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.     

Asymmetric synthesis of the highly potent anti-metastatic prostacyclin analogue cicaprost and its isomer isocicaprost

An asymmetric synthesis of the anti-metastatic prostacyclin analogue cicaprost and a formal one of its isomer isocicaprost by a new route are described. A key step of these syntheses is the coupling of a chiral bicyclic C6-C14 ethynyl building block with a chiral C15-C21 omega-side chain amide building block with formation of the C14-C15 bond of the target molecules. A highly stereoselective reduction of the thereby obtained C6-C21 intermediate carrying a carbonyl group at C15 of the side chain was accomplished by the chiral oxazaborolidine method. The chiral phosphono acetate method was used for the highly stereoselective attachment of the alpha-side chain to the bicyclic C6-C21 intermediate carrying a carbonyl group at C6. Asymmetric syntheses of the bicyclic C6-C14 ethynyl building blocks were carried out starting from achiral bicyclic C6-C12 ketones by using the chiral lithium amide method. In the course of these syntheses, a new method for the introduction of an ethynyl group at the alpha-position of the carbonyl group of a ketone with formation of the corresponding homopropargylic alcohol was devised. Its key steps are an aldol reaction of the corresponding silyl enol ether with chloral and the elimination of a trichlorocarbinol derivative with formation of the ethynyl group. In addition, a new aldehyde to terminal alkyne transformation has been realized. Its key steps are the conversion of an aldehyde to the corresponding 1-alkenyl dimethylaminosulfoxonium salt and the elimination of the latter with a strong base. Two basically different routes have been followed for the synthesis of the enantiomerically pure C15-C21 omega-side chain amide building block. The first is based on the chiral oxazolidinone method and features a highly stereoselective alkylation of (4R)-N-acetyl-4-benzyloxazolidin-2-one, and the second encompasses a malonate synthesis of the racemic amide and its efficient preparative scale resolution by HPLC on a chiral stationary phase containing column.     

Enantio- and diastereoselective synthesis of (E)-1,5-syn-diols: application to the synthesis of the C(23)-C(40) fragment of tetrafibricin

A highly stereoselective synthesis of (E)-1,5-syn-diols 6 is described. The kinetically controlled hydroboration of allenyltrifluoroborate 8 with Soderquist borane 2 provides the (Z)-allylic trifluoroborate 9, which undergoes sequential allylboration with two different aldehydes to provide (E)-1,5-syn-diols 6 in 72-98% yields with >95% ee and >20:1 dr. Application of this method to the synthesis of the tetrafibricin C(23)-C(40) fragment 19 is described.     

Stereoselective hydroformylation: key step for the assembly of polypropionate subunits.

An anti-selective hydroformylation of 2-propylidene-substituted 1,3-dioxanes 16, 17, and 26 with excellent levels of acyclic stereocontrol has been achieved. The basis of this result was a careful substrate design making use of a syn-pentane interaction as the decisive stereochemical control element. Confirmation of this working hypothesis came from conformational analysis studies on alkenic substrate 16 employing 2D NOESY experiments in solution and MACROMODEL/MM3 calculations. This stereoselective, transition metal-catalyzed, C-C bond-forming reaction could serve as a key step for the construction of the all-anti and syn-anti stereotriad building blocks 20, 21, and 31, which should be well-suited for target-oriented polypropionate synthesis. Application of this methodology for the construction of a C5-C11 building block for the synthesis of bafilomycin A1 is described.     

Total synthesis of (−)-dictyostatin, a microtubule-stabilising anticancer macrolide of marine sponge origin

An efficient convergent synthesis of the anticancer marine macrolide (−)-dictyostatin is described that proceeds in 4.6% yield over 27 steps. Most of the stereocentres were configured using substrate control, making use of a common building block to install the C12-C14 and C20-C22 stereotriads, with a lactate boron aldol reaction employed to construct a C4-C10 β-ketophosphonate as utilised in the pivotal Still-Gennari HWE coupling step with a fully elaborated C11-C26 aldehyde. Following introduction of the (2Z,4E)-dienoate, a modified Yamaguchi macrolactonisation and deprotection delivered the requisite 22-membered macrocyclic lactone.     

Synthetic studies on apoptolidin: synthesis of the C12-C28 fragment via a highly stereoselective aldol reaction

The stereoselective and convergent synthesis of the C12-C28 segment 2 of the apoptosis inducing macrolide antibiotic, apoptolidin (1), is described. The synthesis involves a highly stereoselective tin(II)-mediated aldol reaction between the C17-C22 ethyl ketone 3 and the C23-C28 aldehyde 4 as the key step.     

Stereoselective synthesis of the C15-C26 fragment of the antitumor agent (-)-dictyostatin

The synthesis of the C15-C26 fragment of (-)-dictyostatin is reported in 10 steps and 28% overall yield. The key steps are the two stereoselective sulfoxide-directed processes: a Reformatsky-type reaction and a β-keto sulfoxide reduction.     

