Enzymatic glycosylation catalyzed by glycosyltransferases (GTs) has great potential in creating diverse novel and bioactive glycosides. Herein, three new GTs (UGT84 A33, UGT71 AE1 and UGT90 A14) from Carthamus tinctor...Enzymatic glycosylation catalyzed by glycosyltransferases (GTs) has great potential in creating diverse novel and bioactive glycosides. Herein, three new GTs (UGT84 A33, UGT71 AE1 and UGT90 A14) from Carthamus tinctorius exhibited robust catalytic promiscuity to benzylisoquinoline alkaloids, and were used as enzymatic tools in glycosylation of bioactive benzylisoquinoline alkaloids. Seven novel benzylisoquinoline alkaloids O-glycosides were synthesized with high efficiency. These studies indicate the significant potential of promiscuous GTs in synthesis of benzylisoquinoline alkaloids glycosides for drug discovery.展开更多
Three new compounds(1–3), including a chlorine-containing dihydroisocoumarin pericochlorosin A(1), a chlorinated phenol pericochlorosin B(2) and a decalin derivative pericoannosin G(3), were isolated from endophytic ...Three new compounds(1–3), including a chlorine-containing dihydroisocoumarin pericochlorosin A(1), a chlorinated phenol pericochlorosin B(2) and a decalin derivative pericoannosin G(3), were isolated from endophytic fungus Periconia sp. F-31 of the medicinal plant Annona muricata. The structures and absolute configurations were elucidated by extensive spectroscopic methods and calculated electronic circular dichroism analysis. Compound 2 displayed potent anti-HIV activity with IC50 value of 2.2 μM.展开更多
Bistachybotrysins D and E (1 and 2), one stereoisomeric pair of phenylspirodrimane dimers, were isolated from Stachybotrys chartarum CGMCC 3.5365. They represent novel phenylspirodrimane dimers with a central [6,5,6]-...Bistachybotrysins D and E (1 and 2), one stereoisomeric pair of phenylspirodrimane dimers, were isolated from Stachybotrys chartarum CGMCC 3.5365. They represent novel phenylspirodrimane dimers with a central [6,5,6]-tricyclic carbon scaffold containing a cyclopentanone core. The structures of 1 and 2 were elucidated through extensive spectroscopic data analysis, and their absolute configurations were characterized by calculated electronic circular dichroism (ECD). Compounds 1 and 2 displayed potent cytotoxic activity against the four human tumor cell lines HCT116, BGC823, Daoy and HepG2 with IC_ (50)values ranging from 6.7 μmol/L to 11.6 μmol/L. Furthermore, a plausible biogenetic pathway for 1 and 2 is proposed.展开更多
C-glycosylation and C-prenylation are two important C-C-bond forming reactions for preparation,diversification and structural modification of natural/unnatural products with pharmacological activities.Here,we describe...C-glycosylation and C-prenylation are two important C-C-bond forming reactions for preparation,diversification and structural modification of natural/unnatural products with pharmacological activities.Here,we described unprecedented enzymatic cascades to C-glycosylate/prenylate different acyl resorcinol derivatives in stepwise,one-pot reactions by combining two promiscuous enzymes,MiCGT,a C-glycosyltransferase,and AtaPT,a prenyltransferase.Five novel bis-C-alkylated products were obtained and structurally identified by MS and NMR spectroscopic data as well as comparison with the literature.This study provided a potential synthetic strategy for synthesizing structurally novel and diverse compounds bearing both C-glycosyl and C-prenyl moieties by a two-step,enzymatic bis-C-alkylation.展开更多
Astragalosides are the main active constituents of traditional Chinese medicine Huang-Qi,of which cycloastragenol-type glycosides are the most typical and major bioactive compounds.This kind of compounds exhibit vario...Astragalosides are the main active constituents of traditional Chinese medicine Huang-Qi,of which cycloastragenol-type glycosides are the most typical and major bioactive compounds.This kind of compounds exhibit various biological functions including cardiovascular protective,neuroprotective,etc.Owing to the limitations of natural sources and the difficulties encountered in chemical synthesis,re-engineering of biosynthetic machinery will offer an alternative and promising approach to producing astragalosides.However,the biosynthetic pathway for astragalosides remains elusive due to their complex structures and numerous reaction types and steps.Herein,guided by transcriptome and phylogenetic analyses,a cycloartenol synthase and four glycosyltransferases catalyzing the committed steps in the biosynthesis of such bioactive astragalosides were functionally characterized from Astragalus membranaceus.AmCAS1,the first reported cycloartenol synthase from Astragalus genus,is capable of catalyzing the formation of cycloartenol;AmUGT15,AmUGT14,AmUGT13,and AmUGT7 are four glycosyltransferases biochemically characterized to catalyze 3-O-xylosylation,3-O-glucosylation,25-O-glucosylation/O-xylosylation and 2’-O-glucosylation of cycloastragenol glycosides,respectively.These findings not only clarified the crucial enzymes for the biosynthesis and the molecular basis for the structural diversity of astragalosides in Astragalus plants,also paved the way for further completely deciphering the biosynthetic pathway and constructing an artificial pathway for their efficient production.展开更多
