The recombinant thermostable direct hemolysin from Grimontia hollisae (G.h-rTDH) exhibited an “Arrhenius effect”, from which it was detoxified by heating at approximately 60-70oC, but reactivated its functional activity by additional heating above 80oC, coupled with a rapid cooling treatment. In order to characterize this paradoxical phenomenon, we compared the tdh gene from the difference species of Grimontia hollisae listed in a database and used sequence alignment to identify the critical residues. In addition, we used site-directed mutagenesis to construct the corresponding TDH mutants and obtained various mutated proteins via chromatographic purification. In this study herein, we investigated the individual or collective mutational effect on Tyr53, Thr59, and Ser63 positions of G.h-rTDH to characterize the Arrhenius effect, hemolytic activity, and the biophysical properties of various mutants, respectively. In contrast to the G.h-rTDH wild-type (G.h-rTDHWT) protein, no Arrhenius effect was detected from the G.h-rTDHY53H/T59I and G.h-rTDHT59I/S63T double-mutants, as well as the G.h-rTDHY53H/T59I/S63T triple-mutant. These mutants also exhibited a different hemolytic activity compared to that observed for the G.h-rTDHWT protein. The differential scanning calorimetry (DSC) results consistently showed that the Arrhenius effect-losing and -retaining mutants exhibited higher and lower endothermic transition temperatures (Tm) than that of the G.h-rTDHWT, respectively. Circular dichroism (CD) measurements indicated the partial decrease of β–sheet structures near the endothermic transition temperature, consistent with the conformational change of the Arrhenius effect-losing and -retaining protein. Moreover, we also evaluated its toxic effects by assessing their cytotoxic activities against in AGS cells.