and the requirement of higher amounts of ø29 and Nf single-stranded DNA-binding proteins than of GA-1 SSB in gel mobility shift assays to produce a similar effect. The structural differences of the nucleoprotein complexes formed by the three single-stranded DNA-binding proteins with single-stranded DNA correlate with their different functional stimulatory effects in ø29 DNA amplification.

Analysis of O29 DNA polymerase by partial proteolysis: binding of terminal protein in the double-stranded DNA channel

ø29 DNA polymerase, which belongs to the family of the eukaryotic type DNA polymerases, is able to use two kinds of primers to initiate DNA replication: DNA and terminal protein (TP). By partial proteolysis we have studied the regions of ø29 DNA polymerase involved in primer binding. With proteinase K, no change in the proteolytic pattern was observed upon DNA binding, suggesting that it does not induce a global conformational change in ø29 DNA polymerase. Conversely, two of the three main cleavage sites obtained by partial digestion of free ø29 DNA polymerase with endoproteinase LysC were protected upon DNA binding, indicating that the DNA could be occluding these cleavage sites to the protease either directly by itself and/or indirectly by induction of local conformational changes affecting their exposure. Partial proteolysis with endoproteinase LysC of ø29 DNA polymerase/TP heterodimer resulted in a protection and digestion pattern similar to that obtained with DNA, suggesting that both primers, DNA and TP, fit in the same double-stranded DNA-binding channel and protect the same regions of ø29 DNA polymerase.

Processive proofreading and the spatial relationship between polymerase and exonuclease active sites of bacteriophage phi29 DNA polymerase

phi29 DNA polymerase is a multifunctional enzyme, able to incorporate and to proofread misinserted nucleotides, maintaining a very high replication fidelity. Since both activities are functionally separated, a mechanism is needed to guarantee proper coordination between synthesis and degradation, implying movement of the DNA primer terminus between polymerization and 3'-5' exonuclease active sites. Using single-turnover conditions, we have demonstrated that phi29 DNA polymerase edits the polymerization errors using an intramolecular pathway; that is, the primer terminus travels from one active site to the other without dissociation from the DNA. On the other hand, by using chemical tags, we could infer a difference in length of only one nucleotide to contact the primer strand when it is in the polymerization mode versus the editing mode. Using the same approach, it was estimated that phi29 DNA polymerase covers a DNA region of ten nucleotides, as has been measured in other polymerases using different techniques.

A single tyrosine prevents insertion of ribonucleotides in the eukaryotic-type phi29 DNA polymerase

Three conserved motifs (named A, B and C) have been proposed to form the polymerization active site in all classes of DNA-dependent polymerases. In eukaryotic-type (alpha-like) DNA polymerases, motif A is characterized by the consensus "Dx2SLYP". Mutants in phi29 DNA polymerase residue Tyr254 of this conserved motif had been previously shown to be affected in dNTP binding. Here, we show that a single substitution of Tyr254 into a valine residue enables the enzyme to incorporate ribonucleotide substrates, without affecting its wild-type affinity for dNTPs. Whereas the wild-type enzyme preferred dNTPs more than two million-fold over rNTPs, the mutation of Tyr254 into valine reduced the discrimination for rNTPs up to 1000-fold. In addition to this discrimination mechanism, based on sugar selection, phi29 DNA polymerase is very inefficient when extending an RNA primer terminus, allowing its exonucleolytic degradation. These results indicate that the Tyr254 of phi29 DNA polymerase is responsible for the discrimination against the 2'-OH group of an incoming ribonucleotide. This is the first time that the invariant tyrosine residue of motif A is involved in ribo- versus deoxyribonucleotide discrimination in an eukaryotic-type DNA polymerase.

Role of the "YxGG/A" motif of Phi29 DNA polymerase in protein-primed replication

We have analyzed the functional significance of the phi29 DNA polymerase "YxGG/A" motif in initiation and replication reactions involving the terminal protein (TP) as a primer. This motif, located between the proposed limits of the polymerase and exonuclease domains, has been shown to be very important for the coordination between synthesis and degradation in phi29 DNA polymerase. Mutations in this region affected the polymerization/exonucleolysis (pol/exo) balance, due to its importance for DNA template binding stability at both active sites. Here, we show that the YxGG/A motif of phi29 DNA polymerase is necessary for the formation of a stable complex between TP and phi29 DNA polymerase, affecting initiation and transition during replication of phi29 TP-DNA. The phenotypes in TP-primed reactions in nine of 11 mutant polymerases, showed reduced initiation and/or replication activities using TP-DNA as template. High dATP concentrations allowed the reduced initiation activities of some of these mutant polymerases to reach the wild-type level. The reduction in their affinity for the initiating nucleotide is likely due to their reduced interaction with the TP. Besides, the YxGG/A motif of phi29 DNA polymerase controls the pol/exo balance in the transition step immediately after TP-primed initiation, before DNA polymerase and TP dissociate. Thus, from the first elongation step, the phenotypes of the mutant polymerases parallel those obtained in DNA-primed replication: wild-type, high and low pol/exo balance. A detailed analysis of different transition intermediates suggests that mutants at the YxGG/A motif switch from interaction with TP to DNA once the TP has been extended with six nucleotides.

