Exploring Selectivity and Hysteresis Kinetic Studies on a Potato Epoxide Hydrolase

Detta är en avhandling från Uppsala : Acta Universitatis Upsaliensis

Sammanfattning: The kinetic mechanism of an ?/? hydrolase fold epoxide hydrolase from potato, StEH1, has been studied with the aims of explaining the underlying causes for enantio- and regioselectivity, both being important for product purity. Further effort has been laid upon understanding the causes of a hysteretic behavior discovered in the measurements leading to Paper I.The enantioselectivity was investigated with substrates differing only in substituent size at one carbon of the oxirane ring structure. In catalysis with trans-stilbene oxide and styrene oxide, enantioselectivity is the result of differences in alkylation rates.In pre-steady state measurement with trans-2-methylstyrene oxide (2-MeSO), a rate-limiting step involving slow transitions, referred to as hysteresis, was discovered. With this substrate enantioselectivity is proposed to be a consequence of the catalytic rate of (1R,2R)-enantiomer being more influenced by the hysteretic behavior than was the rate of the other enantiomer.In steady-state measurements with (1R,2R)-2-MeSO, at different temperatures and pH, hysteretic cooperativity was displayed. It can be concluded that this behavior is dependent on the relationship between kcat and the rate of transition between two Michaelis complexes. From the differences in pH dependence of kcat/KM in formation of the two diols resulting from low regioselectivity in catalysis of (1R,2R)-2-MeSO, it is suggested that hysteresis is a result of the substrates placed in different conformational modes within the active site cavity.Regioselectivity is proposed to be the result of specific interactions between the catalytically important Tyr and the substrate, with a link between KM-values and degree of regioselectivity. Furthermore, the hysteretic kinetic model proposed can explain hysteresis, cooperativity and regioselectivity resulting from StEH1 catalyzed hydrolysis of (1R,2R)-2-MeSO.