Furopyridines. VI. Preparation and reactions of 2- and 3-substituted furo[2,3-b]pyridines

This paper describes the synthesis and chemical properties of some 2- and 3-substituted furo[2,3-b]pyridines. Reaction of ethyl 2-chloronicotinate 1 with sodium ethoxycarbonylmethoxide or 1-ethoxycarbonyl-1-ethoxide gave β-keto ester 2 or ketone 5 , respectively. Ketonic hydrolysis of 2 afforded ketone 3, from which furo[2,3-b]pyridine 4 was obtained by the method of Sliwa. While, 2-methyl derivative 7 was prepared from 5 by reduction, O-acetylation and the subsequent pyrolysis. Reaction of ketone 3 with methyllithium gave tertiary alcohol 8 which was O-acetylated and pyrolyzed to give 3-methyl derivative 9 . Formylation of 4 , via lithio intermediate, with DMF yielded 2-formyl derivative 10 , from which 7 , was obtained by Wolff-Kishner reduction. Dehydration of the oxime 11 of 10 gave 2-cyano derivative 12 , which was hydrolyzed to give 2-carboxylic acid 13 . Reaction of 3-bromo compound 14 with copper(I) cyanide gave 3-cyano derivative 15 . Alkaline hydrolysis of 15 afforded compound 16 and 17 , while acidic hydrolysis gave carboxamide 18 . Reduction of 15 with DIBAL-H afforded 3-formyl derivative 19 . Wolff-Kishner reduction of 19 gave no reduction product 9 but hydrazone 20 . Reduction of tosylhydrazone 21 with sodium borohydride in methanol afforded 3-methoxymethylfuro[2,3-b]pyridine 22 .     

A new strategy for the enantioselective synthesis of carba-prostacyclin analogues based on organocopper conjugate addition to a bicyclic azoene and its application to the synthesis of 13,14-dinor-inter-p-phenylene carbacyclin

An enantioselective synthesis of E/Z-13,14-dinor-inter-p-phenylene carbacyclin (E/Z-2d) by a new strategy has been realized that holds the prospect of serving as a general route for carba-prostacyclin analogues. The key intermediate in this synthesis is the bicyclic azoene Ts-9, and the key step is the regio- and stereoselective conjugate addition of the chiral arylcopper compound Cu-8d/P-n-Bu3 to the azoene with formation of hydrazone 7d. Enantioselective synthesis of azoene Ts-9 of 95% ee from ketone 4 was accomplished in four and five steps, respectively. Thus, enantioselective deprotonation of bicyclic ketone 4 with chiral base Li-10 and trapping of lithium enolate 11 with ClSiMe3 gave enol ether 12, which was chlorinated with N-chlorosuccinimide (NCS) to afford chloro ketone 13. Alternatively, chloro ketone 13 was also prepared upon chlorination of 11 with NCS. Chloro ketone 13 was converted to chloro hydrazone 14, which upon treatment with a mild base furnished azoene Ts-9. Arylcopper compound 8d of 98% ee was obtained in two steps from alcohol 16, which was prepared by enantioselective reduction of ketone 17 with (-)-diisopinocampheylchloroborane. Carbacyclin derivative E/Z-2d was found to be essentially inactive as an inhibitor of ADP induced human platelet aggregation, having an IC50 of >10 micromol/L.     

Structure reassignment and synthesis of Jenamidines A1/A2, synthesis of (+)-NP25302, and formal synthesis of SB-311009 analogues

The proposed structures of jenamidines A, B, and C (1-3) were revised to jenamidines A1/A2, B1/B2, and C (8-10). Jenamidines A1/A2 (8) were synthesized from activated proline derivative 43 by conversion to 26 in two steps and 50% overall yield. Acylation of 26 with acid chloride 38d gave 39d, which was deprotected with TFA and then mild base to give 8 in 45% yield from 26. (-)-trans-2,5-Dimethylproline ethyl ester (49) was prepared by the enantioselective Michael reaction of ethyl 2-nitropropionate (51) and methyl vinyl ketone (50) using modified dihydroquinine 60 as the catalyst. Further elaboration converted 49 to natural (+)-NP25302 (12). A Wittig reaction of proline NCA (76) with ylide 79 gave 72 as a 9/1 E/Z mixture in 27% yield, completing a one-step formal synthesis of SB-311009 analogues.     

