Role of the C-terminal residue of the DNA polymerase of bacteriophage T7

Plasmid hypermutation using a targeted artificial DNA replisome

Extensive exploration of a protein's sequence space for improved or new molecular functions requires in vivo evolution with large populations. But disentangling the evolution of a target protein from the rest of the proteome is challenging. Here, we designed a protein complex of a targeted artificial DNA replisome (TADR) that operates in live cells to processively replicate one strand of a plasmid with errors. It enhanced mutation rates of the target plasmid up to 2.3 × 10⁵-fold with only a 78-fold increase in off-target mutagenesis. It was used to evolve itself to increase error rate and increase the efficiency of an efflux pump while simultaneously expanding the substrate repertoire. TADR enables multiple simultaneous substitutions to discover functions inaccessible by accumulating single substitutions, affording potential for solving hard problems in molecular evolution and developing biologic drugs and industrial catalysts.

Construction of a highly error-prone DNA polymerase for developing organelle mutation systems

A novel family of DNA polymerases replicates organelle genomes in a wide distribution of taxa encompassing plants and protozoans. Making error-prone mutator versions of gamma DNA polymerases revolutionised our understanding of animal mitochondrial genomes but similar advances have not been made for the organelle DNA polymerases present in plant mitochondria and chloroplasts. We tested the fidelities of error prone tobacco organelle DNA polymerases using a novel positive selection method involving replication of the phage lambda cI repressor gene. Unlike gamma DNA polymerases, ablation of 3'-5' exonuclease function resulted in a modest 5-8-fold error rate increase. Combining exonuclease deficiency with a polymerisation domain substitution raised the organelle DNA polymerase error rate by 140-fold relative to the wild type enzyme. This high error rate compares favourably with error-rates of mutator versions of animal gamma DNA polymerases. The error prone organelle DNA polymerase introduced mutations at multiple locations ranging from two to seven sites in half of the mutant cI genes studied. Single base substitutions predominated including frequent A:A (template: dNMP) mispairings. High error rate and semi-dominance to the wild type enzyme in vitro make the error prone organelle DNA polymerase suitable for elevating mutation rates in chloroplasts and mitochondria.

Catalytically inactive T7 DNA polymerase imposes a lethal replication roadblock

Bacteriophage T7 encodes its own DNA polymerase, the product of gene 5 (gp5). In isolation, gp5 is a DNA polymerase of low processivity. However, gp5 becomes highly processive upon formation of a complex with Escherichia coli thioredoxin, the product of the trxA gene. Expression of a gp5 variant in which aspartate residues in the metal-binding site of the polymerase domain were replaced by alanine is highly toxic to E. coli cells. This toxicity depends on the presence of a functional E. coli trxA allele and T7 RNA polymerase-driven expression but is independent of the exonuclease activity of gp5. In vitro, the purified gp5 variant is devoid of any detectable polymerase activity and inhibited DNA synthesis by the replisomes of E. coli and T7 in the presence of thioredoxin by forming a stable complex with DNA that prevents replication. On the other hand, the highly homologous Klenow fragment of DNA polymerase I containing an engineered gp5 thioredoxin-binding domain did not exhibit toxicity. We conclude that gp5 alleles encoding inactive polymerases, in combination with thioredoxin, could be useful as a shutoff mechanism in the design of a bacterial cell-growth system.

Modeling of pathogenic variants of mitochondrial DNA polymerase: insight into the replication defects and implication for human disease

BACKGROUND

Mutations in human gene encoding the mitochondrial DNA polymerase γ (HsPolγ) are associated with a broad range of mitochondrial diseases. Here we studied the impact on DNA replication by disease variants clustered around residue HsPolγ-K1191, a residue that in several family-A DNA polymerases interacts with the 3' end of the primer.

METHODS

Specifically, we examined the effect of HsPolγ carrying pathogenic variants in residues D1184, I1185, C1188, K1191, D1196, and a stop codon at residue T1199, using as a model the yeast mitochondrial DNA polymerase protein, Mip1p.

RESULTS

The introduction of pathogenic variants C1188R (yV945R), and of a stop codon at residue T1199 (yT956X) abolished both polymerization and exonucleolysis in vitro. HsPolγ substitutions in residues D1184 (yD941), I1185 (yI942), K1191 (yK948) and D1196 (yD953) shifted the balance between polymerization and exonucleolysis in favor of exonucleolysis. HsPolγ pathogenic variants at residue K1191 (yK948) and D1184 (yD941) were capable of nucleotide incorporation albeit with reduced processivity. Structural analysis of mitochondrial DNAPs showed that residue HsPolγ-N864 is placed in an optimal distance to interact with the 3' end of the primer and the phosphate backbone previous to the 3' end. Amino acid changes in residue HsPolγ-N864 to Ala, Ser or Asp result in enzymes that did not decrease their polymerization activity on short templates but exhibited a substantial decrease for processive DNA synthesis.

