Reaction #433623

ord-cb37b6cfcc18455d8950d3d18f7b732c

Reaction equation

O[C@@H]1C=CC=C[C@@H]1O
cis-1,2-dihydrocatechol
[CH2-]C(C)=O
acetonide
[CH2-]C(C)=O
acetonide
O=C(OO)c1ccccc1Cl
chloroperbenzoic acid
OC1C=CC(O)C(O)C1O
conduritol

Solvents

Conditions

Detailed conditions
See reaction.notes.procedure_details.

Workup

  1. 1
    Otherto produce
  2. 2
    Otherreacted with a range of nucleophiles at the allylic carbon of the epoxide ring so as

Procedure

Compound 7 was readily obtained in large quantity and enantiomerically pure form by the biotransformation of iodobenzene using the genetically engineered micro-organism E. coli JM109 (pDTG601) which over expresses toluene dioxygenase (TDO), the enzyme responsible for this dihydroxylation reaction. In the first step of the reaction sequence, cis-1,2-dihydrocatechol 7 was converted into the corresponding acetonide, 8, under standard conditions. The acetonide was immediately reacted with ml-chloroperbenzoic acid (m-CPBA) so as to produce, in a completely regio- and diastereo-selective manner, the epoxide 10. This compound represented a potent electrophile which reacted with a range of nucleophiles at the allylic carbon of the epoxide ring so as to give conduritol and conduramine derivatives. In particular, reaction of compound 10 with 1,6-hexadiamine in dichloromethane at 18° C. for 4 days gave the dimeric species 11 in quantitative yield. The readily obtained bis-acetamido-derivative, 12, of the latter compound was subject to a Pd[0]-mediated carbomethoxylation reaction thereby producing the diester 13 wherein each six-membered ring incorporates an exocyclic carbon in an appropriate oxidation state as required for elaboration to pseudo-sugars.

Source

DOI: 10.6084/m9.figshare.5104873.v1Patent: US07173019B2uspto-grants-2007_02