Abstract
Small molecule activators of protein phosphatase 2A (PP2A), hereafter SMAPs, have attracted substantial interest for their potential to inhibit cancer cell proliferation by targeting PR65, the scaffold subunit of the PP2A heterotrimer. PR65 is a uniquely flexible and stable molecule composed of 15 tandem HEAT (Huntingtin, Elongation factor 3-PP2A-TOR1) repeats. We characterized the binding sites and interactions of two SMAPs ATUX-8385 and DT-061 with PR65 and evaluated the effects on PR65 structural dynamics using docking and molecular dynamics simulations. We initiated SMAP-bound PR65 simulations starting from two binding sites: S1, determined by cryo-electron microscopy for DT-061 bound to PP2A, on the inner helices of the HEAT repeats 2 and 3 (2(i) and 3(i)); and S2, predicted by docking of ATUX-8385 onto PR65, on 4(i) and 5(i) and outer helices 5(o) and 6(o) consistent with footprinting experiments. S2 proved to be a stable site for both SMAPs when simulations were initiated at S2. However, neither DT-061 nor ATUX-8385 demonstrated stable binding to S1. DT-061 rapidly dissociated from S1 to settle instead at a neighboring site S4 overlapping with our previously identified S3 for PR65 in extended form, suggesting that binding to S1 may be a two-step process: an initial binding to PR65 alone, either to S3/S4 or S2, followed by movement to S3/S4, and then an induced relocation to S1 upon complexation with the regulatory and catalytic subunits. Targeted in silico mutagenesis showed that mutations at S2 and S4 destabilized binding of SMAP to PR65 (subunit). Heterotrimeric PP2A simulations showed that S3 and S4 bindings were not persistent upon complexation. Together, these results corroborate our findings. Furthermore, this preferentially stabilized a relatively extended PR65 conformation that would accommodate, if not promote, the assembly of the catalytic and regulatory subunits to prompt the activation of the trimeric phosphatase.