Phi 29 DNA polymerase active site. Mutants in conserved residues Tyr254 and Tyr390 are affected in dNTP binding.

Phi 29 DNA polymerase shares with other alpha-like DNA polymerases several regions of amino acid similarity. Among them, the two conserved regions characterized by the amino acid motifs "D-NSLYP" and "K--NS(L/V)YG," regions 1 and 2a, respectively, according to Blanco et al. (Blanco, L., Bernad, A., Blasco, M. A. and Salas, M. (1991) Gene (Amst.) 100, 27-38) have been proposed to be part of the polymerization active site of alpha-like DNA polymerases. One phi 29 DNA polymerase mutant in residue Tyr254, located in conserved region 1, and two mutants in residue Tyr390, located in conserved region 2a, have been characterized. The three phi 29 DNA polymerase mutant proteins were affected in polymerization when Mg(2+)-dNTPs were used as substrate. However, when the substrate was Mn(2+)-dNTP, mutants behaved as the wild-type phi 29 DNA polymerase. Mutant Tyr254 to Phe (Y254F) was strongly affected in the protein-primed initiation step of phi 29 DNA replication showing a decreased affinity for Me(2+)-dATP, the initiating nucleotide. Furthermore, the analysis of the template-independent deoxynucleotidylation of the TP by Y254F mutant polymerase is consistent with a change in the relative affinity for dNTPs. On the other hand, mutants Y390F and Y390S were found to be hypersensitive to the dNTP analogs 2-(p-n-butylanilino)dATP and N2-(p-n-butyl-phenyl)dGTP. The results obtained indicate that residues Tyr254 and Tyr390 are involved, directly or indirectly, in Me(2+)-dNTP binding.     

phi29 DNA polymerase residue Phe128 of the highly conserved (S/T)Lx(2)h motif is required for a stable and functional interaction with the terminal protein

Bacteriophage phi29 encodes a DNA-dependent DNA polymerase belonging to the eukaryotic-type (family B) subgroup of DNA polymerases that use a protein as primer for initiation of DNA replication. By multiple sequence alignments of DNA polymerases from such a family, we have been able to identify two amino acid residues specifically conserved in the protein-priming subgroup of DNA polymerases, a phenylalanine contained in the (S/T)Lx(2)h motif, and a glutamate belonging to the Exo III motif. Here, we have studied the functional role of these residues in reactions that are specific for DNA polymerases that use a protein-primed DNA replication mechanism, by site-directed mutagenesis in the corresponding amino acid residues, Phe128 and Glu161 of phi29 DNA polymerase. Mutations introduced at residue Phe128 severely impaired the protein-primed replication capacity of the polymerase, being the interaction with the terminal protein (TP) moderately (mutant F128A) or severely (mutant F128Y) diminished. As a consequence, very few initiation products were obtained, and essentially no transition products were detected. Interestingly, phi29 DNA polymerase mutant F128Y showed a decreased binding affinity for short template DNA molecules. These results, together with the high degree of conservation of Phe128 residue among protein-primed DNA polymerases, suggest a functional role for this amino acid residue in making contacts with the TP during the first steps of genome replication and with DNA in the further replication steps.     

Mutagenesis of human DNA polymerase lambda: essential roles of Tyr505 and Phe506 for both DNA polymerase and terminal transferase activities

DNA polymerase (pol) λ is homologous to pol β and has intrinsic polymerase and terminal transferase activities. However, nothing is known about the amino acid residues involved in these activites. In order to precisely define the nucleotide-binding site of human pol λ, we have mutagenised two amino acids, Tyr505 and the neighbouring Phe506, which were predicted by structural homology modelling to correspond to the Tyr271 and Phe272 residues of pol β, which are involved in nucleotide binding. Our analysis demonstrated that pol λ Phe506Arg/Gly mutants possess very low polymerase and terminal transferase activities as well as greatly reduced abilities for processive DNA synthesis and for carrying on translesion synthesis past an abasic site. The Tyr505Ala mutant, on the other hand, showed an altered nucleotide binding selectivity to perform the terminal transferase activity. Our results suggest the existence of a common nucleotide-binding site for the polymerase and terminal transferase activities of pol λ, as well as distinct roles of the amino acids Tyr505 and Phe506 in these two catalytic functions.     

