Further studies on synthesis of the 12,13-seco norditerpenoid alkaloids

After a series of optimization for the reaction conditions (reagents, reaction temperature, etc.), treatment of the sulfonates 4, 8, 13 and 15 with 8% NaOH (room temperature, 24 h) via a semipinacol rearrangement afforded the corresponding C-nor compounds 5, 9, 12 and 16, as the major of a pair of epimer at C-16, to an excellent extent, in 95%, 92%, 100% and 90% yield, respectively. The 12,13-seco compounds 21 and 22 (23) were obtained in 20% and 60% yield, respectively, by treating 5 with Br(2)-glacial HOAc (room temperature, 24 h). Treatment of the C-nor compounds 5 or 6, 16 or 17, and 28 from 10 with SOCl(2)-anhydrous benzene (room temperature, overnight) afforded the 12,13-seco compounds 24, 26 and 30 in 70% or 100%, 40% and 66% yield, respectively. When treatment of the C-nor compound 29 from 9 under same conditions gave the 12,13-seco products 30, 31 and 32 in 33%, 26% and 20% yield. When treating 21 or 24, and 26 with 5% KOH in EtOH afforded the 12,13-seco compounds 25 and 27 quantitatively, respectively. The compound 31 converted to 30 quantitatively by treatment with Na(2)CO(3) in MeOH. All of the new compounds were isolated and fully characterized.     

以N-乙酰基-5-N,4-O-噁唑烷酮保护的唾液酸对甲基苯硫苷给体合成神经节苷脂GM3三糖甲苷衍生物

详细研究了N-乙酰基-5-N,4-O-噁唑烷酮保护的唾液酸对甲基苯硫苷给体1与四种苄基或苯甲酰基保护的半乳糖甲苷二醇的唾液酸化反应, 以较高的产率(72%～89%)得到了相应的唾液酸化产物, α/β＝(1.6～2.0)∶1. 在此基础上, 以乳糖为原料通过7步反应以19%的总产率制得了2,3,6,2’,6’-五-O-苯甲酰基-β-乳糖甲苷17, 使用唾液酸给体1将化合物17唾液酸化, 成功地得到神经节苷脂GM3三糖甲苷衍生物18, 产率68%, α/β＝1.6∶1.     

Bone collagen cross-links: a convergent synthesis of (+)-deoxypyrrololine.

A convergent total synthesis of (+)-deoxypyrrololine (Dpl, 4), a putative cross-link of bone collagen, is described starting from a commercially available L-glutamic acid derivative, (4S)-5-(tert-butoxy)-4-[(tert-butoxycarbonyl)amino]-5- oxopentanoic acid (16). Condensation of aldehyde (S)-(-)-17 with nitro compound (S)-(-)-27, both of which were prepared from a common precursor (S)-16, gave the alpha-hydroxynitro compound 28, which upon acetylation afforded alpha-acetoxynitro compound 14 in good yield. Subsequent condensation and cyclization of alpha-acetoxynitro compound 14 with benzyl isocyanoacetate (15) in the presence of DBU in THF gave the key pyrrole intermediate (S,S)-(-)-12 in 57% yield. N-Alkylation of pyrrole (S,S)-(-)-12 with iodide (S)-(-)-13 using t-BuOK in THF afforded the 2-benzyloxycarbonyl-1,3,4-substituted pyrrole derivative (-)-29 in 42% yield. Removal of the protective groups in (-)-29 followed by hydrogenolysis and decarboxylation afforded the cross-link (+)-Dpl (4) in good overall yield. The synthesis of an analogue (S)-(+)-24 and formation of a novel tetrahydroindole derivative (-)-31 are also described.     

Improved synthesis of the A-G ring segment of brevetoxin B

An efficient synthesis of the A-G ring segment 2, a key intermediate for the total synthesis of brevetoxin B (1), was achieved in 37 steps and 5.0% overall yield. The intramolecular allylation of the O,S-acetal 22, prepared from the ABC ring segment 15 and the FG ring segment 17, was carried out using AgOTf as a Lewis acid to give the desired compound 23, predominantly. Ring-closing metathesis of 23 with the Grubbs catalyst 12 afforded the heptacyclic ether 25. Selective hydrogenation of the E ring olefin of 25 was performed by diimide reduction to afford 2.     

