Co-reporter:Zheming Xiao, Yayue Li, and Shuanhu Gao
Organic Letters April 7, 2017 Volume 19(Issue 7) pp:
Publication Date(Web):March 30, 2017
DOI:10.1021/acs.orglett.7b00592
The first total synthesis of the dimeric tetrahydroxanthone ascherxanthone A has been accomplished. This synthetic strategy features (1) enantioselective intramolecular allylic C–H oxidation to construct a core chiral chromane, (2) intramolecular aldol reaction/dehydration to form the enone group, and (3) intermolecular Suzuki–Miyaura coupling to connect two monomeric tetrahydroxanthones. This synthetic work allowed us to determine the axial chirality of the 2,2′-biaryl C–C bond and the absolute configuration of the ascherxanthone A. This approach should facilitate the preparation of derivatives and structurally related natural products for medicinal studies.
Co-reporter:Dan Wang, Min Hou, Yue Ji, and Shuanhu Gao
Organic Letters April 7, 2017 Volume 19(Issue 7) pp:
Publication Date(Web):March 30, 2017
DOI:10.1021/acs.orglett.7b00722
The first asymmetric total syntheses of scholarisine K and alstolactine A have been accomplished. Our syntheses feature (1) ring closure metathesis and an intramolecular Heck reaction to construct the 1,3-bridged [3,3,1] bicycle (C–D ring), (2) intramolecular alkylation followed by Fischer indolization to form the basic skeleton of akuammilines, and (3) bioinspired, acid-promoted epoxide opening/lactonization to generate the second lactone ring of alstolactine A. These results provide evidence of a biogenetic relationship between scholarisine K and alstolactine A, which should facilitate the preparation of other akuammiline-type natural products and their derivatives for functional studies.
Co-reporter:Xiaojun Li;Qingfei Zheng;Jun Yin;Wen Liu
Chemical Communications 2017 vol. 53(Issue 34) pp:4695-4697
Publication Date(Web):2017/04/25
DOI:10.1039/C7CC01929G
We here report that the biosynthesis of equisetin, a fungal tetramate natural product with potent anti-infectious activity, relies on Fsa2, a Diels–Alderase that constructs the trans-decalin system of the molecule in a stereo-selective manner. This finding led to the development of a concise chemo-enzymatic route toward the synthesis of equisetin, which involves facile preparation of a linear polyene precursor via 7-steps and Fsa2 activity for equisetin maturation through an intramolecular Diels–Alder reaction, thus exemplifying the significance of the combination of chemical and biological methods to achieve structurally complex cyclic natural products and their derivatives.
Co-reporter:Yuanyou Qiu and Shuanhu Gao
Natural Product Reports 2016 vol. 33(Issue 4) pp:562-581
Publication Date(Web):05 Feb 2016
DOI:10.1039/C5NP00122F
Covering: 2006 to 2015
C–H functionalization remains one of the frontier challenges in organic chemistry and drives quite an active area of research. It has recently been applied in various novel strategies for the synthesis of natural products. It can dramatically increase synthetic efficiency when incorporated into retrosynthetic analyses of complex natural products, making it an essential part of current trends in organic synthesis. In this Review, we focus on selected case studies of recent applications of C–H oxidation methodologies in which the C–H bond has been exploited effectively to construct C–O and C–N bonds in natural product syntheses. Examples of syntheses representing different types of C–H oxidation are discussed to illustrate the potential of this approach and inspire future applications.
Co-reporter:Xiaojun Li;Dongsheng Xue;Cheng Wang ;Dr. Shuanhu Gao
Angewandte Chemie International Edition 2016 Volume 55( Issue 34) pp:9942-9946
Publication Date(Web):
DOI:10.1002/anie.201604070
Abstract
The first total synthesis of hamigerans D, G, L, and N–Q has been accomplished. A convergent approach was used to build the basic tricarbocyclic ring system bearing a 5-6-6 structure. A sequence of oxidative cleavage, homologation, and ring regeneration provided access to the 5-7-6 skeleton of hamigeran G. Based on the biogenetic hypothesis, elegant and highly efficient biomimetic transformations of hamigeran G into hamigerans D, N–Q, and L were achieved.
Co-reporter:Shuanhu Gao;Yuanyou Qiu
Science China Chemistry 2016 Volume 59( Issue 9) pp:1093-1108
Publication Date(Web):2016 September
DOI:10.1007/s11426-016-0032-y
This review will focus on the recent advances of radical and photo reactions and their applications in the natural products total synthesis. A brief introduction to the development and mechanism of the newly developed radical and photo reactions will be presented. The organization of the each section is based on the type of reactions used. Examples of synthetic applications are discussed to demonstrate the potential of related methodologies and inspire future explorations.