Toward a modular, bidirectional synthesis of (−)-mucocin

A convergent stereoselective synthesis of the C13-C34 fragment of (−)-mucocin is described. The salient features include (a) the bidirectional synthesis of the C-2 symmetric C13-C21 subunit, (b) regio- and stereoselective preparation of a 1,3-diol derivative from a diene activated by NBS via intramolecular nucleophilic sulfinyl group participation, (c) utilizing the self-metathesis reaction to prepare a functionalized C10 alkene, and (d) regio- and stereoselective intermolecular epoxide opening to construct the ether bond between C20 and C24. An organocatalytic α-hydoxylation has been employed to create the C4 stereogenic center of C1-C12 subunit. Attempted union of the two subunits utilizing the B-alkyl Suzuki coupling did not succeed.     

Fully stereocontrolled total syntheses of the prostacyclin analogues 16S-iloprost and 16S-3-oxa-iloprost by a common route, using alkenylcopper-azoalkene conjugate addition, asymmetric olefination, and allylic alkylation

In this article we describe fully stereocontrolled total syntheses of 16S-iloprost (16S-2), the most active component of the drugs Ilomedin and Ventavis, and of 16S-3-oxa-iloprost (16S-3), a close analogue of 16S-2 having the potential for a high oral activity, by a new and common route. The key steps of this route are (1) the establishment of the complete C13-C20 omega side chain of the target molecules through a stereoselective conjugate addition of the alkenylcopper derivative 9 to the bicyclic C6-C12 azoalkene 10 with formation of hydrazone 8, (2) the diastereoselective olefination of ketone 7 with the chiral phosphoryl acetate 39, and (3) the regio- and stereoselective alkylation of the allylic acetate 43 with cuprate 42. These measures allowed the 5E,15S,16S-stereoselective synthesis of 16S-2 and 16S-3, a goal which had previously not been achieved. Azoalkene 10 was obtained from the achiral bicyclic C6-C12 ketone 11 as previously described by using as key step an enantioselective deprotonation. The configuration at C16 of omega-side chain building block 9 has been installed with high stereoselectivity by the oxazolidinone method and that at C15 by a diastereoselective oxazaborolidine-catalyzed reduction of the C13-C20 ketone 23 with catecholborane. Surprisingly, a high diastereoselectivity in the reduction of 23 was only obtained by using 2 equiv of oxazaborolidine 24. Application of substoichiometric amounts of 24 resulted in irreproducible diastereoselectivities ranging from very high to nil.     

Fully stereocontrolled syntheses of 3-oxacarbacyclin and carbacyclin by the conjugate addition-azoalkene-asymmetric olefination strategy

A fully stereocontrolled synthesis of 3-oxacarbacyclin (3) and a formal synthesis of carbacyclin (2) are described. The syntheses are based on the conjugate addition-azoalkene-asymmetric olefination strategy. Its key features are (1) the stereoselective establishment of the complete omega-side chain of 2 and 3 through conjugate addition of the enantiopure C13-C20 alkenylcopper derivative 10 to the enantiopure C6-C12 bicyclic azoalkene 9 and (2) the 5E-stereoselective construction of the alpha-side chain through a Horner-Wadsworth-Emmons olefination of the bicyclic ketone 7 with the chiral lithium phosphonoacetate 26 with formation of ester E-27. The allylic alcohol 6 serves at late stage as the joint intermediate in the synthesis of 2 and 3.     

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 C(1)-C(25) fragment of amphidinol 3: application of the double-allylboration reaction for synthesis of 1,5-diols

[structure: see text] A synthesis of the C(1)-C(25) fragment of amphidinol 3 is described. The synthesis features two applications of double allylboration reaction methodology for the highly stereoselective synthesis of 1,5-diol units in the C(1)-C(15) segment.     

Short synthesis of enantiopure C2-symmetric 1,2:4,5-diepoxypentane and "pseudo"-C2-symmetric 3-azido-1,2:4,5-diepoxypentane from arabitol

On the basis of our previously described selective protection of arabitol as its 1,2:4,5-bis-pentylidene acetal 5, we report a straightforward synthesis of the novel "pseudo"-C(2)-symmetric 3-azido-1,2:4,5-diepoxypentane building block 4 in 6 steps from arabitol. Using a similar synthetic route, an improved synthesis of the C(2)-symmetrical 1,2:4,5-bis-epoxypentane building block 1 is described, also in 6 steps from arabitol. Both enantiomers of 1 and 4 are accessible, and all reactions involved are easily amenable for large-scale synthesis.     

The first total synthesis of concanamycin f (concanolide a)

A highly stereoselective total synthesis of the macrolide antibiotic concanamycin F (1), a specific and potent inhibitor of vacuolar H(+)-ATPase, has been achieved by a convergent route involving the synthesis and coupling of its 18-membered tetraenic lactone and beta-hydroxyl hemiacetal side chain subunits. The C1-C19 18-membered lactone aldehyde 4 was synthesized through the intermolecular Stille coupling of the C5-C13 vinyl iodide 24 and the C14-C19 vinyl stannane 25, followed by construction of the C1-C4 diene and macrolactonization. Synthesis of 4 via a second convergent route including the esterification of the C1-C13 vinyl iodide 45 and the C14-C19 vinyl stannane 47 followed by the intramolecular Stille coupling was also realized. The highly stereoselective aldol coupling of 4 and the C20-C28 ethyl ketone 5 followed by desilylation provided 1 which was identical with natural concanamycin F.     

