posted on 2019-03-11, 00:00authored byHannah
R. Rose, Ailiena O. Maggiolo, Molly J. McBride, Gavin M. Palowitch, Maria-Eirini Pandelia, Katherine M. Davis, Neela H. Yennawar, Amie K. Boal
Class
I ribonucleotide reductases (RNRs) share a common mechanism
of nucleotide reduction in a catalytic α subunit. All RNRs initiate
catalysis with a thiyl radical, generated in class I enzymes by a
metallocofactor in a separate β subunit. Class Id RNRs use a
simple mechanism of cofactor activation involving oxidation of a MnII2 cluster by free superoxide to yield a metal-based
MnIIIMnIV oxidant. This simple cofactor assembly
pathway suggests that class Id RNRs may be representative of the evolutionary
precursors to more complex class Ia–c enzymes. X-ray crystal
structures of two class Id α proteins from Flavobacterium
johnsoniae (Fj) and Actinobacillus
ureae (Au) reveal that this subunit is distinctly
small. The enzyme completely lacks common N-terminal ATP-cone allosteric
motifs that regulate overall activity, a process that normally occurs
by dATP-induced formation of inhibitory quaternary structures to prevent
productive β subunit association. Class Id RNR activity is insensitive
to dATP in the Fj and Au enzymes
evaluated here, as expected. However, the class Id α protein
from Fj adopts higher-order structures, detected
crystallographically and in solution. The Au enzyme
does not exhibit these quaternary forms. Our study reveals structural
similarity between bacterial class Id and eukaryotic class Ia α
subunits in conservation of an internal auxiliary domain. Our findings
with the Fj enzyme illustrate that nucleotide-independent
higher-order quaternary structures can form in simple RNRs with truncated
or missing allosteric motifs.