Asymmetric Synthesis of Lycoperdic Acid.

Yoshifuji, Shigeyuki; Kaname, Mamoru

doi:10.1248/cpb.43.1617

Cited by 33 publications

(14 citation statements)

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“…Furan derivative 114 , which was readily prepared from 5‐bromofurfural and ( S )‐aspartic acid dimethyl ester, was subjected to a dearomative photocyclization to effectively construct a spirobutenolide fused to pyrrolidine ( 115 ). Subsequent hydrogenation provided the butyrolactone 116 , which could be further transformed to ( S )‐(+)‐lycoperdic acid ( 117 ) by a route described by Yoshifuji …”

Section: Dearomatization Via Photochemically Generated Reactive Ramentioning

confidence: 99%

Visible‐Light‐Induced Dearomatizations

2019

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The dearomatization of aromatic compounds is an important synthetic strategy used in accessing complex three‐dimensional structures from simple aromatic precursors. This minireview aims to provide an overview of recent advancements in this area, with a specific focus on visible‐light‐mediated dearomative transformations. Compared to the conventional high‐energy ultraviolet (UV) light‐promoted processes, not only these new approaches offer milder reaction conditions to accommodate wider variety of substrates with sensitive functionalities, but also enable the use of photocatalysts and other promoters, significantly expanding the reaction space. Application of these transformations to the synthesis of bioactive compounds are also discussed.

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Section: Dearomatization Via Photochemically Generated Reactive Ramentioning

confidence: 99%

Visible‐Light‐Induced Dearomatizations

2019

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“…(+)-Lycoperdic acid ( 1 ) was isolated from a mushroom Lycoperdon perlatum by Rhugenda-Banga et al It is an amino acid that shares structural similarities with both l -glutamic acid ( 2 ) and dysiherbaines ( 3a , 3b , Figure ). , The dysiherbaines are well-known ionotropic glutamate receptor binders, , a fact which has raised questions about the biological activity of (+)- 1 over the years. − …”

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“…To date, there are seven total syntheses and one formal synthesis for (+)- 1 . − Most of them rely on either chiral pool or chiral auxiliaries to set the stereochemistry at C2 and C4 (Figure ). Very recently, the Oikawa group disclosed an approach where catalytic enantioselective hydrogenation was used to control the stereochemistry at C2 of (+)- 1 , but the construction of C4 was not stereoselective …”

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Catalytic Enantioselective Total Synthesis of (+)–Lycoperdic Acid

2020

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“…The first example of this type of reaction was described by Desai and co-workers, 5) who reported one case that attempted the cleavage of a CϭC bond in steroidal enamines. Torii and co-workers 6) revealed the procedure for the RuO 4 oxidative cleavage of enolic olefins including two six-membered nitrogen-containing heterocyles that afforded the carbonyl compounds under the conditions using the substrate in a suspension of CCl 4 and H 2 O in the presence of RuO 2 · xH 2 O and NaIO 4 .On the other hand, we have been working on the transformation of cyclic [7][8][9] and acyclic [10][11][12] N-acyl amines into the corresponding lactams and imides including the natural products [13][14][15][16][17] by the RuO 4 oxidation. The double layer oxidation method using a catalytic amount of RuO 2 hydrate, an excess of a NaIO 4 aqueous solution and ethyl acetate system was established for these purposes in our laboratory.…”

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confidence: 99%

“…On the other hand, we have been working on the transformation of cyclic [7][8][9] and acyclic [10][11][12] N-acyl amines into the corresponding lactams and imides including the natural products [13][14][15][16][17] by the RuO 4 oxidation. The double layer oxidation method using a catalytic amount of RuO 2 hydrate, an excess of a NaIO 4 aqueous solution and ethyl acetate system was established for these purposes in our laboratory.…”

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confidence: 99%

An Efficient Transformation of Cyclic Ene-carbamates into .OMEGA.-(N-Formylamino)carboxylic Acids by Ruthenium Tetroxide Oxidation

Kaname

Yoshifuji

Sashida

2008

CHEMICAL & PHARMACEUTICAL BULLETIN

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The high-valent metal-promoted oxidation of a carboncarbon double (CϭC) bond with cleavage is a promising synthetic route to the corresponding carbonyl compounds. This chemistry has been extensively studied.1) Ruthenium tetroxide (RuO 4 ) is well known as a highly effective oxidant, [2][3][4] and the oxidative cleavage of simple CϭC bonds is one of the most common reactions between RuO 42) and alkenes. However, only a low effort regarding the oxidative cleavage of the CϭC double bond to the corresponding carbonyl compounds in enol ethers, enol esters and enamines has been made to date. To the best of our knowledge, there are only two papers. The first example of this type of reaction was described by Desai and co-workers, 5) who reported one case that attempted the cleavage of a CϭC bond in steroidal enamines. Torii and co-workers 6) revealed the procedure for the RuO 4 oxidative cleavage of enolic olefins including two six-membered nitrogen-containing heterocyles that afforded the carbonyl compounds under the conditions using the substrate in a suspension of CCl 4 and H 2 O in the presence of RuO 2 · xH 2 O and NaIO 4 .On the other hand, we have been working on the transformation of cyclic [7][8][9] and acyclic [10][11][12] N-acyl amines into the corresponding lactams and imides including the natural products [13][14][15][16][17] by the RuO 4 oxidation. The double layer oxidation method using a catalytic amount of RuO 2 hydrate, an excess of a NaIO 4 aqueous solution and ethyl acetate system was established for these purposes in our laboratory. In addition, it was recently reported that the single layer RuO 4 oxidation 18) of cyclic N-acyl amines using a tert-butanol and NaIO 4 aqueous solution system gave the ring opened wamino acids (Chart 1). We now report that the simple RuO 4 oxidation of various cyclic ene-carbamates including the optically active one into the corresponding w-(N-formylamino)carboxylic acids and the formal synthesis of L-carnitine as the utilization of this RuO 4 oxidation. Results and DiscussionThe substrates, five-, six-and seven-membered cyclic enecarbamates (1a, 2a, 3a), were prepared from the corresponding N-acyl amines via the N-acyl lactams in good yields by the reported method. 19) We have previously tested the utility of the urethane type N-protecting groups, 9) benzyloxycarbonyl (Z), p-nitrobenzyloxycarbonyl (PNZ), trichloroethoxycarbonyl (Troc) and tert-butoxycarbonyl (Boc) groups for the RuO 4 oxidation of the cyclic amines, and found the following three points: (1) the Z group is decomposed by RuO 4 that produced a low yield of products, (2) the PNZ and Troc groups generally require a longer reaction until the starting materials disappear, and (3) the Boc group is stable, accelerates the oxidation, and affords the products in high yields. In addition, the Boc group can be easily removed from the Nprotected amines by common procedures. Thus, we selected the Boc group as the N-protecting group for this RuO 4 oxidation.RuO 4 Oxidation of Ene-carbamates The oxidation of N-tert-but...

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Asymmetric Synthesis of Lycoperdic Acid.

Cited by 33 publications

References 1 publication

Visible‐Light‐Induced Dearomatizations

Visible‐Light‐Induced Dearomatizations

Catalytic Enantioselective Total Synthesis of (+)–Lycoperdic Acid

An Efficient Transformation of Cyclic Ene-carbamates into .OMEGA.-(N-Formylamino)carboxylic Acids by Ruthenium Tetroxide Oxidation

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