Important roles of hydroxylic amino acid residues in the function of Bacillus subtilis adenylosuccinate lyase.

Thr(93), Ser(94), Thr(140), and Ser(306) are conserved in all adenylosuccinate lyases (ASL) and are close to other amino acids previously identified by mutagenesis as being in the active site. To test their involvement in the enzyme's function, each of these amino acids was replaced by alanine. All the mutants exhibit circular dichroism spectra which are similar to that of wild-type enzyme, indicating there is no appreciable change in secondary structure. T93A exhibits 0.5% of the V(max) of wild-type ASL with a 10-fold increase in K(m) for adenylosuccinate. S94A has 65% of the V(max) of wild-type ASL with little change in K(m). T140A exhibits 0.03% of the activity of wild-type enzyme with an 11-fold increase in K(m). S306A has 0.4% of the V(max) of wild-type ASL with a sevenfold increase in K(m). Measurements of the pH-V(max) profile reveal a pK(2) value for S94A of 7.83 and S306A of 7.65, in contrast to 8.24 for the wild-type enzyme and 8.42 for T93A. Thr(93) may orient adenylosuccinate optimally for catalysis, while Ser(94) stabilizes protonated His(89), a determinant of pK(2). Thr(140) may, through hydrogen bonding, interact with Asn(270), an amino acid essential for catalysis. Ser(306) may be involved in a hydrogen bond network that ultimately stabilizes protonated His(68), which is probably the general acid in the reaction of enzyme with substrate. The results of this paper demonstrate the importance in the catalytic function of ASL of hydrogen bonds and hydrogen bonding networks involving serine and threonine.