Abstract
All living things have pyrophosphatases that hydrolyze pyrophosphate and release energy. This energetically favorable reaction drives many energetically unfavorable reactions. An accepted catalytic model of pyrophosphatase shows that a water molecule activated by two divalent cations (M1 and M2) within the catalytic center can attack pyrophosphate in an SN2 mechanism and thus hydrolyze the molecule. However, our co-crystal structure of Acinetobacter baumannii pyrophosphatase with pyrophosphate shows that a water molecule from the solvent may, in fact, be the actual catalytic water. In the co-crystal structure of the wild-type pyrophosphatase with pyrophosphate, the electron density of the catalytic centers of each monomer are different from one another. This indicates that pyrophosphates in the catalytic center are dynamic. Our mass spectroscopy results have identified a highly conserved lysine residue (Lys30) in the catalytic center that is phosphorylated, indicating that the enzyme could form a phosphoryl enzyme intermediate during hydrolysis. Mutation of Lys30 to Arg abolished the activity of the enzyme. In the structure of the apo wild type enzyme, we observed that a Na+ ion is coordinated by residues within a loop proximal to the catalytic center. Therefore, we mutated three key residues within the loop (K143R, P147G, and K149R) and determined Na+ and K+-induced inhibition on their activities. Compared to the wild type enzyme, P147G is most sensitive to these cations, whereas K143R was inactive and K149R showed no change in activity. These data indicate that monovalent cations could play a role in down-regulating pyrophosphatase activity in vivo. Overall, our results reveal new aspects of pyrophosphatase catalysis and could assist in the design of specific inhibitors of Acinetobacter baumannii growth.
Highlights
Pyrophosphate (PPi) is essential to several key metabolic steps, including the synthesis of DNA [1], carbohydrates, lipids, as well as lipid degradation [2]
The crystal structures of Acinetobacter PPase (AbPPase) showed that the enzyme has a typical Rossman fold domain that is highly conserved compared to other PPases [13,22,23]
3 of 18 3 of 18 we identified one Mg2+ (M1) bound to the catalytic center, and a Na+ bound to a loop w(reesiiddeuneti1fi4e3d–1n4o9t) oclnolsyeotnoethMegc2a+ta(lMyt1ic) cbeonutnerd(tFoigtuhreec1aAta)l.ytic center, and a Na+ bound to a loop close to theTacbalteal1y.tDicactaencotellrec(tFioignuarned1rAef)i.nement statistics
Summary
Pyrophosphate (PPi) is essential to several key metabolic steps, including the synthesis of DNA [1], carbohydrates, lipids, as well as lipid degradation [2]. Because PPi is stable under normal conditions [4], inorganic pyrophosphatase (PPase) has evolved to hydrolysis the molecule [5]. In bacteria, knocking-out PPase leads to the accumulation of PPi in the cytoplasm, and inhibits growth [6,7]. I PPase is an abundant protein in yeast and bacteria [9,10,11]. These enzymes could be directly purified from hosts and be crystallized [12,13]. Specific chemical modifications of PPases indicate that some unidentified tyrosines and lysines are critical for PPase activity [19,20,21], and CD spectra show that modification of these residues does not greatly change the global fold of the enzyme [21]
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