DNA polymerase III of Gram-positive eubacteria is a zinc metalloprotein conserving an essential finger-like domain

DNA polymerase III (pol III) of Gram-positive eubacteria is a catalytically bifunctional DNA polymerase:3'-5' exonuclease [Low, R. L., Rashbaum, S. A., and Cozzarelli, N. R. (1976) J. Biol.Chem. 251, 1311-1325]. The pol III protein conserves, between its exonuclease and dNTP binding sites, a 35-residue segment of primary structure with the potential to form a zinc finger-like structure [Berg, J. M. (1990) Ann. Rev. Biochem. 19, 405-421]. This paper describes results of experiments which probe the capacity of this segment to bind zinc and the role of this segment in enzyme function. The results of metal and mutational analysis of a model pol III derived from Bacillus subtilis indicate that (i) the Gram-positive pol III is a metalloprotein containing tightly bound zinc in a stoichiometry of 1, (ii) the zinc atom is bound within the 35-residue segment, likely in one of two probable finger-like structures, and (iii) the integrity of the zinc-bound structure is specifically critical to the formation and/or function of the enzyme's polymerase site.

Role of the first aspartate residue of the "YxDTDS" motif of phi29 DNA polymerase as a metal ligand during both TP-primed and DNA-primed DNA synthesis

Almost all known nucleic acid polymerases require three acidic residues to bind the metal ion during catalysis of nucleotide incorporation. Nevertheless, recent crystallographic data on bacteriophage RB69 DNA polymerase indicate that the first aspartate residue belonging to the conserved motif "YxDTDS" could have a merely structural role. To address this question, a mutant protein at the homologous aspartate residue (Asp456) in phi29 DNA polymerase was made 3'-5' exonuclease deficient. This allowed us to analyse the functional importance of this residue in different metal-dependent reactions that can be performed using either terminal protein (TP) or DNA primers. When Mg2+ was used as the metal activator, the synthetic activities of the mutant phi29 DNA polymerase, TP-primed initiation and DNA-primed polymerisation, were about 50-fold less efficient than those of the wild-type enzyme. Interestingly, the use of Mn2+ as the metal activator partially restored the wild-type phenotype. When polymerisation required an efficient translocation along the template, mutation of Asp456 strongly affected the catalytic efficiency of phi29 DNA polymerase. The results presented here indicate that Asp456 has a catalytic role as a metal-activator ligand, but also contributes to enzyme translocation along the DNA, required during consecutive nucleotide incorporation cycles. Moreover, Asp456 appears to be critical to remodel the active site during transition from TP priming to DNA priming. The results are discussed in the light of structural information corresponding to distantly related polymerases.

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.

The RGD sequence in phage phi29 terminal protein is required for interaction with phi29 DNA polymerase

The RGD (Arg-Gly-Asp) motif functions as a recognition site for adhesive proteins responsible for a number of cell-cell interactions. Certain viruses use this sequence as a receptor-binding site by interaction with cellular integrins. To elucidate the role of the RGD sequence of the phi29 terminal protein (TP), seven modified TPs were generated by site-directed mutagenesis. Most of the TP mutants were not efficiently used as primers, leading to a reduction of the TP-dAMP complex formation in the presence of the phi29 TP-DNA template. Moreover, these mutant TPs were poorly deoxyadenylylated by phi29 DNA polymerase in the absence of template. Analysis of primer TP/DNA polymerase complex formation showed that the modified TPs were affected in the formation of the heterodimeric complex. These results indicate that the RGD sequence present in phi29 TP is primarily involved in interaction with the viral DNA polymerase.

