A rapid and efficient one-tube PCR-based mutagenesis technique using Pfu DNA polymerase.

A rapid method for efficiently generating site-directed mutations on a clean sequence background is described. This modification of the megaprimer PCR mutagenesis approach can be performed in one tube in less than 4.5 hours, and does not require purification of intermediate products. High fidelity of DNA sequence replication is obtained by employing Pfu DNA polymerase and limiting the total number of amplification cycles to 30. The mutagenesis efficiency of the procedure is high enough to allow rapid, direct identification of mutants by restriction digest or sequencing techniques.     

Optimal conditions to use Pfu exo– DNA polymerase for highly efficient ligation-mediated polymerase chain reaction protocols

Ligation-Mediated Polymerase Chain Reaction (LMPCR) is the most sensitive sequencing technique available to map single-stranded DNA breaks at the nucleotide level of resolution using genomic DNA. LMPCR has been adapted to map DNA damage and reveal DNA–protein interactions inside living cells. However, the sequence context (GC content), the global break frequency and the current combination of DNA polymerases used in LMPCR affect the quality of the results. In this study, we developed and optimized an LMPCR protocol adapted for Pyrococcus furiosus exo^– DNA polymerase (Pfu exo^–). The relative efficiency of Pfu exo^– was compared to T7-modified DNA polymerase (Sequenase 2.0) at the primer extension step and to Thermus aquaticus DNA polymerase (Taq) at the PCR amplification step of LMPCR. At all break frequencies tested, Pfu exo^– proved to be more efficient than Sequenase 2.0. During both primer extension and PCR amplification steps, the ratio of DNA molecules per unit of DNA polymerase was the main determinant of the efficiency of Pfu exo^–, while the efficiency of Taq was less affected by this ratio. Substitution of NaCl for KCl in the PCR reaction buffer of Taq strikingly improved the efficiency of the DNA polymerase. Pfu exo^– was clearly more efficient than Taq to specifically amplify extremely GC-rich genomic DNA sequences. Our results show that a combination of Pfu exo^– at the primer extension step and Taq at the PCR amplification step is ideal for in vivo DNA analysis and DNA damage mapping using LMPCR.     

Optimal conditions to use Pfu exo(-) DNA polymerase for highly efficient ligation-mediated polymerase chain reaction protocols

Ligation-Mediated Polymerase Chain Reaction (LMPCR) is the most sensitive sequencing technique available to map single-stranded DNA breaks at the nucleotide level of resolution using genomic DNA. LMPCR has been adapted to map DNA damage and reveal DNA-protein interactions inside living cells. However, the sequence context (GC content), the global break frequency and the current combination of DNA polymerases used in LMPCR affect the quality of the results. In this study, we developed and optimized an LMPCR protocol adapted for Pyrococcus furiosus exo(-) DNA polymerase (Pfu exo(-)). The relative efficiency of Pfu exo(-) was compared to T7-modified DNA polymerase (Sequenase 2.0) at the primer extension step and to Thermus aquaticus DNA polymerase (Taq) at the PCR amplification step of LMPCR. At all break frequencies tested, Pfu exo(-) proved to be more efficient than Sequenase 2.0. During both primer extension and PCR amplification steps, the ratio of DNA molecules per unit of DNA polymerase was the main determinant of the efficiency of Pfu exo(-), while the efficiency of Taq was less affected by this ratio. Substitution of NaCl for KCl in the PCR reaction buffer of Taq strikingly improved the efficiency of the DNA polymerase. Pfu exo(-) was clearly more efficient than Taq to specifically amplify extremely GC-rich genomic DNA sequences. Our results show that a combination of Pfu exo(-) at the primer extension step and Taq at the PCR amplification step is ideal for in vivo DNA analysis and DNA damage mapping using LMPCR.     

