A conserved insertion in protein-primed DNA polymerases is involved in primer terminus stabilisation

The Loop of the TPR1 Subdomain of Phi29 DNA Polymerase Plays a Pivotal Role in Primer-Terminus Stabilization at the Polymerization Active Site

Bacteriophage Phi29 DNA polymerase belongs to the protein-primed subgroup of family B DNA polymerases that use a terminal protein (TP) as a primer to initiate genome replication. The resolution of the crystallographic structure showed that it consists of an N-terminal domain with the exonuclease activity and a C-terminal polymerization domain. It also has two subdomains specific of the protein-primed DNA polymerases; the TP Regions 1 (TPR1) that interacts with TP and DNA, and 2 (TPR2), that couples both processivity and strand displacement to the enzyme. The superimposition of the structures of the apo polymerase and the polymerase in the polymerase/TP heterodimer shows that the structural changes are restricted almost to the TPR1 loop (residues 304–314). In order to study the role of this loop in binding the DNA and the TP, we changed the residues Arg306, Arg308, Phe309, Tyr310, and Lys311 into alanine, and also made the deletion mutant Δ6 lacking residues Arg306–Lys311. The results show a defective TP binding capacity in mutants R306A, F309A, Y310A, and Δ6. The additional impaired primer-terminus stabilization at the polymerization active site in mutants Y310A and Δ6 allows us to propose a role for the Phi29 DNA polymerase TPR1 loop in the proper positioning of the DNA and TP-priming 3’-OH termini at the preinsertion site of the polymerase to enable efficient initiation and further elongation steps during Phi29 TP-DNA replication.

Dual role of φ29 DNA polymerase Lys529 in stabilisation of the DNA priming-terminus and the terminal protein-priming residue at the polymerisation site

Resolution of the crystallographic structure of φ29 DNA polymerase binary and ternary complexes showed that residue Lys529, located at the C-terminus of the palm subdomain, establishes contacts with the 3' terminal phosphodiester bond. In this paper, site-directed mutants at this Lys residue were used to analyse its functional importance for the synthetic activities of φ29 DNA polymerase, an enzyme that starts linear φ29 DNA replication using a terminal protein (TP) as primer. Our results show that single replacement of φ29 DNA polymerase residue Lys529 by Ala or Glu decreases the stabilisation of the primer-terminus at the polymerisation active site, impairing both the insertion of the incoming nucleotide when DNA and TP are used as primers and the translocation step required for the next incoming nucleotide incorporation. In addition, combination of the DNA polymerase mutants with a TP derivative at residue Glu233, neighbour to the priming residue Ser232, leads us to infer a direct contact between Lys529 and Glu233 for initiation of TP-DNA replication. Altogether, the results are compatible with a sequential binding of φ29 DNA polymerase residue Lys529 with TP and DNA during replication of TP-DNA.

Anticodon nuclease encoding virus-like elements in yeast

A variety of yeast species are known to host systems of cytoplasmic linear dsDNA molecules that establish replication and transcription independent of the nucleus via self-encoded enzymes that are phylogenetically related to those encoded by true infective viruses. Such yeast virus-like elements (VLE) fall into two categories: autonomous VLEs encode all the essential functions for their inheritance, and additional, dependent VLEs, which may encode a toxin-antitoxin system, generally referred to as killer toxin and immunity. In the two cases studied in depth, killer toxin action relies on chitin binding and hydrophobic domains, together allowing a separate toxic subunit to sneak into the target cell. Mechanistically, the latter sabotages codon-anticodon interaction by endonucleolytic cleavage of specific tRNAs 3' of the wobble nucleotide. This primary action provokes a number of downstream effects, including DNA damage accumulation, which contribute to the cell-killing efficiency and highlight the importance of proper transcript decoding capacity for other cellular processes than translation itself. Since wobble uridine modifications are crucial for efficient anticodon nuclease (ACNase) action of yeast killer toxins, the latter are valuable tools for the characterization of a surprisingly complex network regulating the addition of wobble base modifications in tRNA.

