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.     

Interaction of mutant thioredoxins of Escherichia coli with the gene 5 protein of phage T7. The redox capacity of thioredoxin is not required for stimulation of DNA polymerase activity

DNA polymerase activity in Escherichia coli cells infected with bacteriophage T7 resides in a protein complex consisting of the T7 gene 5 protein and E. coli thioredoxin in a 1 to 1 stoichiometry. We have analyzed nine mutant thioredoxins, both in vivo and in vitro, for their ability to interact with the T7 gene 5 protein and stimulate the DNA polymerase and exonuclease activities inherent in gene 5 protein. The efficiency of plating of T7 on E. coli thioredoxin mutants depends strongly on the copy number of the respective mutant thioredoxin allele. Plating efficiencies at a constant copy number correlate well with the affinity of the purified mutant proteins for T7 gene 5 protein. The observed dissociation constant, Kobs, is increased between 5 and several hundredfold at 42 degrees C compared to wild-type thioredoxin. The maximum polymerase activity of the reconstituted gene 5 protein-thioredoxin complex at saturating concentrations of mutant thioredoxins, however, is reduced by less than 20%. Consequently, none of the mutant thioredoxins acts as a competitive inhibitor of wild-type thioredoxin. The active-site disulfide of thioredoxin is not essential for the activities of the gene 5 protein-thioredoxin complex. Both cysteines can be replaced without significantly affecting the maximum polymerase or exonuclease activities. Substitution or alkylation of either cysteine, however, reduces the affinity for gene 5 protein drastically, indicating that the active site is part of the thioredoxin surface involved in the protein-protein interaction.     

Deoxyribonucleic acid polymerase of bacteriophage T7. Characterization of the exonuclease activities of the gene 5 protein and the reconstituted polymerase.

Homogeneous gene 5 protein of bacteriophage T7, a subunit of T7 DNA polymerase, catalyzes the stepwise hydrolysis of single-stranded DNA in a 3' leads to 5' direction to yield nucleoside 5'-monophosphates. The gene 5 protein itself does not hydrolyze duplex DNA. However, in the presence of Escherichia coli thioredoxin, the host-specified subunit of T7 DNA polymerase, duplex DNA is hydrolyzed in a 3' leads to 5' direction to yield nucleoside 5'-monophosphates. The apparent Km for thioredoxin in the reaction is 4.8 x 10(-8) M, a value similar to that for the apparent Km of thioredoxin in the complementation assay with gene 5 protein to restore T7 DNA polymerase activity. Both exonuclease activities require Mg2+ and a sulfhydryl reagent for optimal activity, and both activities are sensitive to salt concentration. Deoxyribonucleoside 5'-triphosphates inhibit hydrolysis by both exonuclease activities; hydrolysis of single-stranded DNA by the gene 5 protein is inhibited even in the absence of thioredoxin where there is less than 2% active T7 DNA polymerase. E. coli DNA binding protein (helix destabilizing protein) stimulates the hydrolysis of duplex DNA up to 9-fold under conditions where the hydrolysis of the single-stranded DNA is inhibited 4-fold.     

Deoxyribonucleic acid polymerase of bacteriophage T7. Purification and properties of the phage-encoded subunit, the gene 5 protein.

DNA polymerase of bacteriophage T7 is composed of two subunits, the gene 5 protein of the phage and the host-specified thioredoxin. The gene 5 protein has been purified 7400-fold to homogeneity from bacteriophage T7-infected Escherichia coli 7400 trxA cells that lack thioredoxin. The purification procedure has been monitored by using a complementation assay in which thioredoxin interacts with the gene 5 protein to form an active DNA polymerase. The purified gene 5 protein is a single polypeptide having a molecular weight of 87,000. The gene 5 protein itself has only 1 to 2% of the polymerase activity of T7 DNA polymerase. However, T7 DNA polymerase can be reconstituted by the addition of homogeneous thioredoxin to the gene 5 protein. Optimal reconstitution is obtained when the molar ratio of thioredoxin/gene 5 protein is 150. Under these conditions, the gene 5 protein attains approximately 80% of the activity of an equal amount of T7 DNA polymerase. The apparent Km for thioredoxin in the reaction to restore DNA polymerase activity is 2.8 x 10(-8) M. The enzymatic properties of the reconstituted enzyme are indistinguishable from those of T7 DNA polymerase synthesized in vivo; the reconstituted polymerase interacts with T7 gene 4 protein to catalyze DNA synthesis on duplex DNA templates.     

