Re‐engineering the Immune Response to Metastatic Cancer: Antibody‐Recruiting Small Molecules Targeting the Urokinase Receptor

Rullo, Anthony; Fitzgerald, Kelly; Muthusamy, Viswanathan; Liu, Min; Yuan, Cai; Huang, Mingdong; Kim, Minsup; Cho, Art E.; Spiegel, David A.

doi:10.1002/anie.201510866

Cited by 65 publications

(60 citation statements)

References 34 publications

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“…Our predicted binding mode and interaction with Arg-53 was recently independently confirmed by a crystal structure of an analog of IPR-803 bound to uPAR. [19] …”

Section: Introductionmentioning

confidence: 99%

“…Computational studies that include molecular dynamics simulations predicted ab inding mode for the compound along with ac ritical saltbridge interaction with an Arg-53 [18] residue.O ur predicted binding mode and interaction with Arg-53 was recently independently confirmed by ac rystal structure of an analogue of IPR-803 bound to uPAR. [19] Historically,m ost rational approaches for the design of small-molecule inhibitors of protein-protein interactions have focusedo nm imicking the position of amino acids located on the protein ligand of ap rotein-protein interaction. [20][21][22] Several studies have used interface residues of the protein ligand of a protein-protein interaction to guide the design of small-molecule inhibitors in virtuals creening and lead optimization.…”

Section: Introductionmentioning

confidence: 99%

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Mimicking Intermolecular Interactions of Tight Protein–Protein Complexes for Small‐Molecule Antagonists

Bum‐Erdene

et al. 2017

ChemMedChem

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Tight protein-protein interactions (Kd < 100 nM) that occur over a large binding interface (> 1,000 Å2) are highly challenging to disrupt with small molecules. Historically, the design of small molecules to inhibit protein-protein interactions has focused on mimicking the position of interface protein ligand side chains. Here, we explore mimicry of the pairwise intermolecular interactions of the native protein ligand with residues of the protein receptor to enrich commercial libraries for small-molecule inhibitors of tight protein-protein interactions. We use the high-affinity interaction (Kd = 1 nM) between the urokinase receptor (uPAR) and its ligand urokinase (uPA) to test our methods. We introduce three methods for rank-ordering small molecules docked to uPAR: (i) a new fingerprint approach that represents uPA’s pairwise interaction energies with uPAR residues; (ii) a pharmacophore approach to identify small molecules that mimic the position of uPA interface residues; and (iii) a combined fingerprint and pharmacophore approach. Our work led to small molecules with novel chemotypes that inhibited a tight uPAR•uPA protein-protein interaction with single-digit micromolar IC50s. We also report the extensive work that identified several of the hits as either lacking stability, thiol reactive, or redox active. This work suggests that mimicking the binding profile of the native ligand and the position of interface residues can be an effective strategy to enrich commercial libraries for small-molecule inhibitors of tight protein-protein interactions.

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“…Our predicted binding mode and interaction with Arg-53 was recently independently confirmed by a crystal structure of an analog of IPR-803 bound to uPAR. [19] …”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mimicking Intermolecular Interactions of Tight Protein–Protein Complexes for Small‐Molecule Antagonists

Bum‐Erdene

et al. 2017

ChemMedChem

View full text Add to dashboard Cite

show abstract

“…In one case, we screened multiple structures that were sampled from explicit‐solvent molecular‐dynamics simulations and identified a sub‐micromolar affinity compound . The predicted structure of the compound was independently confirmed by X‐ray crystallography . More recently, we introduced a fingerprint method that uses the native protein ligand as a guide to identify small molecules that mimic the interaction of the protein ligand .…”

Section: Introductionmentioning

confidence: 99%

“…[11] The predicted structure of the compound was independently confirmed by X-ray crystallography. [14] More recently,w ei ntroducedafingerprint method that uses the native protein ligand as ag uide to identify small molecules that mimic the interaction of the protein ligand. [13] There is growing interest in the use of structure-based virtual screening to identify small molecules that inhibit challenging protein-protein interactions (PPIs).…”

Section: Introductionmentioning

confidence: 99%

Chemical Space Overlap with Critical Protein–Protein Interface Residues in Commercial and Specialized Small‐Molecule Libraries

