Structural basis of nearest-neighbor cooperativity in the ring-shaped gene regulatory protein TRAP from protein engineering and cryo-EM.

Homotropic cooperativity is widespread in biological regulation. The homo-oligomeric ring-shaped trp RNA binding attenuation protein (TRAP) from bacillus binds multiple tryptophan ligands (Trp) and becomes activated to bind a specific sequence in the 5' leader region of the trp operon mRNA. Ligand-activated binding to this specific RNA sequence regulates downstream biosynthesis of Trp in a feedback loop. Characterized TRAP variants form 11- or 12-mer rings and bind Trp at the interface between adjacent subunits. Various studies have shown that a pair of loops that gate each Trp binding site is flexible in the absence of the ligand and become ordered upon ligand binding. Thermodynamic measurements of Trp binding have revealed a range of cooperative behavior for different TRAP variants, even if the averaged apparent affinities for Trp have been found to be similar. Proximity between the ligand binding sites, and the ligand-coupled disorder-to-order transition has implicated nearest-neighbor interactions in cooperativity. To establish a solid basis for describing nearest-neighbor cooperativity we engineered dodecameric (12-mer) TRAP variants constructed with two subunits connected by a flexible linker (dTRAP). We mutated one of the protomers such that only every other site was competent for Trp binding. Thermodynamic and structural studies using native mass spectrometry, NMR spectroscopy, and cryo-EM provided unprecedented detail into the thermodynamic and structural basis for the observed ligand binding cooperativity. Such insights can be useful for understanding allosteric control networks and for the development of new ones with defined ligand sensitivity and regulatory control.

Thermodynamic coupling between neighboring binding sites in homo-oligomeric ligand sensing proteins from mass resolved ligand-dependent population distributions.

Homo-oligomeric ligand-activated proteins are ubiquitous in biology. The functions of such molecules are commonly regulated by allosteric coupling between ligand-binding sites. Understanding the basis for this regulation requires both quantifying the free energy ΔG transduced between sites, and the structural basis by which it is transduced. We consider allostery in three variants of the model ring-shaped homo-oligomeric trp RNA-binding attenuation protein (TRAP). First, we developed a nearest-neighbor statistical thermodynamic binding model comprising microscopic free energies for ligand binding to isolated sites ΔG0 , and for coupling between adjacent sites, ΔGα . Using the resulting partition function (PF) we explored the effects of these parameters on simulated population distributions for the 2N possible liganded states. We then experimentally monitored ligand-dependent population shifts using conventional spectroscopic and calorimetric methods and using native mass spectrometry (MS). By resolving species with differing numbers of bound ligands by their mass, native MS revealed striking differences in their ligand-dependent population shifts. Fitting the populations to a binding polynomial derived from the PF yielded coupling free energy terms corresponding to orders of magnitude differences in cooperativity. Uniquely, this approach predicts which of the possible 2N liganded states are populated at different ligand concentrations, providing necessary insights into regulation. The combination of statistical thermodynamic modeling with native MS may provide the thermodynamic foundation for a meaningful understanding of the structure-thermodynamic linkage that drives cooperativity.