Total synthesis azides

Azaspirocyclic ketoaziridines 304 (X = Cl or OTBS), potential intermediates for the total synthesis of antitumor alkaloid cephalotaxine 305, have been prepared in 26% (X = Cl) and 76% (X = OTBS) yields, respectively, via an lAOC reaction of azide 303 (Eq. 34) [80]. 

Regioselective Beckmann rearrangements were used as key steps in the synthesis of phosphonoalkyl azepinones (Scheme 36) [43b] and in a formal total synthesis of the protein kinase C inhibitor balanol (Scheme 37) the optically active azide 197 derived from cyclohexadiene mono-oxide was converted into ketone 198 in several steps. After preparation of the oxime tosylates 199 (2.3 1 mixture), a Lewis acid mediated regioselective Beckmann rearrangement gave the lactams 200 and 201 in 66% and 9% yield, respectively. Lactam 201 underwent a 3-e im-ination to give additional 200, which served as a key intermediate in a balanol precursor synthesis (Scheme 37) [43 cj. 

A total synthesis of O-methylarnottianamide (223) was performed by Falck et al. (177) (Scheme 34). The regio- and stereospecific cycloaddition of the 2,4-dinitrophenyl (DNP) salt of 6,7-methylenedioxyisoquinoline (218) with a-methoxystyrene 219 resulted in 220. Compound 220 was hydrolyzed, then aromatized, and the resultant aldehyde was oxidized to carboxylic acid 221. Curtius rearrangement of the appropriate azide yielded urethane 222, which... 

The stereoselective total synthesis of (+)-epiquinamide 301 has been achieved starting from the amino acid L-allysine ethylene acetal, which was converted into piperidine 298 by standard protocols. Allylation of 297 via an. V-acyliminium ion gave 298, which underwent RCM to provide 299 and the quinolizidine 300, with the wrong stereochemistry at the C-l stereocenter. This was corrected by mesylation of the alcohol, followed by Sn2 reaction with sodium azide to give 301, which, upon saponification of the methyl ester and decarboxylation through the Barton procedure followed by reduction and N-acylation, gave the desired natural product (Scheme 66) <20050L4005>. 

Aube took advantage of an intramolecular Schmidt reaction of azide 129 to provide the fused ring heterocyclic lactam 130 as a key step in a total synthesis of (+)-aspidospermidine... 

With both building blocks 103 and 109 in hand, the total synthesis of lb was completed as shown in Scheme 17. Coupling of acid 103 and alcohol 109 under Yamaguchi conditions to give ester 110 and subsequent desilylation followed by chemoselective oxidation provided hydroxy acid 111. Lactonization of the 2-thiopyridyl ester derived from 111 in the presence of cupric bromide produced the macrodiolide 112 in 62% yield, which was finally converted to pamamycin-607 (lb) via one-pot azide reduction/double reductive AT-methylation. In summary, 36 steps were necessary to accomplish the synthesis of lb from alcohols 88 and 104, sulfone 91, ketone 93, and iodide rac-97. 

Fukuyama and Yang (49) developed a highly efficient synthesis of the tetracyclic intermediate 241, used in a total synthesis of mitomycin A (Scheme 9.49). The required azide 240 was produced from 239 in several steps. Upon heating in refluxing toluene, the azide 240 underwent smooth intramolecular cycloaddition with the unsaturated lactone followed by extrusion of nitrogen to give aziridine 241 in 85% yield. 

Cha and co-workers (54) described an enantioselective total synthesis of (—)-slaframine (269) based on an intramolecular cycloaddition of an azide (Scheme 9.54). On reaction with NaN3 in DMF at 60 °C followed by intramolecular... 

Schkeryantz and Pearson (59) reported a total synthesis of ( )-crinane (298) using an intramolecular azide-alkene cycloaddition (Scheme 9.59). The allylic acetate 294 was first subjected to an Ireland-Claisen rearrangement followed by reduction to give alcohol 295, which was then converted into the azide 296 using Mitsunobu conditions. Intramolecular cycloaddition of the azide 296 in refluxing toluene followed by extrusion of nitrogen gave the imine 297 in quantitative yield. On reduction with sodium cyanoborohydride and subsequent reaction with... 

Molander and Hiersemann (60) reported the preparation of the spirocyclic keto aziridine intermediate 302 in an approach to the total synthesis of (zb)-cephalotax-ine (304) via an intramolecular 1,3-dipolar cycloaddition of an azide with an electron-deficient alkene (Scheme 9.60). The required azide 301 was prepared by coupling the vinyl iodide 299 and the aryl zinc chloride 300 using a Pd(0) catalyst in the presence of fni-2-furylphosphine. Intramolecular 1,3-dipolar cycloaddition of the azido enone 301 in boiling xylene afforded the desired keto aziridine 302 in 76% yield. Hydroxylation of 302 according to Davis s procedure followed by oxidation with Dess-Martin periodinane delivered the compound 303, which was converted to the target molecule (i)-cephalotaxine (304). 

Ciufolini et al. (61) reported a facile assembly of the benzazocenone 307 as a part of the total synthesis of the antitumor alkaloids mitomycin C (309) and FR 900482 (310) based on intramolecular 1,3-dipolar cycloadditions of aryl azides with electron-rich alkenes (Scheme 9.61). Azide 305 was heated in refluxing toluene with a catalytic amount of K2CO3 to give the triazoline 306 in 55% yield. Irradiation of a solution of the triazoline 306 in wet THF with a sun lamp gave an 84% yield of the required benzazocene 308, which was converted to the target molecules 309 and 310. 

