RESUMO
One of the seven natural CO2 fixation pathways, the anaerobic Wood-Ljungdahl pathway (WLP) is unique in generating CO as a metabolic intermediate, operating through organometallic intermediates, and in conserving (versus utilizing) net ATP. The key enzyme in the WLP is acetyl-CoA synthase (ACS), which uses an active site [2Ni-4Fe-4S] cluster (A-cluster), a CO tunnel, and an organometallic (Ni-CO, Ni-methyl, and Ni-acetyl) reaction sequence to generate acetyl-CoA. Here, we reveal that an alcove, which interfaces the tunnel and the A-cluster, is essential for CO2 fixation and autotrophic growth by the WLP. In vitro spectroscopy, kinetics, binding, and in vivo growth experiments reveal that a Phe229A substitution at one wall of the alcove decreases CO affinity thirty-fold and abolishes autotrophic growth; however, a F229W substitution enhances CO binding 80-fold. Our results indicate that the structure of the alcove is exquisitely tuned to concentrate CO near the A-cluster; protect ACS from CO loss during catalysis, provide a haven for inhibitory CO, and stabilize the tetrahedral coordination at the Nip site where CO binds. The directing, concentrating, and protective effects of the alcove explain the inability of F209A to grow autotrophically. The alcove also could help explain current controversies over whether ACS binds CO and methyl through a random or ordered mechanism. Our work redefines what we historically refer to as the metallocenter "active site". The alcove is so crucial for enzymatic function that we propose it is part of the active site. The community should now look for such alcoves in all "gas handling" metalloenzymes.
RESUMO
We have investigated the kinetics of NAD+-dependent NADPH:ferredoxin oxidoreductase (NfnI), a bifurcating transhydrogenase that takes two electron pairs from NADPH to reduce two ferredoxins and one NAD+ through successive bifurcation events. NADPH reduction takes place at the bifurcating FAD of NfnI's large subunit, with high-potential electrons transferred to the [2Fe-2S] cluster and S-FADH of the small subunit, ultimately on to NAD+; low-potential electrons are transferred to two [4Fe-4S] clusters of the large subunit and on to ferredoxin. Reduction of NfnI by NADPH goes to completion only at higher pH, with a limiting kred of 36 ± 1.6 s-1 and apparent KdNADPH of 5 ± 1.2 µM. Reduction of one of the [4Fe-4S] clusters of NfnI occurs within a second, indicating that in the absence of NAD+, the system can bifurcate and generate low-potential electrons without NAD+. When enzyme is reduced by NADPH in the absence of NAD+ but the presence of ferredoxin, up to three equivalents of ferredoxin become reduced, although the reaction is considerably slower than seen during steady-state turnover. Bifurcation appears to be limited by transfer of the first, high-potential electron into the high-potential pathway. Ferredoxin reduction without NAD+ demonstrates that electron bifurcation is an intrinsic property of the bifurcating FAD and is not dependent on the simultaneous presence of NAD+ and ferredoxin. The tight coupling between NAD+ and ferredoxin reduction observed under multiple-turnover conditions is instead simply due to the need to remove reducing equivalents from the high-potential electron pathway under multiple-turnover conditions.