Bum‐Erdene

et al. 2018

ChemMedChem

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There is growing interest in the use of structure‐based virtual screening to identify small molecules that inhibit challenging protein–protein interactions (PPIs). In this study, we investigated how effectively chemical library members docked at the PPI interface mimic the position of critical side‐chain residues known as “hot spots”. Three compound collections were considered, a commercially available screening collection (ChemDiv), a collection of diversity‐oriented synthesis (DOS) compounds that contains natural‐product‐like small molecules, and a library constructed using established reactions (the “screenable chemical universe based on intuitive data organization”, SCUBIDOO). Three different tight PPIs for which hot‐spot residues have been identified were selected for analysis: uPAR⋅uPA, TEAD4⋅Yap1, and CaVα⋅CaVβ. Analysis of library physicochemical properties was followed by docking to the PPI receptors. A pharmacophore method was used to measure overlap between small‐molecule substituents and hot‐spot side chains. Fragment‐like conformationally restricted small molecules showed better hot‐spot overlap for interfaces with well‐defined pockets such as uPAR⋅uPA, whereas better overlap was observed for more complex DOS compounds in interfaces lacking a well‐defined binding site such as TEAD4⋅Yap1. Virtual screening of conformationally restricted compounds targeting uPAR⋅uPA and TEAD4⋅Yap1 followed by experimental validation reinforce these findings, as the best hits were fragment‐like and had few rotatable bonds for the former, while no hits were identified for the latter. Overall, such studies provide a framework for understanding PPIs in the context of additional chemical matter and new PPI definitions.

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“…[8] Theo rigin of these endogenous antibodies varies from the consumption of meat (galactose-a-1,3-galactose), commensal bacteria in the gut (phosphorylcholine and rhamnose), and exposure to pesticides (DNP). This approach is intended for local application, that is,b yd irect intratumoral injection, owing to the lack of selectivity towards cancer cells.A nother strategy involves conjugates composed of an antibody-binding motif and atarget-cell-binding motif.F or the latter, several cell surface receptors that are overexpressed by cancer cells have been explored, including the folate receptor, [10] PSMA, [11] uPAR, [12] and others.T hese approaches all involve mono-or at best bivalent molecules,both on the level of the antibody-binding as well as the target-cell-binding motifs. [9] Thel ipid part anchors the cell membrane and exposes the antibody-binding motif to the external medium.…”

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confidence: 99%

Efficient Innate Immune Killing of Cancer Cells Triggered by Cell‐Surface Anchoring of Multivalent Antibody‐Recruiting Polymers

et al. 2019

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Binding of monoclonal antibodies (mAbs) onto ac ell surface triggers antibody-mediated effector killing by innate immune cells through complement activation. As an alternative to mAbs,s ynthetic systems that can recruit endogenous antibodies from the blood stream to acancer cell surface could be of great relevance.H erein, we explore antibodyrecruiting polymers (ARPs) as an ovel class of immunotherapy. ARPs consist of ac ell-binding motif linked to ap olymer that contains multiple small molecule antibody-binding motifs along its backbone.A saproof of concept, we employalipid anchor that inserts into the phospholipid cell membrane and make use of apolymeric activated ester scaffold onto whichwe substitute dinitrophenol as an antibody-binding motif.W e demonstrate that ARPs allow for high avidity antibody binding and drive antibody recruitment to treated cells for several days. Furthermore,weshowthat ARP-treated cancer cells are prone to antibody-mediated killing through phagocytosis by macrophages.

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Re‐engineering the Immune Response to Metastatic Cancer: Antibody‐Recruiting Small Molecules Targeting the Urokinase Receptor

Cited by 65 publications

References 34 publications

Mimicking Intermolecular Interactions of Tight Protein–Protein Complexes for Small‐Molecule Antagonists

Mimicking Intermolecular Interactions of Tight Protein–Protein Complexes for Small‐Molecule Antagonists

Chemical Space Overlap with Critical Protein–Protein Interface Residues in Commercial and Specialized Small‐Molecule Libraries

Efficient Innate Immune Killing of Cancer Cells Triggered by Cell‐Surface Anchoring of Multivalent Antibody‐Recruiting Polymers

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