Total syntheses of seminolipid and its analogues by using 2,6-bis(trifluoromethyl)phenylboronic acid as protective reagent

A Short-Chain Analogue of Seminolipid: Synthesis and Inhibitory Effect on Mouse Fertilization

Background/Objectives: Seminolipid (sulfogalactosylglycerolipid (SGG)) is abundantly present on the sperm surface and its roles in sperm-egg interaction are well-documented. SGG liposomes have direct affinity for the zona pellucida (ZP), the egg extracellular matrix. SGG is also integral to the formation of sperm lipid rafts, which are platforms on the sperm surface for ZP binding. Our objective was to chemically synthesize a short-chain analog of SGG (SC-SGG with a C6 acyl chain instead of C16 in the natural lipid), which is solubilized in an aqueous environment, and to determine the inhibitory effects of SC-SGG in mouse sperm-egg interaction, and thus fertilization. Methods: SC-SGG was synthesized from a 3-O-galactopyranosyl-sn-glycerol intermediate protected on the sugar moiety through the acylation of glycerol with caproic acid, deprotection and regioselective 3-O-sulfation of the galactose residue. SC-SGG solubilized in a medium was used to treat sperm-egg co-incubates or to pretreat sperm or eggs before co-incubating sperm with eggs or vice versa. Sperm-ZP binding and fertilization (scoring eggs with two pronuclei) were microscopically assessed. Results: SC-SGG was efficiently synthesized with a 78% overall yield. SC-SGG inhibited sperm-ZP binding and fertilization of mouse gametes in a concentration-dependent manner, and at 6 µM SC-SGG, the mouse fertilization was zero. SC-SGG inhibited the fertilizing ability of both sperm and eggs, as shown in the pretreatment experiments. Conclusions: SC-SGG was an effective inhibitor of mouse fertilization in vitro. It warrants development to be a non-hormonal contraceptive.

Unified Strategy for the Concise Total Syntheses of All Six 3″-O-Acyl Quercitrins Based on Regioselective Acylation Catalyzed by Boronic Acid

The naturally occurring 3″-O-acylquercitrin family exhibits a range of biological activities with significant potential health and medical benefits. Herein, we present a unified strategy for concise total syntheses of all six known 3″-O-acylquercitrin natural products─namely, 3″-O-galloylquercitrin, 3″-O-(E)-cinnamoylquercitrin, 3″-O-(E)-coumaroylquercitrin, 3″-O-(E)-feruloylquercitrin, 3″-O-acetylquercitrin, and 3″-O-tigloylquercitrin─based on regioselective acylation of carbohydrates catalyzed by N-methylimidazole-containing boronic acid. The core advancement in this approach is a late-stage catalytic regioselective functionalization of a common synthetic intermediate, enabling efficient access to the natural products.

Adjusting the water-sensitivity of sugar/boronate-based organogels

During the investigation of the water-sensitivity of (arylboronate alkylglucoside)-based organogels, we evaluated a series of twelve potential organogelators. They were synthesised in a single step from the corresponding arylboronic acids and alkylglucosides. Eight of them showed organogelation abilities in three solvents (toluene, cyclohexane, and ethyl myristate). Conformational minimisations of the potential organogelators permitted a clear relationship between the arylboronate orientation and the gelation effectiveness to be established. These gels were characterised by rheometry and SEM which revealed a gel-state originating from the self-assembly of the organogelators into long entangled fibres. SAXS confirmed the mode of packing in a hexagonal phase. Gels in toluene were found to be water-sensitive both after addition of a small amount of water and immersion into water. This study demonstrated that the main parameter impacting the water-sensitivity was the length of the alkyl chain at the anomeric position of the glucoside unit, much more than the functionalisation of an arylboronate moiety.

Boronic Acid-Catalyzed Regioselective Koenigs-Knorr-Type Glycosylation

Boronic acid-catalyzed regioselective Koenigs-Knorr-type glycosylation is presented. The reaction of an unprotected or partially protected glycosyl acceptor with a glycosyl halide donor in the presence of silver oxide and a low catalytic amount of imidazole-containing boronic acid was found to proceed smoothly, which enables construction of a 1,2-trans glycosidic linkage with high regioselectivities. This is the first example of the use of a boronic acid catalyst to initiate regioselective glycosylation via the activation of cis-vicinal diols in glycosyl acceptors.

A novel exchange method to access sulfated molecules

Organosulfates and sulfamates are important classes of bioactive molecules but due to their polar nature, they are both difficult to prepare and purify. We report an operationally simple, double ion-exchange method to access organosulfates and sulfamates. Inspired by the novel sulfating reagent, TriButylSulfoAmmonium Betaine (TBSAB), we developed a 3-step procedure using tributylamine as the novel solubilising partner coupled to commercially available sulfating agents. Hence, in response to an increasing demand for complementary methods to synthesise organosulfates, we developed an alternative sulfation route based on an inexpensive, molecularly efficient and solubilising cation exchanging method using off-the-shelf reagents. The disclosed method is amenable to a range of differentially substituted benzyl alcohols, benzylamines and aniline and can also be performed at low temperature for sensitive substrates in good to excellent isolated yield.