Abasic sites represent the most frequent DNA lesions in the genome that have high mutagenic potential and lead to mutations commonly found in human cancers. Although these lesions are devoid of the genetic information, adenine is most efficiently inserted when abasic sites are bypassed by DNA polymerases, a phenomenon termed A-rule. In this study, we present X-ray structures of a DNA polymerase caught while incorporating a nucleotide opposite an abasic site. We found that a functionally important tyrosine side chain directs for nucleotide incorporation rather than DNA. It fills the vacant space of the absent template nucleobase and thereby mimics a pyrimidine nucleobase directing for preferential purine incorporation opposite abasic residues because of enhanced geometric fit to the active site. This amino acid templating mechanism was corroborated by switching to pyrimidine specificity because of mutation of the templating tyrosine into tryptophan. The tyrosine is located in motif B and highly conserved throughout evolution from bacteria to humans indicating a general amino acid templating mechanism for bypass of non-instructive lesions by DNA polymerases at least from this sequence family.
The ability to detect DNA modification sites at single base resolution could significantly advance studies regarding DNA adduct levels, which are extremely difficult to determine. Artificial nucleotides that are specifically incorporated opposite a modified DNA site offer a potential strategy for detection of such sites by DNA polymerase-based systems. Here we investigate the action of newly synthesized base-modified benzimidazole-derived 2'-deoxynucleoside-5'-O-triphosphates on DNA polymerases when performing translesion DNA synthesis past the pro-mutagenic DNA adduct O(6)-benzylguanine (O(6)-BnG). We found that a mutated form of KlenTaq DNA polymerase, i.e., KTqM747K, catalyzed O(6)-BnG adduct-specific processing of the artificial BenziTP in favor of the natural dNTPs. Steady-state kinetic parameters revealed that KTqM747K catalysis of BenziTP is 25-fold more efficient for template O(6)-BnG than G, and 5-fold more efficient than natural dTMP misincorporation in adduct bypass. Furthermore, the nucleotide analogue BenziTP is required for full-length product formation in O(6)-BnG bypass, as without BenziTP the polymerase stalls at the adduct site. By combining the KTqM747K polymerase and BenziTP, a first round of DNA synthesis enabled subsequent amplification of Benzi-containing DNA. These results advance the development of technologies for detecting DNA adducts.
The high substrate specificity of DNA-dependent DNA polymerases is essential for the stability of the genome as well as many biotechnological applications. [1] The discrimination between ribo-and deoxyribonucleotides and between RNA and DNA, particularly in cells, is fundamental since the concentration of ribo moieties by far exceeds that of deoxyribo analogues. Although the selection mechanisms for the incorporation of nucleotides have been investigated intensively for DNA and RNA polymerases, [2] much less is known on how DNA-dependent DNA polymerases discriminate between the different nucleic acid templates (DNA versus RNA). Some viral DNA polymerases (e.g. reverse transcriptases) can utilize both DNA and RNA as a template for nucleic acid synthesis. Crystal-structure analysis of these enzymes, complexed either to an RNA or DNA template, have contributed significantly to our understanding of this process. [3] However, similar structural data of DNA-dependent DNA polymerases that have a poor propensity to process RNA templates are lacking, presumably because the crystallization is hampered by the formation of unstable complexes that leads to structural heterogeneity.Structure analysis of KlenTaq DNA polymerase, a shortened form of Thermus aquaticus DNA polymerase, has added significant contributions to the understanding of how DNA polymerases recognize the cognate substrate, [4] process abasic sites, [5] and non-natural nucleotides. [4d-g] Since our attempts to obtain suitable crystals of KlenTaq complexed to RNA failed, we set out to engineer the enzyme in such a way that it is capable of processing an RNA template more efficiently, which might result in improved crystallization properties. Indeed, we were able to obtain a significantly improved KlenTaq variant from which we obtained structural insights into a DNA-dependent DNA polymerase while processing RNA as a template for the first time. Furthermore, the generated KlenTaq variant turned out to be a thermostable DNA polymerase with significant reverse transcriptase activity, thus resulting in it being a valuable tool for crucial applications in clinical diagnostics and molecular biology, such as transcriptome analysis as well as the detection of pathogens and disease-specific markers.For the generation of an improved enzyme variant the mutation sites of two KlenTaq (KTq) variants M1 (L322M, L459M, S515R, I638F, S739G, E773G) [6] and M747K [7] were recombined by DNA shuffling. Both variants, M1 and M747K, were reported to possess either some reverse transcriptase activity or an expanded substrate spectrum. DNA shuffling was employed since the M1 variant, previously evolved in error-prone PCR, comprises six mutations distributed over the enzyme scaffold, but the individual contributions of the mutations are unknown. We generated a library of 1570 clones to obtain high coverage of all mutation combinations (as described in the Supporting Information). Proteins were expressed in 96-well plates and, after lysis and heat denaturation of the host proteins, use...
DNA is being constantly damaged by endo- and exogenous agents such as reactive oxygen species, chemicals, radioactivity, and ultraviolet radiation. Additionally, DNA is inherently labile, and this can result in, for example, the spontaneous hydrolysis of the glycosidic bond that connects the sugar and the nucleobase moieties in DNA; this results in abasic sites. It has long been obscure how cells achieve DNA synthesis past these lesions, and only recently has it been discovered that several specialized DNA polymerases are involved in translesion synthesis. The underlying mechanisms that render one DNA polymerase competent in translesion synthesis while another DNA polymerase fails are still indistinct. Recently two variants of Taq DNA polymerase that exhibited higher lesion bypass ability than the wild-type enzyme were identified by directed-evolution approaches. Strikingly, in both approaches it was independently found that substitution of a single nonpolar amino acid side chain by a cationic side chain increases the capability of translesion synthesis. Here, we combined both mutations in a single enzyme. We found that the KlenTaq DNA polymerase that bore both mutations superseded the wild-type as well as the respective single mutants in translesion-bypass proficiency. Further insights in the molecular basis of the detected gain of translesion-synthesis function were obtained by structural studies of DNA polymerase variants caught in processing canonical and damaged substrates. We found that increased positive charge of the surface potential in the area proximal to the negatively charged substrates promotes translesion synthesis by KlenTaq DNA polymerase, an enzyme that has very limited naturally evolved capability to perform translesion synthesis. Since expanded positively charged surface potential areas are also found in naturally evolved translesion DNA polymerases, our results underscore the impact of charge on the proficiency of naturally evolved translesion DNA polymerases.
It is estimated that about 10,000 abasic sites are formed per day per cell. Abasic sites impose a significant challenge for bypass synthesis by DNA polymerases. Recently, a tyrosine in KlenTaq DNA polymerase has been highlighted as being crucial for nucleotide selection opposite abasic sites. Structural data indicated a hydrogen bond between the tyrosine's hydroxy group and the N3 of an incoming ddATP opposite the abasic site. In order to further investigate abasic site bypass, we incorporated the unnatural amino acid 2,3,5-trifluorotyrosine at the position of the crucial tyrosine of KlenTaq DNA polymerase. Fluorine substitution at the tyrosine decreased the pka value of the tyrosine's hydroxy group and allowed its protonation state to be modulated. Single-nucleotide-incorporation experiments revealed reduced activity for the KlenTaq mutant compared to the wild-type when bypassing an abasic site analogue. The finding stresses the involvement of this tyrosine and its hydrogen bonding in abasic site bypass.
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