Hub proteins organize large interactomes using their hub domains for protein-protein interactions. αα-hub domains are present in transcriptional regulators such as Sin3A, an integral scaffolding protein of histone deacetylation complexes. Here, we relate αα-hub stability to function by structural and thermodynamic studies of the Sin3A-PAH1 wild-type hub domain and two predicted loss-of-function variants (A126V and K155E) found in patients with the neurodevelopmental Witteveen-Kolk syndrome. For an αα-hub domain, the PAH1 domain is relatively stable with ΔGDN of 14.1 ± 0.9 kJ mol-1, which likely compromises its adaptability in binding, thereby increasing specificity. For the two known binding partners, Tet1 and SAP25, a sequence motif undergoes coupled folding and binding with Sin3A-PAH1. The SAP25-interaction shows prototypical thermodynamics for a disorder-based interaction with an enthalpy-driven interaction counteracted by an entropic penalty. In contrast, for the Tet1-interaction, there is no net contribution from entropy to binding, even when including a disordered context in the motif-containing Tet1 fragment. The variants of Sin3A-PAH1 exhibit lower affinities for both SAP25 and Tet1, with a >15-fold reduction in the affinity of PAH1-K155E for Tet1. Notably, the A126V side-chain substitution results in an increased global stability (ΔΔGDN 6.9 kJ mol-1), representing a case of increased stability associated with loss-of-function. Our findings show how disease-associated Sin3A-PAH1 variants can affect global domain stability and flexibility as well as interactions with specific partner proteins, thereby contributing to the deconvolution of signal fidelity governed by folded hubs in interactions with disordered partner proteins.
Due et al. (Sun,) studied this question.