Mutational analysis of phi29 DNA polymerase residues acting as ssDNA ligands for 3'-5' exonucleolysis

Here, three highly conserved amino acid residues have been characterized to function as ssDNA binding ligands at the 3'-5' exonuclease active site of phi29 DNA polymerase. One of these residues, Phe65, belongs to motif Exo II, previously described to contain an invariant aspartate and an invariant asparagine involved in catalysis and ssDNA binding, respectively. The other two residues, Ser122 and Leu123, form a newly identified motif "(S/T)Lx2h", and are the homologous counterparts of Pol I residues Asp457 and Met458, and of T4 DNA polymerase residues Ser286 and Leu287, the latter three residues shown to contact ssDNA at their corresponding cocrystal 3D structures. Site-directed mutagenesis and biochemical analysis of eight phi29 DNA polymerase mutant proteins at residues Phe65, Ser122 and Leu123 indicated their functional importance for: (1) a stable interaction with ssDNA; (2) 3'-5' exonucleolysis of ssDNA substrates; (3) proofreading of DNA polymerization errors. Extrapolation to the crystal structures of Klenow and T4 DNA polymerases indicates that the invariant aromatic ring contiguous to the catalytic aspartate of the Exo II motif, corresponding to Tyr423 in Klenow, Phe218 in T4, and Phe65 in phi29 DNA polymerase, appears to be critical to orient the ssDNA substrate in a stable conformation to allow 3'-5' exonucleolytic catalysis. This is the first time that the functional importance of this invariant residue, belonging to the Exo II motif, has been demonstrated.

Phi 29 DNA polymerase requires the N-terminal domain to bind terminal protein and DNA primer substrates

A 44 kDa C-terminal fragment of phi 29 DNA polymerase has been separately expressed and purified from Escherichia coli cells. As expected, the truncated protein lacked the 3'-5' exonuclease activity and strand-displacement capacity, previously mapped in the N-terminal domain of phi 29 DNA polymerase. On the other hand, the 44 kDa C-terminal fragment retained polymerase activity when using Mn2+ as metal activator, although the catalytic efficiency was greatly reduced with respect to that of the complete enzyme. Moreover, and in contrast to the high processivity exhibited by phi 29 DNA polymerase (> 70 kb), polymerization by its C-terminal domain was completely distributive. All these polymerization defects were related to a strong impairment of DNA binding, suggesting that additional contacts present in the N-terminal domain are important for an optimal stabilization and translocation of the DNA during polymerization. Moreover, the C-terminal domain showed a very reduced capacity to initiate terminal protein (TP)-primed DNA replication, as a consequence of a weakened interaction with the TP primer, and a lack of activation by protein p6, the initiator of phi 29 DNA replication. We conclude that the C-terminal portion of phi 29 DNA polymerase (residues 188 to 575), although having a structural entity as the domain responsible for the synthetic activities, requires the N-terminal domain to provide important contacts for the two different substrates, DNA and TP, that prime DNA synthesis. These results support the hypothesis of a modular organization of enzymatic activities in DNA-dependent DNA polymerases, but emphasize the functional coordination required for coupling DNA synthesis and proofreading, and for the more specific functions (TP-priming, high processivity and strand-displacement) inherent to phi 29 DNA polymerase.

Bacteriophage phi29 DNA replication arrest caused by codirectional collisions with the transcription machinery

The consequences on replication of collisions between phi29 DNA polymerase, a monomeric replicase endowed with strand displacement capacity, and the transcription machinery have been studied in vitro. Codirectional collisions with stalled transcription ternary complexes at four different promoters in the phi29 genome were found to block replication fork progression. Upon collision, the DNA polymerase remained on the template and was able to resume elongation once the RNA polymerase was allowed to move. Collisions with RNA polymerase molecules moving in the same direction also interfered with replication, causing a decrease in the replication rate. These results lead to the proposal that in bacteriophage phi29 a transcription complex physically blocks the progression of a replication fork. We suggest that temporal regulation of transcription and the low probability that the replication and transcription processes colocalize in vivo contribute to achieving minimal interference between the two events.

An invariant lysine residue is involved in catalysis at the 3'-5' exonuclease active site of eukaryotic-type DNA polymerases

