posted on 2022-03-22, 15:06authored byJan Abendroth, Garry W. Buchko, Fong Ning Liew, Joline N. Nguyen, Hyung J. Kim
The
ammonia-oxidizing bacterium Nitrosomonas europaea expresses two cytochromes in the P460 superfamily that are predicted
to be structurally similar. In one, cytochrome (cyt) P460, the substrate
hydroxylamine (NH2OH) is converted to nitric oxide (NO)
and nitrous oxide (N2O) requiring a unique heme-lysyl cross-link
in the catalytic cofactor. In the second, cyt c′β‐Met, the
cross-link is absent, and the cytochrome
instead binds H2O2 forming a ferryl species
similar to compound II of peroxidases. Here, we report the 1.80 Å
crystal structure of cyt c′β‐Meta well-expressed protein
in N. europaea with a lysine to a methionine
replacement
at the cross-linking position. The structure of cyt c′β‐Met is characterized by a large β-sheet
typical of P460 members; however, several localized structural differences
render cyt c′β‐Met distinct. This includes a large
lasso-like
loop at the “top” of the cytochrome that is not observed
in other structurally characterized members. Active site variation
is also observed, especially in comparison to its closest homologue
cyt c′β from the methane-oxidizing Methylococcus capsulatus Bath, which also lacks the
cross-link. The phenylalanine “cap” which is presumed
to control small ligand access to the distal heme iron is replaced
with an arginine, reminiscent of the strictly conserved distal arginine
in peroxidases and to the NH2OH-oxidizing cytochromes P460.
A critical proton-transferring glutamate residue required for NH2OH oxidation is nevertheless missing in the active site. This
in part explains the inability of cyt c′β‐Met to oxidize
NH2OH. Our structure
also rationalizes the absence of a methionyl cross-link, although
the side chain’s spatial position in the structure does not
eliminate the possibility that it could form under certain conditions.