Hesperetin, one of the polyphenolic secondary metabolites in Citrus fruit, has a number of pharmacological and biological activities, such as ameliorating cardiac inflammation, increasing intact immunity systems, activities of anti-cancer. However, its application is restricted because of its low water solubility. In our previous studies, we found the enzyme, flavonoid phosphate synthetase isolated from B. subtilis BCRC 80517, can phosphorylate some selected flavonoid compounds to produce the correspoiding phosphate conjugates that are water-soluble. In this work, we investigated the biotransformation strategies of B. subtilis BCRC 80517 with hesperetin to produce water-soluble hesperetin phosphate conjugates. In the first part of this thesis, we experimented the feasibility of biotransformation of B.subtils BCRC 80517 with hesperetin, and identified the hesperetin derivates in culture broth. The results of biotransformation indicated that hesperetin 7-O-phosphate ([M+H]+m/z 383.06) and hesperetin 3’-O-phosphate ([M+H]+m/z 383.06) were the predominant products of biotransformation. Furthermore, we demonstrated some minor peaks of high-performance liquid chromatograms which were also related to the biotransformation of hesperetin 7-O-glucoside ([M+H] + m/z 465.15), hesperetin 3’-O-glucoside ([M+H] +m/z 465.15) and 6’’-O-succinyl hesperetin 7-O-glucoside ([M+H] + m/z 565.15) according to the corresponding spectra of UV absorption, ESI-MS/MS and NMR spectral. The minor hesperetin derivatives were also supposed to be water-soluble than hesperetin. With the growth of these peaks and decline during the biotransformation, we concluded that B. subtilis BCRC 80517 transforms hesperetin into hesperetin 7-O-phosphate and hesperetin 3’-O-phosphate majorly and into hesperetin 7-O-glucoside hesperetin 3’-O-glucoside and 6’’-O-succinyl hesperetin 7-O-glucoside inevitably with little amount. The water solubility at 25oC of hesperetin, H7P and H3’P were 40.2 mg/L, 2.6 x104 mg/L and 2.8 x 104 mg/L, respectively. The water solubility of hesperetin phosphate conjugates were 650 times higher than that of hesperetin. In the second part of this thesis, a fermentation process for H7P and H3’P production by Bacillus subtilis BCRC 80517 was successfully scaled up from 500 mL shake flask to 5 L stirred tank bioreactor. We have developed a fed batch fermentation strategy, which can decrease the inhibition effect of feeding hesperetin through the optimal time of feeding hesperetin substrate at OD600 = 4. The conversion rate of hesperetin phosphate conjugates was 84.1% and the biotransformed products were 18.7 g/L at the end of 40 h incubation time.