posted on 2016-11-03, 00:00authored byDipanwita Batabyal, Ariel Lewis-Ballester, Syun-Ru Yeh, Thomas L. Poulos
The
camphor monooxygenase, cytochrome P450cam, exhibits a strict
requirement for its own redox partner, putidaredoxin (Pdx), a two-iron–sulfur
ferredoxin. The closest homologue to P450cam, CYP101D1, is structurally
very similar, uses a similar redox partner, and exhibits nearly identical
enzymatic properties in the monooxygenation of camphor to give the
same single 5-exo-hydroxy camphor product. However,
CYP101D1 does not strictly require its own ferredoxin (Arx) for activity
because Pdx can support CYP101D1 catalysis but Arx cannot support
P450cam catalysis. We have further examined the differences between
these two P450s by determining the effect of spin equilibrium, redox
properties, and stability of oxygen complexes. We find that Arx shifts
the spin state equilibrium toward high-spin, which is the opposite
of the effect of Pdx on P450cam. In both P450s, redox partner binding
destabilizes the oxy–P450 complex but this effect is much weaker
with CYP101D1. In addition, resonance Raman data show that structural
perturbations observed in P450cam upon addition of Pdx are absent
in CYP101D1. These data indicate that Arx does not play the same effector
role in catalysis as Pdx does with P450cam. The most relevant structural
difference between these two P450s centers on a catalytically important
Asp residue required for proton-coupled electron transfer. We postulate
that with P450cam larger Pdx-assisted motions are required to free
this Asp for catalysis while the smaller number of restrictions in
CYP101D1 precludes the need for redox partner-assisted structural
changes.