Abstract
We report studies on radical-initiated fragmentations of model 1,5-dideoxyhomoribofuranose derivatives with bromo, chloro, and tosyloxy substituents on C2. The effects of stereochemical inversion at C2 were probed with the corresponding arabino epimers. In all cases, the elimination of bromide, chloride, and tosylate anions occurred when the 3-hydroxyl group was unprotected. The isolation of deuterium-labeled furanone products established heterolytic cleavage followed by the transfer of deuterium from labeled tributylstannane. In contrast, 3-O-methyl derivatives underwent the elimination of bromine or chlorine radicals to give the 2,3-alkene with no incorporation of label in the methyl vinyl ether. More drastic fragmentation occurred with both of the 3-O-methyl-2-tosyloxy epimers to give an aromatized furan derivative with no deuterium label. Contrasting results observed with the present anhydroalditol models relative to our prior studies with analogously substituted nucleoside models have demonstrated that insights from biomimetic chemical reactions can provide illumination of mechanistic pathways employed by ribonucleotide reductases (RNRs) and the MoaA enzyme involved in the biosynthesis of molybdopterin.
Highlights
Ribonucleotide reductases (RNRs) effect conversion of nucleoside 50 -(di- or tri)phosphates into their 20 -deoxy counterparts and thereby provide the only de novo access to the monomeric precursors for DNA replication and repair [1]
The mechanism proposed [1] for conversion of ribonucleoside 5 ́-diphosphates (A, 8Xof=23OH) to
5 ́The mechanism proposed [1] for conversion of ribonucleoside 50 -diphosphates (A, X = OH)
Summary
Ribonucleotide reductases (RNRs) effect conversion of nucleoside 50 -(di- or tri)phosphates into their 20 -deoxy counterparts and thereby provide the only de novo access to the monomeric precursors for DNA replication and repair [1]. Depletion of these crucial deoxynucleotide pools by inhibition of RNRs presents an inviting approach for rational drug design [2,3]. Spontaneous loss of chloride in B (X = Cl) followed by hydrogen transfer from the thiol to C2’ in C and electron transfer to the dithiol would produce the identical 3’-keto-2’deoxynucleotide in D as with the substrate nucleotide [1,4,6].
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