Functional domains in the bacteriophage phi 29 terminal protein for interaction with the phi 29 DNA polymerase and with DNA.

Deletion mutants at the amino- and carboxyl-ends of the phi 29 terminal protein, as well as internal deletion and substitution mutants, whose ability to prime the initiation of phi 29 DNA replication was affected to different extent, have been assayed for their capacity to interact with DNA or with the phi 29 DNA polymerase. One DNA binding domain at the amino end of the terminal protein has been mapped. Two regions involved in the binding to the DNA polymerase, an internal region near the amino-terminus and a carboxyl-terminal one, have been also identified. Interaction with both DNA and phi 29 DNA polymerase are required to led to the formation of terminal protein-dAMP initiation complex to start phi 29 DNA replication.     

Phage phi29 terminal protein residues Asn80 and Tyr82 are recognition elements of the replication origins.

Initiation of phage phi29 DNA replication starts with the recognition of the origin of replication, located at both ends of the linear DNA, by a heterodimer formed by the phi29 terminal protein (TP) and the phi29 DNA polymerase. The parental TP, covalently linked to the DNA ends, is one of the main components of the replication origin. Here we provide evidence that recognition of the origin is mediated through interactions between the TP of the TP/DNA polymerase heterodimer, called primer TP, and the parental TP. Based on amino acid sequence comparisons, various phi29 TP mutants were generated at conserved amino acid residues from positions 61 to 87. In vitro phi29 DNA amplification analysis revealed that residues Asn80 and Tyr82 are essential for functional interaction between primer and parental TP required for recognition of the origin of replication. Although these mutant TPs can form functional heterodimers with phi29 DNA polymerase that are able to recognize the origin of replication, these heterodimers are not able to recognize an origin containing a mutant TP.     

Tyr26 and Phe73 are essential for full biological activity of the Fd Gene 5 protein

Abstract Using site-saturation mutagenesis, we have established all possible amino acid substitutions at Tyr26 and Phe73 that are compatible with biological activity of the gene 5 protein in vivo. No substitutions were found at either site that gave rise to a fully functional gene 5 protein, indicating that these two amino acid residues are crucial. However, partial activity was found if either residue was replaced by another aromatic amino acid (Y26F, Y26W, F73Y, F73W). The results suggest that both Tyr26 and Phe73 are important for base stacking in the nucleoprotein complex. The functional consequences of the removal of the hydroxyl group from Tyr26 argue that this residue may, in addition, be involved in hydrogen bond formation to confer greater stability on the complex. In contrast, the addition of such a group to Phe73 reduces activity.     

phi29 DNA polymerase-terminal protein interaction. Involvement of residues specifically conserved among protein-primed DNA polymerases

By multiple sequence alignments of DNA polymerases from the eukaryotic-type (family B) subgroup of protein-primed DNA polymerases we have identified five positively charged amino acids, specifically conserved, located N-terminally to the (S/T)Lx(2)h motif. Here, we have studied, by site-directed mutagenesis, the functional role of phi29 DNA polymerase residues Arg96, Lys110, Lys112, Arg113 and Lys114 in specific reactions dependent on a protein-priming event. Mutations introduced at residues Arg96, Arg113 and Lys114 and to a lower extent Lys110 and Lys112, showed a defective protein-primed initiation step. Analysis of the interaction with double-stranded DNA and terminal protein (TP) displayed by mutant derivatives R96A, K110A, K112A, R113A and K114A allows us to conclude that phi29 DNA polymerase residue Arg96 is an important DNA/TP-ligand residue, essential to form stable DNA polymerase/DNA(TP) complexes, while residues Lys110, Lys112 and Arg113 could be playing a role in establishing contacts with the TP-DNA template during the first step of DNA replication. The importance of residue Lys114 to make a functionally active DNA polymerase/TP complex is also discussed. These results, together with the high degree of conservation of those residues among protein-primed DNA polymerases, strongly suggest a functional role of those amino acids in establishing the appropriate interactions with DNA polymerase substrates, DNA and TP, to successfully accomplish the first steps of TP-DNA replication.     