The C-terminal residues of bacteriophage T7 gene 4 helicase-primase coordinate helicase and DNA polymerase activities

The gene 4 protein of bacteriophage T7 plays a central role in DNA replication by providing both helicase and primase activities. The C-terminal helicase domain is not only responsible for DNA-dependent dTTP hydrolysis, translocation, and DNA unwinding, but it also interacts with T7 DNA polymerase to coordinate helicase and polymerase activities. The C-terminal 17 residues of gene 4 protein are critical for its interaction with the T7 DNA polymerase/thioredoxin complex. This C terminus is highly acidic; replacement of these residues with uncharged residues leads to a loss of interaction with T7 DNA polymerase/thioredoxin and an increase in oligomerization of the gene 4 protein. Such an alteration on the C terminus results in a reduced efficiency in strand displacement DNA synthesis catalyzed by gene 4 protein and T7 DNA polymerase/thioredoxin. Replacement of the C-terminal amino acid, phenylalanine, with non-aromatic residues also leads to a loss of interaction of gene 4 protein with T7 DNA polymerase/thioredoxin. However, neither of these modifications of the C terminus affects helicase and primase activities. A chimeric gene 4 protein containing the acidic C terminus of the T7 gene 2.5 single-stranded DNA-binding protein is more active in strand displacement synthesis. Gene 4 hexamers containing even one subunit of a defective C terminus are defective in their interaction with T7 DNA polymerase.     

Interactions of gene 2.5 protein and DNA polymerase of bacteriophage T7.

Bacteriophage T7 gene 2.5 protein has been shown to interact with T7 DNA polymerase (the complex of T7 gene 5 protein and Escherichia coli thioredoxin) by affinity chromatography and fluorescence emission anisotropy. T7 DNA polymerase binds specifically to a resin coupled to gene 2.5 protein and elutes from the resin when the ionic strength of the buffer is raised to 250 mM NaCl. In contrast, T7 gene 5 protein alone binds more weakly to gene 2.5 protein, eluting when the ionic strength of the buffer is 50 mM NaCl. Thioredoxin does not bind to gene 2.5 protein. Steady-state fluorescence emission anisotropy gives a dissociation constant of 1.1 +/- 0.2 microM for the complex of gene 2.5 protein and T7 DNA polymerase, with a ratio of gene 2.5 protein to T7 DNA polymerase in the complex of 1:1. Nanosecond emission anisotropic analysis suggests that the complex contains one monomer each of gene 2.5 protein, gene 5 protein, and thioredoxin. The ability of T7 gene 2.5 protein to stimulate the activity and processivity of T7 DNA polymerase is compared with the ability of three other single-stranded DNA-binding proteins: E. coli single-stranded DNA-binding protein, T4 gene 32 protein, and E. coli recA protein. All except E. coli recA protein stimulate the activity and processivity of T7 DNA polymerase; E. coli recA protein inhibits these activities.     

Rapid isolation of homogeneous cloned T7 gene 5 protein and T7 DNA polymerase by affinity chromatography on immobilized thioredoxin.

Phage T7 DNA polymerase consists of a strong 1:1 complex of T7 gene 5 protein (80 kDa) and the reduced form of Escherichia coli thioredoxin (12 kDa). Immobilization of E. coli thioredoxin on the agarose matrix Affi-Gel retained both its redox activity and its ability to bind T7 gene 5 protein. This was used to develop a simple and fast high-yield purification method. Cloned T7 gene 5 protein, expressed in a thioredoxin-negative host cell, was isolated in pure and highly active form after elution from Affi-Gel--thioredoxin with a pH gradient from 10 to 12. This purification step separated gene 5 protein from variable amounts of two sets of reconstituting large polypeptide fragments without catalytic activity. Proteolytic cleavage in vivo probably gave rise to the fragments, the generation of which was mimicked by trypsin cleavage of pure gene 5 protein. The gene 5 protein preparation had an inherent low DNA polymerase and double-stranded 3'-exonuclease activity, which was stimulated at least 30-fold by the presence of reduced thioredoxin. Highly active and pure T7 DNA polymerase was obtained by reconstitution of gene 5 protein with thioredoxin and was isolated by phosphocellulose or FPLC Mono Q chromatography. The gene 5 protein and T7 DNA polymerase preparations are suitable for further physicochemical characterization and as reagents in DNA sequencing.     

