Lee Pyung-Gang, Kim Joonwon, Kim Eun-Jung, Lee Sang-Hyuk, Choi Kwon-Young, Kazlauskas Romas J, Kim Byung-Gee
School of Chemical and Biological Engineering, Institute of Engineering Research, Seoul National University , Seoul, Republic of Korea.
Institute of Molecular Biology and Genetics, Seoul National University , Seoul, Republic of Korea.
ACS Chem Biol. 2017 Nov 17;12(11):2883-2890. doi: 10.1021/acschembio.7b00624. Epub 2017 Oct 23.
Equols are isoflavandiols formed by reduction of soy isoflavones such as daidzein and genistein by gut microorganisms. These phytoestrogens are of interest for their various biological effects. We report biosynthesis from genistein to (-)-5-hydroxy-equol in recombinant E. coli expressing three reductases (daidzein reductase DZNR, dihidrodaidzein reductase DHDR, tetrahydrodaidzein reductase THDR) and a racemase (dihydrodaidzein racemase, DDRC) originating from the gut bacterium, Slackia isoflavoniconvertens. The biosynthesized 5-hydroxy-equol proved as an optically negative enantiomer, nonetheless it displayed an inverse circular dichroism spectrum to (S)-equol. Compartmentalized expression of DZNR and DDRC in one E. coli strain and DHDR and THDR in another increased the yield to 230 mg/L and the productivity to 38 mg/L/h. If the last reductase was missing, the intermediate spontaneously dehydrated to 5-hydroxy-dehydroequol in up to 99 mg/L yield. This novel isoflavene, previously not known to be synthesized in nature, was also detected in this biotransformation system. Although (S)-equol favors binding to human estrogen receptor (hER) β over hERα, (-)-5-hydroxy-equol showed the opposite preference. This study provides elucidation of the biosynthetic route of (-)-5-hydroxy-equol and measurement of its potent antagonistic character as a phytoestrogen for the first time.
雌马酚是由肠道微生物将大豆异黄酮如大豆苷元和染料木黄酮还原形成的异黄酮二醇。这些植物雌激素因其多种生物学效应而备受关注。我们报道了在表达源自肠道细菌Slackia isoflavoniconvertens的三种还原酶(大豆苷元还原酶DZNR、二氢大豆苷元还原酶DHDR、四氢大豆苷元还原酶THDR)和一种消旋酶(二氢大豆苷元消旋酶,DDRC)的重组大肠杆菌中从染料木黄酮生物合成(-)-5-羟基雌马酚的过程。生物合成的5-羟基雌马酚被证明是一种旋光性为负的对映体,尽管如此,它显示出与(S)-雌马酚相反的圆二色光谱。在一株大肠杆菌中分隔表达DZNR和DDRC,在另一株中表达DHDR和THDR,使产量提高到230 mg/L,生产力提高到38 mg/L/h。如果缺少最后一种还原酶,中间体会自发脱水生成5-羟基脱氢雌马酚,产量高达99 mg/L。这种以前未知在自然界中合成的新型异黄酮,也在这个生物转化系统中被检测到。尽管(S)-雌马酚与人类雌激素受体(hER)β的结合优于hERα,但(-)-5-羟基雌马酚表现出相反的偏好。本研究首次阐明了(-)-5-羟基雌马酚的生物合成途径,并测定了其作为植物雌激素的强效拮抗特性。
