In the realm of natural product chemistry, few isolates have risen to the level of fame justifiably accorded to Taxol™ (1) and its chemical siblings. This report describes the most concise route to date for accessing the highly oxidized members of this family. As representative members of taxanes containing five oxygen atoms, decinnamoyltaxinine E (2) and taxabaccatin III (3) have succumbed to enantioselective total synthesis for the first time in only 18 steps from a simple olefin starting material. The route to these natural products is enabled by a strategy that holistically mimics Nature's approach (two-phase synthesis) and features a carefully choreographed sequence of stereoselective oxidations and a remarkable redox-isomerization to set the key trans-diol present in 2 and 3. This work lays the critical groundwork necessary to access even higher oxidized taxanes such as 1 in a more practical fashion thus empowering a medicinal chemistry campaign that is not wedded to semi-synthesis.
Ingenol derivatives with varying degrees of oxidation were prepared by two‐phase terpene synthesis. This strategy has allowed access to analogues that cannot be prepared by semisynthesis from natural ingenol. Complex ingenanes resulting from divergent C—H oxidation of a common intermediate were found to interact with protein kinase C in a manner that correlates well with the oxidation state of the ingenane core. Even though previous work on ingenanes has suggested a strong correlation between potential to activate PKCδ and induction of neutrophil oxidative burst, the current study shows that the potential to activate PKCβII is of key importance while interaction with PKCδ is dispensable. Thus, key modifications of the ingenane core allowed PKC isoform selectivity wherein PKCδ‐driven activation of keratinocytes is strongly reduced or even absent while PKCβII‐driven activation of neutrophils is retained.
A practical
synthetic route for pilot production of entecavir is
described. It is safe, robust, and scalable to kilogram scale. Starting
from (S)-(+)-carvone, this synthetic route consists
of a series of highly efficient reactions including a Favorskii rearrangement-elimination-epimerization
sequence to establish the cyclopentene skeleton, the Baeyer–Villiger
oxidation/rearrangement to afford the correct configuration of the
secondary alcohol, and a directed homoallylic epoxidation followed
by epoxide ring-opening to introduce the hydroxyl group suitable for
the Mitsunobu reaction. In addition, the synthesis contains only four
brief chromatographic purifications.
Ingenol derivatives with varying degrees of oxidation were prepared by two-phase terpene synthesis.T his strategy has allowed access to analogues that cannot be prepared by semisynthesis from natural ingenol. Complex ingenanes resulting from divergent C À Ho xidation of ac ommon intermediate were found to interact with protein kinase Ci nam anner that correlates well with the oxidation state of the ingenane core
In the realm of natural product chemistry, few isolates have risen to the level of fame justifiably accorded to Taxol (1) and its chemical siblings. This report describes the most concise route to date for accessing the highly oxidized members of this family. As representative members of taxanes containing five oxygen atoms, decinnamoyltaxinine E (2) and taxabaccatin III (3), have succumbed to enantioselective total synthesis for the first time in only 18 steps from a simple olefin starting material. The strategy holistically mimics natures approach (two-phase synthesis) and features a carefully choreographed sequence of stereoselective oxidations and a remarkable redox-isomerization to set the key trans-diol present in 2 and 3. This work lays the critical groundwork necessary to access even higher oxidized taxanes such as 1 in a more practical fashion, thus empowering a medicinal chemistry campaign that is not wedded to semi-synthesis.[ + ] These authors contributed equally.Supporting information and the ORCID identification number(s) for the author(s) of this article can be found under http://dx.
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