Characterization of Microbial Degradation Products of Steviol Glycosides

Steviol glycosides were subjected to bacteria present in a soil sample collected from a Stevia plantation in Paraguay. During the incubation experiments, next to the aglycon steviol, steviol degradation products were also formed. X-ray analysis and NMR methods in combination with chemical synthesis and GIAO NMR calculations were used to fully characterize the structure of these compounds as a tricyclic ketone and the corresponding reduced form. They were nicknamed monicanone and monicanol. The latter has the (S)-configuration at the alcohol site.

Short Protecting Group-free Syntheses of CDE Synthon of Racemic Camptothecin

A practical and concise total synthesis of tricyclic ketone 7 (CDE ring), a valuable intermediate for the synthesis of racemic camptothecin and analogs, was described (8 chemical steps and 29% overall yield). The synthesis starts with two inexpensive, readily available materials and is operationally simple to perform. It is worth mentioning that the reported protecting group-free synthesis, with advantages of a short route, would be helpful for the future development of industry-scale syntheses of camptothecin-family alkaloids.

Palladium Catalyzed Stereoselective Arylation of Biocatalytically Derived Cyclic 1,3-Dienes: Chirality Transfer via a Heck-Type Mechanism

Microbial arene oxidation of benzoic acid with Ralstonia eutropha B9 provides a chiral highly functionalized cyclohexadiene, suitable for further structural diversification. Subjecting this scaffold to a palladium-catalyzed Heck reaction effects a regioselective and stereoselective arylation of the cyclohexadiene ring. The arylation proceeds with a highly selective 1,3-chirality transfer of stereogenic information installed in the microbial arene oxidation. Quantum chemical calculations have provided insight<br>into the mechanism of the palladium catalyzed arylation. The high selectivity can be explained both by a kinetic preference for the observed arylation position and, interestingly, by reversible carbopalladation in competing positions. Functional groups that were well tolerated on the diene substrate included a range of esters, amides and a Weinreb amide, affording a total of 23 different products<br>in good yields. These products, which can be considered as latent enolic nucleophiles, also possess a unique three dimensional structure which can be utilized in further stereoselective transformations. This was demonstrated by subjecting one of the products, which contained a protected aldehyde, to a tandem deprotection – cyclization sequence. The reaction proceeded with complete stereoselectivity<br>and afforded a tricyclic ketone product possessing four stereogenic centers. This demonstrates the capability of the method to introduce stereochemical complexity from a planar molecule such as benzoic acid in just a few steps.<br>

Palladium Catalyzed Stereoselective Arylation of Biocatalytically Derived Cyclic 1,3-Dienes: Chirality Transfer via a Heck-Type Mechanism

Microbial arene oxidation of benzoic acid with Ralstonia eutropha B9 provides a chiral highly functionalized cyclohexadiene, suitable for further structural diversification. Subjecting this scaffold to a palladium-catalyzed Heck reaction effects a regioselective and stereoselective arylation of the cyclohexadiene ring. The arylation proceeds with a highly selective 1,3-chirality transfer of stereogenic information installed in the microbial arene oxidation. Quantum chemical calculations have provided insight<br>into the mechanism of the palladium catalyzed arylation. The high selectivity can be explained both by a kinetic preference for the observed arylation position and, interestingly, by reversible carbopalladation in competing positions. Functional groups that were well tolerated on the diene substrate included a range of esters, amides and a Weinreb amide, affording a total of 23 different products<br>in good yields. These products, which can be considered as latent enolic nucleophiles, also possess a unique three dimensional structure which can be utilized in further stereoselective transformations. This was demonstrated by subjecting one of the products, which contained a protected aldehyde, to a tandem deprotection – cyclization sequence. The reaction proceeded with complete stereoselectivity<br>and afforded a tricyclic ketone product possessing four stereogenic centers. This demonstrates the capability of the method to introduce stereochemical complexity from a planar molecule such as benzoic acid in just a few steps.<br>

Palladium Catalyzed Stereospecific Arylation of Biocatalytically Derived Cyclic 1,3-Dienes: Chirality Transfer via a Heck-Type Mechanism

Microbial arene oxidation of benzoic acid with Ralstonia eutropha B9 provides a chiral highly functionalized cyclohexadiene, suitable for further structural diversification. Subjecting this scaffold to a palladium-catalyzed Heck reaction effects a regioselective and stereospecific arylation of the cyclohexadiene ring, with transfer of the stereogenic information installed in the microbial arene oxidation. Functional groups that were well tolerated on the diene substrate included a range of esters, amides and a Weinreb amide, affording a total of 23 different products in good yields. These products, which can be considered as latent enolic nucleophiles, also possess a unique three dimensional structure which can be utilized in further stereoselective transformations. This was demonstrated by subjecting one of the products, which contained a protected aldehyde, to a tandem deprotection – cyclization sequence. The reaction proceeded with complete stereoselectivity and afforded a tricyclic ketone product possessing four stereogenic centers. This demonstrates the capability of the method to introduce stereochemical complexity from non-chiral benzoic acid in just a few steps. Quantum chemical calculations have provided insight into the mechanism of the palladium-catalyzed arylation. The high selectivity can be explained both by a kinetic preference for the observed arylation position and by reversible carbopalladation in competing positions.<br><br>

α-Alkylation of a norbornene-derived tricyclic ketone: are steric factors really in control?

DFT calculations reveal that torsional strain and a strong conformational preference, rather than steric influences, dictate the observed stereoselectivity.