Pyrococcus furiosus alpha-amylase is stabilized by calcium and zinc.

The hyperthermophilic archeon Pyrococcus furiosus produces an extracellular alpha-amylase that belongs to glycosyl hydrolases' family 13. This enzyme is more thermostable than its bacterial and archaeal homologues (e.g., Bacillus licheniformis TAKA-term and Pyrococcus kodakaraensis KOD1 alpha-amylases, respectively) even without adding Ca(2+) ions. Unlike the TAKA-therm amylase that contains no cysteine, the P. furiosus enzyme contains five cysteines (C152, C153, C165, C387, and C430), only four of which (C152, C153, C387, and C430) are conserved in the P. kodakaraensis alpha-amylase. To test the potential function of cysteines in P. furiosus alpha-amylase stability, these five residues were substituted with Ser or Ala-either one-by-one or in sequence-to produce eight mutant enzymes. Mutation C165S dramatically destabilized P. furiosus alpha-amylase. At the same time, the quadruple mutant enzyme C152S/C153S/C387S/C430A (mutant SSCSA) was as thermostable as the wild-type enzyme. Mutant SSCSA and wild-type alpha-amylases were strongly destabilized by dithiothreitol and ethylenediaminetetraacetic acid, suggesting that metal binding can be involved in this enzyme's thermostability. Inductively coupled plasma-atomic emission spectrometry showed the presence of Ca(2+) and Zn(2+) metal ions in P. furiosus alpha-amylase. Although Ca(2+) is known to contribute to alpha-amylase's stability, the absence of two out of the three conserved Ca(2+) ligands in the P. furiosus enzyme suggests that a different set of amino acids is involved in this enzyme's Ca(2+) binding. We also provide evidence suggesting that Cys165 is involved in Zn(2+) binding and that Cys165 is essential for the stability of P. furiosus alpha-amylase at very high temperatures.