Protein-protein interactions lie at the heart of many biological processes and therefore represent promising drug targets. Despite this opportunity, identification of protein-protein interfaces remains challenging. We have previously developed a method that relies on coating protein surfaces with small-molecule dyes to discriminate between solvent-accessible protein surfaces and hidden interface regions. Dye-bound, solvent-accessible protein regions resist trypsin digestion, whereas hidden interface regions are revealed by denaturation and sequenced by MS. The small-molecule dyes bind promiscuously and with high affinity, but their binding mechanism is unknown. Here, we report on the optimization of a novel dye probe used in protein painting, Fast Blue B ؉ naphthionic acid, and show that its affinity for proteins strongly depends on hydrophobic moieties that we call here "hydrophobic clamps." We demonstrate the utility of this probe by sequencing the protein-protein interaction regions between the Hippo pathway protein Yes-associated protein 2 (YAP2) and tight junction protein 1 (TJP1 or ZO-1), uncovering interactions via the known binding domain as well as ZO-1's MAGUK domain and YAP's N-terminal proline-rich domain. Additionally, we demonstrate how residues predicted by protein painting are present exclusively in the complex interface and how these residues may guide the development of peptide inhibitors using a case study of programmed cell death protein 1 (PD-1) and programmed cell death 1 ligand 1 (PD-L1). Inhibitors designed around the PD-1/PD-L1 interface regions identified via protein painting effectively disrupted complex formation, with the most potent inhibitor having an IC 50 of 5 M.
Protein–protein interactions (PPIs) drive all biologic systems at the subcellular and extracellular level. Changes in the specificity and affinity of these interactions can lead to cellular malfunctions and disease. Consequently, the binding interfaces between interacting protein partners are important drug targets for the next generation of therapies that block such interactions. Unfortunately, protein–protein contact points have proven to be very difficult pharmacological targets because they are hidden within complex 3D interfaces. For the vast majority of characterized binary PPIs, the specific amino acid sequence of their close contact regions remains unknown. There has been an important need for an experimental technology that can rapidly reveal the functionally important contact points of native protein complexes in solution. In this review, experimental techniques employing mass spectrometry to explore protein interaction binding sites are discussed. Hydrogen–deuterium exchange, hydroxyl radical footprinting, crosslinking and the newest technology protein painting, are compared and contrasted.
Osteoarthritis (OA) is the most common form of arthritis and the fastest growing cause of chronic disability in the world. Formation of the ternary IL-1β /IL-1R1/IL-1RAcP protein complex and its downstream signaling has been implicated in osteoarthritis pathology. Current OA therapeutic approaches target either the cytokine IL-1β or the primary receptor IL-1RI but do not exploit the potential of the secondary receptor IL-1RAcP. Our previous work implicated the Arg286 residue of IL-1RAcP as a key mediator of complex formation. Molecular modeling confirmed Arg286 as a high-energy mediator of the ternary IL-1β complex architecture and interaction network. Anti-IL-1RAcP monoclonal antibodies (mAb) targeting the Arg286 residue were created and were shown to effectively reduce the influx of inflammatory cells to damaged joints in a mouse model of osteoarthritis. Inhibitory peptides based on the native sequence of IL-1RAcP were prepared and examined for efficacy at disrupting the complex formation. The most potent peptide inhibitor had an IC50 value of 304 pM in a pull-down model of complex formation, and reduced IL-1β signaling in a cell model by 90% at 2 μM. Overall, therapies that target the Arg286 region surface of IL-1RAcP, and disrupt subsequent interactions with subunits, have the potential to serve as next generation treatments for osteoarthritis.
