Resolving symmetry-masked allosteric cooperativity in the M. tuberculosis proteasome core particle
Resolving symmetry-masked allosteric cooperativity in the M. tuberculosis proteasome core particle
Turner, M.; Wittlinger, V.; Lento, C.; Haris, A.; Ujma, J.; Bruton, D.; Richardson, K.; Giles, K.; Bottcher, T.; Wilson, D.; Vahidi, S.
AbstractThe 20S proteasome core particle (CP) is a stacked 7-{beta}7-{beta}7-7 assembly in which the central {beta}-rings host fourteen catalytic active sites responsible for regulated protein degradation. Allosteric coupling between catalytic {beta}-subunits has been characterized in eukaryotic proteasomes, whose heteromeric {beta}-rings permit subunit-specific perturbation. In bacterial proteasomes, however, the {beta}-rings are homomeric, and any allosteric relationships between subunits with identical sequences have remained refractory to conventional ensemble-averaging structural methods, including to hydrogen/deuterium exchange mass spectrometry (HDX-MS). Here we show that orthosteric inhibitors paradoxically activate the Mycobacterium tuberculosis 20S CP at substoichiometric concentrations, revealing positive cooperativity between its {beta}-subunits. To dissect this cooperativity within the {beta}-ring, we co-assemble wild-type and catalytically inactive (T1A) {beta}-subunits into hybrid 20S CPs. We develop a probabilistic model relating bulk mixing ratios to the ensemble of hybrid 20S CP stoichiometries. Differential 15N-labelling of the wild-type subunits then resolves WT and T1A peptide signals by mass during HDX-MS, enabling subunit-resolved measurements within a single complex. Using this approach, we demonstrate that ligand binding at one {beta}-subunit remodels the conformational dynamics of binding-incompetent neighbours. Measuring deuterium uptake against ring composition identifies two allosteric routes: a lateral pathway from switch helix II to the active site of the adjacent intra-ring subunit, and an axial pathway connecting a loop at the {beta}-ring interface to the S pockets of the opposing ring. More broadly, this work establishes a framework for resolving symmetry-masked allostery in multi-subunit assemblies.