3d) At 60 °C, after incubation for 1 h, the surface-displayed ph

3d). At 60 °C, after incubation for 1 h, the surface-displayed phytase retained approximately 45% activity (Fig. 3d), Compound Library price whereas the secreted phytase retained approximately 80% activity (Promdonkoy et al., 2009). Although the thermostability exhibited by the surface-displayed phytase is lower than that of the native or secreted

phytase, this lower thermostability could be completely circumvented when the cell-surface phytase was mixed with feedstuff. The lower thermostability of cell-surface-displayed enzyme compared with secreted enzyme has also been observed for lipase LipY7p and LipY8p expressed on the cell surface of P. pastoris (Jiang et al., 2007). After heat treatment, cell debris was observed in those samples harboring immobilized lipases, implying that yeast cells were fractured by heat treatment. The lower thermostability may be due, in part, to steric hindrance with the α-agglutinin domain, which may interfere with phytase structure. Inserting a linker

region between phytase and the α-agglutinin domain may help circumvent ERK inhibitor nmr this problem. However, because other characteristics of the cell-surface-displayed phytase (such as its temperature and pH optimum) are similar to those of native enzymes and free enzymes, it is unlikely that the α-agglutinin domain interferes with phytase function at the catalytic domain. Protease susceptibility analysis revealed that rPhyA170-agg was resistant to pepsin at least up to a cell wet weight : pepsin

ratio of 1 : 1, as phytase activity was unchanged, whereas phytase was resistant to trypsin at cell wet weight : trypsin ratio of 200 : 1 or higher (data not shown). These protease Inositol oxygenase resistance properties suggest that the cell-surface phytase can function in the presence of protease, especially pepsin. In vitro digestibility tests were performed to investigate the ability of the recombinant phytase to digest phytic acid in corn-based feedstuff in the presence of pepsin and pancreatin. The amount of phosphate released from feedstuff mixed with celPhyA170-agg cells was compared with that from feedstuff mixed with the secreted phytase r-PhyA170 (Fig. 4a). No significant difference was observed in the amounts of phosphate released from either mixture, demonstrating that the cell-surface-displayed phytase can function as well as the secreted phytase, which in turn was previously shown to function similarly to existing commercial phytase (Natuphos, BASF; Promdonkoy et al., 2009). In addition, although cell-surface-displayed phytase exhibits lower thermostability than the secreted phytase in the absence of stabilizer, when celPhyA170-agg cells were mixed with feedstuff before heat treatment simulating the pelleting process (3 min at 80 °C or 5 min at 90 °C), the amount of phosphate released was similar to the amount released by the secreted phytase (Fig. 4b).

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