Singlet Oxygen Attack on Guanine: Reactivity and Structural Signature within the B-DNA Helix
International audience; Oxidatively generated DNA lesions are numerous and versatile, and have been the subject of intensive research since the discovery of 8-oxoguanine in 1984. Even for this prototypical lesion, the precise mechanism of formation remains elusive due to the inherent difficulties in characterizing high-energy intermediates. We have probed the stability of the guanine endoperoxide in B-DNA as a key intermediate and determined a unique activation free energy of around 6 kcal mol−1 for the formation of the first C−O covalent bond upon the attack of singlet molecular oxygen (1O2) on the central guanine of a solvated 13 base-pair poly(dG-dC), described by means of quantum mechan…
Free energy profiles for two ubiquitous damaging agents: methylation and hydroxylation of guanine in B-DNA
International audience; DNA methylation and hydroxylation are two ubiquitous reactions in DNA damage induction, yet insights are scarce concerning the free energy of activation within B-DNA. We resort to multiscale simulations to investigate the attack of a hydroxyl radical and of the primary diazonium onto a guanine embedded in a solvated dodecamer. Reaction free energy profiles characterize two strongly exergonic processes, yet allow unprecedented quantification of the barrier towards this damage reaction, not higher than 6 kcal mol−1 and sometimes inexistent, and of the exergonicities. In the case of the [G(C8)-OH]˙ intermediate, we challenge the functional dependence of such simulations…
Hydrogen abstraction by photoexcited benzophenone: consequences for DNA photosensitization
International audience; We report a computational investigation of the hydrogen abstraction (H-abstraction) induced by triplet benzophenone (3BP) on thymine nucleobase and backbone sugar. The chemical process is studied using both high level multiconfigurational perturbation and density functional theory. Both methods show good agreement in predicting small kinetic barriers. Furthermore the behavior of benzophenone in DNA is simulated using molecular dynamics and hybrid quantum mechanics/molecular mechanics methods. The accessibility of benzophenone to the labile hydrogens within B-DNA is demonstrated, as well as the driving force for this reaction. We evidence a strong dependence of the H-…
Resolving the Benzophenone DNA-Photosensitization Mechanism at QM/MM Level
International audience; Benzophenone, the parent of the diarylketone family, is a versatile compound commonly used as a UV blocker. It may also trigger triplet-based DNA photosensitization. Therefore, benzophenone is involved in DNA photodamage induction. In the absence of experimentally resolved structure, the mechanism of DNA damage production remains elusive. Employing a hybrid quantum mechanics/molecular mechanics approach, here we address the spin transfer mechanism between this drug and proximal thymine, that is, the DNA nucleobase most prone to suffer triplet damages.
DNA Photodamage and Repair: Computational Photobiology in Action
DNA is constantly exposed to external and metabolic stress agents, including the solar radiation and in particular the UV portion of the electromagnetic spectrum. Such source of stress can induce photochemical modification of the structure of DNA and of its basic components, i.e. the nucleobases. DNA lesions may ultimately lead to genomic instability, mutations, and even to carcinogenesis. Hence, cells dispose of complex biochemical repair pathways in charge of remove the DNA lesions and avoid their accumulation. In this Chapter, we present the complexity of the DNA lesion chemical and structural space, also complicated by the intricate coupling with the biological relevant signaling pathwa…
Dynamics of the excited-state hydrogen transfer in a (dG)·(dC) homopolymer: intrinsic photostability of DNA
Multiscale molecular dynamics simulations reveal out-of-plane distortions that favour DNA photostability. A novel photostability mechanism involving four proton transfers and triggered by a nearby Na+ ion is also unveiled.
How Fragile We Are: Influence of Stimulator of Interferon Genes (STING) Variants on Pathogen Recognition and Immune Response Efficiency.
AbstractThe STimulator of INterferon Genes (STING) protein is a cornerstone of the human immune response. Its activation by cGAMP upon the presence of cytosolic DNA stimulates the production of type I interferons and inflammatory cytokines which are crucial for protecting cells from infections. STING signaling pathway can also influence both tumor-suppressive and tumor-promoting mechanisms, rendering it an appealing target for drug design. In the human population, several STING variants exist and exhibit dramatic differences in their activity, impacting the efficiency of the host defense against infections. Understanding the differential molecular mechanisms exhibited by these variants is o…