Abstract
Dihydropterins are intermediates of folate synthesis and products of folate breakdown that are readily oxidized to their aromatic forms. In trypanosomatid parasites, reduction of such oxidized pterins is crucial for pterin and folate salvage. We therefore sought evidence for this reaction in plants. Three lines of evidence indicated its absence. First, when pterin-6-aldehyde or 6-hydroxymethylpterin was supplied to Arabidopsis (Arabidopsis thaliana), pea (Pisum sativum), or tomato (Lycopersicon esculentum) tissues, no reduction of the pterin ring was seen after 15 h, although reduction and oxidation of the side chain of pterin-6-aldehyde were readily detected. Second, no label was incorporated into folates when 6-[(3)H]hydroxymethylpterin was fed to cultured Arabidopsis plantlets for 7 d, whereas [(3)H]folate synthesis from p-[(3)H]aminobenzoate was extensive. Third, no NAD(P)H-dependent pterin ring reduction was found in tissue extracts. Genetic evidence showed a similar situation in Escherichia coli: a GTP cyclohydrolase I (folE) mutant, deficient in pterin synthesis, was rescued by dihydropterins but not by the corresponding oxidized forms. Expression of a trypanosomatid pterin reductase (PTR1) enabled rescue of the mutant by oxidized pterins, establishing that E. coli can take up oxidized pterins but cannot reduce them. Similarly, a GTP cyclohydrolase I (fol2) mutant of yeast (Saccharomyces cerevisiae) was rescued by dihydropterins but not by most oxidized pterins, 6-hydroxymethylpterin being an exception. These results show that the capacity to reduce oxidized pterins is not ubiquitous in folate-synthesizing organisms. If it is lacking, folate precursors or breakdown products that become oxidized will permanently exit the metabolically active pterin pool.
Highlights
Dihydropterins are intermediates of folate synthesis and products of folate breakdown that are readily oxidized to their aromatic forms
We report here several lines of evidence that plants and E. coli have no detectable capacity to reduce the evidence are quite persuasive, and made more so by the unequivocal genetic evidence for a similar situation in E. coli
Unlike trypanosomatids, plants and E. coli have very little if any potential to salvage oxidized pterins, and that if this potential exists at all, it is physiologically insignificant compared to the capacity to modify the side chain
Summary
Dihydropterins are intermediates of folate synthesis and products of folate breakdown that are readily oxidized to their aromatic forms. Genetic evidence showed a similar situation in Escherichia coli: a GTP cyclohydrolase I (folE) mutant, deficient in pterin synthesis, was rescued by dihydropterins but not by the corresponding oxidized forms. A GTP cyclohydrolase I (fol2) mutant of yeast (Saccharomyces cerevisiae) was rescued by dihydropterins but not by most oxidized pterins, 6-hydroxymethylpterin being an exception These results show that the capacity to reduce oxidized pterins is not ubiquitous in folate-synthesizing organisms. Only Leishmania and other trypanosomatid parasites are definitively known to have this capacity These organisms, which are pterin and folate auxotrophs, contain an NADPH-. Plant genomes encode homologs of mammalian pterin 4a-carbinolamine dehydratase, an enzyme needed to recycle tetrahydropterin cofactors (Thony et al, 2000) that may be considered diagnostic for their presence
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