Allostery and substrate channeling in the tryptophan synthase bienzyme complex: evidence for two subunit conformations and four quaternary states.

The allosteric regulation of substrate channeling in tryptophan synthase involves ligand-mediated allosteric signaling that switches the α- and ß-subunits between open (low activity) and closed (high activity) conformations. This switching prevents the escape of the common intermediate, indole, and synchronizes the α- and ß-catalytic cycles. (19)F NMR studies of bound α-site substrate analogues, N-(4'-trifluoromethoxybenzoyl)-2-aminoethyl phosphate (F6) and N-(4'-trifluoromethoxybenzenesulfonyl)-2-aminoethyl phosphate (F9), were found to be sensitive NMR probes of ß-subunit conformation. Both the internal and external aldimine F6 complexes gave a single bound peak at the same chemical shift, while α-aminoacrylate and quinonoid F6 complexes all gave a different bound peak shifted by +1.07 ppm. The F9 complexes exhibited similar behavior, but with a corresponding shift of -0.12 ppm. X-ray crystal structures show the F6 and F9 CF3 groups located at the α-ß subunit interface and report changes in both the ligand conformation and the surrounding protein microenvironment. Ab initio computational modeling suggests that the change in (19)F chemical shift results primarily from changes in the α-site ligand conformation. Structures of α-aminoacrylate F6 and F9 complexes and quinonoid F6 and F9 complexes show the α- and ß-subunits have closed conformations wherein access of ligands into the α- and ß-sites from solution is blocked. Internal and external aldimine structures show the α- and ß-subunits with closed and open global conformations, respectively. These results establish that ß-subunits exist in two global conformational states, designated open, where the ß-sites are freely accessible to substrates, and closed, where the ß-site portal into solution is blocked. Switching between these conformations is critically important for the αß-catalytic cycle.

Activation of the retroviral budding factor ALIX.

The cellular ALIX protein functions within the ESCRT pathway to facilitate intralumenal endosomal vesicle formation, the abscission stage of cytokinesis, and enveloped virus budding. Here, we report that the C-terminal proline-rich region (PRR) of ALIX folds back against the upstream domains and auto-inhibits V domain binding to viral late domains. Mutations designed to destabilize the closed conformation of the V domain opened the V domain, increased ALIX membrane association, and enhanced virus budding. These observations support a model in which ALIX activation requires dissociation of the autoinhibitory PRR and opening of the V domain arms.

Tryptophan synthase: structure and function of the monovalent cation site.

The monovalent cation (MVC) site of the tryptophan synthase from Salmonella typhimurium plays essential roles in catalysis and in the regulation of substrate channeling. In vitro, MVCs affect the equilibrium distribution of intermediates formed in the reaction of l-Ser with the alpha(2)beta(2) complex; the MVC-free, Cs(+)-bound, and NH(4)(+)-bound enzymes stabilize the alpha-aminoacrylate species, E(A-A), while Na(+) binding stabilizes the l-Ser external aldimine species, E(Aex(1)). Two probes of beta-site reactivity and conformation were used herein, the reactive indole analogue, indoline, and the l-Trp analogue, l-His. MVC-bound E(A-A) reacts rapidly with indoline to give the indoline quinonoid species, E(Q)(indoline), which slowly converts to dihydroiso-l-tryptophan. MVC-free E(A-A) gives very little E(Q)(indoline), and turnover is strongly impaired; the fraction of E(Q)(indoline) formed is <3.5% of that given by the Na(+)-bound form. The reaction of l-Ser with the MVC-free internal aldimine species, E(Ain), initially gives small amounts of an active E(A-A) which converts to an inactive species on a slower, conformational, time scale. This inactivation is abolished by the binding of MVCs. The inactive E(A-A) appears to have a closed beta-subunit conformation with an altered substrate binding site that is different from the known conformations of tryptophan synthase. Reaction of l-His with E(Ain) gives an equilibrating mixture of external aldimine and quinonoid species, E(Aex)(his) and E(Q)(his). The MVC-free and Na(+) forms of the enzyme gave trace amounts of E(Q)(his) ( approximately 1% of the beta-sites). The Cs(+) and NH(4)(+) forms gave approximately 17 and approximately 14%, respectively. The reactivity of MVC-free E(Ain) was restored by the binding of an alpha-site ligand. These studies show MVCs and alpha-site ligands act synergistically to modulate the switching of the beta-subunit from the open to the closed conformation, and this switching is crucial to the regulation of beta-site catalytic activity. Comparison of the structures of Na(+) and Cs(+) forms of the enzyme shows Cs(+) favors complexes with open indole binding sites poised for the conformational transition to the closed state, whereas the Na(+) form does not. The beta-subunits of Cs(+) complexes exhibit preformed indole subsites; the indole subsites of the open Na(+) complexes are collapsed, distorted, and too small to accommodate indole.