Structural and functional organization of the DNA polymerase of bacteriophage T7

Two modes of interaction of the single-stranded DNA-binding protein of bacteriophage T7 with the DNA polymerase-thioredoxin complex

The DNA polymerase encoded by bacteriophage T7 has low processivity. Escherichia coli thioredoxin binds to a segment of 76 residues in the thumb subdomain of the polymerase and increases the processivity. The binding of thioredoxin leads to the formation of two basic loops, loops A and B, located within the thioredoxin-binding domain (TBD). Both loops interact with the acidic C terminus of the T7 helicase. A relatively weak electrostatic mode involves the C-terminal tail of the helicase and the TBD, whereas a high affinity interaction that does not involve the C-terminal tail occurs when the polymerase is in a polymerization mode. T7 gene 2.5 single-stranded DNA-binding protein (gp2.5) also has an acidic C-terminal tail. gp2.5 also has two modes of interaction with the polymerase, but both involve the C-terminal tail of gp2.5. An electrostatic interaction requires the basic residues in loops A and B, and gp2.5 binds to both loops with similar affinity as measured by surface plasmon resonance. When the polymerase is in a polymerization mode, the C terminus of gene 2.5 protein interacts with the polymerase in regions outside the TBD. gp2.5 increases the processivity of the polymerase-helicase complex during leading strand synthesis. When loop B of the TBD is altered, abortive DNA products are observed during leading strand synthesis. Loop B appears to play an important role in communication with the helicase and gp2.5, whereas loop A plays a stabilizing role in these interactions.

Motors, switches, and contacts in the replisome

Replisomes are the protein assemblies that replicate DNA. They function as molecular motors to catalyze template-mediated polymerization of nucleotides, unwinding of DNA, the synthesis of RNA primers, and the assembly of proteins on DNA. The replisome of bacteriophage T7 contains a minimum of proteins, thus facilitating its study. This review describes the molecular motors and coordination of their activities, with emphasis on the T7 replisome. Nucleotide selection, movement of the polymerase, binding of the processivity factor, unwinding of DNA, and RNA primer synthesis all require conformational changes and protein contacts. Lagging-strand synthesis is mediated via a replication loop whose formation and resolution is dictated by switches to yield Okazaki fragments of discrete size. Both strands are synthesized at identical rates, controlled by a molecular brake that halts leading-strand synthesis during primer synthesis. The helicase serves as a reservoir for polymerases that can initiate DNA synthesis at the replication fork. We comment on the differences in other systems where applicable.

Mutation of Phe102 to Ser in the carboxyl terminal helix of Escherichia coli thioredoxin affects the stability and processivity of T7 DNA polymerase

Processivity of T7 DNA polymerase relies on the coupling of its cofactor Escherichia coli thioredoxin (Trx) to gene 5 protein (gp5) at 1:1 stoichiometry. We designed a coexpression system for gp5 and Trx that allows in vivo reconstitution of subunits into a functional enzyme. The properties of this enzyme were compared with the activity of commercial T7 DNA polymerase. Examination of purified enzymes by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that the thioredoxin subunit of the two enzymes did not comigrate. To our surprise, we identified a mutation (Phe102 to Ser) in the Trx component from the commercial T7 DNA polymerase (gp5/TrxS102) that was not in the enzyme from the coexpression system (wild type gp5/Trx). A comparison of polymerase activity of the T7 DNA polymerases shows that both enzymes possessed similar specific activity but they were different in their residual activity at 37 degrees C. The half-life of gp5/TrxS102 was 7 min at 37 degrees C and 12 min for gp5/Trx. gp5/TrxS102 polymerase activity was reduced by fourfold with 3'-5' exonuclease activity as the prominent activity detected after 10 min of heat inactivation at 37 degrees C. Supplementation of reaction mixtures containing gp5/TrxS102 with exogenous nonmutant thioredoxin restored the enzyme activity levels. Pulse proteolysis was used to demonstrate that TrxS102 unfolded at lower urea concentrations than wild type thioredoxin. Thus, Ser substitution at position 102 affected the structural stability of thioredoxin resulting in a reduced binding affinity for gp5 and loss of processivity.

Coexpression of the subunits of T7 DNA polymerase from an artificial operon allows one-step purification of active gp5/Trx complex

T7 DNA polymerase expression was performed from an artificial operon by cloning its cofactor, thioredoxin, downstream of a N-terminal 9xHis-tagged T7 gene 5 (gp5). Up to 90% of gp5 was soluble in the presence, but not in the absence of thioredoxin coexpression suggesting that free-form thioredoxin assisted solubilization of gp5. Expression and single-step nickel-agarose affinity purification resulted in recovery of an enzyme that was 97% pure. Copurification of thioredoxin was observed and the estimated molar ratio of thioredoxin to gp5 was 1:1 in the purified DNA polymerase complex. Purified T7 DNA polymerase exhibited full polymerase activity compared to the commercial enzyme and required no exogenous thioredoxin for activity.

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.

