posted on 2015-03-10, 00:00authored byJeremiah
N. Betz, Nicholas W. Boswell, Corey J. Fugate, Gemma L. Holliday, Eyal Akiva, Anna G. Scott, Patricia C. Babbitt, John W. Peters, Eric M. Shepard, Joan B. Broderick
HydE and HydG are radical S-adenosyl-l-methionine enzymes required for the
maturation of [FeFe]-hydrogenase
(HydA) and produce the nonprotein organic ligands characteristic of
its unique catalytic cluster. The catalytic cluster of HydA (the H-cluster)
is a typical [4Fe-4S] cubane bridged to a 2Fe-subcluster that contains
two carbon monoxides, three cyanides, and a bridging dithiomethylamine
as ligands. While recent studies have shed light on the nature of
diatomic ligand biosynthesis by HydG, little information exists on
the function of HydE. Herein, we present biochemical, spectroscopic,
bioinformatic, and molecular modeling data that together map the active
site and provide significant insight into the role of HydE in H-cluster
biosynthesis. Electron paramagnetic resonance and UV–visible
spectroscopic studies demonstrate that reconstituted HydE binds two
[4Fe-4S] clusters and copurifies with S-adenosyl-l-methionine. Incorporation of deuterium from D2O
into 5′-deoxyadenosine, the cleavage product of S-adenosyl-l-methionine, coupled with molecular docking experiments
suggests that the HydE substrate contains a thiol functional group.
This information, along with HydE sequence similarity and genome context
networks, has allowed us to redefine the presumed mechanism for HydE
away from BioB-like sulfur insertion chemistry; these data collectively
suggest that the source of the sulfur atoms in the dithiomethylamine
bridge of the H-cluster is likely derived from HydE’s thiol
containing substrate.