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Mitsunobu lactonization

Scheme 21 shows the synthesis of a dihydrofuran derivative 86. Synthesis of this compound was described by Nam et al. [68] utilizing a furanone compound 87 synthesized by Kim et al. [61] via a similar synthetic approach as described in Scheme 17. The lactone was reduced using lithium aluminum hydride to give the diol 88 and intramolecular etherification using the Mitsunobu reaction afforded the dihydrofuran 86 in moderate yield (47%). Scheme 21 shows the synthesis of a dihydrofuran derivative 86. Synthesis of this compound was described by Nam et al. [68] utilizing a furanone compound 87 synthesized by Kim et al. [61] via a similar synthetic approach as described in Scheme 17. The lactone was reduced using lithium aluminum hydride to give the diol 88 and intramolecular etherification using the Mitsunobu reaction afforded the dihydrofuran 86 in moderate yield (47%).
Amino acid synthesis.1 Optically pure amino acids can be prepared in two steps from serine, readily available as either the d- or L-enantiomer. Reaction of N-benzylserine (or of N-benzyl-N-Boc-serine) with the preformed Mitsunobu reagent in CH3CN at -55° provides the protected serine (J-lactone (2) in almost quantitative yield. The lactone reacts with lithium organocuprates (R2CuLi) to... [Pg.282]

A synthesis of 149, cucujolide VIII, proceeded via the tert-butyldimethylsi-lyl-(TBS)-ether of methyl (E)-12-hydroxydodec-4-enoate B [293] (Fig. 7). Deprotonation in a-position and reaction with di(4-methoxyphenyl)diselenide furnished C. This was transformed to the macrolide E after saponification of the ester moiety, deprotection of the hydroxy group, and Mitsunobu lactonization. Alternatively, the unsaturated lactone F was synthesized from B following a sequence similar to that from C to D. Oxidative elimination of the arylseleno group... [Pg.138]

The hydroxymethyl and carboxyl group of Ser can participate in pyrazole-ring formation, as shown in the transformation of A -protected L-Ser with the Mitsunobu reagent into a /3-lactone which afforded the N-protected serine hydrazide upon treatment with methyl hydrazine. Cyclization to 25 was achieved by diisopropyl azodicarboxylate (DIAD) and TPP [90H(31)79]. [Pg.17]

One of the early syntheses of orlistat (1) by Hoffmann-La Roche utilized the Mukaiyama aldol reaction as the key convergent step. Therefore, in the presence of TiCU, aldehyde 7 was condensed with ketene silyl acetal 8 containing a chiral auxiliary to assemble ester 9 as the major diastereomer in a 3 1 ratio. After removal of the amino alcohol chiral auxiliary via hydrolysis, the a-hydroxyl acid 10 was converted to P-lactone 11 through the intermediacy of the mixed anhydride. The benzyl ether on 11 was unmasked via hydrogenation and the (5)-7V-formylleucine side-chain was installed using the Mitsunobu conditions to fashion orlistat (1). [Pg.152]

Thus, 1.7-octadiene (79), which was subjected to monohydroboration followed by asymmetric dihydroxylation of the remaining double bond to give triol 80 with approximately 80% ee. Further transformations then afforded the desired butenolide 81. Double asymmetric dihydroxylation of diene 83 and subsequent protection gave hydroxy lactone 84 [98], which was then converted into acetylenic bis(hydroxy)bistetrahydrofuran 82 as the required intermediate for the (+)-asimicin synthesis. Mitsunobu inversion at C-24 gave rise to the diastereomeric (+)-bullatacin precursor. [Pg.421]

In 2005, ot-benzylserine derivative [153] was reported to be converted into the (3-lactone using PPh3 and diethyl azodicarboxylate, giving an aza-peptide, which was then subjected to Mitsunobu conditions to afford the 3-benzyl-(3-lactam azapeptidomimetic (Scheme 61), [154]. [Pg.137]

Lactone inversion.3 The rran.v-y-lactone 1 has been converted into the cis-isomer (2) by treatment of the dry potassium salt of the hydroxy acid derived from 1 with sulfene, followed by relactonization. The Mitsunobu inversion failed in this case. [Pg.252]

The successful synthesis of optically active 7 then led to the first synthesis of verrucarin A (8), a macrotrilactone with significant cytostatic activity. The synthesis involved esterification of the primary alcohol of verrucarol (the tricyclic fragment) with the acetate of 7 (DCC, 4-pyrrolinopyridine) and then with a protected derivative of (E, Z)-muconic acid. After deprotection (Bu4NF), lactonization was effected by the Mitsunobu procedure (7,405-406). [Pg.613]

Diastereoselective /3-lactone formation was also carried out by a tandem Mukaiyama aldol lactonization between an aldehyde 132 and a thiopyridyl ketene acetal 133 (Equation 46) <2005CCL1448>. This reaction gave the /3-lactone 134 as a 10 1 (transacts) mixture of diastereoisomers and the major isomer was converted into (-)-tetrahydrolipstatin by silyl deptotection followed by a Mitsunobu coupling to form the ester. [Pg.354]