Two positively charged residues of phi29 DNA polymerase, conserved in protein-primed DNA polymerases, are involved in stabilisation of the incoming nucleotide

In DNA polymerases from families A and B in the closed conformation, several positively charged residues, located in pre-motif B and motif B, have been shown to interact with the phosphate groups of the incoming nucleotide at the polymerisation active site: the invariant Lys of motif B and the nearly invariant Lys of pre-motif B (family B) correspond to a His in family A DNA polymerases. In phi29 DNA polymerase, belonging to the family B DNA polymerases able to start replication by protein-priming, the corresponding residues, Lys383 and Lys371, have been shown to be dNTP-ligands. Since in several DNA polymerases a third residue has been involved in dNTP binding, we have addressed here the question if in the DNA polymerases of the protein-primed subfamily, and especially in phi29 DNA polymerase, there are more than these two residues involved in nucleotide binding. By site-directed mutagenesis in phi29 DNA polymerase the functional role of the remaining two conserved positively charged amino acid residues of pre-motif B and motif B (besides Lys371 and Lys383) has been studied. The results indicate that residue Lys379 of motif B is also involved in dNTP binding, possibly through interaction with the triphosphate moiety of the incoming nucleotide, since the affinity for nucleotides of mutant DNA polymerase K379T was reduced in DNA and TP-primed reactions. On the other hand, we propose that, when the terminal protein (TP) is present at the polymerisation active site, residue Lys366 of pre-motif B is involved in stabilising the incoming nucleotide in an appropriate position for efficient TP-deoxynucleotidylation. Although mutant DNA polymerase K366T showed a wild-type like phenotype in DNA-primed polymerisation in the presence of DNA as template, in TP-primed reactions as initiation and transition it was impaired, especially in the presence of the phi29 DBP, protein p6.     

phi 29 DNA polymerase residue Leu384, highly conserved in motif B of eukaryotic type DNA replicases,is involved in nucleotide insertion fidelity

Replicative DNA polymerases achieve insertion fidelity by geometric selection of a complementary nucleotide followed by induced fit: movement of the fingers subdomain toward the active site to enclose the incoming and templating nucleotides generating a binding pocket for the nascent base pair. Several residues of motif B of DNA polymerases from families A and B, localized in the fingers subdomain, have been described to be involved in template/primer binding and dNTP selection. Here we complete the analysis of this motif, which has the consensus "KLX2NSXYG" in DNA polymerases from family B, characterized by mutational analysis of conserved leucine, Leu384 of phi 29 DNA polymerase. Mutation of Leu384 into Arg resulted in a phi 29 DNA polymerase with reduced nucleotide insertion fidelity during DNA-primed polymerization and protein-primed initiation reactions. However, the mutation did not alter the intrinsic affinity for the different dNTPs, as shown in the template-independent terminal protein-deoxynucleotidylation reaction. We conclude that Leu384 of phi 29 DNA polymerase plays an important role in positioning the templating nucleotide at the polymerization active site and in controlling nucleotide insertion fidelity. This agrees with the localization of the corresponding residue in the closed ternary complexes of family A and family B DNA polymerases, contributing to form the binding pocket for the nascent base pair. As an additional effect, mutant polymerase L384R was strongly reduced in DNA binding, resulting in reduced processivity during polymerization.     

DNA-independent deoxynucleotidylation of the phi 29 terminal protein by the phi 29 DNA polymerase.

