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1. Why is thiol unexpectedly less reactive but more selective than alcohol in phenanthroline-catalyzed 1,2- cis O - and S -furanosylations?

   https://doi.org/10.1039/d4ob01593b  

   Ramakrishna, Boddu S; Rani, Neha; Xu, Hengfu; Alan-Lee, Cyrus; Schlegel, H Bernhard; Nguyen, Hien M (January 2025, Organic & Biomolecular Chemistry)

   The lack of catalytic stereoselective approaches for producing 1,2-cis S-furanosides emphasizes the critical need for further research in this area. Herein, we present a stereoselective S-furanosylation method, utilizing a 4,7-dipiperidine-substituted phenanthroline catalyst. This developed protocol fills a gap in the field, enabling the coupling of cysteine residues and thiols with furanosyl bromide electrophiles. The process allows for stereoselective access to 1,2-cis S-furanosides. Through computational and experimental investigations, thiol is found to be less reactive than alcohol but exhibits greater stereoselectivity. The 1,2-cis stereoselectivity of O-products depends on the nature of the electrophile, while S-products are obtained with excellent 1,2-cis stereoselectivity, irrespective of the furanose structure. The displaced bromide ion from the glycosyl electrophile influences the reaction’s reactivity and stereoselectivity. Alcohol-OH forms a stronger hydrogen bond with bromide ion than thiol-SH, contributing to the difference in their reactivity. The energy difference between forming S-furanoside and O-furanoside transition states is 3.7 kcal/mol, supporting the increased reactivity of alcohol over thiol. The difference in transition state energies between the major and minor S-product is greater than that for the major and minor O-product. This is consistent with experimental data showing how thiol is more stereoselective than alcohol. The catalyst and reaction conditions utilized for the generation of 1,2-cis O-furanosides in our prior studies are found to be unsuitable for the synthesis of 1,2-cis S-furanosides. In the present study, a highly reactive phenanthroline catalyst and specific reaction conditions have been developed to achieve stereoselective S-linked product formation. 

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2. Highly stereoselective synthesis of α-glycosylated carboxylic acids by phenanthroline catalysis

   https://doi.org/10.1039/D4QO00710G  

   Alom, Nur-E; Rani, Neha; Schlegel, H Bernhard; Nguyen, Hien M (October 2024, Organic Chemistry Frontiers)

   Carbohydrate molecules with an alpha-glycosylated carboxylic acid motif provide access to biologically relevant chemical space but are difficult to synthesize with high selectivity. To address this challenge, we report a mild and operationally simple protocol to synthesize a wide range of functionally and structurally diverse alpha-glycosylated carboxylic acids in good yields with high diastereoselectivity. While there is no apparent correlation between reaction conversion and the pKa of carboxylic acids, there is a notable trend in selectivity. Carboxylic acids with a pKa ranging from 4 to 5 exhibit high selectivity, whereas those with a pKa of 2.5 or lower do not display the same level of selectivity. Our strategy utilizes readily available 2,9-dibutyl-1,10-phenanthroline as an effective nucleophilic catalyst to displace a bromide leaving group from an activated sugar electrophile in a nucleophilic substitution reaction, forming phenanthrolinium intermediates. The attack of the carboxylic acid takes place from the alpha-face of the more reactive intermediate, resulting in the formation of alpha-glycosylated carboxylic acid. Previous calculations suggested that the hydroxyl group participates in the hydrogen bond interaction with the basic C2-oxygen of a sugar moiety and serves as a nucleophile to attack the C1-anomeric center. In contrast, our computational studies reveal that the carbonyl oxygen of the carboxylic acid serves as a nucleophile, with the carboxylic acid-OH forming a hydrogen bond with the basic C2-oxygen of the sugar moiety. This strong hydrogen bond (1.65 Å) interaction increases the nucleophilicity of the carbonyl oxygen of carboxylic acid and plays a critical role in the selectivity-determining step. In contrast, when alcohol acts as a nucleophile, this scenario is not possible since the -OH group of the alcohol interacts with the C2-oxygen and attacks the C1-anomeric carbon of the sugar moiety. This is also reflected in alcohol-OH's weak hydrogen bond (1.95 Å) interaction with the C2-oxygen. The O(C2)-HO (carboxylic acid) angle was measured to be 171° while the O(C2)-HO (alcohol) angle at 122° deviates from linearity, resulting in weak hydrogen bonding. 

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3. Catalytic Orthogonal Glycosylation Enabled by Enynal‐Derived Copper Carbenes

   https://doi.org/10.1002/adsc.202301207  

   Pratap Singh, Surya; Ghosh, Bidhan; Sharma, Indrajeet (March 2024, Advanced Synthesis & Catalysis)

   Abstract Herein, we present an approach for catalytic orthogonal glycosylation utilizing earth‐abundant copper carbenes. This method operates under mild conditions and employs readily accessible starting materials, including benchtop stable enynal‐derived glycosyl donors, synthesized at the gram scale. The reaction accommodates a variety of glycosyl acceptors, including primary, secondary, and tertiary alcohols. The enynal‐derived copper carbenes exhibit remarkable reactivity and selectivity, allowing for the formation of glycosidic linkages with different protecting groups and stereochemical patterns. This approach provides access to both 1,2‐cis‐ and ‐trans‐glycosidic linkages. The product stereoselectivity is independent of the anomeric configuration of the glycosyl donor, which also has orthogonal reactivity to widely used alkynes and thioglycoside donors. An iterative synthesis of a trisaccharide further demonstrates the application of this orthogonal reactivity. 

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4. Direct, stereoselective thioglycosylation enabled by an organophotoredox radical strategy

   https://doi.org/10.1039/D0SC04136J  

   Ji, Peng; Zhang, Yueteng; Gao, Feng; Bi, Fangchao; Wang, Wei (December 2020, Chemical Science)

   null (Ed.)

   While strategies involving a 2e − transfer pathway have dictated glycosylation development, the direct glycosylation of readily accessible glycosyl donors as radical precursors is particularly appealing because of high radical anomeric selectivity and atom- and step-economy. However, the development of the radical process has been challenging owing to notorious competing reduction, elimination and/or S N side reactions of commonly used, labile glycosyl donors. Here we introduce an organophotocatalytic strategy through which glycosyl bromides can be efficiently converted into corresponding anomeric radicals by photoredox mediated HAT catalysis without a transition metal or a directing group and achieve highly anomeric selectivity. The power of this platform has been demonstrated by the mild reaction conditions enabling the synthesis of challenging α-1,2- cis -thioglycosides, the tolerance of various functional groups and the broad substrate scope for both common pentoses and hexoses. Furthermore, this general approach is compatible with both sp 2 and sp 3 sulfur electrophiles and late-stage glycodiversification for a total of 50 substrates probed. 

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5. 1,2- cis -Selective glucosylation enabled by halogenated benzyl protecting groups

   https://doi.org/10.1039/d0ob00373e  

   Njeri, Dancan K.; Pertuit, Claude J.; Ragains, Justin R. (April 2020, Organic & Biomolecular Chemistry)

   We report on our initial results from a systematic effort to implement electron-withdrawing protecting groups and Lewis basic solvents/additives as an approach to 1,2- cis (α)-selective O -glucosylation. 1,2- cis -Selective O -glucosylations are reported with thioglucosides and glucosyl trichloroacetimidates and a range of acceptors. A correlation between electron-withdrawing effects and 1,2- cis selectivity has been established. This phenomenon may prove to be broadly applicable in the area of chemical O -glycosylation. 

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