Molecular basis for DarT ADP-ribosylation of a DNA base.
Marion SchullerRachel E ButlerAntonio ArizaCallum Tromans-CoiaGytis JankeviciusTimothy D W ClaridgeSharon L KendallShan GohGraham R StewartIvan AhelPublished in: Nature (2021)
ADP-ribosyltransferases use NAD+ to catalyse substrate ADP-ribosylation1, and thereby regulate cellular pathways or contribute to toxin-mediated pathogenicity of bacteria2-4. Reversible ADP-ribosylation has traditionally been considered a protein-specific modification5, but recent in vitro studies have suggested nucleic acids as targets6-9. Here we present evidence that specific, reversible ADP-ribosylation of DNA on thymidine bases occurs in cellulo through the DarT-DarG toxin-antitoxin system, which is found in a variety of bacteria (including global pathogens such as Mycobacterium tuberculosis, enteropathogenic Escherichia coli and Pseudomonas aeruginosa)10. We report the structure of DarT, which identifies this protein as a diverged member of the PARP family. We provide a set of high-resolution structures of this enzyme in ligand-free and pre- and post-reaction states, which reveals a specialized mechanism of catalysis that includes a key active-site arginine that extends the canonical ADP-ribosyltransferase toolkit. Comparison with PARP-HPF1, a well-established DNA repair protein ADP-ribosylation complex, offers insights into how the DarT class of ADP-ribosyltransferases evolved into specific DNA-modifying enzymes. Together, our structural and mechanistic data provide details of this PARP family member and contribute to a fundamental understanding of the ADP-ribosylation of nucleic acids. We also show that thymine-linked ADP-ribose DNA adducts reversed by DarG antitoxin (functioning as a noncanonical DNA repair factor) are used not only for targeted DNA damage to induce toxicity, but also as a signalling strategy for cellular processes. Using M. tuberculosis as an exemplar, we show that DarT-DarG regulates growth by ADP-ribosylation of DNA at the origin of chromosome replication.
Keyphrases
- mass spectrometry
- dna repair
- dna damage
- high resolution
- escherichia coli
- mycobacterium tuberculosis
- pseudomonas aeruginosa
- oxidative stress
- circulating tumor
- dna damage response
- single molecule
- cell free
- palliative care
- nitric oxide
- gene expression
- deep learning
- big data
- staphylococcus aureus
- dna methylation
- candida albicans
- artificial intelligence
- antiretroviral therapy