群柱虫内酯官能团化的C2-C10片段的立体选择性合成

本文以廉价的消旋甲基戊二酸酐为起始原料,完成了具有抗肿瘤活性的海洋天然产物群柱虫内酯（Clavulactone）官能团化的C2-C10片段的立体选择性合成。使用的关键方法包括不对称去对称化获得光学纯手性孤立甲基,和RCM方法构建顺式烯烃。该片段的获得为群柱虫内酯的全合成提供了基础。     

Asymmetric Synthesis of the C(33) – C(37) Fragment of Amphotericin B

We have devised an expeditious, efficient, asymmetric synthesis of the C(33) – C(37) fragment of amphotericin B that proceeds in 14 steps and 16% overall yield from tiglic aldehyde ((E)‐2‐methylbut‐2‐enal) with complete stereocontrol. The route described herein relies on the application of recently developed methods in catalytic asymmetric synthesis for stereocontrol through enantio‐ and diastereoselective functionalization of a substituted sorbate derivative.     

Bioinspired Oxidative Cyclization of the Geissoschizine Skeleton for the Total Synthesis of (−)‐17‐nor‐Excelsinidine

We report the first total synthesis of (?)‐17‐nor‐excelsinidine, a zwitterionic monoterpene indole alkaloid that displays an unusual N4?C16 connection. Inspired by the postulated biosynthesis, we explored an oxidative coupling approach from the geissoschizine framework to forge the key ammonium–acetate connection. Two strategies allowed us to achieve this goal, namely an intramolecular nucleophilic substitution on a 16‐chlorolactam with the N4 nitrogen atom or a direct I₂‐mediated N4?C16 oxidative coupling from the enolate of geissoschizine.     

Iodine‐Catalyzed Highly Diastereoselective Synthesis of trans‐2,6‐Disubstituted‐3,4‐Dihydropyrans: Application to Concise Construction of C28–C37 Bicyclic Core of (+)‐Sorangicin A

A novel iodine‐catalyzed highly diastereoselective synthesis of trans‐2,6‐disubstituted‐3,4‐dihydropyrans have been achieved from δ‐hydroxy α,β‐unsaturated aldehydes by treating with allyltrimethyl silane in THF at room temperature with good to excellent yields. This methodology has been successfully implemented for a concise asymmetric synthesis of C28–C37 dioxabicyclo[3.2.1]octane ring system of (+)‐sorangicin A in 8 steps with 21 % overall yield.     

Biocatalytic Approach for the Total Synthesis of (–)‐Malyngolide and Its C(5)‐Epimer

An enzymatic approach has been successfully utilized in the total synthesis of (–)‐malyngolide and its C(5)‐epimer. The required configuration was established by an enzymatic kinetic resolution and Sharpless asymmetric dihydroxylation.     

Stereoselective Synthesis of the Halaven C14–C26 Fragment from D‐Quinic Acid: Crystallization‐Induced Diastereoselective Transformation of an α‐Methyl Nitrile

Crystallization‐induced diastereoselective transformation (CIDT) of an α‐methyl nitrile completes an entirely non‐chromatographic synthesis of the halichondrin B C14–C26 stereochemical array. The requisite α‐methyl nitrile substrate is derived from D ‐quinic acid through a series of substrate‐controlled stereoselective reactions via a number of crystalline intermediates that benefit from a rigid polycyclic template. Therefore, all four stereogenic centers in the Halaven C14–C26 fragment were derived from the single chiral source D ‐quinic acid.     

A Simple Synthesis of 5‐(2‐Aminophenyl)‐1H‐pyrazoles

A four‐step synthesis of 1‐substituted 5‐(2‐aminophenyl)‐1H‐pyrazoles 5 as a novel type of histamine analogs and versatile building blocks for further transformations was developed. The synthesis starts from commercially available 2‐nitroacetophenone ( 12 ), which is converted into the enamino ketone 13 as the key intermediate. Cyclization of the key intermediate 13 with monosubstituted hydrazines 14a – 14l afforded the 5‐(2‐nitrophenyl)‐1H‐pyrazoles 17a – 17l . Finally, catalytic hydrogenation of the nitro compounds 17a, 17c – 17e , and 17g – 17j furnished the title compounds 5a, 5c – 5e , and 5g – 5j , respectively, in good yields. As demonstrated by some further transformations, additional functionalization of compounds 17 and 5 is feasible, either by electrophilic substitution at C(4) of the pyrazole ring, or at the NH₂ group.     

