Rhodium Carbenoid Induced [1,2]-Migration in an l-Lyxo-Configured α-Diazo β-Keto Ester: Synthesis of a New Griseolic Acid Analogue

 

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Abstract

An appropriately substituted α-diazo β-keto ester, prepared from d-glucose, on treatment with a catalytic amount of dirhodium tetraacetate gave a strained 1,5-dioxabicyclo[3.3.0]octane ring system with concomitant diastereoselective formation of a quaternary carbon substituted with both an ethoxycarbonyl group and a 2-ethoxy-2-oxoethyl group; the product is a key intermediate in the synthesis of a new griseolic acid analogue.

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The unstable nature of compound 7 precluded further characterization. At this stage, attempts were made to convert the keto compound 7 into one with an olefinic functionality at the ring junction. Thus, attempts at the reaction of 7 by using the Shapiro protocol (SO₂Cl₂ and POCl₃) led to a complex mixture. Attempts to activate the hydroxyl functionality by using mesyl chloride and subsequent treatment with base under reflux were also unsuccessful.

Our attempts to isolate the other diastereomer (C-5β-OH) in a pure form were unsuccessful.

In the ^¹H NMR spectrum of 9, the C-5 appeared at δ = 5. 5 as a doublet (J _5,4 = 5.00 Hz). In 1D NOSEY irradiation, one of the C-7 methylene protons at δ = 2.48 showed a NOE with H-3, H-4, H-5, indicating a syn-relationship between the
-CCH₂COOEt group and the sugar ring protons, and confirming our earlier assignment.

The ^¹H NMR spectrum of 10 shows the presence of an anomeric mixture in the ratio 1:15 in favor of the β-anomer.

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