Competition NMR for Detection of Hit/Lead Inhibitors of Protein-Protein Interactions.

Screening for small-molecule fragments that can lead to potent inhibitors of protein-protein interactions (PPIs) is often a laborious step as the fragments cannot dissociate the targeted PPI due to their low µM-mM affinities. Here, we describe an NMR competition assay called w-AIDA-NMR (weak-antagonist induced dissociation assay-NMR), which is sensitive to weak µM-mM ligand-protein interactions and which can be used in initial fragment screening campaigns. By introducing point mutations in the complex's protein that is not targeted by the inhibitor, we lower the effective affinity of the complex, allowing for short fragments to dissociate the complex. We illustrate the method with the compounds that block the Mdm2/X-p53 and PD-1/PD-L1 oncogenic interactions. Targeting the PD-/PD-L1 PPI has profoundly advanced the treatment of different types of cancers.

Robust NMR screening for lead compounds using tryptophan-containing proteins.

NMR-based drug screening methods provide the most reliable characterization of binding propensities of ligands to their target proteins. Unique to NMR is its capability to detect weak microM-mM bindings. NMR assays are, however, one of the least effective methods in terms of the amount of protein required and the time needed for acquiring NMR experiments. We have recently described a time efficient 1D proton NMR assay for studying the effect of antagonists on protein-protein interactions. The method, named AIDA-NMR (for Antagonist Induced Dissociation Assay-NMR), can provide information on whether an antagonist of a protein-protein interaction is strong enough to dissociate the complex and, in addition, whether its interaction is through denaturation, precipitation, or release of a protein in its functional folded state. AIDA requires a large protein fragment (larger than ca. 30 kDa) to bind to a small reporter protein (smaller than ca.12 kDa). Here, we present an extension of this method, named SEI AIDA (SEI, for Selective Excitation-Inversion). The SEI AIDA uses tryptophan-bearing proteins, and by selectively exciting only the proton NMR signals of the (N)H(epsilon) indole side chains of tryptophans, the acquisition time of the AIDA experiment can be reduced by an order of magnitude relative to the corresponding 1D AIDA that uses hard pulses. Thus, at 600 MHz, the (N)H(epsilon) signal of a 35 microM protein complex can be acquired in only 2.5 min, making the SEI AIDA suitable for high-throughput screening pipelines in drug discovery.

Selective targeting of disease-relevant protein binding domains by O-phosphorylated natural product derivatives.

Phosphorylation-dependent protein binding domains are crucially important for intracellular signaling pathways and thus highly relevant targets in chemical biology. By screening of chemical libraries against 12 structurally diverse phosphorylation-dependent protein binding domains, we have identified fosfosal and dexamethasone-21-phosphate as selective inhibitors of two antitumor targets: the SH2 domain of the transcription factor STAT5b and the substrate-binding domain of the peptidyl-prolyl isomerase Pin1, respectively. Both compounds are phosphate prodrugs with documented clinical use as anti-inflammatory agents in humans and were discovered with a high hit rate from a small subgroup within the screening library. Our study indicates O-phosphorylation of appropriately preselected natural products or natural product derivatives as a generally applicable strategy for the identification of non-reactive and non-peptidic ligands of phosphorylation-dependent protein binding domains. Moreover, our data indicate that it would be advisable to monitor the bioactivities of clinically used prodrugs in their uncleaved state against phosphorylation-dependent protein binding domains.