Diastereoselective Total Synthesis of (±)‐Schindilactone A,Part 3: The Final Phase and Completion

The final phase for the total synthesis of (±)‐schindilactone A ( 1 ) is described herein. Two independent synthetic approaches were developed that featured Pd–thiourea‐catalyzed cascade carbonylative annulation reactions to construct intermediate 3 and a RCM reaction to make intermediate 4 . Other important steps that enabled the completion of the synthesis included: 1) A Ag‐mediated ring‐expansion reaction to form vinyl bromide 17 from dibromocyclopropane 30 ; 2) a Pd‐catalyzed coupling reaction of vinyl bromide 17 with a copper enolate to synthesize ketoester 16 ; 3) a RCM reaction to generate oxabicyclononenol 10 from diene 11 ; 4) a cyclopentenone fragment in substrate 8 was constructed through a Co–thiourea‐catalyzed Pauson–Khand reaction (PKR); 5) a Dieckmann‐type condensation to successfully form the A ring of schindilactone A ( 1 ). The chemistry developed for the total synthesis of schindilactone A ( 1 ) will shed light on the synthesis of other family members of schindilactone A.     

Towards the Synthesis of 1‐Deoxy‐1‐nitropiperidinoses

In the course of the first of several attempts to elaborate methods for the synthesis of 1‐nitropiperidinoses, lincosamine was transformed into lactam 6 via hemiacetal 1 , lactone 2 , amide 3 , oxo amide 4 , and its cyclic tautomer 5 . Treatment of the N‐Boc‐protected lactam oxime 9 , obtained from lactam 6 , with brominating agents failed to provide the bromonitroso carbamate 10 . The N‐Boc‐protected lactam 13 derived from 6 was reduced to hemiacetal 14 , but the corresponding N‐Boc‐aminooxime did not tautomerise to the C(1)‐hydroxylamine, and nitrone 17 , a potential precursor of the nitropiperidine 12 , was not formed. Oxidation of the anomeric azide 20 with HOF?MeCN failed to provide the expected nitropiperidine 21 . The phosphinimines 22 derived from 20 did not react with O₃. In the next approach to 1‐nitropiperidinoses, we treated the N‐Boc‐protected hemiacetal 25 , obtained from the known gluconolactam 23 with N‐benzylhydroxylamine. The resulting nitrone 26 exits in equilibrium with the anomeric N‐benzyl‐glycosylhydroxylamine that was oxidized to the anomeric nitrone 28 . Ozonolysis of 28 led to the hemiacetal 25 , resulting from the desired, highly reactive protected nitropiperidinose 29 , that was evidenced by an IR band at 1561 cm^?1. Similarly to the synthesis of nitrone 26 , reaction of the N‐tosyl‐protected hemiacetal 31 with N‐benzylhydroxylamine and oxidation provided the anomeric N‐benzylhydroxylamines 33 via the p‐toluenesulfonamido nitrone 32 . Their oxidation with MnO₂ led to the anomeric nitrone 34 . Ozonolysis of 34 as evidenced by ¹H‐NMR and ReactIR spectroscopy led to the highly reactive nitropiperidinose 35 . Like 29, 35 was transformed during workup, and only the hemiacetal 31 was isolated. The similarly prepared lincosamine‐derived nitrone 17 was subjected to ReactIR‐monitored ozonolysis that evidenced the formation of the protected nitropiperidinose 12 , but only led to the isolation of 14 . The facile transformation of the nitropiperidinoses to hemiacetals is rationalised by heterolysis of the anomeric C,N bond, recombination of the ion pair, and denitrosation of the resulting anomeric nitrite by a nucleophile. Attempts to convert the 1‐deoxy‐1‐nitropiperidinose 35 to uloses 43 by base‐catalysed Michael additions or Henry reactions were unsuccessful.     

Heck Reaction as Key Step in the Synthesis of Hydrogenated 2‐benzazepin‐1‐ones

Two strategies were pursued for the synthesis of 2‐benzazepin‐1‐ones 16 and 17 with an N/O‐acetal or enamide in 3‐position. Establishment of the propionaldehyde substructure first and subsequently the amide moiety via a four step sequence failed to provide amides 11 . However the Pd‐catalyzed Heck reaction of 2‐iodobenzamides 13 with allyl alcohol and subsequent reaction of the products 14 / 15 with acid led to 2‐benzazepin‐1‐ones in a two‐step sequence. Depending on the size of the N‐substituent the 3‐methoxy derivative 16a or the dihydro‐2‐benzazepine 17b was formed.     

An Alternative Synthesis of the Dopaminergic Drug 2‐Amino‐1,2,3,4‐tetrahydronaphthalene‐5,6‐diol (5,6‐ADTN)

Racemic 2‐amino‐1,2,3,4‐tetrahydronaphthalene‐5,6‐diol (5,6‐ADTN; 4 ) was synthesized from 5,6‐dimethoxynaphthalene‐2‐carboxylic acid ( 14 ) in four steps (60% overall yield; Scheme). The crucial steps of the synthesis are Birch reduction of 14 to the valuable synthon 15 , Curtius reaction and carbamate formation ( 16 ), hydrogenolysis ( 17 ), and demethylation to the biologically active hydrobromide salt 18 of 4 .     

