To understand this PTM in more detail and consequently develop effective drugs based on this information, it is essential to investigate the key proteins involved in ADP-ribosylation: ADP-ribosyltransferases (writers), hydrolases (erasers), and the proteins interacting with ADP-ribose (readers). Much past and current research has examined proteins that function as the writers and erasers of ADP-ribosylation. This research has led to the development of anti-cancer drugs, such as olaparib, and advancements towards future antiviral therapies targeting COVID-19. However, there is also significant potential in exploring the readers of ADP-ribosylation, as they regulate many downstream processes related to ADP-ribosylated proteins and may present valuable therapeutic targets. To gain a better understanding of the readers of ADP-ribose as post-translational modification, it is essential to identify which proteins specifically interact with each of the various forms of ADP-ribose, including mono-ADP-ribose, linear poly-ADP-ribose, and branched poly-ADP-ribose. Well-defined synthetic ADP-ribose derivatives serve as ideal molecular probes in proteomics studies, allowing clear differentiation between the different forms of ADP-ribosylation. This Thesis outlines the development of novel mono- and oligo-ADP-ribose derivatives and describes their use as molecular probes in interactomics screenings to facilitate a more detailed investigation of the proteins involved in ADP-ribosylation.

• adp-ribosylation
• bio-organic synthesis
• proteomics
• synthetic probes

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