A synthetic approach to the Stemona alkaloids.

This paper describes our work developing a strategy for the construction of the typical core structure of the Stemona alkaloids. The approach is to control the relative stereochemistry of the groups on the core 1-azabicyclo[5.3.0]decane ring system by a [3,3] sigmatropic rearrangement of an acylimmonium ion followed by selective reduction. After optimization, this reaction sequence afforded the desired diastereomer in 62% yield. Further efforts were directed toward elaboration of the characteristic butyrolactone substituent.

Further studies of the Daphniphyllum alkaloid polycyclization cascade.

The scope of the 2-azadiene intramolecular Diels-Alder cyclization, previously employed for synthesis of the Daphniphyllum alkaloids, has been further investigated. Through a series of 1,5-diol cyclization precursors the substitution pattern of both the dienophile and the 2-azadiene were examined. From these studies it was shown that the cascade reaction is tolerant toward a variety of alkyl-substituted dienophiles. However, it was also demonstrated that this reaction is very sensitive to the substitution pattern of the 2-azadiene. Alterations made to the structure of the 2-azadiene cause either competing side reactions or complete failure of the reaction cascade.

A simple biomimetic synthesis of styelsamine B.

An extremely rapid, low cost, and environmentally friendly entry into the pyridoacridine family of alkaloids has been devised, as demonstrated here by the first total synthesis of styelsamine B (3) and its oxidation to the quinoneimine cystodytin J (4). The known reaction of cystodytin J with methanethiol makes this a formal synthesis of diplamine. [reaction: see text]

alpha,beta-epoxy vinyl triflates in Pd-catalyzed reactions.

[reaction: see text] Reactions of steroidal alpha,beta-epoxy vinyl triflates in Pd-catalyzed reactions are described. Oxidative insertion of Pd(0) into the C-O bond, giving vinylpalladium 12, is faster than formation of the pi-allyl derivative from the vinyl epoxide. Although 12 can be trapped under certain conditions, it eventually rearranges to palladium alkoxide 14, which is in equilibrium with 15 and/or 10.

Synthesis of the C29-C44 portion of spongistatin 1 (altohyrtin A).

Two synthetic approaches to the C29-C44 portion of spongistatin 1 (altohyrtin A) have been developed. The key step of the first approach relies on the Claisen rearrangement of glucal 18 to provide ester 20a. This intermediate was advanced to silyl enol ether 30, which was coupled under Mukaiyama aldol conditions with aldehyde 3. Cyclization of this aldol adduct completed our first synthesis of the C29-C44 portion of spongistatin 1, requiring 25 total steps and occurring in 2.4% yield over the longest linear sequence (21 steps). We have also developed a second-generation approach based on the C-glycosidation of glucal 43. Through equilibration of the corresponding C-glycosides 49a/b and 50a/b the desired C-glycoside (50a) was obtained in good yield. Aldol condensation of this ketone provided cyclization precursor 67, which undergoes acid-catalyzed ketalization to close the E-ring of the spongistatins. An oxidation/reduction protocol was employed to set the C37 stereocenter. Protection of the C37 carbonol and selective unmasking of the C44 carbonol completed our second generation synthesis. This approach requires 27 steps and occurred in 13.2% yield over the longest linear sequence (18 steps).

Total synthesis of (+/-)-aspidospermidine.

(+/-)-Aspidospermidine (1) has been synthesized from readily available methyl 3-ethyl-2-oxocylo-pentanecarboxylate (17) in 5.9% yield over 13 steps. The key step of the synthesis is an intramolecular cascade reaction that simultaneously forms the B, C, and D rings of 1. A high-yielding method of closing the remaining E ring is also described.

Synthesis of a model for C7-C13 of lankamycin.

[structure: see text] A convenient method is reported for construction of the C7-C13 segment of the macrolide antiobiotic lankamycin.

Total syntheses of (+/-)-preussomerins G and I.

[formula: see text] Preussomerins G and I (2 and 3) have been synthesized for the first time. The key reaction in the synthesis is a possibly biomimetic tautomerization reaction depicted in Scheme 3 and the foregoing graphic. The driving force for this interesting rearrangement is primarily derived from the increase in resonance energy associated with converting a naphthalene ring into two isolated benzene rings.

Total synthesis of (+/-)-isoschizogamine.

[formula: see text] Isoschizogamine has been prepared for the first time. The synthesis requires eight steps from a readily available ketone starting material and features an aminal-forming cyclization that is based on a proposed biosynthetic transformation.

A method for constructing the C44-C51 side chain of altohyrtin C.

[formula: see text] A method to construct the C44-C51 side chain of altohyrtin C has been developed and applied to a model aldehyde derived from D-glucose. The approach relies on a Wittig reaction to couple the side chain to an aldehyde and utilizes an allylic diazene rearrangement to place the C45 double bond in the correct position.

Nature knows best: an amazing reaction cascade is uncovered by design and discovery.

The Daphniphyllum alkaloids are a group of highly complex polycyclic alkaloids. Examination of the structures if several members of this family of natural products led to a hypothesis about their mode of biosynthesis (depicted in Scheme I). Based on this hypothetical biosynthetic pathway, a laboratory synthesis was designed that incorporated as a key transformation the novel one-pot transformation of dialdehyde 24 to pentacyclic unsaturated amine 25. This process turned out to be an exceptionally efficient way to construct the pentacyclic nucleus of the Daphniphyllum alkaloids. However, a purely fortuitous discovery, resulting from accidental use of methylamine rather than ammonia, led to a great improvement in the synthesis and suggests an even more attractive possible biosynthesis.

