Stereochemically versatile synthesis of the C1-C12 fragment of tedanolide C

A flexible synthesis of the C1-C12 fragment of Tedanolide C has been accomplished in eight steps from 2-methyl-2,4-pentadienal. Asymmetric hydroformylation of a 1,3-diene allows for the late-stage generation of either C10 epimer with complete catalyst control. Diastereoselective addition of an isobutyryl β-ketoester dianion to an α,β-disubstituted chiral aldehyde sets the C5 stereochemistry while installing the geminal dimethyl unit. Differential protection of a syn-1,3-diol is performed as a highly efficient single-pot operation.     

Studies on the synthesis of tedanolide. 2. Stereoselective synthesis of a protected C(1)-C(12) fragment

[reaction: see text] Highly diastereoselective syntheses of diketo esters 6a and 6b are described. These intermediates undergo efficient aldol reactions with protected C(13)-C(21) aldehydes 3 and 23, thereby providing advanced C(1)-C(21) tedanolide seco ester precursors 9a and 9b.     

Studies on the synthesis of tedanolide: synthesis of the C(5)-C(21) segment via a highly stereoselective fragment assembly aldol reaction of a chiral beta,gamma-unsaturated methyl ketone

[formula: see text] A highly diastereoselective synthesis of 3, corresponding to the C(5)-C(21) segment of tedanolide, has been accomplished by a route utilizing the aldol reaction of aldehyde 4 and the beta,gamma-unsaturated methyl ketone 5.     

A Kiyooka aldol approach for the synthesis of the C(14)-C(23) segment of the diastereomeric analog of tedanolide C

The challenging synthesis of a quaternary center within the highly oxygenated setting of tedanolide C can be performed via a Kiyooka aldol reaction. Here, the diastereomeric analog of tedanolide C with the configurations between C10 and C20 opposite compared to the proposed structure was chosen as the synthetic target. The tetra-substituted silyl ketene acetal provides the southern hemisphere of tedanolide C in useful selectivities, and the absolute configuration of the newly generated quaternary center was determined by NOE experiments of the corresponding acetonide.     

A highly stereoselective synthesis of the C10-C23 fragment of (-)-dictyostatin

A highly stereoselective synthesis of the C10-C23 fragment of (-)-dictyostatin has been achieved using a Carreira alkynylation and a Marshall-Tamaru allenylzinc addition as key steps.     

Synthetic studies of tedanolide, a marine macrolide displaying potent antitumor activity. Stereoselective synthesis of the C13-C23 segment

[structure: see text] A highly stereoselective synthesis of the C13-C23 segment of tedanolide (1), an 18-membered macrolide isolated from the Caribbean sponge Tedania ignis, displaying significant cytotoxicity against KB and PS tumor cell lines, is described which involves two stereoselective epoxidations of regioisomeric trisubstituted double bonds and a stereospecific S(N)2' methylation reaction of a trans-gamma,delta-epoxy-cis-alpha,beta-unsaturated ester as the key steps.     

Studies toward the total synthesis of tedanolide: stereoselective synthesis of the C(8)-C(17) segment

The stereoselective synthesis of the C(8)-C(17) sub-unit (−)-5 of tedanolide (1), which involves iterative Evans aldol reactions as the key steps, is described.     

Synthetic studies toward the total synthesis of tedanolide: assembly of the C1-C23 carbon backbone

A stereoselective assembly of the C1-C23 fragment representing the carbon backbone of tedanolide was accomplished utilizing a chiral boron reagent to effect the aldol coupling of the C1-C12 diketoester fragment with the C13-C23 aldehyde fragment.     

Stereoselective synthesis of the C1-C13 fragment of bistramide A

The C1-C13 fragment of bistramide A was prepared from 5-hexenoic acid in 15 linear steps and in 16% overall yield. The core 2,6-trans-tetrahydropyran ring was obtained via a kinetically controlled oxa-Michael cyclization from the corresponding chiral α,β-unsaturated hydroxyester. This precursor was prepared by using a diastereoselective alkylation reaction using Davies Superquat auxiliary and a diastereoselective Roush’s allylboration as key steps.     

Stereoselective synthesis of a fully protected C13-C23 fragment of tedanolide

The combination of a high-yielding dienyllithium addition and a highly diastereoselective 1,2-reduction allows the preparation of the completely protected C₁₃-C₂₃ fragment 3 of the potent cytotoxic agent tedanolide 1. A convergent approach was used, namely a late stage coupling of the dienyllithium 16 with the selectively protected aldehyde 5 followed by oxidation-reduction and final epoxidation to give 3. The dienylstannane 4 was prepared from the dibromide 6 in five steps, the key step being the highly regio- and stereoselective stannylcupration of the alkyne 7. The commercially available hydroxy ester 10 was converted in 11 steps to the aldehyde 5. The compound 3 could potentially be a key intermediate for the synthesis of tedanolide 1.     

