A desthiobiotin labelled NAD+ analogue to uncover Poly(ADP-ribose) polymerase 1 protein targets.

ADP-ribosylation is a post-translational modification catalyzed by the enzyme family of polyadenosine diphosphate (ADP)-ribose) polymerases (PARPs). This enzymatic process involves the transfer of single or multiple ADP-ribose molecules onto proteins, utilizing nicotinamide adenine dinucleotide (NAD+ ) as a substrate. It, thus, plays a pivotal role in regulating various biological processes. Unveiling PARP-selective protein targets is crucial for a better understanding of their biological functions. Nonetheless, this task proves challenging due to overlapping targets shared among PARP family members. Therefore, we applied the "bump-and-hole" strategy to modify the nicotinamide binding site of PARP1 by introducing a hydrophobic pocket ("hole"). This PARP1-mutant binds an orthogonal NAD+ (Et-DTB-NAD+ ) containing an ethyl group ("bump") at the nicotinamide moiety. Furthermore, we added a desthiobiotin (DTB) tag directly to the adenosine moiety, enabling affinity enrichment of ADP-ribosylated proteins. Employing this approach, we successfully identified protein targets modified by PARP1 in cell lysate. This strategy expands the arsenal of chemically modified NAD+ analogs available for studying ADP-ribosylation, providing a powerful tool to study these critical post-translational modifications.

Profiling of the ADP-Ribosylome in Living Cells.

Post-translational modification (PTM) with ADP-ribose and poly(ADP-ribose) using nicotinamide adenine dinucleotide (NAD+ ) as substrate is involved in the regulation of numerous cellular pathways in eukaryotes, notably the response to DNA damage caused by cellular stress. Nevertheless, due to intrinsic properties of NAD+ e.g., high polarity and associated poor cell passage, these PTMs are difficult to characterize in cells. Here, two new NAD+ derivatives are presented, which carry either a fluorophore or an affinity tag and, in combination with developed methods for mild cell delivery, allow studies in living human cells. We show that this approach allows not only the imaging of ADP-ribosylation in living cells but also the proteome-wide analysis of cellular adaptation by protein ADP-ribosylation as a consequence of environmental changes such as H2 O2 -induced oxidative stress or the effect of the approved anti-cancer drug olaparib. Our results therefore pave the way for further functional and clinical studies of the ADP-ribosylated proteome in living cells in health and disease.