Total Synthesis of Dimethyl Glolosiphone A via α-Carbonyl Radical Spiro-Cyclization

A general approach toward spiro[4.4]nonane structure based on the α-carbonyl radical cyclization has been developed. Efficient total synthesis of dimethyl gloiosiphone A ( 2 ) was achieved. Thus, alkylation of the anion of dimethylhydrazone of cyclopentanone with 5-iodopent-1-yne followed by hydrolysis gave ketone 4 . Iodination of 4 via its TMS-enol ether yielded iodo ketone 7 . Radical spiro-cyclization of 7 gave spiro ketone 10 . Iodination of 10 afford iodo spiro ketone 23 . Oxidation and iodination of 23 gave compound 24 . Methylation of 24 furnished methoxy iodo enone 25 . Substitution of iodide in 25 with methoxide produced dimethoxy enone 26 . Allylic oxidation of 26 gave diketone 27 . Treatment of 27 with OsO₄ and N-methylmorpholine N-oxide gave dihydroxy ketone 28 . Methylation of the primary alcohol group in 28 afforded dimethyl gloiosiphone A ( 2 ).     

Total Syntheses of (-)-Papuamine and (-)-Haliclonadiamine

The pentacyclic marine alkaloids (-)-papuamine (1) and (-)-haliclonadiamine (2) have been prepared by total synthesis. The synthesis began with (-)-8, which was converted into diester 20 by way of bis-mesylate 17, dinitrile 18, and diacid 19. Dieckmann cyclization of 20 provided keto ester 21, which was transformed into acetal 22. After hydrolysis of the acetal, ketone 25 was subjected to reductive amination with 1,3-propanediamine and sodium triacetoxyborohydride to obtain diamines 26 and 27 as a 71:29 mixture of diastereomers, favoring the symmetrical isomer having the papuamine relative configuration. After transformation of the diamines to their t-Boc derivatives, the benzyl ethers were cleaved and the resulting diol was oxidized to dialdehyde 30. Application of the Seyferth procedure for conversion of aldehydes to alkynes gave a mixture of diynes 31 and 32. After removal of the t-Boc protecting groups from 31, diamino diyne 15 was treated with tributylstannane and azoisobutyronitrile to obtain the bis-vinylstannane 34. Treatment of this compound with Pd(II) and Cu(I) in the presence of air produced (-)-papuamine (1). (-)-Haliclonadiamine (2) was obtained from the unsymmetrical isomer, 32. The NMR spectra of the synthetic alkaloids were identical to those of authentic samples of the natural alkaloids.     

大二环型侧向穴醚的合成

本文报道一个大二环型侧向穴醚的合成方法借2,6-二(溴甲基)吡啶与β-(N-对甲苯磺酰基)丙氨酸酯缩合,产物经水解成酸后转换为酰氯(8),8借高度稀释法与1,7-二氮杂-4,10-二硫杂环十二烷(5)缩合成环,然后还原羰基.脱对甲苯磺酰基后得大二环型侧向穴醚1,5,13,17,28-五氮杂-20,25-二硫杂-三环[15,5,5,1~(7,11)]-廿八-7,9,11(28)三烯(2).     

Anionic cyclization approach toward perhydrobenzofuranone: stereocontrolled synthesis of the hexahydrobenzofuran subunit of avermectin

A facile anionic cyclization approach toward stereocontrolled synthesis of the hexahydrobenzofuran subunit 3 of avermectin is described. As a model study, treatment of iodo compound 7 with n-BuLi at -100 degrees C effected metal-halogen exchange and subsequent anionic cyclization to afford perhydrobenzofuranone 8. For the total synthesis of subunit 3, compound 9 was dihydroxylated to give diol 10. Protection of the hydroxyl groups of diol 10 gave compound 11. Ketone 11 was then converted into the required enone 12 using Saegusa's protocol. On iodination followed by Luche reduction, enone 12 yielded alpha-iodo allylic alcohol 14, which on alkylation afforded ether 15. Conversion of the ester unit of 15 into a Weinreb amide group followed by anionic cyclization gave enone 17. 1,4-Addition of (MeOCH(2))(2)CuCNLi(2) to enone 17 followed by cleavage of the acetal unit afforded ketone 19. Preferential acetylation of the secondary alcoholic function of 19 afforded compound 20. The stereochemistry of 20 is confirmed by single-crystal X-ray analysis. Elimination of HOAc from 20 gave the crucial olefin 21. Hydrolysis of the acetate unit of 21 followed by protection of the resulting alcoholic function yielded tert-butyldimethylsilyl ether 23. Introduction of a hydroxyl group at the ring junction of 23, using Davis's procedure, finally afforded the hexahydrobenzofuran subunit 3.     