Crystal structure of Pfu, the high fidelity DNA polymerase from Pyrococcus furiosus

We have determined a 2.6 Å resolution crystal structure of Pfu DNA polymerase, the most commonly used high fidelity PCR enzyme, from Pyrococcus furiosus. Although the structures of Pfu and KOD1 are highly similar, the structure of Pfu elucidates the electron density of the interface between the exonuclease and thumb domains, which has not been previously observed in the KOD1 structure. The interaction of these two domains is known to coordinate the proofreading and polymerization activity of DNA polymerases, especially via H147 that is present within the loop (residues 144–158) of the exonuclease domain. In our structure of Pfu, however, E148 rather than H147 is located at better position to interact with the thumb domain. In addition, the structural analysis of Pfu and KOD1 shows that both the Y-GG/A and β-hairpin motifs of Pfu are found to differ with that of KOD1, and may explain differences in processivity. This information enables us to better understand the mechanisms of polymerization and proofreading of DNA polymerases.     

Engineered split in Pfu DNA polymerase fingers domain improves incorporation of nucleotide gamma-phosphate derivative

Using compartmentalized self-replication (CSR), we evolved a version of Pyrococcus furiosus (Pfu) DNA polymerase that tolerates modification of the γ-phosphate of an incoming nucleotide. A Q484R mutation in α-helix P of the fingers domain, coupled with an unintended translational termination-reinitiation (split) near the finger tip, dramatically improve incorporation of a bulky γ-phosphate-O-linker-dabcyl substituent. Whether synthesized by coupled translation from a bicistronic (-1 frameshift) clone, or reconstituted from separately expressed and purified fragments, split Pfu mutant behaves identically to wild-type DNA polymerase with respect to chromatographic behavior, steady-state kinetic parameters (for dCTP), and PCR performance. Although naturally-occurring splits have been identified previously in the finger tip region of T4 gp43 variants, this is the first time a split (in combination with a point mutation) has been shown to broaden substrate utilization. Moreover, this latest example of a split hyperthermophilic archaeal DNA polymerase further illustrates the modular nature of the Family B DNA polymerase structure.     

一种简单高效的5'-突出末端平端化方法

目的:报道一种利用Pfu DNA聚合酶延伸法补平限制片段5’-突出末端的平端化方法。方法:Pfu DNA聚合酶是用于PCR扩增的常规高保真DNA聚合酶,可在DNA模板和dNTPs存在条件下,沿5’→3’方向催化寡聚核苷酸聚合。由于终产物为平末端,可利用这一特点进行限制片段5’-突出末端补平。本文采用这一方法消除pAN7-1潮霉素抗性标记末端的XbaⅠ位点,以便载体构建中能够利用这一常见位点。pAN7-1先用XbaⅠ酶切成线性化载体,产生的5’-突出末端再用Pfu DNA聚合酶延伸法补平,通过平端化载体自连后XbaⅠ位点的消除来评价Pfu DNA聚合酶的平端化效果。结果:随机挑取3个重组子提取质粒均不能再用XbaⅠ切开,表明XbaⅠ位点成功消除。结论:Pfu DNA聚合酶具有高效率及高保真特性,因此本法简单高效而且经济适用。     

Mutability of DNA polymerase I: implications for the creation of mutant DNA polymerases

DNA polymerases of the Family A catalyze the addition of deoxynucleotides to a primer with high efficiency, processivity, and selectivity-properties that are critical to their function both in nature and in the laboratory. These polymerases tolerate many amino acid substitutions, even in regions that are evolutionarily conserved. This tolerance can be exploited to create DNA polymerases with novel properties and altered substrate specificities, using rational design and molecular evolution. These efforts have focused mainly on the Family A DNA polymerises -Taq, E. coli Pol I, and T7 - because they are widely utilized in biotechnology today. The redesign of polymerases often requires knowledge of the function of specific residues in the protein, including those located in six evolutionarily conserved regions. The most well characterized of these are motifs A and B, which regulate the fidelity of replication and the incorporation of nucleotide analogs such as dideoxynucleotides. Regions that remain to be more thoroughly characterized are motif C, which is critical for catalysis, and motifs 1, 2 and 6, all of which bind to DNA primer or template. Several recently identified mutants with abilities to incorporate nucleotides with bulky adducts have mutations that are not located within conserved regions and warrant further study. Analysis of these mutants will help advance our understanding of how DNA polymerases select bases with high fidelity.     

