Enhancement of folates in plants through metabolic engineering.
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Present and future of folate biofortification of crop plantsA systematic map of genetic variation in Plasmodium falciparumBiochemical and functional characterization of Plasmodium falciparum GTP cyclohydrolase IOrigin of robustness in generating drug-resistant malaria parasitesComparative genomics of bacterial and plant folate synthesis and salvage: predictions and validationsFolate synthesis in plants: purification, kinetic properties, and inhibition of aminodeoxychorismate synthase.Genetic basis for natural variation in seed vitamin E levels in Arabidopsis thaliana.The molecular basis of antifolate resistance in Plasmodium falciparum: looking beyond point mutations.Folate biofortification of tomato fruitBiofortification of plant-based food: enhancing folate levels by metabolic engineering.The Rickettsia Endosymbiont of Ixodes pacificus Contains All the Genes of De Novo Folate Biosynthesis.Folates in Plants: Research Advances and Progress in Crop BiofortificationDirect evidence for the adaptive role of copy number variation on antifolate susceptibility in Plasmodium falciparum.Transgenic multivitamin corn through biofortification of endosperm with three vitamins representing three distinct metabolic pathways.Quantification of Förster resonance energy transfer by monitoring sensitized emission in living plant cells.Metabolic engineering of folate and its precursors in Mexican common bean (Phaseolus vulgaris L.).Folate biofortification in tomatoes by engineering the pteridine branch of folate synthesis.Enhancing the health-promoting effects of tomato fruit for biofortified foodControl limits for accumulation of plant metabolites: brute force is no substitute for understanding.Plant gamma-glutamyl hydrolases and folate polyglutamates: characterization, compartmentation, and co-occurrence in vacuoles.Recombinant overexpression of dihydroneopterin aldolase catalyst potentially regulates folate-biofortification.The manipulation of gene expression and the biosynthesis of Vitamin C, E and folate in light-and dark-germination of sweet corn seeds.A nudix enzyme removes pyrophosphate from dihydroneopterin triphosphate in the folate synthesis pathway of bacteria and plants.Nonflowering plants possess a unique folate-dependent phenylalanine hydroxylase that is localized in chloroplasts.Enhancing pterin and para-aminobenzoate content is not sufficient to successfully biofortify potato tubers and Arabidopsis thaliana plants with folate.Bioengineering of crop plants for improved tetrahydrofolate production.Metabolic engineering of micronutrients in crop plants.Pterin and folate salvage. Plants and Escherichia coli lack capacity to reduce oxidized pterins.Toward Eradication of B-Vitamin Deficiencies: Considerations for Crop Biofortification.Biotechnology for Enhanced Nutritional Quality in PlantsDevelopment of an HPLC-MS method for the determination of natural pteridines in tomato samples
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Enhancement of folates in plants through metabolic engineering.
description
article científic
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article scientifique
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articolo scientifico
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artigo científico
@pt
bilimsel makale
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scientific article published on 24 March 2004
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vedecký článok
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vetenskaplig artikel
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videnskabelig artikel
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vědecký článek
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name
Enhancement of folates in plants through metabolic engineering.
@en
Enhancement of folates in plants through metabolic engineering.
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type
label
Enhancement of folates in plants through metabolic engineering.
@en
Enhancement of folates in plants through metabolic engineering.
@nl
prefLabel
Enhancement of folates in plants through metabolic engineering.
@en
Enhancement of folates in plants through metabolic engineering.
@nl
P2093
P2860
P356
P1476
Enhancement of folates in plants through metabolic engineering.
@en
P2093
Ganesh Kishore
Irwin Rosenberg
Jacob Selhub
Karel Schubert
Roger Beachy
Tahzeeba Hossain
P2860
P304
P356
10.1073/PNAS.0401342101
P407
P577
2004-03-24T00:00:00Z