Co-reporter:Xiaojun Li;Dongsheng Xue;Cheng Wang ;Dr. Shuanhu Gao
Angewandte Chemie 2016 Volume 128( Issue 34) pp:10096-10100
Publication Date(Web):
DOI:10.1002/ange.201604070
Abstract
The first total synthesis of hamigerans D, G, L, and N–Q has been accomplished. A convergent approach was used to build the basic tricarbocyclic ring system bearing a 5-6-6 structure. A sequence of oxidative cleavage, homologation, and ring regeneration provided access to the 5-7-6 skeleton of hamigeran G. Based on the biogenetic hypothesis, elegant and highly efficient biomimetic transformations of hamigeran G into hamigerans D, N–Q, and L were achieved.
Co-reporter:Yingbo Shi, Shuanhu Gao
Tetrahedron 2016 Volume 72(Issue 14) pp:1717-1735
Publication Date(Web):7 April 2016
DOI:10.1016/j.tet.2016.02.022
Co-reporter:Zheming Xiao, Shujun Cai, Yingbo Shi, Baochao Yang and Shuanhu Gao
Chemical Communications 2014 vol. 50(Issue 40) pp:5254-5257
Publication Date(Web):12 Nov 2013
DOI:10.1039/C3CC47426G
A metal-free, photo-induced C–O bond formation methodology was developed to construct tetrahydroxanthones. This mild and efficient methodology was based on intramolecular oxygen trapping of the reactive species produced by photolytic activation of a C–Cl bond. We believe this method could be used in the synthesis of related xanthone-type natural products.
Co-reporter:Lili Kong, Mingjin Rao, Jinjie Ou, Jun Yin, Weiqiang Lu, Mingyao Liu, Xiufeng Pang and Shuanhu Gao
Organic & Biomolecular Chemistry 2014 vol. 12(Issue 38) pp:7591-7597
Publication Date(Web):04 Aug 2014
DOI:10.1039/C4OB01149J
Total synthesis of cryptocin, a fungus metabolite, was achieved based on the biosynthetic hypothesis. A variety of derivatives of cryptocin, equisetin and fusarisetin A were prepared, wherein the racemization of C-3 and diastereoselectivity of C-5 were investigated. We further examined their inhibitory effects on breast cancer cell survival and metastasis, and summarized the structure–activity relationship.
Co-reporter:Yingbo Shi;Baochao Yang;Shujun Cai;Dr. Shuanhu Gao
Angewandte Chemie International Edition 2014 Volume 53( Issue 36) pp:9539-9543
Publication Date(Web):
DOI:10.1002/anie.201405418
Abstract
The total synthesis of gracilamine, a pentacyclic Amaryllidaceae alkaloid, was achieved from simple building blocks. The synthesis features a mild photo-Nazarov reaction, intramolecular 1,4-addition, and an intramolecular Mannich reaction. This approach not only confirms the C6 stereochemistry of natural gracilamine, and also provides a novel solution to prepare its derivatives and structurally related natural products.
Co-reporter:Shujun Cai;Zheming Xiao;Yingbo Shi;Dr. Shuanhu Gao
Chemistry - A European Journal 2014 Volume 20( Issue 28) pp:8677-8681
Publication Date(Web):
DOI:10.1002/chem.201402993
Abstract
The reaction conditions and scope of the photo-Nazarov reaction of aryl vinyl ketones were investigated. In contrast to the conventional acid-catalyzed methods, this photolytic electrocyclization proceeds in the neutral or basic conditions. Irradiating substrates bearing various aromatic rings, acid-sensitive groups, cyclohexenyl, cycloheptenyl, and unsaturated pyran with UV-light (254 nm) smoothly yielded hexahydrofluorenones and related structures. This photo-Nazarov reaction could also be applicable to the substrates carrying β-alkyl groups on the enone, which gave corresponding polycyclic rings containing quaternary centers. These photo-electrocyclized products may prove useful for synthesizing a variety of natural products and their derivatives. Further application of this mild photo-Nazarov reaction in the synthesis of taiwaniaquinol B was achieved.