First Total Synthesis of (±)-Abieta-8, 11, 13-trien-7β-ol

The first total synthesis of (±)-abieta-8, 11, 13-trien-7β-ol (7) was accomplished via a strategy of AC→ABC, in which the reduction of the ketone 6 with LiAlH4 gave exclusively the title compound.     

Furopyridines. V. A simple synthesis of furo[2,3-c]pyridine and its 2-and 3-methyl derivatives

A simple synthesis of furo[2,3-c]pyridine and its 2- and 3-methyl derivatives from ethyl 3-hydroxyisonicotinate ( 2 ) is described. The hydroxy ester 2 was O-alkylated with ethyl bromoacetate or ethyl 2-bromopropionate to give the diester 3a or 3b . Cyclization of compound 3a afforded ethyl 3-hydroxyfuro [2,3-c]pyridine-2-carboxylate ( 4 ) which was hydrolyzed and decarboxylated to give furo[2,3-c]pyridin-3(2H)-one ( 5a ). Cyclization of 3b gave the 2-methyl derivative 5b . Reduction of 5a and 5b with sodium borohydride yielded the corresponding hydroxy derivative 6a and 6b , respectively, which were dehydrated with phosphoric acid to give furo[2,3-c]pyridine ( 7a ) and its 2-methyl derivative 7b . 4-Acetylpyridin-3-ol ( 8 ) was O-alkylated with ethyl bromoacetate to give ethyl 2-(4-acetyl-3-pyridyloxy) acetate ( 9 ). Saponification of compound 9 , and the subsequent intramolecular Perkin reaction gave 3-methylfuro[2,3-c]pyridine ( 10 ). Cyclization of 9 with sodium ethoxide gave 3-methylfuro[2,3-c]pyridine-2-carboxylic acid, which in turn was decarboxylated to give compound 10 .     

First Total Synthesis of (±)-Abieta-8,11,13-trien-7-ol

(?-Abieta-8, 11, 13-trien-7-ol (7)1was a diterpene isolated from the leaves of J. chinensis kaizuka2. To our knowledge, no total synthetic work has been reported on it. Many of this type diterpenes exhibit significant bioactivities, such as antibacterial activity3, antitumor4~5, and anti HIV6. In order to study the further relationship between the structure and bioactivities, we synthesized the title compound. To contrast with our prior work7~10, the synthesis in this work had some diffe…     

Asymmetric synthesis of a selective endothelin A receptor antagonist

An asymmetric synthesis of a selective endothelin A receptor antagonist 1b is described. Asymmetric conjugate addition of aryllithium derived from 18 to the chiral oxazoline 17 followed by hydrolysis afforded 15 in 96% ee via purification as (S)-(-)-1-phenylethylamine salt. Pd(OAc)(2)/dppf (1,1'-bis(diphenylphosphino)ferrocene) catalyzed carbonylation followed by chemoselective addition of aryllithium derived from 23 which gave ketone 24. Diastereoselective reduction of the ketone with catecholborane followed by concomitant activation of the resulting alcohol and cyclization gave the late intermediate 26. Introduction of amino moiety on the pyridine ring by imidoyl rearrangement followed by deprotection and purification by crystallization furnished the enantiomerically pure target molecule 1b in 8% overall yield from 16.     

An alternative synthesis of piritrexim,a lipophilic inhibitor of human dihydrofolate-reductase

An alternative synthesis of the lipophilic antifolate piritrexim ( 1 ) is outlined. Starting from ketone 2 , treatment with phosphorus oxychloride and dimethylformamide gave the β-chlorocrotonaldehydes 3E/Z , which were reacted with cyanoacetamide ( 6 ) in the presence of sodium hydride to yield a 3-cyano-2-pyridone derivative 7 . Chlorination of 7 with thionyl chloride and subsequent reaction with guanidine ( 9 ) gave rise to piritrexim ( 1 ). The reaction of β-chlorocrotonaldehydes 3E/Z , with 2,4,6-triaminopyrimidine ( 4 ) yielded iso-piritrexim ( 5 ).     