Viral polymerases

Viral polymerases play a central role in viral genome replication and transcription. Based on the genome type and the specific needs of particular virus, RNA-dependent RNA polymerase, RNA-dependent DNA polymerase, DNA-dependent RNA polymerase, and DNA-dependent RNA polymerases are found in various viruses. Viral polymerases are generally active as a single protein capable of carrying out multiple functions related to viral genome synthesis. Specifically, viral polymerases use variety of mechanisms to recognize initial binding sites, ensure processive elongation, terminate replication at the end of the genome, and also coordinate the chemical steps of nucleic acid synthesis with other enzymatic activities. This review focuses on different viral genome replication and transcription strategies, and the polymerase interactions with various viral proteins that are necessary to complete genome synthesis.

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 novel replicative enzyme encoded by the linear Arthrobacter plasmid pAL1

The soil bacterium Arthrobacter nitroguajacolicus Rü61a contains the linear plasmid pAL1, which codes for the degradation of 2-methylquinoline. Like other linear replicons of actinomycetes, pAL1 is characterized by short terminal inverted-repeat sequences and terminal proteins (TPpAL1) covalently attached to its 5' ends. TPpAL1, encoded by the pAL1.102 gene, interacts in vivo with the protein encoded by pAL1.101. Bioinformatic analysis of the pAL1.101 protein, which comprises 1,707 amino acids, suggested putative zinc finger and topoisomerase-primase domains and part of a superfamily 2 helicase domain in its N-terminal and central regions, respectively. Sequence motifs characteristic of the polymerization domain of family B DNA polymerases are partially conserved in a C-terminal segment. The purified recombinant protein catalyzed the deoxycytidylation of TPpAL1 in the presence of single-stranded DNA templates comprising the 3'-terminal sequence (5'-GCAGG-3'), which in pAL1 forms the terminal inverted repeat, but also at templates with 5'-(G/T)CA(GG/GC/CG)-3' ends. Enzyme assays suggested that the protein exhibits DNA topoisomerase, DNA helicase, and DNA- and protein-primed DNA polymerase activities. The pAL1.101 protein, therefore, may act as a replicase of pAL1.

Functional characterization of highly processive protein-primed DNA polymerases from phages Nf and GA-1, endowed with a potent strand displacement capacity

This paper shows that the protein-primed DNA polymerases encoded by bacteriophages Nf and GA-1, unlike other DNA polymerases, do not require unwinding or processivity factors for efficient synthesis of full-length terminal protein (TP)-DNA. Analysis of their polymerization activity shows that both DNA polymerases base their replication efficiency on a high processivity and on the capacity to couple polymerization to strand displacement. Both enzymes are endowed with a proofreading activity that acts coordinately with the polymerization one to edit polymerization errors. Additionally, Nf double-stranded DNA binding protein (DBP) greatly stimulated the in vitro formation of the TP-dAMP initiation complex by decreasing the K_m value for dATP of the Nf DNA polymerase by >20-fold. Whereas Nf DNA polymerase, as the φ29 enzyme, is able to use its homologous TP as well as DNA as primer, GA-1 DNA polymerase appears to have evolved to use its corresponding TP as the only primer of DNA synthesis. Such exceptional behaviour is discussed in the light of the recently solved structure of the DNA polymerase/TP complex of the related bacteriophage φ29.

Involvement of phi29 DNA polymerase thumb subdomain in the proper coordination of synthesis and degradation during DNA replication

φ29 DNA polymerase achieves a functional coupling between its 3′–5′ exonuclease and polymerization activities by means of important contacts with the DNA at both active sites. The placement and orientation of residues Lys538, Lys555, Lys557, Gln560, Thr571, Thr573 and Lys575 in a modelled φ29 DNA polymerase–DNA complex suggest a DNA-binding role. In addition, crystal structure of φ29 DNA polymerase–oligo (dT)₅ complex showed Leu567, placed at the tip of the thumb subdomain, lying between the two 3′-terminal bases at the exonuclease site. Single replacement of these φ29 DNA polymerase residues by alanine was made, and mutant derivatives were overproduced and purified to homogeneity. The results obtained in the assay of their synthetic and degradative activities, as well as their coordination, allow us to propose: (1) a primer-terminus stabilization role at the polymerase active site for residues Lys538, Thr573 and Lys575, (2) a primer-terminus stabilization role at the exonuclease active site for residues Leu567 and Lys555 and (3) a primer-terminus binding role in both editing and polymerization modes for residue Gln560. The results presented here lead us to propose φ29 DNA polymerase thumb as the main subdomain responsible for the coordination of polymerization and exonuclease activities.

