Takumi Furuta

Total Synthesis of (-)-Serotobenine

The efficient total synthesis of (-)-serotobenine (1) has been achieved by constructing an optically active dihydrobenzofuran ring via a rhodium carbenoid mediated intramolecular C-H insertion reaction, which was developed by our group. Then the possibility of racemization of 1 was investigated using optically active synthetic 1.

Concise Synthesis of Chafurosides A and B

The regioselective synthesis of chafurosides A (1) and B (2) from the same methyl ketone 5 was accomplished using a novel protecting group strategy. Both flavone rings were constructed from beta-diketone intermediate 4, which was readily obtained by condensation of an acyl donor and ketone 5. Construction of the dihydrofuran ring was achieved via an intramolecular Mitsunobu reaction.

Total Synthesis of Ellagitannins through Regioselective Sequential Functionalization of Unprotected Glucose

Short total syntheses of natural glycosides (ellagitannins) were performed through sequential and regioselective functionalization of the hydroxy groups of unprotected glucose. The key reactions are β-selective glycosidation of a gallic acid derivative by using unprotected glucose as a glycosyl donor and catalyst-controlled regioselective introduction of a galloyl group into the inherently less reactive hydroxy group of the glucoside.

Binding affinity of tea catechins for HSA: characterization by high-performance affinity chromatography with immobilized albumin column.

Catechins are the major polyphenols in green tea leaves. Recent studies have suggested that the catechins form complexes with HSA for transport in human blood, and their binding affinity for albumin is believed to modulate their bioavailability. In this study, the binding affinities of catechins and their analogs were evaluated and the relationship between the chemical structure of each catechin and its binding property were investigated. Comparing these catechins by HPLC analysis with the HSA column, we showed that galloylated catechins have higher binding affinities with HSA than non-galloylated catechins. In addition, pyrogallol-type catechins have a high affinity compared to catechol-type catechins. Furthermore, the binding affinity of the catechin with 2,3-trans structure was higher than those of the catechin with 2,3-cis structure. The importance of the hydroxyl group on the galloyl group and B-ring was confirmed using methylated catechins. These results indicate that the most important structural element contributing to HSA binding of tea catechins is the galloyl group, followed by the number of hydroxyl groups on the B-ring and the galloyl group or the configuration at C-2. Our findings provide fundamental information on the relationship between the chemical structure of tea catechins and its biological activity.

Domino Heck–C–H activation reaction of unsymmetrically substituted [3]cumulene

The Heck reaction of an unsymmetrically substituted [3]cumulene has been investigated. Although a carbonyl conjugated alkene is present, the arylpalladium species selectively inserts into the C3-4 double bond, and a subsequent C-H activation reaction with a neighboring phenyl group gives the indene derivatives with a tetrasubstituted olefin moiety.

Structural characteristics of green tea catechins for formation of protein carbonyl in human serum albumin

Catechins are polyphenolic antioxidants found in green tea leaves. Recent studies have reported that various polyphenolic compounds, including catechins, cause protein carbonyl formation in proteins via their pro-oxidant actions. In this study, we evaluate the formation of protein carbonyl in human serum albumin (HSA) by tea catechins and investigate the relationship between catechin chemical structure and its pro-oxidant property. To assess the formation of protein carbonyl in HSA, HSA was incubated with four individual catechins under physiological conditions to generate biotin-LC-hydrazide labeled protein carbonyls. Comparison of catechins using Western blotting revealed that the formation of protein carbonyl in HSA was higher for pyrogallol-type catechins than the corresponding catechol-type catechins. In addition, the formation of protein carbonyl was also found to be higher for the catechins having a galloyl group than the corresponding catechins lacking a galloyl group. The importance of the pyrogallol structural motif in the B-ring and the galloyl group was confirmed using methylated catechins and phenolic acids. These results indicate that the most important structural element contributing to the formation of protein carbonyl in HSA by tea catechins is the pyrogallol structural motif in the B-ring, followed by the galloyl group. The oxidation stability and binding affinity of tea catechins with proteins are responsible for the formation of protein carbonyl, and consequently the difference in these properties of each catechin may contribute to the magnitude of their biological activities.

Organocatalytic chemoselective monoacylation of 1,n-linear diols.

Selective monoacylation of 1,n-linear diols seems to be a simple molecular transformation, however, it is still a challenging subject in current organic synthesis because overacylation is usually unavoidable. High reactivity of primary hydroxy groups at the both ends of the linear diols makes selective monoacylation difficult. Since the steric environments of the free OH groups in diol 1 are similar to those of a free OH in 2 (Scheme 1), the strategy for

Preparation and absolute configuration of hexahydroxyter- and octahydroxyquaternaphthalene derivatives

Abstract Oxidative coupling reactions of the stereochemically defined S -tetrahydroxybinaphthalene derivative gave a separable mixture of two diastereomers of the quaternaphthalenes of S , S , S and S , R , S configurations, whose stereostructures were confirmed by an alternative chemical transformation through the ternaphthalenes as well as the X-ray structure analysis. The CD spectra of the corresponding diastereomers were indicative of the stereochemistry across the axis.

Regioselective synthesis of methylated epigallocatechin gallate via nitrobenzenesulfonyl (Ns) protecting group.

Regioselective synthesis of methylated epigallocatechin gallate from epigallocatechin was accomplished using a 2-nitrobenzenesulfonyl (Ns) group as a protecting group for phenols. This methodology provided several methylated catechins, which are naturally scarce catechin derivatives.

Stereocontrolled Synthesis of (+)-Methoxyphenylkainic Acid and (+)-Phenylkainic Acid

The efficient total syntheses of (+)-methoxyphenylkainic acid (3) and (+)-phenylkainic acid (4) were achieved using a rhodium carbenoid-mediated intermolecular C-H insertion reaction. Complete stereoselective construction of the kainoid skeleton was accomplished by utilizing the stereochemistry at the C-4 position as a pivotal stereogenic center.