Abstract
Sirtuins are NAD+-dependent protein deacylases that remove acyl modifications from acyl-lysine residues, resulting in essential cellular signaling. Recognized for their role in lifespan extension, humans encode seven sirtuin isoforms (Sirt1-7), and loss of sirtuin deacylase activity is implicated in many aging-related diseases. Despite being intriguing therapeutic targets, cellular studies of sirtuins are hampered by the lack of chemical probes to measure sirtuin activity independent of sirtuin protein levels. Here, we use a modular, peptide-based approach to develop activity-based probes (ABPs) that directly measure Sirt1 activity in vitro and in cell lysates. ABPs were synthesized containing four elements: (1) thioacetyl-lysine for mechanism-based affinity towards only active sirtuins, (2) either histone H3 lysine-14 (H3K14) or p53 sequences for Sirt1 specificity, (3) a diazirine for covalent labeling upon UV irradiation, and (4) an alkyne for bioorthogonal conjugation to a fluorophore for gel-based detection of active Sirt1. Compared to the H3K14 ABP, the p53 ABP showed increased sensitivity and selective labeling of active Sirt1. Acyl-lysine peptide competition, pharmacological inhibition, and inhibitory post-translational modification of Sirt1 resulted in the loss of p53 ABP labeling both in vitro and in HEK293T cell lysates, consistent with the ABP measuring decreased Sirt1 activity. Furthermore, the p53 ABP measured subcellular Sirt1 activity in MCF7 breast cancer cells. The development of a Sirt1-selective ABP that detects Sirt1 activity with an order of magnitude increased sensitivity compared to previous approaches demonstrates the utility of a modular, peptide-based approach for selective-targeting of the sirtuin protein family and provides a framework for further development of sirtuin-selective chemical probes.