RESUMEN
The molybdenum storage protein (MoSto) deposits large amounts of molybdenum as polyoxomolybdate clusters in a heterohexameric (αß)3 cage-like protein complex under ATP consumption. Here, we suggest a unique mechanism for the ATP-powered molybdate pumping process based on X-ray crystallography, cryoelectron microscopy, hydrogen-deuterium exchange mass spectrometry, and mutational studies of MoSto from Azotobacter vinelandii. First, we show that molybdate, ATP, and Mg2+ consecutively bind into the open ATP-binding groove of the ß-subunit, which thereafter becomes tightly locked by fixing the previously disordered N-terminal arm of the α-subunit over the ß-ATP. Next, we propose a nucleophilic attack of molybdate onto the γ-phosphate of ß-ATP, analogous to the similar reaction of the structurally related UMP kinase. The formed instable phosphoric-molybdic anhydride becomes immediately hydrolyzed and, according to the current data, the released and accelerated molybdate is pressed through the cage wall, presumably by turning aside the Metß149 side chain. A structural comparison between MoSto and UMP kinase provides valuable insight into how an enzyme is converted into a molecular machine during evolution. The postulated direct conversion of chemical energy into kinetic energy via an activating molybdate kinase and an exothermic pyrophosphatase reaction to overcome a proteinous barrier represents a novelty in ATP-fueled biochemistry, because normally, ATP hydrolysis initiates large-scale conformational changes to drive a distant process.
RESUMEN
Nicotinamide nucleotide transhydrogenases are integral membrane proteins that utilizes the proton motive force to reduce NADP+ to NADPH while converting NADH to NAD+. Atomic structures of various transhydrogenases in different ligand-bound states have become available, and it is clear that the molecular mechanism involves major conformational changes. Here we utilized hydrogen/deuterium exchange mass spectrometry (HDX-MS) to map ligand binding sites and analyzed the structural dynamics of E. coli transhydrogenase. We found different allosteric effects on the protein depending on the bound ligand (NAD+, NADH, NADP+, NADPH). The binding of either NADP+ or NADPH to domain III had pronounced effects on the transmembrane helices comprising the proton-conducting channel in domain II. We also made use of cyclic ion mobility separation mass spectrometry (cyclic IMS-MS) to maximize coverage and sensitivity in the transmembrane domain, showing for the first time that this technique can be used for HDX-MS studies. Using cyclic IMS-MS, we increased sequence coverage from 68 % to 73 % in the transmembrane segments. Taken together, our results provide important new insights into the transhydrogenase reaction cycle and demonstrate the benefit of this new technique for HDX-MS to study ligand binding and conformational dynamics in membrane proteins.
RESUMEN
Flavin-based electron bifurcation (FBEB) is a novel mechanism of energy coupling used by anaerobic microorganisms to optimize their energy metabolism efficiency. The first high-resolution structure of a complete FBEB enzyme complex, the NADH-dependent reduced ferredoxin: NADP+ -oxidoreductase (NfnAB) of Thermotoga maritima, was recently solved. However, no experimental evidence for the NADPH-binding site and conformational changes during the FBEB reaction are available. Here we analyzed ligand binding and the conformational dynamics of oxygen-sensitive NfnAB using Hydrogen-Deuterium Exchange Mass-Spectrometry, including a customized anaerobic workflow. We confirmed the NADH and the previously postulated NADPH-binding site. Furthermore, we observed an NfnA-NfnB rearrangement upon NADPH binding which supports the proposed FBEB mechanism.