Electron spin-labelling of the EutC subunit in B12-dependent ethanolamine ammonia-lyase reveals dynamics and a two-state conformational equilibrium in the N-terminal, signal-sequence-associated domain.

The B12 (adenosylcobalamin)-dependent ethanolamine ammonia-lyase (EAL) is a product of the ethanolamine utilisation (eut) gene cluster, that is involved in human gut microbiome homeostasis and in disease conditions caused by pathogenic strains of Salmonella and Escherichia coli. Toward elucidation of the molecular basis of EAL catalysis, and its intracellular trafficking and targeting to the Eut biomicrocompartment (BMC), we have applied electron spin-labelling and electron paramagnetic resonance spectroscopy to wild-type (wt) EAL from Salmonella typhimurium, by using the sulphydryl-specific, 4-maleimido-TEMPO (4MT) spin label. One cysteine residue per active site displays exceptional reactivity with 4MT. This site is identified as ßC37 on the EutC subunit, by using 4MT-labeling of site-specific cysteine-to-alanine mutants, enzyme kinetics, and accessible surface area calculations. Electron paramagnetic resonance (EPR) spectra of 4MT-labelled wt EAL are collected over 200-265 K in frozen, polycrystalline water-only, and 1% v/v DMSO solvents. EPR simulations reveal two mobility components for each condition. Detectable spin probe reorientational motion of the two components occurs at 215 and 225 K with 1% v/v DMSO, relative to the water-only condition, consistent with formation of an aqueous-DMSO solvent mesodomain around EAL. Parallel trends in fast- and slow-reorientational correlation times and interconversion of the two populations with increasing temperature, indicate 4MT labelling of a single site (ßC37). A two-state model is proposed, in which the fast and slow motional populations represent EAL-bound and free conformations of the EutC N-terminal domain. The approximately equal proportion of each state may represent a balance between EutC and EAL protein stability and efficient targeting to the BMC.

Cobinamide production of hydrogen in a homogeneous aqueous photochemical system, and assembly and photoreduction in a (ßα)8 protein.

Components of a protein-integrated, earth-abundant metal macrocycle catalyst, with the purpose of H2 production from aqueous protons under green conditions, are characterized. The cobalt-corrin complex, cobinamide, is demonstrated to produce H2 (4.4 ± 1.8 × 10(-3) turnover number per hour) in a homogeneous, photosensitizer/sacrificial electron donor system in pure water at neutral pH. Turnover is proposed to be limited by the relatively low population of the gateway cobalt(III) hydride species. A heterolytic mechanism for H2 production from the cobalt(II) hydride is proposed. Two essential requirements for assembly of a functional protein-catalyst complex are demonstrated for interaction of cobinamide with the (ßα)8 TIM barrel protein, EutB, from the adenosylcobalamin-dependent ethanolamine ammonia lyase from Salmonella typhimurium: (1) high-affinity equilibrium binding of the cobinamide (dissociation constant 2.1 × 10(-7) M) and (2) in situ photoreduction of the cobinamide-protein complex to the Co(I) state. Molecular modeling of the cobinamide-EutB interaction shows that these features arise from specific hydrogen-bond and apolar interactions of the protein with the alkylamide substituents and the ring of the corrin, and accessibility of the binding site to the solution. The results establish cobinamide-EutB as a platform for design and engineering of a robust H2 production metallocatalyst that operates under green conditions and uses the advantages of the protein as a tunable medium and material support.