Co-reporter:Yingbo Shi;Baochao Yang;Shujun Cai;Dr. Shuanhu Gao
Angewandte Chemie 2014 Volume 126( Issue 36) pp:9693-9697
Publication Date(Web):
DOI:10.1002/ange.201405418
Abstract
The total synthesis of gracilamine, a pentacyclic Amaryllidaceae alkaloid, was achieved from simple building blocks. The synthesis features a mild photo-Nazarov reaction, intramolecular 1,4-addition, and an intramolecular Mannich reaction. This approach not only confirms the C6 stereochemistry of natural gracilamine, and also provides a novel solution to prepare its derivatives and structurally related natural products.
Co-reporter:Cheng Wang, Dan Wang, and Shuanhu Gao
Organic Letters 2013 Volume 15(Issue 17) pp:4402-4405
Publication Date(Web):August 15, 2013
DOI:10.1021/ol4019425
The first total synthesis of cyanthiwigins A, C, H and concise synthesis of cyanthiwigin G was achieved from a common intermediate. A modified formal [4 + 2] cycloaddition was developed to construct the key cis-hydrindanone (A–B). Stereospecific 1,4-addition, alkylation, and ring-closing metathesis were used to build the tricarbocyclic ring system (A–B–C). Various site-selective oxidations were applied to create the desired oxidation states of the different cyanthiwigins.
Co-reporter:Ke Li, Cheng Wang, Gang Yin and Shuanhu Gao
Organic & Biomolecular Chemistry 2013 vol. 11(Issue 43) pp:7550-7558
Publication Date(Web):11 Sep 2013
DOI:10.1039/C3OB41693C
Ophiobolin and variecolin type sesterterpenoids belong to cyclooctane-containing natural products. Both sesterterpenoids have challenging structures and appealing biological activities. We envisioned that a key tandem ring closing metathesis of dienynes could provide the basic skeleton of ophiobolin A and variecolin. We report herein the detailed reactivities of the dienynes which furnished the 5-8-5 and 5-8-6-5 rings efficiently.
Co-reporter:Jun Yin;Lili Kong;Cheng Wang;Yingbo Shi;Shujun Cai;Dr. Shuanhu Gao
Chemistry - A European Journal 2013 Volume 19( Issue 39) pp:13040-13046
Publication Date(Web):
DOI:10.1002/chem.201302163
Abstract
(+)-Fusarisetin A belongs to a group of acyl tetramic acid natural products that show potential anticancer activity. Equisetin, a biogenetically related acyl tetramic acid, contains the basic skeleton of (+)-fusarisetin A. We proposed that equisetin and (+)-fusarisetin A share a biosynthetic pathway that starts with naturally occurring (S)-serine and an unsaturated fatty acid. In support of this hypothesis, we have demonstrated that a cyclization sequence involving an intramolecular Diels–Alder reaction followed by a Dieckmann cyclization of polyenoylamino acid yielded equisetin. The aerobic oxidation of equisetin, promoted by either MnIII/O2 or a reactive oxygen species (ROS) produced by visible-light chemistry, gave peroxyfusarisetin, which could be easily reduced to (+)-fusarisetin A. We report herein detailed information on the biogenetic synthesis of equisetin and (+)-fusarisetin A.
Co-reporter:Jun Yin;Cheng Wang;Lili Kong;Shujun Cai ;Dr. Shuanhu Gao
Angewandte Chemie International Edition 2012 Volume 51( Issue 31) pp:7786-7789
Publication Date(Web):
DOI:10.1002/anie.201202455
Co-reporter:Jun Yin;Cheng Wang;Lili Kong;Shujun Cai ;Dr. Shuanhu Gao
Angewandte Chemie 2012 Volume 124( Issue 31) pp:7906-7909
Publication Date(Web):
DOI:10.1002/ange.201202455
Co-reporter:Xiaojun Li, Qingfei Zheng, Jun Yin, Wen Liu and Shuanhu Gao
Chemical Communications 2017 - vol. 53(Issue 34) pp:NaN4697-4697
Publication Date(Web):2017/04/04
DOI:10.1039/C7CC01929G
We here report that the biosynthesis of equisetin, a fungal tetramate natural product with potent anti-infectious activity, relies on Fsa2, a Diels–Alderase that constructs the trans-decalin system of the molecule in a stereo-selective manner. This finding led to the development of a concise chemo-enzymatic route toward the synthesis of equisetin, which involves facile preparation of a linear polyene precursor via 7-steps and Fsa2 activity for equisetin maturation through an intramolecular Diels–Alder reaction, thus exemplifying the significance of the combination of chemical and biological methods to achieve structurally complex cyclic natural products and their derivatives.