Prenylflavonoids are valuable natural products that have diverse biological properties, and are usually generated biologically by multiple metabolic enzymes in nature. In this study, structurally diverse prenylflavono...Prenylflavonoids are valuable natural products that have diverse biological properties, and are usually generated biologically by multiple metabolic enzymes in nature. In this study, structurally diverse prenylflavonoids were conveniently synthesized by enzymatic catalysis by combining GuILDT, a regiospecific chalcone prenyltransferase, and Gu CHI, a stereospecific chalcone isomerase that has promiscuous activity for both chalcones and prenylchalcones as substrates. Our findings provided a new approach for the synthesis of natural/unnatural bioactive prenylflavonoids, including prenylchalcones and optical prenylflavanones with chalcone origins.展开更多
Bibenzyls,a kind of important plant polyphenols,have attracted growing attention for their broad and remarkable pharmacological activities.However,due to the low abundance in nature,uncontrollable and environmentally ...Bibenzyls,a kind of important plant polyphenols,have attracted growing attention for their broad and remarkable pharmacological activities.However,due to the low abundance in nature,uncontrollable and environmentally unfriendly chemical synthesis processes,these compounds are not readily accessible.Herein,one high-yield bibenzyl backbone-producing Escherichia coli strain was constructed by using a highly active and substrate-promiscuous bibenzyl synthase identified from Dendrobium officinale in combination with starter and extender biosynthetic enzymes.Three types of efficiently postmodifying modular strains were engineered by employing methyltransferases,prenyltransferase,and glycosyltransferase with high activity and substrate tolerance together with their corresponding donor biosynthetic modules.Structurally different bibenzyl derivatives were tandemly and/or divergently synthesized by co-culture engineering in various combination modes.Especially,a prenylated bibenzyl derivative(12)was found to be an antioxidant that exhibited potent neuroprotective activity in the cellular and rat models of ischemia stroke.RNA-seq,quantitative RT-PCR,and Western-blot analysis demonstrated that 12 could up-regulate the expression level of an apoptosis-inducing factor,mitochondria associated 3(Aifm3),suggesting that Aifm3 might be a new target in ischemic stroke therapy.This study provides a flexible plug-and-play strategy for the easy-to-implement synthesis of structurally diverse bibenzyls through a modular co-culture engineering pipeline for drug discovery.展开更多
基金financially supported by the National Natural Science Foundation of China (No. 81573317)CAMS Innovation Fund for Medical Sciences(Nos. CIFMS-2016-I2M-3-012 and CIFMS-2016-I2M-2-002)
文摘Enzymatic glycosylation catalyzed by glycosyltransferases (GTs) has great potential in creating diverse novel and bioactive glycosides. Herein, three new GTs (UGT84 A33, UGT71 AE1 and UGT90 A14) from Carthamus tinctorius exhibited robust catalytic promiscuity to benzylisoquinoline alkaloids, and were used as enzymatic tools in glycosylation of bioactive benzylisoquinoline alkaloids. Seven novel benzylisoquinoline alkaloids O-glycosides were synthesized with high efficiency. These studies indicate the significant potential of promiscuous GTs in synthesis of benzylisoquinoline alkaloids glycosides for drug discovery.
基金National Natural Science Foundation of China(Grant No.81773607)CAMS Innovation Fund for Medical Sciences(Grant Nos.CIFMS-2018-I2M-3-005 and CIFMS-2016-I2M-2-002)the Drug Inn ovation Major Project(Grant No.2018ZX09711001-001-001)
文摘Three new compounds(1–3), including a chlorine-containing dihydroisocoumarin pericochlorosin A(1), a chlorinated phenol pericochlorosin B(2) and a decalin derivative pericoannosin G(3), were isolated from endophytic fungus Periconia sp. F-31 of the medicinal plant Annona muricata. The structures and absolute configurations were elucidated by extensive spectroscopic methods and calculated electronic circular dichroism analysis. Compound 2 displayed potent anti-HIV activity with IC50 value of 2.2 μM.
基金financially supported by CAMS Innovation Fund for Medical Sciences (Nos. CIFMS-2016-I2M-3-012 and CAMS-I2M2-002)
文摘Bistachybotrysins D and E (1 and 2), one stereoisomeric pair of phenylspirodrimane dimers, were isolated from Stachybotrys chartarum CGMCC 3.5365. They represent novel phenylspirodrimane dimers with a central [6,5,6]-tricyclic carbon scaffold containing a cyclopentanone core. The structures of 1 and 2 were elucidated through extensive spectroscopic data analysis, and their absolute configurations were characterized by calculated electronic circular dichroism (ECD). Compounds 1 and 2 displayed potent cytotoxic activity against the four human tumor cell lines HCT116, BGC823, Daoy and HepG2 with IC_ (50)values ranging from 6.7 μmol/L to 11.6 μmol/L. Furthermore, a plausible biogenetic pathway for 1 and 2 is proposed.