Synthesis of optically active (+)-19-nortestosterone by asymmetric bis-annulation reaction

Michael reaction of 1,7-pctadien-3-one with 2-methylcyclopentane-1,3-dione, followed by intramolecular aldol condensation promoted by L-amino acids produced the optically active (+)-4-(3-butenyl)-7a-methyl-5,6,7,7a-tetrahydroindane-1,5-dione in high chemical and optical yields. The PdCl₂-catalyzed oxidation of the terminal double bond gave the methyl ketone, which had 76% optical purity and was made 100% optically pure by recrystallization. Then aldol condensation afforded the tricyclic ketone, which was alkylated with 3-butenyl iodide to afford (?)-3β-t-butoxy-2,3,3a,4,5,7,8,9,9aβ,9bα-decahydro-6-(3-butenyl)-3aβ-methyl-1H-benz[e]inden-7-one. The synthesis of this compound means the total synthesis of (+)-19-nortestosterone.     

Development of a common fully stereocontrolled access to the medicinally important and promising prostacyclin analogues iloprost, 3-oxa-iloprost and cicaprost

We describe new fully stereocontrolled syntheses of the prostacyclin analogues iloprost (2), the most active component of the drugs Ilomedin and Ventavis, and 3-oxa-iloprost (3), a derivative that is expected to have a significantly higher metabolic stability than 2 perhaps allowing an oral application. The syntheses are based on the same strategy and chiral bicyclic building block as used in the synthesis of cicaprost (4), the third most potent analogue that exhibits, besides prostacyclin-like activities, antimetastatic activities. Reaction of the enantiopure C6-C13 bicyclic aldehyde 17 with Cl(3)CCOOH/Cl(3)CCOONa afforded trichlorocarbinol 24 which was converted via mesylate 25 to the C6-C14 bicyclic alkyne 9. The palladium-catalysed hydrostannylation of alkyne 9 gave with high regio- and stereoselectivity the alkenylstannane 26, Sn/Li exchange of which afforded the E-configured alkenyllithium derivative 8. Coupling of the C6-C14 building block 8 with the enantiopure C15-C20 building block, the N-methoxyamide 7, gave the C6-C20 bicyclic ketone 6 in high yield without epimerisation at C16. The configuration at C15 of iloprost (2) and 3-oxa-iloprost (3) was established through a highly diastereoselective reduction of ketone 6 with catecholborane and the chiral oxazaborolidine 28 which furnished alcohol (15S)-29. The highly stereoselective conversions of alcohol (15S)-29 to iloprost (2) and 3-oxa-iloprost (3), which include as key stereoselective steps an olefination with a chiral phosphonoacetate and a copper-mediated allylic alkylation, have already been described.     

1,4-二硝基-2,3-二硝胺基哌嗪的合成

本文以乙二胺, 乙二醛和脲为原料, 通过Mannich反应, 合成出2,5,7,9-四氮杂双环[4.3.0]壬-8-酮盐酸盐(1); 化合物1 亚硝化给出2,5-二亚硝基-2,5,7,9-四氮杂双环[4.3.0]壬-8-酮(2); 硝化化合物2制得2,5,7,9-四硝基-2,5,7,9-四氮杂双环[4.3.0]壬-8-酮(3); 化合物3水解制得1,4-二硝基-2,3-二硝胺基哌嗪(4).     

Synthesis of tricyclic analogues of methyllycaconitine using ring closing metathesis to append a B ring to an AE azabicyclic fragment