The phi29 DNA polymerase:protein-primer structure suggests a model for the initiation to elongation transition

The absolute requirement for primers in the initiation of DNA synthesis poses a problem for replicating the ends of linear chromosomes. The DNA polymerase of bacteriophage phi29 solves this problem by using a serine hydroxyl of terminal protein to prime replication. The 3.0 A resolution structure shows one domain of terminal protein making no interactions, a second binding the polymerase and a third domain containing the priming serine occupying the same binding cleft in the polymerase as duplex DNA does during elongation. Thus, the progressively elongating DNA duplex product must displace this priming domain. Further, this heterodimer of polymerase and terminal protein cannot accommodate upstream template DNA, thereby explaining its specificity for initiating DNA synthesis only at the ends of the bacteriophage genome. We propose a model for the transition from the initiation to the elongation phases in which the priming domain of terminal protein moves out of the active site as polymerase elongates the primer strand. The model indicates that terminal protein should dissociate from polymerase after the incorporation of approximately six nucleotides.

Involvement of the "linker" region between the exonuclease and polymerization domains of phi29 DNA polymerase in DNA and TP binding

For several DNA-dependent DNA polymerases it has been shown that their synthetic and degradative activities are organized in two separated modules. The functional coordination required between them to accomplish successfully the replication process is provided by important contacts with the substrate contributed by residues coming from both modules. These domains are connected by a central "linker" region adjacent to the "YxGG/A" motif, the putative limit of the polymerization domain. We describe here the mutational analysis of phi29 DNA polymerase in several residues of this region, connecting the N- and C-terminal domains and conserved in DNA polymerases able to start replication by protein-priming. The mutant polymerases with the less conservative changes showed reduced DNA binding activity. Additionally, their TP binding capacity was reduced, affecting the TP-deoxynucleotidylation in the absence of template. Interestingly, the role of the residues studied here in DNA binding seems to be especially important to start replication, when the polymerase enters from the closed binary into the ternary complex. These results allow us to propose that this interdomain region of phi29 DNA polymerase is playing an important role for substrate binding including both DNA and TP.

A specific subdomain in phi29 DNA polymerase confers both processivity and strand-displacement capacity

Recent crystallographic studies of phi29 DNA polymerase have provided structural insights into its strand displacement and processivity. A specific insertion named terminal protein region 2 (TPR2), present only in protein-primed DNA polymerases, together with the exonuclease, thumb, and palm subdomains, forms two tori capable of interacting with DNA. To analyze the functional role of this insertion, we constructed a phi29 DNA polymerase deletion mutant lacking TPR2 amino acid residues Asp-398 to Glu-420. Biochemical analysis of the mutant DNA polymerase indicates that its DNA-binding capacity is diminished, drastically decreasing its processivity. In addition, removal of the TPR2 insertion abolishes the intrinsic capacity of phi29 DNA polymerase to perform strand displacement coupled to DNA synthesis. Therefore, the biochemical results described here directly demonstrate that TPR2 plays a critical role in strand displacement and processivity.

Insights into Strand Displacement and Processivity from the Crystal Structure of the Protein-Primed DNA Polymerase of Bacteriophage φ29

The DNA polymerase from phage phi29 is a B family polymerase that initiates replication using a protein as a primer, attaching the first nucleotide of the phage genome to the hydroxyl of a specific serine of the priming protein. The crystal structure of phi29 DNA polymerase determined at 2.2 A resolution provides explanations for its extraordinary processivity and strand displacement activities. Homology modeling suggests that downstream template DNA passes through a tunnel prior to entering the polymerase active site. This tunnel is too small to accommodate double-stranded DNA and requires the separation of template and nontemplate strands. Members of the B family of DNA polymerases that use protein primers contain two sequence insertions: one forms a domain not previously observed in polymerases, while the second resembles the specificity loop of T7 RNA polymerase. The high processivity of phi29 DNA polymerase may be explained by its topological encirclement of both the downstream template and the upstream duplex DNA.

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.