Synthesis of Tetrahydropyridoimidazole‐2‐acetates: Effect of Carboxy and Methoxycarbonyl Groups at C(2) on the Inhibition of Some β‐ and α‐Glycosidases

The gluco‐ and manno‐tetrahydropyridoimidazole‐2‐acetates and ‐acetic acids 16 and 17 , and 20 and 21 , respectively, were synthesized by condensation, in the presence of HgCl₂, of the known thionolactam 26 with the β‐amino ester 25 that was obtained by addition of AcOMe to the imine 22 , followed by debenzylation. The resulting methyl esters 16 and 20 were hydrolyzed to the acetic acids 17 and 21 . The (methoxycarbonyl)‐imidazole 14 and the acid 15 were obtained via the known aldehyde 29 . The imidazoles 14 – 17, 20 , and 21 were tested as inhibitors of the β‐glucosidase from Caldocellum saccharolyticum, the α‐glucosidase from brewer's yeast, the β‐mannosidase from snail, and the α‐mannosidase from Jack beans (Tables 1–3). There is a similar dependence of the K_i values on the nature of the C(2)‐substituent in the gluco‐ and manno‐series. With the exception of 19 , manno‐imidazoles are weaker inhibitors than the gluco‐analogues. The methyl acetates 16 and 20 are 3–4 times weaker than the methyl propionates 5 and 11 , in agreement with the hydrophobic effect. The gluco‐configured (methoxycarbonyl)‐imidazole 14 is 20 times weaker than the methyl acetate 16 , reflecting the reduced basicity of 14 , while the manno‐configured (methoxycarbonyl)‐imidazole 18 is only 1.2 times weaker than the methyl acetate 20 , suggesting a binding interaction of the MeOCO group and the β‐mannosidase. The carboxylic acids 6, 12, 15, 17, 19 , and 21 are weaker inhibitors than the esters, with the propionic acids 6 and 12 being the strongest and the carboxy‐imidazoles 15 and 19 the weakest inhibitors. The manno‐acetate 21 inhibits the β‐mannosidase ca. 8 times less strongly than the propionate 12 , but only 1.5 times more strongly than the carboxylate 19 , suggesting a compensating binding interaction also of the COOH group and the β‐mannosidase. The α/β selectivity for the gluco‐imidazoles ranges between 110 for 15 and 13.4?10³ for 6 ; the manno‐imidazoles are less selective. The methyl propionates proved the strongest inhibitors of the α‐glucosidase (IC₅₀ ( 5 )=25 μM ) and the α‐mannosidase (K_i( 11 ) =0.60 μM ).     

Design,Synthesis, and in vitro Antimicrobial Activity of New Furan/Thiophene‐1,3‐Benzothiazin‐4‐one Hybrids

This study presents the design, synthesis, spectral analysis, and in vitro antimicrobial evaluation of a new series of furan/thiophene‐1,3‐benzothiazin‐4‐one hybrids ( 17 , 18 , 19 , 20 , 21 , 22 , 23 , 24 , 25 , 26 , 27 , 28 , 29 , 30 , 31 , 32 ). New compounds were obtained by cyclization reaction of N‐substituted furan/thiophene‐2‐carboxamide derivatives ( 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 , 15 , 16 ) with thiosalicylic acid. All synthesized compounds were screened for their in vitro antimicrobial activities using the broth microdilution method. Nine of the synthesized compounds showed good activity against Gram‐positive, Gram‐negative bacteria, and yeasts belonging to Candida spp. (MIC = 7.81–500 μg/mL), especially against Staphylococcus spp. (MIC = 15.62–62.5 μg/ml), Bacillus spp. (MIC = 7.81–62.5 μg/mL), Bordetella bronchiseptica ATCC 4617 (MIC = 62.5–125 μg/mL), and fungistatic activity against Candida spp. (MIC = 62.5–125 μg/mL).     

Concise,Enantioselective, and Versatile Synthesis of (−)‐Englerin A Based on a Platinum‐Catalyzed [4C+3C] Cycloaddition of Allenedienes

A practical synthesis of (−)‐englerin A was accomplished in 17 steps and 11 % global yield from commercially available achiral precursors. The key step consists of a platinum‐catalyzed [4C+3C] allenediene cycloaddition that directly delivers the trans‐fused guaiane skeleton with complete diastereoselectivity. The high enantioselectivity (99 % ee) stems from an asymmetric ruthenium‐catalyzed transfer hydrogenation of a readily assembled diene–ynone. The synthesis also features a highly stereoselective oxygenation, and a late‐stage cuprate alkylation that enables the preparation of previously inaccessible structural analogues.     

