Activation of ARTD2/PARP2 by DNA damage induces conformational changes relieving enzyme autoinhibition
AbstractHuman ARTD2/PARP2 is an ADP-ribosyltransferase which, when activated by 5’- phosphorylated DNA ends, catalyzes poly-ADP-ribosylation of itself, other proteins and DNA. A crystal structure of ARTD2 in complex with an activating 5’-phosphorylated DNA shows that the WGR domain bridges the dsDNA gap and joins the DNA ends. This DNA binding results in major conformational changes, reorganization of helical fragments, in the ARTD2 regulatory domain. Comparison of ARTD1-3 crystal structures reveal how binding to a DNA damage site leads to formation of a catalytically competent conformation capable of binding substrate NAD+ and histone PARylation factor 1 changing the ARTD2 residue specificity from glutamate to serine when initiating DNA repair processes. The structure also reveals how the conformational changes in the autoinhibitory regulatory domain would promote the flexibility needed by the enzyme to reach the target macromolecule for ADP-ribosylation.