In this paper, we show that the phi 29 DNA polymerase, in the absence of DNA, is able to catalyze the formation of a covalent complex between the phi 29 terminal protein (TP) and 5'-dAMP. Like the reaction in the presence of phi 29 DNA, TP.dAMP complex formation is strongly dependent on activating Mn2+ ions and on the efficient formation of a TP/DNA polymerase heterodimer. The nature of the TP-dAMP linkage was shown to be identical (a O-5'-deoxyadenylyl-L-serine bond) to that found covalently linking TP to the DNA of bacteriophage phi 29, indicating that this DNA-independent reaction actually mimics that occurring as the initiation step of phi 29 DNA replication. Furthermore, as in normal TP-primed initiation on the phi 29 DNA template, this novel reaction showed the same specificity for TP Ser232 as the OH donor and the involvement of the YCDTD amino acid motif, highly conserved in alpha-like DNA polymerases. However, unlike the reaction in the presence of phi 29 DNA, the DNA-independent deoxynucleotidylation of TP by the phi 29 DNA polymerase did not show dATP specificity, being possible to obtain any of the four TP.dNMP complexes with a similar yield. This lack of specificity together with the poor efficiency of this reaction at low deoxynucleoside triphosphate (dNTP) concentration reflect a weak, but similar stability of the four dNTPs at the phi 29 DNA polymerase dNTP-binding site. Thus, the presence of a director DNA would mainly contribute to stabilizing a complementary nucleotide, giving base specificity to the protein-primed initiation reaction. According to all these data, the novel DNA polymerase reaction described in this paper could be considered as a "non-DNA-instructed" protein-primed deoxynucleotidylation.     

Function of the C-terminus of phi29 DNA polymerase in DNA and terminal protein binding

The thumb subdomain, located in various family B DNA polymerases in the C-terminal region, has been shown in their crystal structures to move upon binding of DNA, changing its conformation to nearly completely wrap around the DNA. It has therefore been involved in DNA binding. In agreement with this, partial proteolysis studies of 29 DNA polymerase have shown that the accessibility of the cleavage sites located in their C-terminal region is reduced in the presence of DNA or terminal protein (TP), indicating that a conformational change occurs in this region upon substrate binding and suggesting that this region might be involved in DNA and TP binding. Therefore, we have studied the role of the C-terminus of 29 DNA polymerase by deletion of the last 13 residues of this enzyme. This fragment includes a previously defined region conserved in family B DNA polymerases. The resulting DNA polymerase Δ13 was strongly affected in DNA binding, resulting in a distributive replication activity. Additionally, the capacity of the truncated polymerase to interact with TP was strongly reduced and its initiation activity was very low. On the other hand, its nucleotide binding affinity and its fidelity were not affected. We propose that the C-terminal 13 amino acids of 29 DNA polymerase are involved in DNA binding and in a stable interaction with the initiator protein TP, playing an important role in the intrinsic processivity of this enzyme during polymerization.     

Involvement of residues of the 29 terminal protein intermediate and priming domains in the formation of a stable and functional heterodimer with the replicative DNA polymerase

Bacteriophage Φ29 genome consists of a linear double-stranded DNA with a terminal protein (TP) covalently linked to each 5' end (TP-DNA) that together with a specific sequence constitutes the replication origins. To initiate replication, the DNA polymerase forms a heterodimer with a free TP that recognizes the origins and initiates replication using as primer the hydroxyl group of TP residue Ser232. The 3D structure of the DNA polymerase/TP heterodimer allowed the identification of TP residues that could be responsible for interaction with the DNA polymerase. Here, we examined the role of TP residues Arg158, Arg169, Glu191, Asp198, Tyr250, Glu252, Gln253 and Arg256 by in vitro analyses of mutant derivatives. The results showed that substitution of these residues had an effect on either the stability of the TP/DNA polymerase complex (R158A) or in the functional interaction of the TP at the polymerization active site (R169A, E191A, Y250A, E252A, Q253A and R256A), affecting the first steps of Φ29 TP-DNA replication. These results allow us to propose a role for these residues in the maintenance of the equilibrium between TP-priming domain stabilization and its gradual exit from the polymerization active site of the DNA polymerase as new DNA is being synthesized.     