Syntheses of substituted-oxazolo-1,3,4-thiadiazoles, 1,3,4-oxadiazoles,and 1,2,4-triazoles

Starting from readily available methyl 5-methyloxazole-4-carboxylate ( 1 ) and 4-methyl-5-oxazolylcar-boxylic acid hydrazide ( 11 ) the title compounds were prepared. The reaction of compound 1 with hydrazine hydrate afforded the corresponding hydrazide 2 . The reaction of compound 2 with formic acid yielded 1-formyl-2-(5-methyloxazole-4-carboxyl)hydrazine ( 3 ). Refluxing of the latter with phosphorus pentasulfide in xylene gave compound 5 in 62% yield. The reaction of compound 3 with phosphorus pentoxide afforded compound 4 . Starting from hydrazide 11 , compounds 13 and 14 were prepared similarly. Reaction of compound 2 with substituted isothiocyanate yielded compound 9 which was cyclized in basic medium to 4-alkyl-5-(5-methyl-4-oxazolyl)-2,4-dihydro-3H-1,2,4-triazole-3-thione ( 10 ). The isomer 19 was prepared similarly. Methylation and subsequent oxidation of compound 19 gave compound 21 . Reaction of the acid 7 with thiosemicarbazide in the presence of phosphorus oxychloride gave 2-amino-5-(5-methyl-4-oxazolyl)1,3,4-thiadiazole ( 8 ). 2-Amino-5-(4-methyl-5-oxazolyl)-1,3,4-thiadiazole ( 17 ) was prepared from acyl chloride 15 by the usual method.     

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.     

3-氨基-2-羟基-4-苯基丁酸的合成

3-氨基-2-羟基-4-苯基丁酸的合成;乌苯美司;氨基羟基苯基丁酸;合成     

Nitroimidazoles. IX. Synthesis of 2-acetyl-1-methyl-5-nitroimidazole

Manganese dioxide oxidation of 2-hydroxymethyl-1-methyl-5-nitroimidazole (6) gave 1-methyl-5-nitroimidazole-2-carboxaldehyde (7) in high yield. Reaction of diazomethane with 7 afforded the title compound 1 in low yield. Treatment of ethyl acid malonate with two equivalents of isopropylmagnesium bromide in THF and subsequent addition to 1-methyl-5-nitroimidazole-2-carbonylimidazolide (12) yielded ethyl (1-methyl-5-nitroimidazole-2-carbonyl)acetate (10) in 70% yield. Hydrolysis and decarboxylation of compound 10 gave the desired compound 1 in 97% yield.     

Syntheses of substituted 1-methyl-2-(1,3,4-thiadiazol-2-yl)-4-nitropyrroles and 1-methyl-2-(1,3,4-oxadiazol-2-yl)-4-nitropyrroles

Starting from readily available ethyl-4-nitropyrrole-2-carboxylate ( 1 ), substituted 1-methyl-2-(1,3,4-thiadiazol-2-yl)-4-nitropyrroles and 1-methyl-2-(1,3,4-oxadiazol-2-yl)-4-nitropyrroles were prepared. The reaction of 1 with diazomethane gave ethyl 1-methyl-4-nitropyrrole-2-carboxylate ( 2 ). Reaction of compound 2 with hydrazine hydrate afforded the corresponding hydrazide 3 . The reaction of 3 with formic acid yielded 1-(1-methyl-4-nitropyrrole-2-carboxyl)-2-(formyl)hydrazine ( 7 ). Refluxing of the latter with phosphorus pentasulfide in xylene yielded compound 6 in 40% yield. Reaction of compound 7 with phosphorus pentoxide afforded compound 9 . Reaction of compound 3 with 1,1′-carboxyldiimidazole in the presence of triethylamine yielded 2-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-oxadiazoline-4(H)-5-one ( 11 ). Refluxing compound 3 with cyanogen bromide in methanol gave compound 12 . Compound 13 could be obtained through the reaction of compound 3 with carbon disulfide in basic medium. Alkylation of compound 13 afforded the correspanding alkylthio derivative 14 . Reaction of 1-methyl-4-nitropyrrole-2-carboxylic acid ( 15 ) with thiosemicarbazide and phosphorus oxychloride gave 2-amino-5-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-thiadiazole ( 16 ). Sandmeyer reaction of compound 16 yielded 2-chloro-5-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-thiadiazole ( 17 ). Refluxing of the latter with thiourea afforded 2-(1-methyl-4-nitro-2-pyrrolyl)-1,3,4-thiadiazoline-4(H)-5-thione ( 18 ). Alkylation of compound 18 gave the corresponding alkylthio derivative 19 . Oxidation of the latter with hydrogen peroxide in acetic acid yielded 2-(1-methyl-4-nitro-2-pyrrolyl)-5-methylsulfonyl-1,3,4-thiadiazole ( 20 ).     