T7-induced DNA polymerase. Characterization of associated exonuclease activities and resolution into biologically active subunits.

Bacteriophage T7-induced DNA polymerase has been isolated by a procedure suitable for large scale use and which yields near homogeneous enzyme. In addition to previously described DNA polymerase activity and 3' to 5' exonucleolytic activity on single stranded DNA (Grippo, P., and Richardson, C. C. (1971) J. Biol. Chem. 246, 6867-6873), the enzyme also possesses a highly active exonuclease which hydrolyzes duplex substrates with 3' to 5' directionality. The native polymerase has been dissociated using 6 M guanidine HCl and resolved into biologically active subunits: T7 gene 5 protein and Escherichia coli thioredoxin. The phage-specified subunit obtained by this procedure is deficient in DNA polymerase and double strand exonuclease activities, with deficiencies in these activities being apparent at the level of a single turnover. However, it possesses near normal levels of a single strand hydrolytic activity which is identical to that associated with the native polymerase with respect to substrate specificity and suppression of hydrolysis by low levels of deoxyribonucleoside 5'-triphosphates. Thioredoxin forms a molecular complex with the T7 gene 5 protein, and addition of the host protein restores restores DNA polymerase and double strand exonuclease activities to near normal levels.     

The highly processive DNA polymerase of bacteriophage T5. Role of the unique N and C termini

The DNA polymerase encoded by bacteriophage T5 has been reported previously to be processive and to catalyze extensive strand displacement synthesis. The enzyme, purified from phage-infected cells, did not require accessory proteins for these activities. Although T5 DNA polymerase shares extensive sequence homology with Escherichia coli DNA polymerase I and T7 DNA polymerase, it contains unique regions of 130 and 71 residues at its N and C termini, respectively. We cloned the gene encoding wild-type T5 DNA polymerase and characterized the overproduced protein. We also examined the effect of N- and C-terminal deletions on processivity and strand displacement synthesis. T5 DNA polymerase lacking its N-terminal 30 residues resembled the wild-type enzyme albeit with a 2-fold reduction in polymerase activity. Deletion of 24 residues at the C terminus resulted in a 30-fold reduction in polymerase activity on primed circular DNA, had dramatically reduced processivity, and was unable to carry out strand displacement synthesis. Deletion of 63 residues at the C terminus resulted in a 20,000-fold reduction in polymerase activity. The 3' to 5' double-stranded DNA exonuclease activity associated with T5 DNA polymerase was reduced by a factor of 5 in the polymerase truncated at the N terminus but was stimulated by a factor of 7 in the polymerase truncated at the C terminus. We propose a model in which the C terminus increases the affinity of the DNA for the polymerase active site, thus increasing processivity and decreasing the accessibility of the DNA to the exonuclease active site.     

A Mutation in the gene-encoding bacteriophage T7 DNA polymerase that renders the phage temperature-sensitive

Gene 5 of bacteriophage T7 encodes a DNA polymerase essential for phage replication. A single point mutation in gene 5 confers temperature sensitivity for phage growth. The mutation results in an alanine to valine substitution at residue 73 in the exonuclease domain. Upon infection of Escherichia coli by the temperature-sensitive phage at 42 degrees C, there is no detectable T7 DNA synthesis in vivo. DNA polymerase activity in these phage-infected cell extracts is undetectable at assay temperatures of 30 degrees C or 42 degrees C. Upon infection at 30 degrees C, both DNA synthesis in vivo and DNA polymerase activity in cell extracts assayed at 30 degrees C or 42 degrees C approach levels observed using wild-type T7 phage. The amount of soluble gene 5 protein produced at 42 degrees C is comparable to that produced at 30 degrees C, indicating that the temperature-sensitive phenotype is not due to reduced expression, stability, or solubility. Thus the polymerase induced at elevated temperatures by the temperature-sensitive phage is functionally inactive. Consistent with this observation, biochemical properties and heat inactivation profiles of the genetically altered enzyme over-produced at 30 degrees C closely resemble that of wild-type T7 DNA polymerase. It is likely that the polymerase produced at elevated temperatures is a misfolded intermediate in its folding pathway.     