A highly conserved lysine residue in phi29 DNA polymerase is important for correct binding of the templating nucleotide during initiation of phi29 DNA replication

DNA polymerases that initiate replication by protein-priming are able to catalyze terminal protein (TP)-primed initiation, the following transition steps and finally DNA-primed elongation. Therefore, their structures must be able to position sequentially both primers, TP and DNA, at a common binding site. For DNA-templated initiation, these DNA polymerases have to bind the origin of replication as template and TP as primer. It is likely that very precise interactions are required to position both TP and templating nucleotide at the polymerization active site. Such a specificity during TP-priming must rely on specific amino acids that must be evolutionarily conserved in this subfamily of DNA polymerases. By site-directed mutagenesis, we have analyzed the functional significance of Lys392 of phi29 DNA polymerase, immediately adjacent to the Kx3NSxYG motif, and specifically conserved among protein-primed DNA polymerases. During TP-primed initiation, mutations in this residue did not affect untemplated TP-dAMP formation, indicating that the interaction with the initiating nucleotide and TP were not affected, whereas the template-directed initiation activity was severely inhibited. Both mutant DNA polymerases had a wild-type-like (overall) DNA binding activity. We thus infer that residue Lys392 of phi29 DNA polymerase is important for the correct positioning of the templating nucleotide at the polymerization active site, a critical requirement during template-directed TP-priming at phi29 DNA origins. Consequently, mutation of this residue compromised the fidelity of the initiation reaction, not controlled by the 3'-5' exonuclease activity. During DNA-primed polymerization, the mutant polymerases showed a defect in translocation of the template strand. This translocation problem could be the consequence of a more general defect in the stabilization and positioning of a next templating nucleotide at the polymerization active site, during DNA-primed DNA synthesis.     

Mapping and mutation of the conserved DNA polymerase interaction motif (DPIM) located in the C-terminal domain of fission yeast DNA polymerase δ subunit Cdc27

Background  

DNA polymerases α and δ play essential roles in the replication of chromosomal DNA in eukaryotic cells. DNA polymerase α (Pol α)-primase is required to prime synthesis of the leading strand and each Okazaki fragment on the lagging strand, whereas DNA polymerase δ (Pol δ) is required for the elongation stages of replication, a function it appears capable of performing on both leading and lagging strands, at least in the absence of DNA polymerase ε (Pol ε).     

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

?29 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 ?29 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 ?29 DNA polymerase. Conversely, two of the three main cleavage sites obtained by partial digestion of free ?29 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 ?29 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 ?29 DNA polymerase.     

Function of the fully conserved residues Asp99, Tyr52 and Tyr73 in phospholipase A2

In the active centre of pancreatic phospholipase A2 His48 is at hydrogen-bonding distance to Asp99. This Asp-His couple is assumed to act together with a water molecule as a catalytic triad. Asp99 is also linked via an extended hydrogen bonding system to the side chains of Tyr52 and Tyr73. To probe the function of the fully conserved Asp99, Tyr52 and Tyr73 residues in phospholipase A2, the Asp99 residue was replaced by Asn, and each of the two tyrosines was separately replaced by either a Phe or a Gln. The catalytic and binding properties of the Phe52 and Phe73 mutants did not change significantly relative to the wild-type enzyme. This rules out the possibility that either one of the two Tyr residues in the wild-type enzyme can function as an acyl acceptor or proton donor in catalysis. The Gln73 mutant could not be obtained in any significant amounts probably due to incorrect folding. The Gln52 mutant was isolated in low yield. This mutant showed a large decrease in catalytic activity while its substrate binding was nearly unchanged. The results suggest a structural role rather than a catalytic function of Tyr52 and Tyr73. Substitution of asparagine for aspartate hardly affects the binding constants for both monomeric and micellar substrate analogues. Kinetic characterization revealed that the Asn99 mutant has retained no less than 65% of its enzymatic activity on the monomeric substrate rac 1,2-dihexanoyldithio-propyl-3-phosphocholine, probably due to the fact that during hydrolysis of monomeric substrate by phospholipase A2 proton transfer is not the rate-limiting step.(ABSTRACT TRUNCATED AT 250 WORDS)     