Concise,Enantioselective, and Versatile Synthesis of (−)‐Englerin A Based on a Platinum‐Catalyzed [4C+3C] Cycloaddition of Allenedienes

A practical synthesis of (?)‐englerin A was accomplished in 17 steps and 11 % global yield from commercially available achiral precursors. The key step consists of a platinum‐catalyzed [4C+3C] allenediene cycloaddition that directly delivers the trans‐fused guaiane skeleton with complete diastereoselectivity. The high enantioselectivity (99 % ee) stems from an asymmetric ruthenium‐catalyzed transfer hydrogenation of a readily assembled diene–ynone. The synthesis also features a highly stereoselective oxygenation, and a late‐stage cuprate alkylation that enables the preparation of previously inaccessible structural analogues.     

Total Synthesis of (−)‐Salvinorin A

Salvinorin A ( 1 ) is natural hallucinogen that binds the human κ‐opioid receptor. A total synthesis has been developed that parlays the stereochemistry of l ‐(+)‐tartaric acid into that of (?)‐ 1 via an unprecedented allylic dithiane intramolecular Diels–Alder reaction to obtain the trans‐decalin scaffold. Tsuji allylation set the C9 quaternary center and a late‐stage stereoselective chiral ligand‐assisted addition of a 3‐titanium furan upon a C12 aldehyde/C17 methyl ester established the furanyl lactone moiety. The tartrate diol was finally converted into the C1,C2 keto‐acetate.     

Synthesis of the 2‐Alkenyl‐4‐alkylidenebut‐2‐eno‐4‐lactone (=α‐Alkenyl‐γ‐alkylidenebutenolide) Core Structure of the Carotenoid Pyrrhoxanthin via the Regioselective Dihydroxylation of Hepta‐2,4‐diene‐5‐ynoic Acid Esters

A new strategy for the stereoselective synthesis of 4‐alkylidenebut‐2‐eno‐4‐lactones (=γ‐alkylidenebutenolides) with (Z)‐configuration of the exocyclic CC bond at C(4) was developed. It is exemplified by the synthesis of 4‐alkylidenebutenolactone 31 (Scheme 4), which constitutes a substructure of the carotenoids pyrrhoxanthin ( 1 ) and peridinin. The formation of the precursor 4‐(1‐hydroxyalkyl)butenolactone 29 was accomplished either by cyclocarbonylation of the prop‐2‐yn‐1‐ol moiety of 27 (→ 29 ) or by hydrostannylation of the isopropylidene‐protected alkynoic acid ester 26 (→ 28 ) followed by transacetalization/transesterification (→ 30 ). The 4‐alkylidenebutenolactone was formed by the anti‐selective Mitsunobu dehydration 29 → 31 .     

Enantioselective Synthesis of (−)‐Halenaquinone

The efficient, 12–14 step (LLS) total synthesis of (?)‐halenaquinone has been achieved. Key steps in the synthetic sequence include: (a) proline sulfonamide‐catalyzed, Yamada–Otani reaction to establish the C6 all‐carbon quaternary stereocenter, (b) multiple, novel palladium‐mediated oxidative cyclizations to introduce the furan moiety, and (c) oxidative Bergman cyclization to form the final quinone ring.     

Synthesis of [18,19,21,22‐13C4]‐Labeled Tautomycin as an NMR Probe of Protein Phosphatase Inhibitor

We have accomplished the synthesis of ¹³C‐labeled tautomycin at the C18, C19, C21, and C22 positions starting from 100 % [¹³C]triethylphosphonoacetate for the purpose of elucidating the dynamics and conformation of the C17–C26 moiety. NMR spectroscopy of ¹³C‐labeled tautomycin revealed strong binding with protein phosphatase type 1 and new features in the ¹³C NMR spectrum, such as the very small three‐bond coupling constants (²J).     

Total Synthesis of the 7,10‐Epimer of the Proposed Structure of Amphidinolide N,Part I: Synthesis of the C1–C13 Subunit

Amphidinolide N, the structure of which has been recently revised, is a 26‐membered macrolide featuring allyl epoxide and tetrahydropyran moieties with 13 chiral centers. Due to its challenging structure and extraordinary potent cytotoxicity, amphidinolide N is a highly attractive target of total synthesis. During our total synthesis studies of the 7,10‐epimer of the proposed structure of amphidinolide N, we have synthesized the C1–C13 subunit enantio‐ and diastereoselectively. Key reactions include an l ‐proline catalyzed enantioselective intramolecular aldol reaction, Evans aldol reaction, Sharpless asymmetric epoxidation and Tamao–Fleming oxidation. To aid late‐stage manipulations, we also developed the 4‐(N‐benzyloxycarbonyl‐N‐methylamino)butyryl group as a novel ester protective group for the C9 alcohol.