Total synthesis of microtubule-stabilizing agent (-)-laulimalide.

An enantioselective first total synthesis of laulimalide (1) is described. Laulimalide, a remarkably potent antitumor macrolide, has been isolated from the Indonesian sponge Hyattella sp. and the Okinawan sponge Fasciospongia rimosa. Laulimalide represents a new class of antitumor agents with significant clinical potential. The synthesis is convergent and involved the assembly of C(3)-C(16) segment 4 and C(17)-C(28) segment 5 by Julia olefination. The sensitive C(2)-C(3) cis-olefin functionality was installed by Yamaguchi macrolactonization of a hydroxy alkynic acid followed by hydrogenation of the resulting alkynoic lactone over Lindlar's catalyst. Initial attempts of intramolecular Still's variant of Horner-Emmons olefination between the C(19)-phosphonocetate and C(3)-aldehyde provided a 1:2 mixture of cis- and trans-macrolactones. The trans-isomer was photoisomerized to a mixture of cis- and trans-isomers. The other key steps involved ring-closing olefin metathesis to construct both dihydropyran units, stereoselective anomeric alkylation to functionalize the dihydropyran ring, stereoselective reduction of the resulting alkynyl ketone to set the C(20)-hydroxyl stereochemistry, and a novel Julia olefination protocol for the installation of the C(13)-exo-methylene unit. The sensitive epoxide at C(16)-C(17) was introduced in a highly stereoselective manner by Sharpless epoxidation at the final stage of the synthesis.     

(-)-Lytophilippine A: synthesis of a C1-C18 building block

The convergent enantioselective synthesis of a protected C1-C18 building block for the total synthesis of (-)-lytophilippine A was achieved. A catalytic asymmetric Gosteli-Claisen rearrangement and an Evans aldol reaction served as key C/C-connecting transformations during the assembling of the C1-C7 subunit (10 steps from 4, 29%). The synthesis of the C8-C18 segment was achieved utilizing d-galactose as inexpensive ex-chiral-pool starting material (15 steps, 15%). The merger of the subunits was accomplished by a remarkably efficient sequence consisting of esterification and ring-closing metathesis (five steps, 56%).     

Synthesis of the C(21)-C(26) fragment of superstolide A: concerning the stereochemistry of (E)-crotylboration reactions of alaninal derivatives

A stereoselective synthesis of the C(21)-C(26) fragment of superstolide A has been completed. The absolute and relative stereochemistry of intermediate 14 has been conclusively proven by NMR and X-ray diffraction methods. In the course of this work, it was found that the stereochemistry of 3 had been misassigned in our previously reported synthesis of the C(18)-C(26) segment. This error stems from the unexpected diastereoselectivity in the double asymmetric reaction of N-acetyl-d-alaninal 1 and the tartrate ester modified (E)-crotylboronate (R,R)-2.     

Total synthesis of (-)-callystatin A

[reaction: see text] A convergent enantioselective synthesis of the natural product (-)-callystatin A (1) is described. Key features of the synthesis include a lipase-mediated kinetic resolution to install the C5 lactone stereochemistry, a hydrozirconation-based approach to the C8-C9 trisubstituted (Z)-olefin, and a stereoselective cross-coupling of a vinyl dibromide to install the C14-C15 trisubstituted (E)-olefin.     

Synthesis of C13-C22 of amphidinolide T2 via nickel-catalyzed reductive coupling of an alkyne and a terminal epoxide

Several stereoselective routes to the synthesis of (1S,3R)-t-butyldimethyl-(1-methyl-3-oxiranyl-propoxy)-silane (13a) were explored, and the use of Jacobsen's hydrolytic kinetic resolution to separate a mixture of diastereomeric epoxides was a key step in the shortest of these. As part of an approach to the total synthesis of amphidinolide T2 (2), this epoxide, corresponding to C17-C22 of the natural product, was successfully joined with an alkyne (C13-C16) by way of a nickel-catalyzed reductive coupling reaction.     

Total synthesis of the Hsp90 inhibitor geldanamycin

An enantioselective synthesis of the Hsp90 inhibitor geldanamycin was achieved in 20 linear steps and 2.0% overall yield from 2-methoxyhydroquinone. The synthesis is highlighted by a regio- and stereoselective hydroboration reaction; a Sc(OTf)(3)/Et(3)SiH-mediated pyran ring-opening reaction; an enantioselective crotylation to simultaneously install the C8-C9 (E) -trisubstituted olefin, the C10 and C11 stereocenters; a chelation-controlled asymmetric metallated acetylide addition; and an intramolecular copper(I)-mediated aryl amidation reaction to close the 19-membered macrolactam.