A cross-metathesis approach for the synthesis of tedanolide and 13-deoxytedanolide: stereoselective synthesis of the C3-C16 segment

A unified synthetic strategy has been devised for the synthesis of both tedanolide and 13-deoxytedanolide, which involves a cross-metathesis reaction as the key step. We report herein the stereoselective synthesis of the C3-C16 segment (+)-5b and subsequent manipulation of the C12-C13 double bond leading to the preparation of both tedanolides.     

Synthesis of tedanolide and 13-deoxytedanolide. Assembly of a common C(1)-C(11) subtarget

[formula: see text] In this Letter we describe a synthetic strategy and an efficient assembly of a common C(1)-C(11) subtarget, (-)-3, for (+)-tedanolide (1) and (+)-13-deoxytedanolide (2), architecturally complex marine macrolides displaying potent antitumor activity. Key elements of the synthesis include two iterations of the Evans aldol protocol to construct the C(1)-C(6) moiety and a stereocontrolled vinyl anion addition to generate the C(8,9) trisubstituted olefin incorporating stereogenicity at C(7). Alkylation with a model epoxide demonstrates that (-)-3 is a competent dithiane for further elaboration of the macrolide skeleton.     

Synthetic studies of an 18-membered antitumor macrolide, tedanolide. 5. Stereoselective synthesis of the C13-C23 part via condensation of two fragments, C13-C17 and C18-C21, by taking advantage of the 3,4-dimethoxybenzyl protecting group.

An efficient and stereoselective synthesis of the C13-C23 part (8) was achieved starting from methyl (R)- and (S)-3-hydroxy-2-methylpropionates (9) via coupling of the C13-C17 aldehyde (6), prepared by Evans asymmetric aldol reaction, with the C18-C21 iodoalkene (5b) by taking advantage of the 3,4-dimethoxybenzyl protecting group.     

Stereoselective synthesis of the C1-C13 fragment of 2,3-dihydrodorrigocin A

[Chemical reaction: see text] The first synthesis of the C1-C13 fragment of 2,3-dihydrodorrigocin A has been achieved from 6-bromohexanoic acid in 14 linear steps and an overall yield of 2%. The configurations of the stereogenic centers C8, C9, and C10 have been determined to be the same as for migrastatin.     

Synthetic studies of the 18-membered antitumor macrolide, tedanolide. 3. Stereocontrolled synthesis of the C1-C12 part via a synthesis of the C1-C7 fragment by a mismatched but efficient sharpless dihydroxylation and its coupling with the C8-C11 fragment

The C1-C12 part (4) of tedanolide (1) was synthesized starting from methyl (R)-3-hydroxy-2-methylpropionate (11a) via a coupling between the C1-C7 aldehyde (6) and the C8-C11 iodoalkene (7a). For a synthesis of 6, a mismatched but highly efficient Sharpless dihydroxylation of the alpha, beta-unsaturated ester (15) with AD-mix-alpha was successfully applied. Compound 7a was synthesized using hydrozirconation to the alkyne (32).     

Stereoselective synthesis of the C(1)-C(19) fragment of tetrafibricin

[reaction: see text] A stereoselective synthesis of the C(1)-C(19) fragment of tetrafibricin has been accomplished via a highly diastereoselective double allylboration reaction of 6-8 and an iodonium ion promoted urethane cyclization for the installation of the C(15) alkoxy function in 3.     

Gram scale synthesis of the C(18)-C(34) fragment of amphidinolide C

The synthesis of the C(18)-C(34) fragment of amphidinolide C has been achieved via two routes, culminating in both the shortest (11 steps) and highest yielding (26% overall yield) approaches to this segment. The highly convergent approach will facilitate the synthesis of analogues, including the C(18)-C(29) fragment of amphidinolide F. Synthetic highlights include the selective methylation of a diyne, and the highly efficient use of a second generation cobalt catalyst in the Mukaiyama oxidative cyclization to form the trans-THF ring.     

Stereoselective synthesis of the C(1)-C(11) fragment of peloruside A

A highly stereoselective synthesis of the C(1)-C(11) fragment 4 of peloruside A has been accomplished via a stereoselective double allylboration and an intramolecular epoxide opening to provide the functionally dense C(3)-C(11) segment 14. A glycolate aldol reaction was then employed to introduce the remaining stereocenters at C(2)-C(3). [reaction: see text]     

Synthesis of the C23-C32 fragment of spirangien

The synthesis of the C23-C32 fragment of spirangien A is reported using Evans’ alkylation, Evans-Metternich aldol reaction and a substrate controlled stereoselective reduction.     

Diastereoselective synthesis of the C(17)-C(28) fragment (the C-D spiroketal unit) of spongistatin 1 (altohyrtin A) via a kinetically controlled iodo-spiroketalization reaction

[reaction: see text] A convergent and stereocontrolled synthesis of spiroketal 15 corresponding to the C-D fragment of spongistatin 1 has been accomplished by a sequence utilizing a kinetically controlled intramolecular iodo-spiroketalization of glycal 2, which in turn was synthesized via a ring-closing metathesis reaction.