De novo synthesis of carbohydrates by stereoselective aldol reaction: L-cladinose.

Aldol reactions of methyl 2-methoxypropanoate (4), the corresponding ester of 2-methoxypropanoic acid with 4-methyl-2,6-di-(tert-butyl)phenol (13), and silylketene acetals 14 and 15 with (S)-2-(phenyl-methoxy)propanal (17) have been investigated. The lithium enolate of 4 reacts with 17 to give primarily beta-hydroxy ester 18a. If the reaction is carried out with the bis-silylketene acetal 14 under the influence of stannic chloride, beta-hydroxy acid 20c is produced. Compound 20c is cleanly inverted, via the beta-lactone 26, to provide beta-hydroxy acid 19c. Compound 18a has been converted into L-cladinose by the sequence of steps: 18a----35----39----40----41----42----1.

Biomimetic total synthesis of proto-daphniphylline.

Proto-daphniphylline, the imputed biogenetic parent of the Daphniphyllum alkaloids, has been assembled in a biogenetically styled laboratory synthesis in which a pentacyclization process is the fundamental synthetic stratagem. This extraordinary transformation involves the formation of six (r-bonds under the influence of three elementary reagents-potassium hydroxide, anmnonia, and acetic acid. The facility of the process adds credibility to the previous speculation that a similar process is an important step in the biosynthesis of the Daphniphyllum alkaloids.

Synthesis and biological evaluation of a monocyclic, fully functional analogue of compactin.

Compound 8, a monocyclic analogue of compactin, has been prepared and its efficacy as an inhibitor of 3-hydroxy-3-methylglutarylcoenzyme A reductase (HMGR) evaluated. The synthesis (Schemes I and II) requires seven steps starting with di-(-)-menthyl fumarate and employs the useful RR-phosphonate reagent 14 to attach the mevinic acid side chain to aldehyde 13. A molecular mechanics study shows that the preferred conformations of 18 (a model for compactin) and 19 (a model for 8) are nearly identical. Compound 8 inhibits HMGR with IC50 = 320 microM, compared to a corresponding value of 32 nM for the compactin ketone, 5. The factor of 10,000 difference in the two inhibitors corresponds to a difference in binding energy of 5.45 kcal mol-1, or 1.36 kcal mol-1 for each of the four carbons of 5 that are missing in analogue 8. This quantitative difference is consistent with the idea that the decalin moiety of the mevinic acids play a purely hydrophobic role in binding the inhibitors to the enzyme.

Total synthesis and biological evaluation of structural analogues of compactin and dihydromevinolin.

The full experimental details for the total synthesis of (+)-compactin and 19 structural analogues are reported. We have evaluated three classes of analogues as inhibitors of 3-hydroxy-3-methylglutaryl-coenzyme A reductase: (1) functional and stereoisomeric analogues that possess the full carbon skeleton of compactin or dihydromevinolin, (2) functional analogues in which one carbon of the skeleton has been replaced by oxygen, and (3) analogues in which all of the 3,5-dihydroxyvaleric acid moiety has been omitted. Our most potent inhibitors belong to the first class of analogues. Compounds 42 (5-ketocompactin) and 69 (5-ketodihydromevinolin) are as active as the natural products compactin and dihydromevinolin, respectively (I50 = 1-20 nM). The corresponding enones 37 and 68 are less active, having I50 values 20-30 times larger. Inverting the stereochemistry at C-3 or C-5 or about the hexahydronaphthalene ring of compactin results in the elevation of the I50 to values in the micromolar range, comparable to the KM of the natural substrate 3-hydroxy-3-methylglutaryl coenzyme A. Class 2 analogues are active in this concentration range also. The synthetic sequence developed for compactin and its analogues includes a new method that permits the selective preparation of either the R or the S epimer at C-3 of the 3,5-dihydroxyvaleric acid moiety. This entails the reaction of anhydride 9 with either (R)- or (S)-1-phenylethanol in the presence of 4-(N,N-dimethylamino)pyridine and triethylamine. The prochiral recognition is surprisingly high; under optimum conditions, the reaction of 9 with (R)-1-phenylethanol leads to a 15:1 ratio of diesters 17 and 18.

Stereostructure of the archaebacterial C40 diol.

The stereostructure of the archaebacterial C40 diol has been established as (3R,7R,11R,15S,18S,22R,26R,30R)-3,7,11,15,18,22,26,30- octamethyldotriacontane-1,32-diol by stereorational total synthesis. This provides the final evidence necessary to establish the structure of an archaebacterial membrane substance that is a 72-membered-ring tetraether with 18 stereocenters.

Acyclic stereocontrol through the aldol condensation.

For the scientist who wishes to synthesize complex organic compounds, the most difficult problem is often establishing the correct configuration at the various chiral centers as the synthesis is being carried out. In the past decade, there has been an increasing effort to find direct solutions to this problem, which is particularly acute in the synthesis of acyclic and other conformationally flexible molecules. One of the oldest organic reactions, the aldol condensation, is emerging as a powerful tool for use in achieving such stereocontrol.