Synthesis of Novel Benzo‐substituted Macrocyclic Ligands Containing Thienothiophene Subunits

A facile synthetic approach was adopted toward the synthesis of benzo‐fused macrocyclic ligands with thienothiophene group incorporated into the ring system. Thus, treatment of bis(bromomethyl) compound 2 with the K salt of the appropriate bis(phenol)s 3a , 3b , 3c , 3d in boiling DMF led to the formation of the novel macrocyclic diamides 4a , 4b , 4c , 4d in 39–58% yield. Reaction of 2 with the potassium salt (obtained upon treatment of salicylaldehyde 5 with ethanolic potassium hydroxide) in refluxing DMF afforded the novel bis(aldehyde) 6 in 73% yield. Cyclocondensation of 6 with the appropriate bis(N‐substituted) cyanoacetamide derivatives 7a and 7b afforded the target macrocycles 8a and 8b in 48 and 55% yields, respectively. Reaction of the bis(aldehyde) 6 with 1,3‐ and 1,4‐diaminopropane 9a and 9b in refluxing ethanol under high‐dilution conditions afforded the corresponding macrocyclic Schiff bases 10a and 10b in 41 and 37% yields, respectively. Cyclocondensation of 6 with 1,3‐bis(4‐amino‐5‐phenyl‐3‐ylsulfanylmethyl)propane ( 15 ) in glacial acetic acid under high‐dilution conditions gave the macrocyclic Schiff base 14 in 46% yield. On the other hand, cyclocondensation of bis(aldehydes) 17 and 20 with 3,4‐bis(4‐amino‐5‐phenyl‐3‐ylsulfanylmethyl)thienothiophene 16 in refluxing acetic acid under high‐dilution conditions afforded unexpectedly the novel condensed heteromacrocycles 18 and 21 in 33 and 28%, respectively. The novel bis(amine) 16 was obtained in 50% yield upon treatment of 2 with 4‐amino‐1,2,4‐triazol‐3‐thione 11 in ethanol/water mixture containing potassium hydroxide.     

Nitroimidazoles. VI. Syntheses of 1-methyl-2-(1,3,4-thiadiazol-2-yl)-5-nitroimidazole and 1-methyl-2-(1,3,4-oxadiazol-2-yl)-5-nitroimidazole

Starting from readily available 1-methyl-5-nitroimidazole-2-carboxylic acid hydrazide (1), 1-methyl-2-(1,3,4-thiadiazol-2-yl)-5-nitroimidazole (4) and 1-methyl-2-(1,3,4-oxadiazol-2-yl)-5-nitroimidazole (10) were prepared. The reaction of 1 with formic acid gave 1-(1-methyl-5-nitroimidazole-2-carboxyl)-2-(formyl)hydrazine ( 8 ) in high yield. Refluxing of the latter with phosphorus pentasulfide in xylene yielded compound 4 in 50% yield. Reaction of compound 8 with phosphorus pentoxide afforded compound 10 in 60% yield.     

Solid-phase synthesis of hydroxysteroid derivatives using the diethylsilyloxy linker

Four different types of hydroxysteroids (primary alcohol, secondary alcohols, and phenol), bearing either an oxirane or an azide as a precursor of molecular diversity, were linked in good yields to solid support using the butyldiethylsilane polystyrene (PS-DES) resin. These molecules were then used as scaffolds to generate hydroxysteroid derivatives containing two levels of diversity. The proposed libraries were tested by running steroidal alcohols through a model sequence of reactions (solid-phase coupling, aminolysis of oxirane or reduction of azide, amidation, and final cleavage). As a result, two linked secondary alcohols (17beta-hydroxy-spiro-3(R)-oxirane-5alpha-androstane and 3beta-hydroxy-spiro- 17(S)-oxirane-5alpha-androstane) and a primary alcohol (spiro-17(S)-oxirane-3-(hydroxymethyl)-1,3,5(10)-estratriene) afforded good overall yields (>45%) and high HPLC purities (>90%) of hydroxysteroids derivatized as alkylamides without purification. One limitation was noted for the fourth library: the phenolic steroid linked by the diethylsilyloxy linker gave a poor overall yield of 8% of the desired model compound. Finally, the diethylsilyloxy linker was used successfully for a rapid solid-phase synthesis of a model library of twenty C19-steroid derivatives (3beta-amido-3alpha-hydroxy-5alpha-androstane-17-ones), with an average yield of 53% and average HPLC purity of 97% without purification steps.     