CONCLUSION

Our data suggest that in mitochondrial DNA polymerases multiple amino acids are involved in the primer-stand stabilization.

It seems like only yesterday

I spent my childhood and adolescence in North and South Carolina, attended Duke University, and then entered Duke Medical School. One year in the laboratory of George Schwert in the biochemistry department kindled my interest in biochemistry. After one year of residency on the medical service of Duke Hospital, chaired by Eugene Stead, I joined the group of Arthur Kornberg at Stanford Medical School as a postdoctoral fellow. Two years later I accepted a faculty position at Harvard Medical School, where I remain today. During these 50 years, together with an outstanding group of students, postdoctoral fellows, and collaborators, I have pursued studies on DNA replication. I have experienced the excitement of discovering a number of important enzymes in DNA replication that, in turn, triggered an interest in the dynamics of a replisome. My associations with industry have been stimulating and fostered new friendships. I could not have chosen a better career.

Enthalpic switch-points and temperature dependencies of DNA binding and nucleotide incorporation by Pol I DNA polymerases

This study examines the relationship between the DNA binding thermodynamics and the enzymatic activity of the Klenow and Klentaq Pol I DNA polymerases from Escherichia coli and Thermus aquaticus. Both polymerases bind DNA with nanomolar affinity at temperatures down to at least 5°C, but have lower than 1% enzymatic activity at these lower temperatures. For both polymerases it is found that the temperature of onset of significant enzymatic activity corresponds with the temperature where the enthalpy of binding (ΔHbinding) crosses zero (TH) and becomes favorable (negative). This TH/activity upshift temperature is 15°C for Klenow and 30°C for Klentaq. The results indicate that a negative free energy of DNA binding alone is not sufficient to proceed to catalysis, but that the enthalpic versus entropic balance of binding may be a modulator of the temperature dependence of enzymatic function. Analysis of the temperature dependence of the catalytic activity of Klentaq polymerase using expanded Eyring theory yields thermodynamic patterns for ΔG(‡), ΔH(‡), and TΔS(‡) that are highly analogous to those commonly observed for direct DNA binding. Eyring analysis also finds a significant ΔCp(‡) of formation of the activated complex, which in turn indicates that the temperature of maximal activity, after which incorporation rate slows with increasing temperature, will correspond with the temperature where the activation enthalpy (ΔH(‡)) switches from positive to negative.

C-terminal phenylalanine of bacteriophage T7 single-stranded DNA-binding protein is essential for strand displacement synthesis by T7 DNA polymerase at a nick in DNA

Single-stranded DNA-binding protein (gp2.5), encoded by gene 2.5 of bacteriophage T7, plays an essential role in DNA replication. Not only does it remove impediments of secondary structure in the DNA, it also modulates the activities of the other replication proteins. The acidic C-terminal tail of gp2.5, bearing a C-terminal phenylalanine, physically and functionally interacts with the helicase and DNA polymerase. Deletion of the phenylalanine or substitution with a nonaromatic amino acid gives rise to a dominant lethal phenotype, and the altered gp2.5 has reduced affinity for T7 DNA polymerase. Suppressors of the dominant lethal phenotype have led to the identification of mutations in gene 5 that encodes the T7 DNA polymerase. The altered residues in the polymerase are solvent-exposed and lie in regions that are adjacent to the bound DNA. gp2.5 lacking the C-terminal phenylalanine has a lower affinity for gp5-thioredoxin relative to the wild-type gp2.5, and this affinity is partially restored by the suppressor mutations in DNA polymerase. gp2.5 enables T7 DNA polymerase to catalyze strand displacement DNA synthesis at a nick in DNA. The resulting 5'-single-stranded DNA tail provides a loading site for T7 DNA helicase. gp2.5 lacking the C-terminal phenylalanine does not support this event with wild-type DNA polymerase but does to a limited extent with T7 DNA polymerase harboring the suppressor mutations.

Structural Basis for the Bifunctionality of the U5 snRNP 52K Protein (CD2BP2)

The bifunctional protein U5-52K is associated with the spliceosomal 20 S U5 snRNP, and it also plays a role in immune response as CD2 receptor binding protein 2 (CD2BP2). U5-52K binds to the CD2 receptor via its GYF-domain specifically recognizing a proline-rich motif on the cytoplasmic surface of the receptor. The GYF-domain is also mediating the interaction of the proteins U5-52K and U5-15K within the spliceosomal U5 snRNP. Here we report the crystal structure of the complex of GYF-domain and U5-15K protein revealing the structural basis for the bifunctionality of the U5-52K protein. The complex structure unveils novel interaction sites on both proteins, as neither the polyproline-binding site of the GYF-domain nor the common ligand-binding cleft of thioredoxin-like proteins, to which U5-15K belongs, are involved in the interaction of U5-15K and U5-52K.

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.