The next generation of molecular cancer therapeutics will target pivotal protein-protein interaction interfaces participating in immune cell receptor signaling, oncogenes, and suppressor genes. We have created a wholly novel, technology “protein painting” for the rapid direct sequencing of hidden native protein-protein interaction hot spots. Our technology, employs previously unexplored small molecule (12 Å) aryl hydrocarbon dyes or “paints” to cut out, and MS sequence, only the hidden unmodified contact interfaces between two or more interacting native proteins. Novel Technology: Paint chemistries have extremely high affinities (rapid on-rates, and very slow off-rates that are ten to 100 times higher than most protein-protein interactions). When mixed with a native pre-formed protein complex for only 5 minutes at physiologic pH and salinity, the paints non-covalently coat all external sites on the protein without altering the 3D conformation of the complex, but cannot gain access to the solvent inaccessible hidden protein-protein interaction domains. Each paint molecule spans less than 3 amino acids, and has high affinity for protease cleavage consensus sites. Following painting, the proteins are dissociated. This leaves the paint molecules coating surfaces not participating in the interface. Following dissociation, the proteins are linearized, digested with trypsin, and sequenced by standard MS. The paint molecules remain non-covalently bound after the proteins are denatured. Trypsin will not cleave the regions of the protein that are “painted”. Following proteolysis peptides emerging from MS will be generated exclusively from the unmodified opposing points where the proteins were in intimate contact. Results: Protein Painting identified hot spot domains between PD-L1:PD-1, including two surface interface regions that are separated in the linear sequence but adjacent in the 3D structure. We created novel cyclized multivalent inhibitors that block both sides of the PD-L1:PD-1 interface and markedly suppress cell-cell coupling and abolished downstream signaling through this complex in cultured tumor cell immune cell interactions. A very high correlation (p<0.0003) was found for known contact points predicted by crystal structure, with a 97% specificity for true positive hot spots: 95% agreement with Robetta prediction software for known complexes. Protein painting outperforms (425%) hydrogen deuterium exchange and cross linking for number of positive hits and % true positive hits. Conclusions: Protein painting is a new tool to identify highly specific drug targets located within protein interaction interfaces, yielding inhibitors that abolish protein signaling relevant to cancer immunotherapy. Citation Format: Alessandra Luchini, Luisa Paris, Virginia Espina, Kelsey Mitchell, Angela Dailing, Lance A. Liotta. Protein painting identifies PD-1: PDL-1 therapeutic targets at protein-protein interfaces [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 211. doi:10.1158/1538-7445.AM2017-211
Protein-protein interactions are thought to be the next frontier in drug discovery. However, there are several well-known challenges facing development of protein-protein interaction (PPI) inhibitors that lead to slow development in the field, including difficulty identifying PPIs and difficulty designing small molecule inhibitors of relatively flat, featureless PPIs. We address these difficulties with the development of a novel method of discovering PPI hotspots, called protein painting. This technique relies on non-covalent labeling of solvent- accessible protein surfaces using small molecular dyes optimized for protein binding. The dyes block access to trypsin cleavage sites, allowing for digestion only of undyed interface regions following denaturation of the protein complex. Interface regions can be identified using mass spectrometry and used as target sequences for drug development. Here we introduce new dye chemistries and elucidate their mechanism of protein binding for the first time. This allows for rapid identification of functionally-relevant hotspots without the need to screen many dye chemistries to optimize surface coverage of the protein complex. We applied this method to elucidate functional hotspots for immmuno-oncology targets PD-1 and PD-L1 and Hippo pathway targets YAP2 and tight junction protein ZO-1. To further functionally validate the hotspot regions identified, we focused on the case study of PD-1 and PD-L1. We discovered a hotspot of PD-1 Lys 78 in the protein-protein interface, and rationally designed a series of 8 peptide inhibitors to target this hotspot. The most active peptide YRCMISYGGADYKRITV derived from PD-L1 disrupted the PD-1/PD-L1 complex with an IC50 of 5.07 µM. The predicted binding site of this peptide on PD-1 overlaps the binding site of therapeutic anti-PD-1 antibody pembrolizumab; crystal structures of pembrolizumab and PD-1 show hydrogen bonding between the antibody and our identified hotspot Lys 78. Furthermore, we prepared a cyclized analog peptide CYRAMISYGGADYKRITC by disulfide bond stapling to increase peptide stability and found that this did not significantly reduce inhibitor potency, with an IC50 of 8.02 µM. Taken together, this data suggests a specific region of PD-1 found within the larger PD-1/PD-L1 interface that may serve as a target for development of next generation small molecule PD-1/PD-L1 inhibitors. By focusing drug discovery efforts against only the PPI hotspot regions, we may accelerate drug development against these difficult targets. Citation Format: Amanda Still, Douglass Dey, Rachel Carter, Angela Dailing, Mikell Paige, Lance Liotta, Alessandra Luchini. Functionally important hotspot interfaces between immune-oncology targets PD-1 and PD-L1 and between Hippo pathway targets YAP2 and tight junction protein ZO-1 are identified using a protein-protein interaction technique optimized with novel dye chemistries [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 982.
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