1,n‐Glycols as Dialdehyde Equivalents in Iridium‐Catalyzed Enantioselective Carbonyl Allylation and Iterative Two‐Directional Assembly of 1,3‐Polyols

Abstract: Nature's vast collection of polyketide natural products comprises thousands of compounds incorporating polyacetate derived 1,3-diol or higher 1,3-polyol substructures. While numerous protocols for the synthesis of these ubiquitous structural motifs have been advanced,[1] the iterative allylmetallation of aldehydes has found exceptionally broad use.

“…18 The resulting C 2 -symmetric diol 3 is converted to the mono -TBS ether 4 . Deprotonation of 4 using sodium hydride followed by addition of the alkoxide to tert -butyl 3-bromo-2-fluorobenzoate delivers the S N Ar product 5 .…”

Evaluation of Chromane-Based Bryostatin Analogues Prepared via Hydrogen-Mediated C–C Bond Formation: Potency Does Not Confer Bryostatin-like Biology

“…18 The resulting C 2 -symmetric diol 3 is converted to the mono -TBS ether 4 . Deprotonation of 4 using sodium hydride followed by addition of the alkoxide to tert -butyl 3-bromo-2-fluorobenzoate delivers the S N Ar product 5 .…”

Evaluation of Chromane-Based Bryostatin Analogues Prepared via Hydrogen-Mediated C–C Bond Formation: Potency Does Not Confer Bryostatin-like Biology

“…Indeed, as borne out in total syntheses of roxaticin, 7a bryostatin 7, 7b trienomycins A and F, 7c cyanolide A, 7d and 6-deoxyerythronolide B, 7e application of these methods have availed a “step-function increase” in efficiency – in each case, the synthetic route was significantly more concise than in any prior approach. 4b These studies brought to light an especially powerful protocol for the direct assembly of acetate- or propionate-based triketide stereopolyads 2a or 2b involving the bidirectional enantioselective double allylation 8a or anti -crotylation 8b of 1,3-diols 1a or 1b , respectively (eq. 1).…”

“…Key C-C bond formations include Breit’s method for the stereospecific substitution of α-hydroxy ester triflates with Grignard reagents to create the C22 stereocenter, 15 stereoselective Wittig olefination, 17 which defines the geometry of the trisubstituted olefin, and direct redox-triggered anti -crotylation of allylic alcohol 5 to form the C18-C19 stereodiad. 18 The synthesis of Fragment B takes advantage of the two-directional double anti -crotylation of 2-methyl-1,3-propane diol 1b to form adduct 2b , 7e,8b which directly establishes the triketide stereopolyad spanning C6-C10. Cross-metathesis is used to introduce the C12-C13 carbon atoms of allyl alcohol 8 , and hydroformylation is used to forge the C3-C4 bond of Fragment B .…”

“…7e,8b Iodoetherification defines the chirotopic nonstereogenic center of diol 2b at C8, and serves to differentiate the terminal olefin moieties. The pseudo - C -symmetric diol 2b is produced as a single enantiomer due to Horeau’s principle, 21 that is, the minor enantiomer of the intervening mono-adduct is converted to the pseudo - meso -diastereomer.…”

Direct Generation of Triketide Stereopolyads via Merged Redox-Construction Events: Total Synthesis of (+)-Zincophorin Methyl Ester

“…4 Tetrafibricin is a fibrinogen receptor inhibitor that embodies a unique array of functionality, including alternating 1,3-diol and 1,5-ene-diol substructures, a tetraenoic acid moiety and a primary amine. 5 Although biosynthetically related to oxo-polyene macrolide antibiotics such as lienomycin, 6 tetrafibricin lacks a macrocyclic structure and is inactive against Bacillus subtilis and Escherichia coli .…”

C(21)−C(40) of Tetrafibricin via Metal Catalysis: Beyond Stoichiometric Chiral Reagents, Auxiliaries, and Premetalated Nucleophiles