Stereoselective synthesis from acyclic precursors

SCHMIDT Stereoselective Synthesis from Acyclic Precursors... 

The stereoselective synthesis of carbohydrates from acyclic precursors is a research topic that has attracted considerable attention over the past decadeT Efforts in this area are easily justified and have maximum impact particularly when directed toward rare sugars or other polyhydroxylated molecules that are not conveniently accessed via classical "chiron" approaches.2 An underlying theme of such efforts, of course, is the development of practical synthetic methodology that will find broad application in the enantio- and diastereoselective synthesis of natural products, their analogues, and other compounds of biological interest. 

This manuscript is based on a lecture presented in the "Stereoselective Synthesis of Carbohydrates from Acyclic Precursors" Symposium at the 194th American Chemical Society National Meeting, New Orleans, September 2,1987. This research is also discussed in Roush, W. R., "Strategies and Tactics in Organic Synthesis," Vol. 2. Lindberg, T., ed. Academic Press New York, 1988. 

Recendy, we described a useful sequence where Michael-acceptor sulfoxides 30 were obtained in two steps from homopropargylic alcohols 29 by radical addition of thiophenol and oxidation with sodium periodate. The unsaturated sulfoxides were used in a highly stereoselective intramolecular oxa-Michael reaction. The sequence provided stereoselective functionalization of the sulfoxide moiety, and the products 31 proved to be useful in the synthesis of modified furanosides 32. This represents a good exanple where sugars are prepared from acyclic precursors. The Michael addition was followed by a hydrolytic Pummerer reaction, yielding protected a-hydroxy aldehydes tScheme 20.8) that upon acidic treatment afforded 3-substituted ribofuranoses. 

Kishi has cleverly employed chelation control in the second-generation synthesis of ketone 49 [62], a key intermediate in the synthesis of the polyether antibiotic lasalocid A (50, Scheme 2.5) [63]. The stereoselective addition of ethylmagnesium bromide to ketone 46 can be understood as proceeding through chelate 47. This example demonstrates the synthetic utility of chelation as a stereochemical control element in a complex molecular setting. Application of this method along with other modern synthetic improvements allowed Kishi to synthesize ketone 49 in only 10 steps, starting exclusively from acyclic precursors [62], compared to his first reported 19-step synthesis [63]. 

An example of a surprisingly facile and stereoselective formation of an eight-membered lactone from an acyclic precursor diene ester was observed during the total synthesis of the antitumor agent octalactin A (148) (Scheme 27) [81]. The dense substitution pattern in cyclization substrate 146 presumably imposes... 

The epothilone synthesis in Scheme 13.49 has been used as the basis for a combinatorial approach to epothilone analogs. 167 The acyclic precursors were synthesized and attached to a solid support resin by steps A-E in Scheme 13.58. The cyclization and disconnection from the resin were then done by the olefin metathesis reaction. The aldol condensation in step D is not highly stereoselective. Similarly, olefin metathesis gives a mixture of E- and Z-stereoisomers so that the product of each combinatorial sequence is a mixture of four isomers. These were separated by thin-layer chromatography prior to bioassay. In this project, reactants A (3 variations), B (3 variations), and C (5 variations) were used, generating 45 possible combinations. The stereoisomeric products increase this to 180 (45 x 4). 

An additional advantage of the intramolecular protocol stems from the opportunity to prepare easily the required polyfunctional precursors via cobalt carbonyl stabilized propargyl cations. The approach based on the tandem utilization of Co-mediated alkylation and Pauson-Khand annulation was developed in Schreiber s studies to elaborate short pathways for the synthesis of polycyclic compounds. An example of the efficiency of this protocol is the two-step transformation of the acyclic precursor 409 into the tricyclic derivative 410. The cobalt-complexed acetal 409 was first transformed into the cyclooctyne derivative 411 via intramolecular reaction of the in situ generated propargyl cation 409a with the allylsilane moiety. Cyclooctyne 411 underwent smooth cycloaddition in the presence of carbon monoxide to give the target compound 410 with excellent stereoselectivity. 

N-donor ligand. The reaction appears to proceed via an acyclic iminoplatinum(II) intermediate that undergoes a subsequent intramolecular cyclization. Some mechanistic aspects of this versatile reaction have been elucidated.225,226 A4-l,2,4-oxadiazolines have been prepared by the [2+3] cycloaddition of various nitrones to coordinated benzonitrile in m-[PtCl2( D M SO)(PhCN)] precursors.227,228 Racemic and chiral [PtCl2(PhMeSO)(PhCN)] complexes have also been used in order to introduce a degree of stereoselectivity into the reaction, resulting in the first enantioselective synthesis of A4-l,2,4-oxadiazolines, which can be liberated from the complexes by the addition of excess ethane-1,2-diamine. 

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