An efficient stereoselective synthesis of the (pyrrolidin-2-ylidene)glycinate intermediate 325 was reported in a total synthesis of carzinophilin (326), employing an intramolecular cycloaddition of an azide with an alkene (63) (Scheme 9.63). The arabinose derivative 319 was converted into the required azide 321 via the triflate 320. Thermolysis of the azide 321 at 50 °C in THF produced the unstable triazoline 322, which on rearrangement gave the (pyrrolidin-2-ylidene)glycinate 325 in 60-72% overall yield from the triflate 320. 

Hudlicky et al. (65) reported a formal stereoselective total synthesis of the oxygenated pyrrolizidine alkaloids platynecine (336), dihydroxyheliotridane (337), hastanecine (341), and tumeforcidine (342), involving an intramolecular azide-diene cycloadditions (Scheme 9.65). Intramolecular 1,3-dipolar cycloaddition of... 

The first total synthesis of the potent cytotoxic marine natural product makaluvamine F (5) involved the preparation of 2,3-dihydrobenzothiophene 2 <99CC143>. Debenzylation and subsequent acid-catalyzed cyclization of thioether 1 gave 2 which was converted in four steps to 2-azido-2,3-dihydrobenzothiophene 3 using a combination of Phl=0 and McjSiNj for installation of the azide. Reduction of the azide followed by coupling the resultant amine with pyrroloiminoquinone 4 then gave makaluvamine F (5). 

Reddy, P. G., Baskaran, S. (2004) Epoxide-initiated cationic cyclization of azides a novel method for the stereoselective construction of 5-hydroxymethyl azabicyclic compounds and application in the stereo- and enan-tioselective total synthesis of (+)- and ( —) -indolizidine 167B and 209D. J Org Chem 69, 3093-3101. 

The Dendrobatid poison arrow frogs of Central and South America exude a potent mixture of alkaloids from their skins. It was originally thought that the frogs biosynthesized these alkaloids, but it has since been shown that they are of dietary origin. The skin exudate of the Colombian frog Minyobates bombetes causes severe locomotor difficulties, muscle spasms and convulsions upon injection in mice. The major component of the alkaloid mixture is 251F3. Jeff Aube of the University of Kansas recently described (J. Am. Chem. Soc. 2004,126,5475) the enantioselective total synthesis of 3. The key step in the synthesis was the cyclization of the keto azide 2. 

The elegant asymmetrization methodology of a meso compound, achieved in high enantioexcess under chiral environment, was the highlight of the total synthesis of (+)-pancratistatin (94) reported by Trost and Pulley (31]. The synthesis commenced with ( )-conduritol-A (130), obtained from p-benzoquinone, (Scheme 18) which was converted into the acetonide 131 and thence, via the dialkoxide to the cis-bis carbonate 132 (Scheme 19). The chiral n-ailyl palladium complex A formed on treatment erf 132 with the catalyst generated from chiral bis-amide 133 and n-allyl palladium chloride underwent azide substitution from the less hindered face of the molecule to provide the monocarbonate 134 in excellent yield and with high optical induction. 

Oxidative cyclizations of 3-(/ -azidoethyl)indoles with BTIB afford pyr-roloiminoquinones 15, compounds that appear as sub-structures in biologically active marine alkaloids such as the makaluvamines and discorhabdins (Scheme 22) [67- 69]. In fact, BTIB-mediated sulfide and azide cyclizations, and a-azido-nation of the cyclic sulfide with PhIO/TMSN3, were incorporated into the first total synthesis of ( )-makaluvamine F [68,69]. 

Various dialkyl- and diaryl(vinyl)sulfonium salts react with l//-indole-2-carbaldehyde in the presence of NaH to form a tetracyclic oxirane, for example, 167 these upon treatment with sodium azide form tricyclic azido alcohols analogous to compound 168 in 72% yield (Scheme 35) <1999T10659>. This annulation was a key step in total synthesis of Mitomycin K <1996TL6049>. 

Virantmycin is a tetrahydroquinoline alkaloid that has inhibitory activity against DNA and RNA viruses. A total synthesis of virantmycin making use of a key type II aziridine has elucidated the absolute stereochemistry at C-2 and C-3 <1996T10609>. An intramolecular photocyclization of an azide onto a Z-alkene produces type II aziridine 351 in excellent yield. A three-step reduction/selective reoxidation procees yields key aziridine alcohol 352 in 76% overall yield (Scheme 71). The alcohol is methylated and the ester hydrolyzed without harm to the azirdine. A TFA-induced ring opening of the aziridine by chloride provides the natural product virantmycin in good yield. This entire process was also carried out with the -alkene to produce /)(-virantmycin, thus proving the stereochemistry at C-2 and C-3. 

The dipolar cycloaddition of an alkyl azide with an alkene to form an aziridine has been exploited in the total synthesis of the alkaloid ( )-aspidospermidine <20050BC213>. Enone 353 was prepared in 11 steps from 3-ethoxycyclohexenone and coupled to 2-iodo nitrobenzene under Ullman cross-coupling conditions. The acetate group of 354 was hydrolyzed and the resulting alcohol converted to an azide using standard conditions in 75% overall yield. The cycloaddition of the azide with the enone was conducted in refluxing benzene for 3 days. The fused-ring aziridine 355 was the only product isolated. None of the initial dipolar cycloadduct triazoline was observed. The... 

Basic hydrolysis of the allylic azide affords the rearranged 1,2-isomer, which was an intermediate in the synthesis of (+)-conduramine E. Following a similar strategy, but starting with dr-3,6-dibenzoyloxycyclohex-l-ene, a total synthesis of the nonopioid analgesic (—)-epibatidine was developed. ... 

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