基金National Natural Science Foundation of China(Grant Nos.21572277,81573317 and 81703369)CAMS Innovation Fund for Medical Sciences(CIFMS-2016-I2M-3-012)
文摘C-glycosylation and C-prenylation are two important C-C-bond forming reactions for preparation,diversification and structural modification of natural/unnatural products with pharmacological activities.Here,we described unprecedented enzymatic cascades to C-glycosylate/prenylate different acyl resorcinol derivatives in stepwise,one-pot reactions by combining two promiscuous enzymes,MiCGT,a C-glycosyltransferase,and AtaPT,a prenyltransferase.Five novel bis-C-alkylated products were obtained and structurally identified by MS and NMR spectroscopic data as well as comparison with the literature.This study provided a potential synthetic strategy for synthesizing structurally novel and diverse compounds bearing both C-glycosyl and C-prenyl moieties by a two-step,enzymatic bis-C-alkylation.
基金supported by the National Key Research and Development Program of China(2020YFA0908000)CAMS Innovation fund for Medical Sciences(CIFMS,No.2021-I2M-1029,China)Beijing Key Laboratory of non-Clinical Drug Metabolism and PK/PD Study(Z141102004414062)。
文摘Astragalosides are the main active constituents of traditional Chinese medicine Huang-Qi,of which cycloastragenol-type glycosides are the most typical and major bioactive compounds.This kind of compounds exhibit various biological functions including cardiovascular protective,neuroprotective,etc.Owing to the limitations of natural sources and the difficulties encountered in chemical synthesis,re-engineering of biosynthetic machinery will offer an alternative and promising approach to producing astragalosides.However,the biosynthetic pathway for astragalosides remains elusive due to their complex structures and numerous reaction types and steps.Herein,guided by transcriptome and phylogenetic analyses,a cycloartenol synthase and four glycosyltransferases catalyzing the committed steps in the biosynthesis of such bioactive astragalosides were functionally characterized from Astragalus membranaceus.AmCAS1,the first reported cycloartenol synthase from Astragalus genus,is capable of catalyzing the formation of cycloartenol;AmUGT15,AmUGT14,AmUGT13,and AmUGT7 are four glycosyltransferases biochemically characterized to catalyze 3-O-xylosylation,3-O-glucosylation,25-O-glucosylation/O-xylosylation and 2’-O-glucosylation of cycloastragenol glycosides,respectively.These findings not only clarified the crucial enzymes for the biosynthesis and the molecular basis for the structural diversity of astragalosides in Astragalus plants,also paved the way for further completely deciphering the biosynthetic pathway and constructing an artificial pathway for their efficient production.
基金financially supported by the National Natural Science Foundation of China (Grant No. 81273405)CAMS Innovation Fund for Medical Sciences (Nos. CIFMS-2016-I2M-3012 and CIFMS-2017-I2M-3-013)
文摘Prenylflavonoids are valuable natural products that have diverse biological properties, and are usually generated biologically by multiple metabolic enzymes in nature. In this study, structurally diverse prenylflavonoids were conveniently synthesized by enzymatic catalysis by combining GuILDT, a regiospecific chalcone prenyltransferase, and Gu CHI, a stereospecific chalcone isomerase that has promiscuous activity for both chalcones and prenylchalcones as substrates. Our findings provided a new approach for the synthesis of natural/unnatural bioactive prenylflavonoids, including prenylchalcones and optical prenylflavanones with chalcone origins.
基金supported by the National Key Research and Development Program of China(2020YFA0908000)CAMS Innovation fund for Medical Sciences(CIFMS-2021-I2M1-028 and CIFMS-2021-I2M-1-029,China)Beijing Key Laboratory of non-Clinical Drug Metabolism and PK/PD Study(Z141102004414062,China)。
文摘Bibenzyls,a kind of important plant polyphenols,have attracted growing attention for their broad and remarkable pharmacological activities.However,due to the low abundance in nature,uncontrollable and environmentally unfriendly chemical synthesis processes,these compounds are not readily accessible.Herein,one high-yield bibenzyl backbone-producing Escherichia coli strain was constructed by using a highly active and substrate-promiscuous bibenzyl synthase identified from Dendrobium officinale in combination with starter and extender biosynthetic enzymes.Three types of efficiently postmodifying modular strains were engineered by employing methyltransferases,prenyltransferase,and glycosyltransferase with high activity and substrate tolerance together with their corresponding donor biosynthetic modules.Structurally different bibenzyl derivatives were tandemly and/or divergently synthesized by co-culture engineering in various combination modes.Especially,a prenylated bibenzyl derivative(12)was found to be an antioxidant that exhibited potent neuroprotective activity in the cellular and rat models of ischemia stroke.RNA-seq,quantitative RT-PCR,and Western-blot analysis demonstrated that 12 could up-regulate the expression level of an apoptosis-inducing factor,mitochondria associated 3(Aifm3),suggesting that Aifm3 might be a new target in ischemic stroke therapy.This study provides a flexible plug-and-play strategy for the easy-to-implement synthesis of structurally diverse bibenzyls through a modular co-culture engineering pipeline for drug discovery.
