139594-87-9

Basic information

• Product Name: amphidinolide F
• Synonyms: amphidinolide F
• CAS NO: 139594-87-9
• Molecular Formula: C35H52O9
• Molecular Weight: 616.78198
• Mol File: 139594-87-9.mol

Chemical Properties

• Boiling Point: 809.3°Cat760mmHg
• Flash Point: 249.3°C
• Appearance: /
• Density: 1.17g/cm³
• Vapor Pressure: 2.56E-30mmHg at 25°C
• Refractive Index: 1.548
• CAS DataBase Reference: amphidinolide F(CAS DataBase Reference)
• NIST Chemistry Reference: amphidinolide F(139594-87-9)
• EPA Substance Registry System: amphidinolide F(139594-87-9)

Safety Data

• Hazardous Substances Data: 139594-87-9(Hazardous Substances Data)

Usage

InChI:InChI=1/C35H52O9/c1-19(2)9-8-10-29-30-12-11-26(42-30)16-25(36)14-21(4)27(37)17-28(38)24(7)20(3)13-23(6)34(40)35(41)32-15-22(5)31(43-32)18-33(39)44-29/h8-10,13,21-22,24,26,28-32,34-35,38,40-41H,6,11-12,14-18H2,1-5,7H3/b10-8+,20-13+

Upstream product

• 1402820-11-4 C₁₇H₂₀O₄ 
• 1402820-13-6 C₂₆H₄₀O₇Si 
• 1402820-14-7 C₂₆H₄₀O₇Si 
• 1402820-38-5 C₅H₈O₂ 
• 1402820-10-3 C₁₂H₁₂O₂ 

Relevant articles and documents

Total Synthesis of the Marine Macrolide Amphidinolide F

A new and efficient convergent approach toward the synthesis of amphidinolide F is described through the assembly of three fragments. The two trans-tetrahydrofurans were built by a diastereoselective C-glycosylation with titanium enolate of bulky N-acetyloxazolidinethiones. The side chain was inserted by a Liebeskind-Srogl cross-coupling reaction. A sulfone condensation/desulfonylation sequence, a Stille cross-coupling, and a macrolactonization were applied to connect the fragments.

Concise total syntheses of amphidinolides C and F

The marine natural products amphidinolide C (1) and F (4) differ in their side chains but share a common macrolide core with a signature 1,4-diketone substructure. This particular motif inspired a synthesis plan predicating a late-stage formation of this non-consonant ("umpoled") pattern by a platinum-catalyzed transannular hydroalkoxylation of a cycloalkyne precursor. This key intermediate was assembled from three building blocks (29, 41 and 47 (or 65)) by Yamaguchi esterification, Stille cross-coupling and a macrocyclization by ring-closing alkyne metathesis (RCAM). This approach illustrates the exquisite alkynophilicity of the catalysts chosen for the RCAM and alkyne hydroalkoxylation steps, which activate triple bonds with remarkable ease but left up to five other p-systems in the respective substrates intact. Interestingly, the inverse chemoselectivity pattern was exploited for the preparation of the tetrahydrofuran building blocks 47 and 65 carrying the different side chains of the two target macrolides. These fragments derive from a common aldehyde precursor 46 formed by an exquisitely alkene-selective cobalt-catalyzed oxidative cyclization of the diunsaturated alcohol 44, which left an adjacent acetylene group untouched. The northern sector 29 was prepared by a two-directional Marshall propargylation strategy, whereas the highly adorned acid subunit 41 derives from d-glutamic acid by an intramolecular oxa-Michael addition and a proline-mediated hydroxyacetone aldol reaction as the key steps; the necessary Me3Sn-group on the terminus of 41 for use in the Stille coupling was installed via enol triflate 39, which was obtained by selective deprotonation/triflation of the ketone site of the precursor 38 without competing enolization of the ester also present in this particular substrate.

Exploiting hidden symmetry in natural products: Total syntheses of amphidinolides C and F

The total synthesis of amphidinolide C and a second-generation synthesis of amphidinolide F have been accomplished through the use of a common intermediate to access both the C1-C8 and the C18-C 25 sections. The development of a Ag-catalyzed cyclization of a propargyl benzoate diol is described to access both trans-tetrahydrofuran rings. The evolution of a Felkin-controlled, 2-lithio-1,3-dienyl addition strategy to incorporate C9-C11 diene as well as C8 stereocenter is detailed. Key controlling aspects in the sulfone alkylation/oxidative desulfurization to join the major subunits, including the exploration of the optimum masking group for the C18 carbonyl motif, are discussed. A Trost asymmetric alkynylation and a stereoselective cuprate addition to an alkynoate have been developed for the rapid construction of the C26-C34 subunit. A Tamura/Vedejs olefination to introduce the C26 side arm of amphidnolides C and F is employed. The late-stage incorporation of the C15, C18 diketone motif proved critical to the successful competition of the total syntheses.

Total synthesis of amphidinolide f

Orchestrated yet nonconsonant: The challenge posed by the "umpoled" 1,4-dioxygenation pattern characteristic for the polyketide frame of amphidinolide F was mastered by a late-stage ring-closing alkyne metathesis followed by a directed transannular hydration under the aegis of a carbophilic π-acid catalyst. This concordant strategy enabled a concise total synthesis of this enticing marine natural product. Copyright

Enantioselective total synthesis of amphidinolide F

A common-intermediate approach is utilized in the total synthesis of amphidinolide F (see scheme, left) to access both the C1-C8 and the C18-C25 portions of the macrolide. A silver-catalyzed rearrangement/cyclization was employed to construct the two tetrahydrofuran rings. A Felkin-controlled, dienyl lithium addition to an α-chiral aldehyde incorporated both the C9-C11 diene and the alcohol at C8. An umpolung sulfone alkylation/oxidative desulfurization sequence is employed to couple the two moieties. Copyright