A new method for the preparation of 2-thio substituted furans by methylsulfanylation of gamma-dithiane carbonyl compounds

Several related methods for the preparation of differentially substituted 2-thiofurans are described. The general procedure involves the formation of a thionium ion from a gamma-dithianyl substituted carbonyl compound followed by cyclization of this reactive intermediate onto the tethered carbonyl group. Two methods for thionium ion generation were explored. One of these involved an acid-catalyzed reaction of beta-ketenedithioacetals, prepared from the condensation of 2,2-bis(methylsulfanyl)acetaldehyde with a variety of ketones. Cyclization followed by loss of methane thiol gave 2-thiofurans 17, 18 and 23, 24 in 70-90% yield. Attempts to prepare 5-heteroatom substituted 2-thiofurans from the corresponding beta-ketenedithioacetal amides or esters were unsuccessful, leading to 1,2-thio rearranged products. A more successful route involved the reaction of beta-acetoxy-gamma-thianyl carbonyl compounds with dimethyl(methylthio)sulfonium tetrafluoroborate (DMTSF). Treatment of the dithiane with this reagent resulted in the smooth generation of a thionium ion. Cyclization followed by loss of acetic acid afforded thiofurans 17, 18, 23, 47-49, 51, and 61-64 in 40-100% yield. The N-butenyl substituted thioamido furan furnished a rearranged hexahydropyrroloquinolin-2-one in high yield when heated at 110 degrees C.     

Asymmetric and nonasymmetric addition of RLi and RMgX to 3-methoxynaphthalen-2-yl oxazolines and imines. An approach to substituted 2-tetralones

Chiral and achiral 3-methoxynaphthalen-2-yl oxazolines 4a,b failed to undergo an aromatic nucleophilic displacement of the 3-methoxy group with organolithium reagents and instead afforded dihydronaphthalenes 9 and 14 in 30-95% yield. Dihydronaphthalenes 9 (racemic) and 14 (nonracemic) were easily converted into the corresponding aldehydes 15. Alternatively, aldehydes 15 were prepared via tandem addition of Grignard reagents to imines 17 in 50-65% yield. Aldehydes 15 served as precursors to 3,3, 4-trisubstituted 2-tetralones 16. Use of methyl chloroformate to trap the azaenolate derived from 17f and i-PrMgCl afforded, in 65% yield, a versatile synthetic intermediate 23 which may serve to access 4-alkyl-, 3,4-dialkyl-, 3,4-disubstituted and 3,3, 4-trisubstituted 2-tetralones with diverse substitution patterns.     

Synthesis of jenamidines A1/A2

[reaction: see text] Addition of the enolate of tert-butyl acetate to cyanamide methyl ester 17 followed by treatment with LHMDS afforded vinylogous urea 19 in 27% yield. Vinylogous urea 19 was also obtained from 37 and tert-butyl cyanoacetate in 50% yield. Acylation of 19 with acid chloride 31d, followed by hydrolysis of the tert-butyl ester and decarboxylation with 9:1 CH2Cl2/TFA and very mild basic hydrolysis of the methoxyacetate ester, afforded jenamidines A1/A2 (3) in 45% yield. This first synthesis confirms our reassignment of the jenamidines A1/A2 structure.     