Escherichia coli thioredoxin stabilizes complexes of bacteriophage T7 DNA polymerase and primed templates

The DNA polymerase activity induced after bacteriophage T7 infection of Escherichia coli is found in a complex of two proteins, the T7 gene 5 protein and a host protein, thioredoxin. Gene 5 protein is a DNA polymerase and a 3' to 5' exonuclease. Thioredoxin binds tightly to the gene 5 protein and increases the processivity of polymerization some 1000-fold. Gene 5 protein forms a short-lived complex with the primer-template, poly(dA).oligo(dT), in the absence of Mg2+ and nucleotides. Thioredoxin increases the half-life of the preformed primer-template-polymerase complex from less than a second to approximately 5 min. The dissociation is accelerated by excess single-stranded DNA in an apparent second order reaction, indicating direct transfer of polymerase between DNA fragments. Thioredoxin also reduces the equilibrium dissociation constant, Kd, of the gene 5 protein -poly(dA).oligo(dT) complex 20- to 80-fold. The salt dependence of Kd indicates that thioredoxin stabilizes the primer-template-polymerase complex mainly through additional charge-charge interactions, increasing the estimated number of interactions from 2 to 7. The affinity of gene 5 protein for single-stranded DNA is at least 1000-fold higher than for double-stranded DNA and is little affected by thioredoxin. Under conditions of steady state synthesis the effect of thioredoxin on the polymerization rate is determined by two competing factors, an increase in processivity and a decrease of the dissociation rate of polymerase and replicated template.     

Identification and characterization of thioredoxin and thioredoxin reductase from Aeropyrum pernix K1.

We have identified and characterized a thermostable thioredoxin system in the aerobic hyperthermophilic archaeon Aeropyrum pernix K1. The gene (Accession no. APE0641) of A. pernix encoding a 37 kDa protein contains a redox active site motif (CPHC) but its N-terminal extension region (about 200 residues) shows no homology within the genome database. A second gene (Accession no. APE1061) has high homology to thioredoxin reductase and encodes a 37 kDa protein with the active site motif (CSVC), and binding sites for FAD and NADPH. We cloned the two genes and expressed both proteins in E. coli. It was observed that the recombinant proteins could act as an NADPH-dependent protein disulfide reductase system in the insulin reduction. In addition, the APE0641 protein and thioredoxin reductase from E. coli could also catalyze the disulfide reduction. These indicated that APE1061 and APE0641 express thioredoxin (ApTrx) and thioredoxin reductase (ApTR) of A. pernix, respectively. ApTR is expressed as an active homodimeric flavoprotein in the E. coli system. The optimum temperature was above 90 degrees C, and the half-life of heat inactivation was about 4 min at 110 degrees C. The heat stability of ApTR was enhanced in the presence of excess FAD. ApTR could reduce both thioredoxins from A. pernix and E. coli and showed a similar molar specific activity for both proteins. The standard state redox potential of ApTrx was about -262 mV, which was slightly higher than that of Trx from E. coli (-270 mV). These results indicate that a lower redox potential of thioredoxin is not necessary for keeping catalytic disulfide bonds reduced and thereby coping with oxidative stress in an aerobic hyperthermophilic archaea. Furthermore, the thioredoxin system of aerobic hyperthermophilic archaea is biochemically close to that of the bacteria.     

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.     

Soluble expression of cloned phage K11 RNA polymerase gene in Escherichia coli at a low temperature.

The gene 1 of the Klebsiella phage K11 encoding the phage RNA polymerase was amplified using the polymerase chain reaction of the Pfu DNA polymerase, cloned and expressed under the control of tac promoter in Escherichia coli. Although the gene was efficiently expressed in E. coli BL21 cells at 37 degrees C, most of the K11 RNA polymerase produced was insoluble, in contrast to soluble expression of the cloned T7 RNA polymerase gene. Coexpression of the bacterial chaperone GroES and GroEL genes together did not help solubilize the K11 RNA polymerase. When the temperature of cell growth was lowered, however, solubility of the K11 RNA polymerase was increased substantially. It was found much more soluble when expressed at 25 degrees C than at 30 and 37 degrees C. Thus, the cloned K11 RNA polymerase gene was expressed in E. coli mostly to the soluble form at 25 degrees C. The protein was purified to homogeneity by chromatography using DEAE-Sephacel and Affigel-blue columns and was found to be active in vitro with the K11 genome or a K11 promoter. The purified K11 RNA polymerase showed highly stringent specificity for the K11 promoter. Low-level cross-reactivity was shown with the SP6 and T7 consensus promoters, while no activity shown with the T3 consensus promoter at all.     