On one hand, the a,P-unsaturated lactone 40, which was derived from di-O-acetyl-L-rhamnal (39) according to reported procedures, was submitted to Mitsunobu inversion with HCO2H, followed by hydrolysis and methoxymethylation to afford 40. On the other hand, the o-methylbenzoate 41 was obtained from 3,5-dihydroxytoluene under the protocols described by Solladig. [Pg.170]

If the Mitsunobu inversion is carried out intramolecularly (i.e., in a hydroxycarboxylic acid), a lactone is produced with inversion of the configuration at the OH-bearing stereocenter (Figure 2.35). This lactonization is stereochemically complementary to the paths via activated hydroxycarboxylic acids, which lead to lactones with retention of the configuration at the OH-bearing C atom (Section 6.4.2). [Pg.94]

The l,5-dioxaspiro[3,2]hexane (42) has been shown to be a useful precursor for both aminodiol and aminotriol sphingoid bases. The synthesis of oxetane (42) started with serine via a Mitsunobu lactone formation followed by sequential titanium-mediated methylenation and oxidation with dimethyldioxirane <02OL1719>. [Pg.109]

A concise and efficient synthesis of racemic five steps from precursor diethyl oxalopropionate <02TL9513>. In the first step, racemic diethyl oxalopropionate was alkylated under basic conditions. The lactonization is the last step of the synthesis and was achieved according to the Mitsunobu protocol. [Pg.110]

In a process resembling the Mitsunobu reaction (Chapter 17), alcohols and acids can be coupled to give esters, even macrocyclic lactones as shown below. In contrast to the Mitsunobu reaction, the reaction leads to retention of stereochemistry at the alcohol. Propose a mechanism that explains the stereochemistry. Why is sulfur necessary here ... [Pg.1275]

The synthesis of [3-lactones has received considerable attention6 since the first representative of this class of heterocycles was prepared in 1883. Classical routes to (3-lactones generally involved the cyclization of (3-halocarboxylate salts6 and the related "deaminative cyclization that occurs upon diazotization of [3-amino acids.9 p-Hydroxy acids undergo a similar cyclization under Mitsunobu conditions,10 and the... [Pg.68]

Macrolactonization can also be achieved by the Mitsunobu reaction [44] with inversion of the configuration of the alcohol. The reaction principle and mechanism are demonstrated in Scheme 24. Addition of triphenylphosphine to diethyl azodicarboxylate (DEAD, 73) forms a quaternary phosphonium salt 74, which is protonated by hydroxy acid 11, followed by phosphorus transfer from nitrogen to oxygen yielding the alkoxyphosphonium salt 76 and diethyl hydrazinedicarboxy-late 75. Then, an intramolecular Sn2 displacement of the important intermediate 76 results in the formation of the lactone 15 and triphenylphosphine oxide. [Pg.122]

A further reaction mechanistically similar to the Mitsunobu reaction as shown in Scheme 26, with the use of AT,iV-dimethylformamide dineopentylacetal (80), can also be employed for macrolactonization [47]. Takei and coworkers [48] applied it to the synthesis of the macrocyclic antibiotic A26771B (55). As shown in Scheme 27, treatment of the linear precursor 82 with 80 in refluxing dichloromethane for 7 h afforded the lactone 83 (39% yield). [Pg.124]

Mitsunobu reaction as well as by mesylation and subsequent base treatment failed, the secondary alcohol was inverted by oxidation with pyridinium dichromate and successive reduction with sodium borohydride. The inverted alcohol 454 was protected as an acetate and the acetonide was removed by acid treatment to enable conformational flexibility. Persilylation of triol 455 was succeeded by acetate cleavage with guanidine. Alcohol 456 was deprotonated to assist lactonization. Mild and short treatment with aqueous hydrogen fluoride allowed selective cleavage of the secondary silyl ether. Dehydration of the alcohol 457 was achieved by Tshugaejf vesLCtion. The final steps toward corianin (21) were deprotection of the tertiary alcohols of 458 and epoxidation with peracid. This alternative corianin synthesis needed 34 steps in 0.13% overall yield. [Pg.180]

See other pages where Mitsunobu lactonization is mentioned: [Pg.164]    [Pg.259]    [Pg.139]    [Pg.5]    [Pg.144]    [Pg.35]    [Pg.192]    [Pg.527]    [Pg.154]    [Pg.402]    [Pg.432]    [Pg.64]    [Pg.282]    [Pg.175]    [Pg.180]    [Pg.264]    [Pg.95]    [Pg.36]    [Pg.80]    [Pg.127]    [Pg.154]    [Pg.602]    [Pg.13]    [Pg.295]   
See also in sourсe #XX -- [ Pg.43 , Pg.45 , Pg.103 , Pg.104 , Pg.105 , Pg.110 , Pg.111 , Pg.119 ]



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Mitsunobu reaction macrocyclic lactones

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