CDP-Chase, a CDP-Choline Pyrophosphatase, is a Member of a Novel Nudix Family in Gram-Positive Bacteria

A Nudix enzyme from Bacillus cereus, CDP-Chase, acts as a CDP-choline pyrophosphatase, hydrolyzing the phosphoanhydride bond of CDP-choline to produce CMP and phosphocholine. The structure of the free enzyme, determined to 1.8 A resolution, shows that the enzyme is an asymmetric dimer. Each monomer consists of two domains, an N-terminal helical domain and a C-terminal Nudix domain. The N-terminal domain is placed relative to the C-terminal domain in such a way that produces an overall asymmetry. Residues that may be important for determining the asymmetry are conserved among a group of uncharacterized Nudix enzymes from Gram-positive bacteria. In addition to its Nudix activity, the enzyme has a 3’ to 5’ RNA exonuclease activity. This alternative activity appears to be facilitated by the asymmetry in the protein as the position of the N-terminal domain results in differences in the exposure of the two enzyme active sites. Two single-site mutations, E112A and E163A, were characterized to further investigate the mechanism of the enzyme. E112 is involved in the coordination of catalytic metals in both active sites, and E163 is only in close proximity in one of the active sites. Both mutations abolish CDP-choline pyrophosphatase activity but E112A has a much more profound effect on RNase activity, supporting a model where CDP-choline hydrolysis is catalyzed by one active site of the dimer and RNA exonuclease activity is catalyzed by the other. These data suggest that CDP-Chase is a member of a novel Nudix family in which structural asymmetry has a profound effect on the recognition of substrates by the Nudix enzymatic machinery.