Improved Thermal Stability of a Novel Acidophilic Phytase.

Phytase increases the availability of phosphate and trace elements by hydrolyzing the phosphomonoester bond in phytate present in animal feed. It is also an important enzyme from an environmental perspective because it not only promotes the growth of livestocks but also prevents phosphorus contamination released into the environment. Here we present a novel phytase derived from Turicimonas muris, TmPhy, which has distinctive structure and properties compared to other previously known phytases. TmPhy gene expressed in the Pichia system was confirmed to be 41 kDa in size and was used in purified form to evaluate optimal conditions for maximum activity. TmPhy has a dual optimum pH at pH3 and pH6.8 and exhibited the highest activity at 70°C. However, the heat tolerance of the wildtype was not satisfactory for feed application. Therefore, random mutation, disulfide bond introduction, and N-terminal mutation were performed to improve the thermostability of the TmPhy. Random mutation resulted in TmPhyM with about 45% improvement in stability at 60°C. Through further improvements, a total of three mutants were screened and their heat tolerance was evaluated. As a result, we obtained TmPhyMD1 with 46.5% residual activity, TmPhyMD2 with 74.1%, and TmPhyMD3 with 66.8% at 80°C heat treatment without significant loss of or with increased activity.

Mutation of a conserved tryptophan residue in the CBM3c of a GH9 endoglucanase inhibits activity.

The presence of the family of 3c cellulose binding module (CBM3c) is important for the catalytic activity of family 9 endoglucanases such as the EngZ from Clostridium cellulovorans. To determine the role of CBM3c in catalytic activity, we made a tryptophan to alanine substitution because tryptophan can bind strongly to both substrates and other amino acids. The conserved tryptophan substitution (W483A) did not influence substrate binding, but it reduced enzyme activity to 10-14% on both amorphous and crystalline cellulose. CBM3c is directly involved in the endoglucanase reaction independent of substrate binding. EngZ W483A was also inactivated independent of substrate concentrations. Specially, EngZ W483A restored its catalytic base activity (31.6±1.2U/nM) which is similar to the wild-type (29.4±0.3U/nM) on Avicel in the presence of 50mM sodium azide which is instead of catalytic base reaction. These results suggest that CBM3c is deeply involved in the cellulolytic reaction, specifically at the catalytic base region. Moreover, EngZ W483A was also easily denatured by DTT, an outer disulfide bond breaker, compared to the wild-type. CBM3c could influence the surface stability. These features of CBM3c result from the hydrophobic interaction of tryptophan with the catalytic domain that is unrelated to substrate binding.