The synthesis of several ABE tricyclic analogues of the alkaloid methyllycaconitine 1 is reported. The analogues contain two key pharmacophores: a homocholine motif formed from a tertiary N-ethyl amine in a 3-azabicyclo[3.3.1]nonane ring system and a 2-(3-methyl-2,5-dioxopyrrolidin-1-ly)benzoate ester 4. The synthesis of the ABE tricyclic analogues of MLA 1 began with selective allylation at C-3 of 3 to produce allyl beta-keto ester 4. Double Mannich reaction of 4 with ethylamine and formaldehyde produced bicyclic amine 5 The C-9 ketone of bicyclic amine 5 was selectively reduced to form bicyclic alcohols 6 and 7 which were subsequently allylated to form dienes 8 and 9. Ring closing metathesis of dienes 8 and 9 afforded tricyclic ethers 11 and 12, respectively, the C-8 ester of which was reduced to a hydroxymethyl group to form ABE tricyclic analogues 13 and 14. Addition of allylmagnesium bromide to the C-9 ketone of 20 afforded dienes 21 and 22, which underwent ring closing metathesis to form tricyclic esters 23 and 24, respectively. Reduction of the C-8 ethyl ester of 23 and 24 to a hydroxymethyl group afforded diols 25 and 26 respectively. The 2-(3-methyl-2,5-dioxopyrrolin-1-ly)benzoate ester was introduced by conversion of alcohols 13, 14, 25 and 26, to the anthranilate esters 16, 17, 27 and 28 using N-(trifluoroacetyl)anthranilic acid 15 followed by fusion with methylsuccinic anhydride to afford the substituted anthranilates 18, 19, 29 and 30 containing the key 2-(3-methyl-2,5-dioxopyrrolidin-1-ly)benzoate ester pharmacophore.     

Stereoselective total synthesis of (±)-peribysin E

Radical cyclization of iodoketone 3 afforded cis-hydrindanone 8. Compound 8 was converted into key intermediate 5 via conventional transformations. Annulation of a spiro-lactal unit to 5 was pursued with three different approaches. In the first approach, radical cyclization of propargyl ester 17 provided spiro-lactone 18 with an undesired stereochemistry. Attempts to invert the stereochemistry at the spiro-center via retro-aldol and aldol condensation of compound 20 failed. In the second approach, key intermediate 5 was transformed into 23. Acylation of compound 23 gave 24 as a single diastereomer with the desired stereochemistry but in low yield. NBS bromination of 24 followed by lactone formation gave 26 in low yield. Alternatively, allylic oxidation of 24 with SeO(2) followed by lactonization gave 26 also in low yield. Finally, a third approach employing a semipinacol-type rearrangement of epoxy-alcohol 33 gave aldehyde 34 with the desired stereochemistry. Treatment of compound 34 with HCl in MeOH effected spiro-lactal formation and provided (±)-peribysin E. The overall yield of our synthesis is 3.2% from 2-methylcyclohenen-1-one.     

An efficient approach to 3,4-disubstituted pyridin-2-ones. Formal synthesis of mappicine ketone

Treatment of 3,4-dihydro-3-tosylpyridin-2-one 5 with sodium hydride and then alkyl halides gave various 3,4-disubstituted pyridin-2-ones 6. Formal synthesis of mappicine ketone (1) was also reported.     

New rearrangement reactions of the trichothecane framework]

Treatment of the apotrichothecane derivative 4 with H₂SO₄ in dioxan gave the acetal 6 and with H₂SO₄ in acetone the ketal 9 . Whereas the oxidation of 4 with Ag₂CO₃ yielded the hydroxy aldehyde 7 , the reaction with CrO₃ or MnO₂ led to the α,β-unsaturated ketone 8 . Upon treatment of 8 with base the cyclic keto ether 11 was obtained due to 1,4-addition. Acetylation of the latter compound gave a mixture consisting of the enolacetate 13 and the acetylketone 14 . The oxim 15 of ketone 14 was transformed to the nitrile 16 and not the Beckmann fragmentation product 18 . For the identification of the C(11) hydrogen atom in biosynthetic studies the triol 22 was oxidized to the keto aldehyde 26 which, upon treatment with methanolic K₂CO₃, gave the spirolactol 30 and the cyclic acetal 29 as second product when the reaction was carried out in dilute solution. The spirolactol 30 was oxidized to the spirolactone 31 . The corresponding 19 possessing the intact 12,13-epoxy group underwent rearrangement to the apotrichothecane derivatives 20 and 21 under the same conditions. Oxidation of the triol 22 with MnO₂ or CrO₃ gave a mixture of the acetal 23 and the keto acid 24 . – The mechanisms of the rearrangements observed are discussed.     

(Z)-3-丁烯基-5-羟基苯酞的合成

以对羟基苯甲酸为原料,首次合成(Z)-3-丁烯基-5-羟基苯酞．发现芳环上的甲胺甲酸基中氮原子的诱导作用是关键步骤,使甲胺甲酸基邻位选择性理化,从而在芳环上定向引入甲酸基．