A lysine residue, contained in the motif "Kx2h", has been invariantly found in the eukaryotic-type (family B) class of DNA-dependent DNA polymerases with a proofreading function. The importance of this lysine has been assessed by site-directed mutagenesis in the corresponding residue (Lys143) of phi29 DNA polymerase. Substitution of this residue either by arginine or isoleucine severely impaired the catalytic efficiency of the 3'-5' exonuclease activity, giving a characteristic distributive pattern that contrasts with the processive pattern displayed by the wild-type phi29 DNA polymerase. Exonuclease assays carried out in the presence of a DNA trap, together with direct analysis of enzyme/ssDNA interaction, allowed us to conclude that this altered pattern was due to a reduction in the catalytic rate of these mutants, but not to a weakened association with ssDNA. These phenotypes indicate that the lysine residue of motif Kx2h plays an auxiliary role in catalysis of the exonuclease reaction, in very good agreement with recent crystallographic data showing that the lysine homologue of T4 DNA polymerase is indirectly involved in metal binding at the 3'-5' exonuclease active site. In agreement with a critical role in proofreading, substitution of Lys143 of phi29 DNA polymerase by arginine or isoleucine produced mutator enzymes that displayed a high frequency of misincorporation. Mutants at Lys143 also showed a reduced DNA polymerization capacity, but only when DNA synthesis was coupled to strand-displacement, an intrinsic property of phi29 DNA polymerase that is specifically affected by mutations at residues directly or indirectly involved in metal binding at the 3'-5' exonuclease active site.

ø29 DNA polymerase residue Lys383, invariant at motif B of DNA-dependent polymerases, is involved in dNTP binding

Bacteriophage ø29 DNA polymerase shares with other DNA-dependent DNA polymerases several regions of amino acid homology along the primary structure. Among them, motif B, characterized by the consensus +x3Kx(6-7)YG (+ being a positively charged amino acid), appears to be specifically conserved in those polymerases that use DNA but not RNA as template. In particular, the lysine residue of this motif is invariant in all members of DNA-dependent polymerases. In this paper we report a mutational analysis of this invariant residue of motif B with the construction and characterization of two mutant proteins in the corresponding residue (Lys383) of ø29 DNA polymerase. Mutant proteins (K383R and K383P) were overexpressed, purified and analyzed under steady-state conditions. In agreement with the modular organization proposed for ø29 DNA polymerase, the exonuclease activity was not affected in either mutant protein. Conversely, mutant K383P showed no detectable capacity to incorporate dNTP substrates using either DNA or TP as primer, although its affinity for DNA was not affected. The conservative substitution of Lys383 by arginine (K383R) resulted in a considerable impairment to use dNTPs, in both processive and non-processive DNA synthesis; the Km for dNTPs being 200-fold higher than that of the wild-type enzyme. Mutant K383R recovered the wild-type polymerase/exonuclease ratio when Mn2+ was used instead of Mg2+ as metal activator, indicating a distorted binding of the [dNTP-metal] chelate at the mutant enzyme active site. The positive charge at residue Lys383 was also critical in the catalysis of deoxynucleotidylation of the terminal protein by ø29 DNA polymerase. The results obtained suggest a direct role for the lysine residue in motif B in forming an evolutionarily conserved DNA templated dNTP binding pocket. Additionally, K383R mutant protein was also affected in the progression from protein-primed initiation to DNA elongation, a switch between two modes of priming that characterizes ø29 DNA replication.

Protein-primed DNA replication: a transition between two modes of priming by a unique DNA polymerase

Phage phi29 from Bacillus subtilis is a paradigm of the protein-primed replication mechanism, in which a single-subunit DNA polymerase is involved in both the specific protein-primed initiation step and normal DNA elongation. To start phi29 DNA replication, the viral DNA polymerase must interact with a free molecule of the viral terminal protein (TP), to prime DNA synthesis once at each phi29 DNA end. The results shown in this paper demonstrate that the DNA polymerase-primer TP heterodimer is not dissociated immediately after initiation. On the contrary, there is a transition stage in which the DNA polymerase synthesizes a five nucleotide-long DNA molecule while complexed with the primer TP, undergoes some structural change during replication of nucleotides 6-9, and finally dissociates from the primer protein when nucleotide 10 is inserted onto the nascent DNA chain. This behaviour probably reflects the polymerase requirement for a DNA primer of a minimum length to efficiently catalyze DNA elongation. The significance of such a limiting transition stage is supported by the finding of abortive replication products consisting of the primer TP linked up to eight nucleotides, detected during in vitro replication of phi29 TP-DNA particularly under conditions that decrease the strand-displacement capacity of phi29 DNA polymerase.

In vitro evolution of terminal protein-containing genomes

A new self-sustained terminal protein-primed DNA amplification system has been used to describe in vitro evolutionary changes affecting maintenance of the genome size of bacteriophage phi29. These changes involve generation and efficient amplification of short palindromic molecules containing an inverted duplication of one of the original DNA ends. A template-switching mechanism is proposed to account for the appearance of these molecules. After their formation, they would replicate by means of hairpin intermediates. Relevant kinetic information about this DNA replication system has been obtained from the competition between the input full-length phi29 DNA and its derived truncated versions. The physiological relevance of these molecules and the mechanisms to control their formation are discussed.