Co-reporter:Lili Kong, Mingjin Rao, Jinjie Ou, Jun Yin, Weiqiang Lu, Mingyao Liu, Xiufeng Pang and Shuanhu Gao
Organic & Biomolecular Chemistry 2014 - vol. 12(Issue 38) pp:NaN7597-7597
Publication Date(Web):2014/08/04
DOI:10.1039/C4OB01149J
Total synthesis of cryptocin, a fungus metabolite, was achieved based on the biosynthetic hypothesis. A variety of derivatives of cryptocin, equisetin and fusarisetin A were prepared, wherein the racemization of C-3 and diastereoselectivity of C-5 were investigated. We further examined their inhibitory effects on breast cancer cell survival and metastasis, and summarized the structure–activity relationship.
Co-reporter:Dan Wang and Shuanhu Gao
Inorganic Chemistry Frontiers 2014 - vol. 1(Issue 5) pp:NaN566-566
Publication Date(Web):2014/03/20
DOI:10.1039/C3QO00086A
This review will focus on selected applications of Sonogashira coupling and subsequent transformations as key steps in the total synthesis of natural products. A brief introduction to the history and development of Sonogashira coupling will be presented. The organization of the synthetic applications is based on the structure of target molecules and the transformations followed by the Sonogashira coupling, which includes (1) preparation of natural products containing conjugated enynes or enediynes; (2) Sonogashira coupling followed by stereoselective reduction and (3) Sonogashira coupling followed by regioselective annulations.
Co-reporter:Shujun Cai, Zheming Xiao, Jinjie Ou, Yingbo Shi and Shuanhu Gao
Inorganic Chemistry Frontiers 2016 - vol. 3(Issue 3) pp:NaN358-358
Publication Date(Web):2016/01/14
DOI:10.1039/C5QO00392J
A metal-free, photo-induced C–C bond formation methodology was developed to construct tetrahydrofluorenones and their related structures. This mild and efficient method proceeds either through electrocyclization or radical cyclization from β-Cl or β-Br aryl vinyl ketone. We believe that this method is particularly useful for the synthesis of related tetrahydrofluorenone containing natural products.
Co-reporter:Ke Li, Cheng Wang, Gang Yin and Shuanhu Gao
Organic & Biomolecular Chemistry 2013 - vol. 11(Issue 43) pp:NaN7558-7558
Publication Date(Web):2013/09/11
DOI:10.1039/C3OB41693C
Ophiobolin and variecolin type sesterterpenoids belong to cyclooctane-containing natural products. Both sesterterpenoids have challenging structures and appealing biological activities. We envisioned that a key tandem ring closing metathesis of dienynes could provide the basic skeleton of ophiobolin A and variecolin. We report herein the detailed reactivities of the dienynes which furnished the 5-8-5 and 5-8-6-5 rings efficiently.
Co-reporter:Zheming Xiao, Shujun Cai, Yingbo Shi, Baochao Yang and Shuanhu Gao
Chemical Communications 2014 - vol. 50(Issue 40) pp:NaN5257-5257
Publication Date(Web):2013/11/12
DOI:10.1039/C3CC47426G
A metal-free, photo-induced C–O bond formation methodology was developed to construct tetrahydroxanthones. This mild and efficient methodology was based on intramolecular oxygen trapping of the reactive species produced by photolytic activation of a C–Cl bond. We believe this method could be used in the synthesis of related xanthone-type natural products.
