Allosteric regulation of ß-reaction stage I in tryptophan synthase upon the α-ligand binding.

ABSTRACT

Tryptophan synthase (TRPS) is a bifunctional enzyme consisting of α- and ß-subunits that catalyzes the last two steps of L-tryptophan (L-Trp) biosynthesis. The first stage of the reaction at the ß-subunit is called ß-reaction stage I, which converts the ß-ligand from an internal aldimine [E(Ain)] to an α-aminoacrylate [E(A-A)] intermediate. The activity is known to increase 3-10-fold upon the binding of 3-indole-D-glycerol-3'-phosphate (IGP) at the α-subunit. The effect of α-ligand binding on ß-reaction stage I at the distal ß-active site is not well understood despite the abundant structural information available for TRPS. Here, we investigate the ß-reaction stage I by carrying out minimum-energy pathway searches based on a hybrid quantum mechanics/molecular mechanics (QM/MM) model. The free-energy differences along the pathway are also examined using QM/MM umbrella sampling simulations with QM calculations at the B3LYP-D3/aug-cc-pVDZ level of theory. Our simulations suggest that the sidechain orientation of ßD305 near the ß-ligand likely plays an essential role in the allosteric regulation a hydrogen bond is formed between ßD305 and the ß-ligand in the absence of the α-ligand, prohibiting a smooth rotation of the hydroxyl group in the quinonoid intermediate, whereas the dihedral angle rotates smoothly after the hydrogen bond is switched from ßD305-ß-ligand to ßD305-ßR141. This switch could occur upon the IGP-binding at the α-subunit, as evidenced by the existing TRPS crystal structures.