Abstract

Family II inorganic pyrophosphatases (PPases) constitute a new evolutionary group of PPases, with a different fold and mechanism than the common family I enzyme; they are related to the “DHH” family of phosphoesterases. Biochemical studies have shown that Mn2+ and Co2+ preferentially activate family II PPases; Mg2+ partially activates; and Zn2+ can either activate or inhibit (Zyryanov et al., Biochemistry, 43, 14395−14402, accompanying paper in this issue). The three solved family II PPase structures did not explain the differences between the PPase families nor the metal ion differences described above. We therefore solved three new family II PPase structures: Bacillus subtilis PPase (Bs-PPase) dimer core bound to Mn2+ at 1.3 Å resolution, and, at 2.05 Å resolution, metal-free Bs-PPase and Streptococcus gordonii (Sg-PPase) containing sulfate and Zn2+. Comparison of the new and old structures of various family II PPases demonstrates why the family II enzyme prefers Mn2+ or Co2+, as an activator rather than Mg2+. Both M1 and M2 undergo significant changes upon substrate binding, changing from five-coordinate to octahedral geometry. Mn2+ and Co2+, which readily adopt different coordination states and geometries, are thus favored. Combining our structures with biochemical data, we identified M2 as the high-affinity metal site. Zn2+ activates in the M1 site, where octahedral geometry is not essential for catalysis, but inhibits in the M2 site, because it is unable to assume octahedral geometry but remains trigonal bipyramidal. Finally, we propose that Lys205−Gln81−Gln80 form a hydrophilic channel to speed product release from the active site.