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![Benz[6,7]indolizino[1,2-b]quinolin-11(13H)-one, 8,9-dimethoxy-](http://img.cochemist.com/ccimg/577800/577705-01-2.png)
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![4a,14a-Epoxy-4,14-[3]hexene[1,5]diynonaphtho[2,3-c]phenanthridine-2-carboxylicacid,1,4,7,12,13,14-hexahydro-6,8,11-trihydroxy-3-methoxy-1-methyl-7,12-dioxo-,(1S,4R,4aR,14S,14aS,18Z)-](http://img.cochemist.com/ccimg/124500/124412-57-3.png)
![4a,14a-Epoxy-4,14-[3]hexene[1,5]diynonaphtho[2,3-c]phenanthridine-2-carboxylicacid,1,4,7,12,13,14-hexahydro-6,8,11-trihydroxy-3-methoxy-1-methyl-7,12-dioxo-,(1S,4R,4aR,14S,14aS,18Z)-](http://img.cochemist.com/ccimg/124500/124412-57-3_b.png)
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![Indeno[1,2-b]indol-10(2H)-one, 1,3,4,4a,5,10a-hexahydro-, cis-](http://img.cochemist.com/ccimg/113700/113618-14-7_b.png)
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![Carbamic acid,N-[(1R,4Z,8S,13E)-8-[[4,6-dideoxy-4-[[[2,6-dideoxy-4-S-[4-[(6-deoxy-3-O-methyl-a-L-mannopyranosyl)oxy]-3-iodo-5,6-dimethoxy-2-methylbenzoyl]-4-thio-b-D-ribo-hexopyranosyl]oxy]amino]-2-O-[2,4-dideoxy-4-(ethylamino)-3-O-methyl-a-L-threo-pentopyranosyl]-b-D-glucopyranosyl]oxy]-1-hydroxy-13-[2-(methyltrithio)ethylidene]-11-oxobicyclo[7.3.1]trideca-4,9-diene-2,6-diyn-10-yl]-,methyl ester](http://img.cochemist.com/ccimg/108300/108212-75-5.png)
![Carbamic acid,N-[(1R,4Z,8S,13E)-8-[[4,6-dideoxy-4-[[[2,6-dideoxy-4-S-[4-[(6-deoxy-3-O-methyl-a-L-mannopyranosyl)oxy]-3-iodo-5,6-dimethoxy-2-methylbenzoyl]-4-thio-b-D-ribo-hexopyranosyl]oxy]amino]-2-O-[2,4-dideoxy-4-(ethylamino)-3-O-methyl-a-L-threo-pentopyranosyl]-b-D-glucopyranosyl]oxy]-1-hydroxy-13-[2-(methyltrithio)ethylidene]-11-oxobicyclo[7.3.1]trideca-4,9-diene-2,6-diyn-10-yl]-,methyl ester](http://img.cochemist.com/ccimg/108300/108212-75-5_b.png)
![3,6-Imino-1H-2-oxa-11c-azanaphth[1,2,3-cd]azulene-5-carboxylic acid, 2a,3,4,5,6,6a,7,11b-octahydro-11-methoxy-12-methyl-,](/data/chemimg/1982000/84573-33-1.png)
![3,6-Imino-1H-2-oxa-11c-azanaphth[1,2,3-cd]azulene-5-carboxylic acid, 2a,3,4,5,6,6a,7,11b-octahydro-11-methoxy-12-methyl-,](/data/chemimg/1982000/84573-33-1_b.png)
![11H-Benzo[a]fluoren-11-one, 6b,7,8,9,10,10a-hexahydro-, cis-](http://img.cochemist.com/ccimg/63000/62934-28-5.png)
![11H-Benzo[a]fluoren-11-one, 6b,7,8,9,10,10a-hexahydro-, cis-](http://img.cochemist.com/ccimg/63000/62934-28-5_b.png)
![(2s,3s)-4-[(e)-3-[(1r)-1-carboxy-2-(3,4-dihydroxyphenyl)ethoxy]-3-oxoprop-1-enyl]-2-(3,4-dihydroxyphenyl)-7-hydroxy-2,3-dihydro-1-benzofuran-3-carboxylic Acid](http://img.cochemist.com/ccimg/28900/28831-65-4.png)
![(2s,3s)-4-[(e)-3-[(1r)-1-carboxy-2-(3,4-dihydroxyphenyl)ethoxy]-3-oxoprop-1-enyl]-2-(3,4-dihydroxyphenyl)-7-hydroxy-2,3-dihydro-1-benzofuran-3-carboxylic Acid](http://img.cochemist.com/ccimg/28900/28831-65-4_b.png)
![15-[(3aR,11bR,11cR)-8-hydroxy-3-methyl-6-oxo-2,3,5,6-tetrahydro-4H-3a,11c-epoxyindolo[3,2,1-de][1,5]naphthyridin-11b(1H)-yl]-16,17-dimethoxy-1-methyl-3,4-didehydro-19,21-epoxyaspidospermidin-21-one](http://img.cochemist.com/ccimg/16700/16625-20-0.png)
![15-[(3aR,11bR,11cR)-8-hydroxy-3-methyl-6-oxo-2,3,5,6-tetrahydro-4H-3a,11c-epoxyindolo[3,2,1-de][1,5]naphthyridin-11b(1H)-yl]-16,17-dimethoxy-1-methyl-3,4-didehydro-19,21-epoxyaspidospermidin-21-one](http://img.cochemist.com/ccimg/16700/16625-20-0_b.png)
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