Structural Basis for The Recognition of Deaminated Nucleobases by An Archaeal DNA Polymerase

With increasing temperature, nucleobases in DNA become increasingly damaged by hydrolysis of exocyclic amines. The most prominent damage includes the conversion of cytosine to uracil and adenine to hypoxanthine. These damages are mutagenic and put the integrity of the genome at risk if not repaired appropriately. Several archaea live at elevated temperatures and thus, are exposed to a higher risk of deamination. Earlier studies have shown that DNA polymerases of archaea have the property of sensing deaminated nucleobases in the DNA template and thereby stalling the DNA synthesis during DNA replication providing another layer of DNA damage recognition and repair. However, the structural basis of uracil and hypoxanthine sensing by archaeal B‐family DNA polymerases is sparse. Here we report on three new crystal structures of the archaeal B‐family DNA polymerase from Thermococcus kodakarensis (KOD) DNA polymerase in complex with primer and template strands that have extended single stranded DNA template 5’‐overhangs. These overhangs contain either the canonical nucleobases as well as uracil or hypoxanthine, respectively, and provide unprecedented structural insights into their recognition by archaeal B‐family DNA polymerases.

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Structural Basis for The Recognition of Deaminated Nucleobases by An Archaeal DNA Polymerase

Kropp

Ludmann

Diederichs

et al. 2021

ChemBioChem

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Structural insights into a DNA polymerase reading the xeno nucleic acid HNA

Gutfreund,

Betz,

Abramov

et al. 2024

Nucleic Acids Research

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Xeno nucleic acids (XNAs) are unnatural analogues of the natural nucleic acids in which the canonical ribose or deoxyribose rings are replaced with alternative sugars, congener structures or even open-ring configurations. The expanding repertoire of XNAs holds significant promise for diverse applications in molecular biology as well as diagnostics and therapeutics. Key advantages of XNAs over natural nucleic acids include their enhanced biostability, superior target affinity and (in some cases) catalytic activity. Natural systems generally lack the mechanisms to transcribe, reverse transcribe or replicate XNAs. This limitation has been overcome through the directed evolution of nucleic acid-modifying enzymes, especially polymerases (pols) and reverse transcriptases (RTs). Despite these advances, the mechanisms by which synthetic RT enzymes read these artificial genetic polymers remain largely unexplored, primarily due to a scarcity of structural information. This study unveils first structural insights into an evolved thermostable DNA pol interacting with the XNA 1,5-anhydrohexitol nucleic acid (HNA), revealing unprecedented HNA nucleotide conformations within a ternary complex with the enzyme. These findings not only deepen our understanding of HNA to DNA reverse transcription but also set the stage for future advancements of this and similar enzymes through deliberate design.

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Structural Basis for The Recognition of Deaminated Nucleobases by An Archaeal DNA Polymerase

Cited by 2 publications

References 28 publications