A mutant of DNA polymerase I (Klenow fragment) with reduced fidelity

The kinetic parameters governing incorporation of correct and incorrect bases into synthetic DNA duplexes have been investigated for Escherichia coli DNA polymerase I [Klenow fragment (KF)] and for two mutants, Tyr766Ser and Tyr766Phe. Tyr766 is located at the C-terminus of helix O in the DNA-binding cleft of KF. The catalytic efficiency for correct incorporation of dNTP is reduced 5-fold for Tyr766Ser. The catalytic efficiencies of all 12 possible misincorporations have been determined for both KF and Tyr766Ser by using single-turnover kinetic conditions and a form of the enzyme that is devoid of the 3'-5' exonuclease activity because of other single amino acid replacements. Tyr766Ser displays an increased efficiency of misincorporation (a reduction in fidelity) for several of the 12 mismatches. The largest increase in efficiency of misincorporation for Tyr766Ser occurs for the misincorporation of TMP opposite template guanosine, a 44-fold increase. In contrast, the efficiencies of misincorporation of dAMP opposite template A, G, or C are little affected by the mutation. A determination of the kinetic parameters associated with a complete kinetic scheme has been made for Tyr766Ser. The rate of addition of the next correct nucleotide onto a preexisting mismatch is decreased for Tyr766Ser. The fidelity of Tyr766Phe was not substantially different from that of KF for the misincorporations examined, indicating that it is the loss of the phenolic ring of the side chain of Tyr766 that leads to the significant decrease in fidelity. The results indicate that KF actively participates in the reduction of misincorporations during the polymerization event and that Tyr766 plays an important role in maintaining the high fidelity of replication by KF.     

A mammalian DNA- mutant decreasing nuclear DNA polymerase alpha activity at nonpermissive temperature.

A temperature-sensitive Dna^? mutant (ts T244) of the mouse FM3A cell line was characterized. ts T244 showed no increase in cell number and rapid decrease in the rate of DNA synthesis after temperature upshift (33°C→39°C). The activity of nuclear DNA polymerase α decreased as rapidly as the rate of DNA synthesis, whereas the activities of thymidine kinase and thymidylate kinase decreased more slowly. The results suggest that the level of nuclear DNA polymerase α has close relation to the ts defect of this Dna^? mutant.     

A DNA polymerase beta mutator mutant with reduced nucleotide discrimination and increased protein stability

DNA polymerase beta (pol beta) offers a simple system to examine the role of polymerase structure in the fidelity of DNA synthesis. In this study, the M282L variant of pol beta (M282Lbeta) was identified using an in vivo genetic screen. Met282, which does not contact the DNA template or the incoming deoxynucleoside triphosphate (dNTP) substrate, is located on alpha-helix N of pol beta. This mutant enzyme demonstrates increased mutagenesis in both in vivo and in vitro assays. M282Lbeta has a 7.5-fold higher mutation frequency than wild-type pol beta; M282Lbeta commits a variety of base substitution and frameshift errors. Transient-state kinetic methods were used to investigate the mechanism of intrinsic mutator activity of M282Lbeta. Results show an 11-fold decrease in dNTP substrate discrimination at the level of ground-state binding. However, during the protein conformational change and/or phosphodiester bond formation, the nucleotide discrimination is improved. X-ray crystallography was utilized to gain insights into the structural basis of the decreased DNA synthesis fidelity. Most of the structural changes are localized to site 282 and the surrounding region in the C-terminal part of the 31-kDa domain. Repositioning of mostly hydrophobic amino acid residues in the core of the C-terminal portion generates a protein with enhanced stability. The combination of structural and equilibrium unfolding data suggests that the mechanism of nucleotide discrimination is possibly affected by the compacting of the hydrophobic core around residue Leu282. Subsequent movement of an adjacent surface residue, Arg283, produces a slight increase in volume of the pocket that may accommodate the incoming correct base pair. The structural changes of M282Lbeta ultimately lead to an overall reduction in polymerase fidelity.     