A positive charge at position 33 of thioredoxin primarily affects its interaction with other proteins but not redox potential

Oxidoreductases of the thioredoxin superfamily possess the C-X-X-C motif. The redox potentials vary over a wide range for these proteins. A crucial determinant of the redox potential has been attributed to the variation of the X-X dipeptide. Here, we substitute Lys for Gly at the first X of Escherichia coli thioredoxin to investigate how a positive charge would affect the redox potential. The substitution does not affect the protein's redox potential. The equilibrium constant obtained from pairwise reaction between the mutant and wild-type proteins equals 1.1, indicating that the replacement does not significantly affect the thiol-disulfide redox equilibrium. However, the catalytic efficiency of thioredoxin reductase on the G33K mutant decreases approximately 2.8 times compared to that of the wild type. The mutation mainly affects K(m), with little effect on k(cat). The mutation also inhibits thioredoxin's ability to reduce insulin disulfide by approximately one-half. Whether the mutant protein supports the growth of phages T3/7 and f1 was tested. The efficiency of plating (EOP) of T3/7 on the mutant strain decreases 5 times at 37 degrees C and 3 x 10(4) times at 42 degrees C relative to that of the wild-type strain, suggesting that interaction between phage gene 5 protein and thioredoxin is hindered. The mutation also reduces the EOP of phage f1 by 8-fold at 37 degrees C and 1.5-fold at 42 degrees C. The global structure of the mutant protein does not change when studied by CD and fluorescence spectra. Therefore, G33K does not significantly affect the overall structure or redox potential of thioredoxin, but primarily interferes with its interaction with other proteins. Together with the G33D mutation, the overall results show that a charged residue at the first X has a greater influence on the molecular interaction of the protein than the redox potential.     

Replication of the mini-R1 plasmid Rsc11 and Rsc11 hybrid plasmids

Summary The DNA polymerase induced by bacteriophage T7 is composed of a phage-specified subunit, the gene 5 protein, and a host-specified subunit, the 12,000 dalton thioredoxin of Escherichia coli. tsnC mutants of E. coli B (Chamberlin, 1974) have no detectable thioredoxin, and thus cannot support the growth of phage T7, although they are killed by phage infection. A mutant of E. coli K12 affecting thioredoxin has been isolated by a modification of the procedure used by Chamberlin (1974) to isolate tsnC mutants of E. coli B. The gene affecting thioredoxin has been designated trxA. This mutant, E. coli JM109, shows the TsnC phenotype in that it is killed by, but cannot support the growth of, bacteriophage T7. T7 DNA replication does not occur in mutantinfected cells. These phenotypic expressions of the tsnC mutation have enabled us to screen recombinants for the trxA allele in HfrxF^- crosses and F-ductants in episome transfer experiments. Extracts of transductants in generalized transduction by P1 phage were screened for their ability to complement partially purified phage T7 gene 5 protein to form T7 DNA polymerase. The trxA gene is located at 84 min on the E. coli linkage map, between uvrE and metE; trxA is 34% co-transducible with metE.     

Thioredoxin and related proteins in procaryotes

Thioredoxin is a small (Mr 12,000) ubiquitous redox protein with the conserved active site structure: -Trp-Cys-Gly-Pro-Cys-. The oxidized form (Trx-S2) contains a disulfide bridge which is reduced by NADPH and thioredoxin reductase; the reduced form [Trx(SH)2] is a powerful protein disulfide oxidoreductase. Thioredoxins have been characterized in a wide variety of prokaryotic cells, and generally show about 50% amino acid homology to Escherichia coli thioredoxin with a known three-dimensional structure. In vitro Trx-(SH)2 serves as a hydrogen donor for ribonucleotide reductase, an essential enzyme in DNA synthesis, and for enzymes reducing sulfate or methionine sulfoxide. E. coli Trx-(SH)2 is essential for phage T7 DNA replication as a subunit of T7 DNA polymerase and also for assembly of the filamentous phages f1 and M13 perhaps through its localization at the cellular plasma membrane. Some photosynthetic organisms reduce Trx-S2 by light and ferredoxin; Trx-(SH)2 is used as a disulfide reductase to regulate the activity of enzymes by thiol redox control. Thioredoxin-negative mutants (trxA) of E. coli are viable making the precise cellular physiological functions of thioredoxin unknown. Another small E. coli protein, glutaredoxin, enables GSH to be hydrogen donor for ribonucleotide reductase or PAPS reductase. Further experiments with molecular genetic techniques are required to define the relative roles of the thioredoxin and glutaredoxin systems in intracellular redox reactions.