Asymmetric total synthesis of (+)-cannabisativine

The asymmetric total synthesis of natural (+)-cannabisativine 1 was completed in 19 steps and 7% overall yield. The key synthetic intermediate 29 was prepared with a high degree of stereocontrol in 12 steps starting from chiral 1-acylpyridinium salt 10. Addition of zinc enolate 11 to pyridinium salt 10 furnished dihydropyridone 12 containing two contiguous stereocenters of the correct absolute configuration. Luche reduction of ketone 16 afforded diol 17 in high yield (96%) and excellent diastereoselectivity. The Mukaiyama-Michael reaction of pyridones 27a/b with O-silyl ketene acetal 32 gave phenyl selenyl ketones 33a/b with complete stereoselectivity. Elimination of cis-beta-hydroxyselenides 34 and 35 effected the regiocontrolled preparation of tetrahydropyridine derivative 29. Several approaches to the macrocyclic ring closure of the 13-membered ring were investigated, ultimately leading to the completion of an asymmetric synthesis of the target compound with a high degree of stereocontrol.     

Asymmetric synthesis of alpha-amino acids: preparation and alkylation of monocyclic iminolactones derived from alpha-methyl trans-cinnamaldehyde

Two novel chiral monocyclic iminolactones 14a and 14b have been prepared. The chiral auxiliary 12 was obtained from alpha-methyl-trans-cinnamaldehyde through reduction, methylation, Sharpless asymmetric dihydroxylation, and oxidation in 87% overall yield. Esterification of compound 12 with the respective protected amino acids followed by deprotection and cyclization provided the corresponding iminolactones, each in 82% overall yield. Alkylation of the iminolactone 14a afforded the alpha-methyl-alpha,alpha-disubstituted products 15 and 16 in good yields (78-99%) and excellent diastereoselectivity (de >98%). Alkylations of the iminolactone 14b furnished the alpha-benzyl-alpha,alpha-disubstituted products 15a, 16b, 17, and 18 in good yields (51-86%) but moderate diastereoselectivities (43-56%). When HMPA or DMPU was used as a cosolvent, the rate of alkylation of the iminolactone 14b was accelerated with improved yields (56-99%) and diastereoselectivities (50-83%). Hydrolysis of the dialkylated iminolactones yielded the alpha,alpha-disubstituted alpha-amino acids in good yields (80-98%) and high enantiomeric excesses (98-99%) with good recovery of compound 12 (83-92%).     

Studies on the identification and synthesis of insect pheromone: XXIV. Synthesis of (7R, 8S)-(+)- and (7S, 8R)-(−)-sex pheromone of gypsy moth and stereochemistry of β-hydroxysilane

Condensation of the epoxy aldehyde 2 or 2 prepared by Sharpless asymmetric epoxydation in 96—97% yield, with trimethylsilane lithiated 3 gave 7 or 7 ′, which after transformation to the corresponding acetoxyl compound 8 or 8 ′ afforded the title compound 1a or 1b via β-acetoxysilane elimination and catalytic homogeneous hydrogenation. The configurations of the stereoisomers 7 and 7 ′ were determined.     

N-[(S)-脯氨酰]羟胺的合成及催化直接不对称羟醛反应研究

(S)-脯氨酸用苯甲氧羰酰氯保护氨基后用混合酸酐法与羟胺偶合, 给出N-[N-苯甲氧羰酰-(S)-脯氨酰]羟胺, 催化氢解脱去保护基得标题化合物. 该化合物对映选择性催化直接羟醛反应, 产率最高达到90.0%, 对映体过量最高达89.5%.     

Novel products from oxidation of the norditerpenoid alkaloid pseudaconine with HIO4.

Oxidation of pseudaconine 8, a norditerpenoid alkaloid, with HIO4 led to a series of novel interesting products, depending greatly on reaction medium and work-up conditions. Treatment of 8 in MeOH-H2O (1:1) with NaIO4 gave compounds 10 and 11, but compound 12 was obtained quantitatively when the final reaction solution was alkalized with conc. NH4OH. The imine 12 was also obtained in 100% yield by treating 8 in 5% HCl solution with NaIO4 followed by alkalizing the reaction products to pH>9 with conc. NH4OH. When the work up pH was 7-8, only N,O-mixed acetal-ketal 13 was formed in 96% yield, which was converted quantitatively to 12 by further alkalizing. When the reaction mixture was alkalized to pH 7-8 with Na2CO3, a hemiacetalketal 14 was afforded quantitatively, which was converted to 15 in 87% yield by further treatment with Na2CO3 or 5% NaOH methanol. Compound 15 could be converted back to 14 by treatment with 10% HCl solution. Acetylation of the imine 12 gave the compounds 16 and 17 in 15% and 19% yields, respectively. All of the new compounds were isolated and fully characterized.