A nuclear mutant of Saccharomyces cerevisiae deficient in mitochondrial DNA replication and polymerase activity

We have isolated a thermosensitive mutant which is transformed into a population of cells devoid of mitochondrial DNA (rho 0 cells) at 35 degrees C and is deficient in mitochondrial (mt) DNA polymerase activity. A single recessive nuclear mutation (mip1) is responsible for rho 0 phenotype and mtDNA polymerase deficiency in vitro. At 25 degrees C (or 30 degrees C) a dominant suppressor mutation (SUP) masks the deficiency in vivo. The meiotic segregants (mip1 sup) which do not harbor the suppressor have a rho 0 phenotype both at 25 and 35 degrees C. They have no mtDNA polymerase activity, in contrast with MIP rho 0 mutants of mitochondrial inheritance which do exhibit mtDNA polymerase activity. In the thermosensitive mutant (mip1 SUP), the replication of mtDNA observed in vivo at 30 degrees C is completely abolished at 35 degrees C. In the meiotic segregants (mip1 sup), no mtDNA replication takes place at 30 and 35 degrees C. The synthesis of nuclear DNA is not affected. DNA polymerases may have replicative and/or repair activity. There is no evidence that mip mutants are deficient in mtDNA repair. In contrast the MIP gene product is strictly required for the replication of mtDNA and for the expression of the mtDNA polymerase activity. This enzyme might be the replicase of mtDNA.     

A new paradigm for DNA polymerase specificity

We show that T7 DNA polymerase exists in three distinct structural states, as reported by a conformationally sensitive fluorophore attached to the recognition (fingers) domain. The conformational change induced by a correct nucleotide commits the substrate to the forward reaction, and the slow reversal of the conformational change eliminates the rate of the chemistry step from any contribution toward enzyme specificity. Discrimination against mismatches is enhanced by the rapid release of mismatched nucleotides from the ternary E.DNA.deoxynucleoside triphosphate complex and by the use of substrate-binding energy to actively misalign catalytic residues to reduce the rate of misincorporation. Our refined model for enzyme selectivity extends traditional thermodynamic formalism by including substrate-induced structural alignment or misalignment of catalytic residues as a third dimension on the free-energy profile and by including the rate of substrate dissociation as a key kinetic parameter.     

Insights into the high fidelity of a DNA polymerase I mutant

Mutants of DNA polymerase I from Thermus aquaticus (Taq) with higher fidelity compared to the wild type enzyme were identified in an earlier study by Summerer et al. (Angew Chem Int Ed 44:4712–4715, 2005). Here, one of these mutants, PLQ (consensus residues 879–881), was analysed using molecular dynamics simulations. This was done by calculating the structures of the ternary complex comprising the enzyme, the DNA primer and template as well as the incoming nucleotide before the chemical reaction for the Watson-Crick and different mismatched base pairings. The results show that the high fidelity of the mutant can be explained partly by different specific interactions between the amino acids of the enzyme and the DNA primer end as well as, in some mismatches, a displacement of the primer relative to the incoming deoxyribonucleoside triphosphate and the catalytic magnesium ion. This displacement is facilitated by reduced steric interactions between the enzyme and the DNA. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Reading DNA at single-nucleotide resolution with a mutant MspA nanopore and phi29 DNA polymerase

Nanopore technologies are being developed for fast and direct sequencing of single DNA molecules through detection of ionic current modulations as DNA passes through a pore's constriction. Here we demonstrate the ability to resolve changes in current that correspond to a known DNA sequence by combining the high sensitivity of a mutated form of the protein pore Mycobacterium smegmatis porin A (MspA) with phi29 DNA polymerase (DNAP), which controls the rate of DNA translocation through the pore. As phi29 DNAP synthesizes DNA and functions like a motor to pull a single-stranded template through MspA, we observe well-resolved and reproducible ionic current levels with median durations of ～28 ms and ionic current differences of up to 40 pA. Using six different DNA sequences with readable regions 42-53 nucleotides long, we record current traces that map to the known DNA sequences. With single-nucleotide resolution and DNA translocation control, this system integrates solutions to two long-standing hurdles to nanopore sequencing.