The absence of molybdenum cofactor sulfuration is the primary cause of the flacca phenotype in tomato plants

The molybdenum cofactor (MoCo)-containing enzymes aldehyde oxidase (AO; EC 1.2.3.1) and xanthine dehydrogenase (XDH; EC 1.2.1.37) require for activity a sulfuration step that inserts a terminal sulfur ligand into the MoCo. The tomato flacca mutation was originally isolated as a wilty phenotype due to a lack of abscisic acid (ABA) that is related to simultaneous loss of AO and XDH activities. An expressed sequence tag candidate from tomato was selected on the basis of homology to sulfurases from animals, fungi and the recently isolated Arabidopsis genes LOS5/ABA3. The tomato homologue maps as a single gene to the bottom of chromosome 7, consistent with the genetic location of the flacca mutation. The structure of FLACCA shows a multidomain protein with an N-terminal NifS-like sulfurase domain; a mammal-specific intermediate section; and a C-terminus containing conserved motifs. Prominent among these are molybdopterin oxidoreductases and thioredoxin redox-active centre/iron-sulfur-binding region signatures which may be relevant to the specific sulfuration of MoCo. Indeed, the molecular analysis of flacca identifies the mutation in a highly conserved motif located in the C-terminus. Activity gel assays show that FLACCA is expressed throughout the plant. Transient and stable complementation of flacca and the Arabidopsis aba3 mutants with Aspergillus nidulans hxB and FLACCA yielded full, partial and tissue-specific types of Mo-hydroxylase activities. Restoration of activity in the root alone is sufficient to augment plant ABA content and rectify the wild-type phenotype. Thus the pleiotropic flacca phenotype is due to the loss of activity of enzymes requiring a sulfurated MoCo.

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.

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.

The acidic carboxyl terminus of the bacteriophage T7 gene 4 helicase/primase interacts with T7 DNA polymerase

The gene 4 proteins of bacteriophage T7 provide both primase and helicase activities at the replication fork. Efficient DNA replication requires that the functions of the gene 4 protein be coordinated with the movement of the T7 DNA polymerase. We show that a carboxyl-terminal domain of the gene 4 protein is required for interaction with T7 DNA polymerase during leading strand DNA synthesis. The carboxyl terminus of the gene 4 protein is highly acidic: of the 17 carboxyl-terminal amino acids 7 are negatively charged. Deletion of the coding region for these 17 residues results in a gene 4 protein that cannot support the growth of T7 phage. The purified mutant gene 4 protein has wild-type levels of both helicase and primase activities; however, DNA synthesis catalyzed by T7 DNA polymerase on a duplex DNA substrate is stimulated by this mutant protein to only about 5% of the level of synthesis obtained with wild-type protein. The mutant gene 4 protein can form hexamers and bind single-stranded DNA, but as determined by native PAGE analysis, the protein cannot form a stable complex with the DNA polymerase. The mutant gene 4 protein can prime DNA synthesis normally, indicating that for lagging strand synthesis a different set of helicase/primase-DNA polymerase interactions are involved. These findings have implications for the mechanisms coupling leading and lagging strand DNA synthesis at the T7 replication fork.

Amino acid changes in a unique sequence of bacteriophage T7 DNA polymerase alter the processivity of nucleotide polymerization

T7 gene 5 DNA polymerase forms a complex with Escherichia coli thioredoxin (its processivity factor), and a 76-amino acid sequence (residues 258-334), unique to gene 5 protein, has been implicated in this interaction. We have examined the effect of amino acid substitution(s) in this region on T7 phage growth and on the interaction of the polymerase with thioredoxin. Among the mutations in gene 5, we found that a substitution of either Glu or Ala for Lys-302 yielded a protein that could not complement T7 phage lacking gene 5 (T7Delta5) to grow on E. coli having reduced thioredoxin levels. One triple mutant (K300E,K302E,K304E) could not support the growth of T7Delta5 even in wild type cells. This altered polymerase is stimulated 4-fold less by thioredoxin than is the wild type enzyme and the polymerase-thioredoxin complex has reduced processivity. The exonuclease activity of the altered polymerase is not stimulated to the same extent as that of the wild type enzyme by thioredoxin. The observed dissociation constant of the gene 5 protein K(300,302,304)E-thioredoxin complex is 7-fold higher than that of the wild type complex. The altered polymerase also has a lower binding affinity for double-stranded DNA.

The thioredoxin binding domain of bacteriophage T7 DNA polymerase confers processivity on Escherichia coli DNA polymerase I

Bacteriophage T7 DNA polymerase shares extensive sequence homology with Escherichia coli DNA polymerase I. However, in vivo, E. coli DNA polymerase I is involved primarily in the repair of DNA whereas T7 DNA polymerase is responsible for the replication of the viral genome. In accord with these roles, T7 DNA polymerase is highly processive while E. coli DNA polymerase I has low processivity. The high processivity of T7 DNA polymerase is achieved through tight binding to its processivity factor, E. coli thioredoxin. We have identified a unique 76-residue domain in T7 DNA polymerase responsible for this interaction. Insertion of this domain into the homologous site in E. coli DNA polymerase I results in a dramatic increase in the processivity of the chimeric DNA polymerase, a phenomenon that is dependent upon its binding to thioredoxin.