Primer-terminus stabilization at the 3'-5' exonuclease active site of phi29 DNA polymerase. Involvement of two amino acid residues highly conserved in proofreading DNA polymerases.

By site-directed mutagenesis in phi29 DNA polymerase, we have analyzed the functional importance of two evolutionarily conserved residues belonging to the 3'-5' exonuclease domain of DNA-dependent DNA polymerases. In Escherichia coli DNA polymerase I, these residues are Thr358 and Asn420, shown by crystallographic analysis to be directly acting as single-stranded DNA (ssDNA) ligands at the 3'-5' exonuclease active site. On the basis of these structural data, single substitution of the corresponding residues of phi29 DNA polymerase, Thr15 and Asn62, produced enzymes with a very reduced or altered capacity to bind ssDNA. Analysis of the residual 3'-5' exonuclease activity of these mutant derivatives on ssDNA substrates allowed us to conclude that these two residues do not play a direct role in the catalysis of the reaction. On the other hand, analysis of the 3'-5' exonuclease activity on either matched or mismatched primer/template structures showed a critical role of these two highly conserved residues in exonucleolysis under polymerization conditions, i.e. in the proofreading of DNA polymerization errors, an evolutionary advantage of most DNA-dependent DNA polymerases. Moreover, in contrast to the dual role in 3'-5' exonucleolysis and strand displacement previously observed for phi29 DNA polymerase residues acting as metal ligands, the contribution of residues Thr15 and Asn62 appears to be restricted to the proofreading function, by stabilization of the frayed primer-terminus at the 3'-5' exonuclease active site.     

Specific residues in the connector loop of the human cytomegalovirus DNA polymerase accessory protein UL44 are crucial for interaction with the UL54 catalytic subunit

The human cytomegalovirus DNA polymerase includes an accessory protein, UL44, which has been proposed to act as a processivity factor for the catalytic subunit, UL54. How UL44 interacts with UL54 has not yet been elucidated. The crystal structure of UL44 revealed the presence of a connector loop analogous to that of the processivity subunit of herpes simplex virus DNA polymerase, UL42, which is crucial for interaction with its cognate catalytic subunit, UL30. To investigate the role of the UL44 connector loop, we replaced each of its amino acids (amino acids 129 to 140) with alanine. We then tested the effect of each substitution on the UL44-UL54 interaction by glutathione S-transferase pulldown and isothermal titration calorimetry assays, on the stimulation of UL54-mediated long-chain DNA synthesis by UL44, and on the binding of UL44 to DNA-cellulose columns. Substitutions that affected residues 133 to 136 of the connector loop measurably impaired the UL44-UL54 interaction without altering the ability of UL44 to bind DNA. One substitution, I135A, completely disrupted the binding of UL44 to UL54 and inhibited the ability of UL44 to stimulate long-chain DNA synthesis by UL54. Thus, similar to the herpes simplex virus UL30-UL42 interaction, a residue of the connector loop of the accessory subunit is crucial for UL54-UL44 interaction. However, while alteration of a polar residue of the UL42 connector loop only partially reduced binding to UL30, substitution of a hydrophobic residue of UL44 completely disrupted the UL54-UL44 interaction. This information may aid the discovery of small-molecule inhibitors of the UL44-UL54 interaction.