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Biophysical characterization of the binary and ternary interactions between PROTAC molecules and their protein binding partners can provide unique and complementary insights relative to widely used cellular systems. Understanding the affinity between each warhead of a PROTAC molecule and its protein binding partners can help guide medicinal chemistry efforts toward the optimization of those interactions. Previously published crystal structures of ternary PROTAC complexes have revealed that atoms in the linker region can form interactions with one or both of the protein binding partners16,20. Experimentally determining the cooperativity of ternary complex formation can support linker optimization.
Described in this report is the utilization of three different biophysical techniques that can provide information about the binding affinities between PROTAC molecules and their protein binding partners. Method 1 details the isothermal titration calorimetry (ITC) experimental set-up for the PROTAC molecule, MZ1, the VHL E3 ligase complex, and the Brd4BD2 bromodomain. ITC results showed KD's of 59 nM for the binary interaction between MZ1 and VHL and 4 nM for the ternary interaction between VHL and pre-mixed MZ1 and Brd4BD2. The affinities were consistent with those observed in SPR (immobilized VHL binding to MZ1 KD = 26 nM, immobilized VHL binding to pre-mixed MZ1 and Brd4BD2 KD=1 nM) and BLI (KD= 2.8 nM). While the ITC KD results for VHL binding to MZ1 are consistent with reported values16, the stoichiometry obtained is different. One potential explanation for this result is the poor solubility of MZ1 in the HEPES-based buffer used in the protocol described here, while the results from the literature were generated using a Bis-tris-based buffer. The authors preferred to use the same buffer components across SPR, ITC, and BLI.
Method 2 describes the experimental setup for the BLI analysis of the interaction of immobilized VHL, a fixed concentration of Brd4BD2, and varying concentrations of MZ1. Because of the sensitivity limitations of the technique, KD, kon, and koff values for ternary complex formation could be generated, but not for the binary interaction between MZ1 and the proteins.
Method 3 describes multiple SPR assays. SPR is more sensitive than BLI and can be applied to observe both the protein-small molecule (binary) and protein-protein (ternary) interactions. In the latter case, background signals should be carefully monitored as protein in the analyte could give high and unstable signals. SPR is very sensitive to reagents with a high refractive index, including DMSO, glycerol, and detergents. If the protein is stored in the buffer containing glycerol or detergent, the running buffer must contain matching concentrations of those components. Alternatively, applying size-exclusion chromatography completely removes them before any SPR experiment. Care should be taken to match the DMSO concentrations between buffer and analyte samples closely. The DMSO solvent corrections are performed according to the manufacturer's instructions.
The method in step 3.1 describes the SPR assay for the binary VHL-MZ1 interaction. Method 3.2 describes the SPR assay for the VHL: MZ1: Brd4BD2 ternary complex where VHL is immobilized, and the analyte is either Brd4BD2 alone or the MZ1:Brd4BD2 complex. In this system, the interaction between Brd4BD2 and VHL is negligible. The ternary complex formation is highly cooperative (ɑ = 26). The off-rate for ternary complex formation is 0.014 s-1, which requires the use of single-cycle kinetics. Results from ITC also show a highly cooperative ternary complex formation (ɑ=15). SPR methods in steps 3.3, 3.4, and 3.5 describe assays for evaluating the formation of a complex between CRBN and PPM1D induced by the presence of a PROTAC molecule, BRD-5110. The PROTAC molecule has a weak affinity for CRBN (KD ~3 µM) and a strong affinity for PPM1D (KD = 1-2 nM). As a result, the weak binding to CRBN is not saturated and results in an observed "hook-effect". While it is possible to increase ligand solubility by increasing the DMSO concentration used in the experiment, it is important in those instances to carefully monitor protein stability which can be negatively impacted by high concentrations of DMSO. Additionally, DMSO has a high heat of dissolution which can obscure the heat of binding of ligands to protein. Care should be taken to match the DMSO concentrations of the solution in the syringe and the solution in the cell. The authors recommend dialysis of the two solutions against the same buffer preparation.
General recommendations and guidelines are provided based on the experiments performed and reported here. When the affinities of binary interactions between PROTAC molecules and their protein binding partners are strong (KD <1 µM), SPR provides reliable and reproducible affinities along with valuable information on the cooperativity of ternary complex formation. When the affinities of the binary interaction between one of the protein binding partners and the PROTAC molecule are weak (KD >1 µM), the assay setup will need to be modified. In those instances, the use of molecular simulations where the binding constants are fixed, and the concentrations of ligand and analyte are varied can be valuable in guiding assay design and interpreting experimental results. ITC assays provide important information on the stoichiometry of binding but require significantly more protein and compound reagents relative to SPR and BLI. Additionally, the solubility of the PROTAC molecule can be limiting for ITC experiments. BLI has higher throughput than ITC and requires less protein and compound reagents. However, due to sensitivity limitations, BLI can only be used to assess the ternary complex formation and not binary interactions between PROTAC molecules and their protein binding partners. It is recommended that SPR be used for routine testing of both binary and ternary PROTAC binding assays and BLI and ITC assays used for orthogonal validation of results from SPR.