Kinetics of nucleotide incorporation opposite DNA bulky guanine N2 adducts by processive bacteriophage T7 DNA polymerase (exonuclease-) and HIV-1 reverse transcriptase

Six oligonucleotides with carcinogen derivatives bound at the N2 atom of deoxyguanosine were prepared, including adducts derived from butadiene, acrolein, crotonaldehyde, and styrene, and examined for effects on the replicative enzymes bacteriophage DNA polymerase T7- (T7-) and HIV-1 reverse transcriptase for comparison with previous work on smaller DNA adducts. All of these adducts strongly blocked dCTP incorporation opposite the adducts. dATP was preferentially incorporated opposite the acrolein and crotonaldehyde adducts, and dTTP incorporation was preferred at the butadiene- and styrene-derived adducts. Steady-state kinetic analysis indicated that the reduced catalytic efficiency with adducted DNA involved both an increased Km and attenuated kcat. Fluorescence estimates of Kd and pre-steady-state kinetic measurements of koff showed no significantly decreased affinity of T7- with the adducted oligonucleotides or the dNTP. Pre-steady-state kinetics showed no burst phase kinetics for dNTP incorporation with any of the modified oligonucleotides. These results indicate that phosphodiester bond formation or a conformational change of the enzyme.DNA complex is rate-limiting instead of the step involving release of the oligonucleotide. Thio elemental effects for dNTP incorporation were generally relatively small but variable, indicating that the presence of adducts may sometimes make phosphodiester bond formation rate-limiting but not always.

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 unique region in bacteriophage t7 DNA polymerase important for exonucleolytic hydrolysis of DNA

A crystal structure of the bacteriophage T7 gene 5 protein/Escherichia coli thioredoxin complex reveals a region in the exonuclease domain (residues 144-157) that is not present in other members of the E. coli DNA polymerase I family. To examine the role of this region, a genetically altered enzyme that lacked residues 144-157 (T7 polymerase (pol) Delta144-157) was purified and characterized biochemically. The polymerase activity and processivity of T7 pol Delta144-157 on primed M13 DNA are similar to that of wild-type T7 DNA polymerase implying that these residues are not important for DNA synthesis. The ability of T7 pol Delta144-157 to catalyze the hydrolysis of a phosphodiester bond, as judged from the rate of hydrolysis of a p-nitrophenyl ester of thymidine monophosphate, also remains unaffected. However, the 3'-5' exonuclease activity on polynucleotide substrates is drastically reduced; exonuclease activity on single-stranded DNA is 10-fold lower and that on double-stranded DNA is 20-fold lower as compared with wild-type T7 DNA polymerase. Taken together, our results suggest that residues 144-157 of gene 5 protein, although not crucial for polymerase activity, are important for DNA binding during hydrolysis of polynucleotides.

The herpes simplex virus type 1 DNA polymerase processivity factor increases fidelity without altering pre-steady-state rate constants for polymerization or excision

Pre-steady-state and steady-state kinetics of nucleotide incorporation and excision were used to assess potential mechanisms by which the fidelity of the herpes simplex virus type 1 DNA polymerase catalytic subunit (Pol) is enhanced by its processivity factor, UL42. UL42 had no effect on the pre-steady-state rate constant for correct nucleotide incorporation (150 s(-1)) nor on the primary rate-limiting conformational step. However, the equilibrium dissociation constant for the enzyme in a stable complex with primer-template was 44 nm for Pol and 7.0 nm for Pol/UL42. The catalytic subunit and holoenzyme both selected against incorrect nucleotide incorporation predominantly at the level of nucleotide affinity, although UL42 slowed by 4-fold the maximum rate of incorporation of incorrect, compared with correct, nucleotide. Pol, with or without UL42, cleaved matched termini at a slower rate than mismatched ones, but UL42 did not significantly alter the pre-steady-state rate constant for mismatch excision ( approximately 16 s(-1)). The steady-state rate constant for nucleotide addition was 0.09 s(-1) and 0.03 s(-1) for Pol and Pol/UL42, respectively, and enzyme dissociation was the rate-limiting step. The longer half-life for DNA complexes with Pol/UL42 (23 s) compared with that with Pol (8 s) affords a greater probability for excision when a misincorporation event does occur, accounting predominantly for the failure of Pol/UL42 to accumulate mismatched product at moderate nucleotide concentrations.

Computer simulation studies of the fidelity of DNA polymerases

Computer simulations can provide in principle quantitative correlation between the structures of DNA polymerases and the replication fidelity. This paper describes our progress in this direction. Using several theoretical approaches, including the free energy perturbation (FEP), linear response approximation (LRA), and the empirical valence bond (EVB) methods, we examined the stability of several mismatched base pairs in DNA duplex in aqueous solution, the contribution of binding energy to the fidelity of DNA polymerases beta and T7, and the mechanism and energetics of the polymerization reaction catalyzed by T7 DNA polymerase.

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.