Plant Physiology DOI: 10.1104/pp.124.2.781
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Oliver Yu
1
,
Woosuk Jung
2
,
June Shi
3
et al.
Abstract: Metabolic engineering for production of isoflavones in non-legume plants may provide the health benefits of these phytoestrogens from consumption of more widely used grains. In legumes, isoflavones function in both the symbiotic relationship with rhizobial bacteria and the plant defense response. Expression of a soybean isoflavone synthase (IFS) gene in Arabidopsis plants was previously shown to result in the synthesis and accumulation of the isoflavone genistein in leaf and stem tissue (Jung et al., 2000). He… Show more
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Cited by 249 publications
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References 49 publications
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“…The qualitative and quantitative differences in the accumulation of particular flavonoids when the maize enzymes are expressed in Arabidopsis suggest that modest differences in their substrate preferences may exist, providing both powerful tools and remarkable challenges for the engineering of novel metabolites in specific plants. The recent demonstration that a soybean (Phaseolus vulgaris) isoflavone synthase, by itself or in the presence of a soybean chalcone reductase, is capable of inducing the accumulation of soybean isoflavonoids (genistein and daidzein) in maize, tobacco (Yu et al, 2000), and Arabidopsis (Jung et al, 2000), provides further evidence of the efficacy of the heterologous expression of biosynthetic enzymes for metabolic engineering. The findings presented here also indicate the value of the Arabidopsis flavonoid biosynthetic mutants as a convenient system to assay the activity of biosynthetic genes from other plants.…”
Section: Discussionmentioning confidence: 99%
Dong
1
,
Braun
2
,
Grotewold
3
2001
Plant Physiology
Mutations in the transparent testa (tt) loci abolish pigment production in Arabidopsis seed coats. The TT4, TT5, and TT3 loci encode chalcone synthase, chalcone isomerase, and dihydroflavonol 4-reductase, respectively, which are essential for anthocyanin accumulation and may form a macromolecular complex. Here, we show that the products of the maize (Zea mays) C2, CHI1, and A1 genes complement Arabidopsis tt4, tt5, and tt3 mutants, restoring the ability of these mutants to accumulate pigments in seed coats and seedlings. Overexpression of the maize genes in wild-type Arabidopsis seedlings does not result in increased anthocyanin accumulation, suggesting that the steps catalyzed by these enzymes are not rate limiting in the conditions assayed. The expression of the maize A1 gene in the flavonoid 3Ј hydroxylase Arabidopsis tt7 mutant resulted in an increased accumulation of pelargonidin. We conclude that enzymes involved in secondary metabolism can be functionally exchangeable between plants separated by large evolutionary distances. This is in sharp contrast to the notion that the more relaxed selective constrains to which secondary metabolic pathways are subjected is responsible for the rapid divergence of the corresponding enzymes.
“…The qualitative and quantitative differences in the accumulation of particular flavonoids when the maize enzymes are expressed in Arabidopsis suggest that modest differences in their substrate preferences may exist, providing both powerful tools and remarkable challenges for the engineering of novel metabolites in specific plants. The recent demonstration that a soybean (Phaseolus vulgaris) isoflavone synthase, by itself or in the presence of a soybean chalcone reductase, is capable of inducing the accumulation of soybean isoflavonoids (genistein and daidzein) in maize, tobacco (Yu et al, 2000), and Arabidopsis (Jung et al, 2000), provides further evidence of the efficacy of the heterologous expression of biosynthetic enzymes for metabolic engineering. The findings presented here also indicate the value of the Arabidopsis flavonoid biosynthetic mutants as a convenient system to assay the activity of biosynthetic genes from other plants.…”
Section: Discussionmentioning confidence: 99%
Dong
1
,
Braun
2
,
Grotewold
3
2001
Plant Physiology
Mutations in the transparent testa (tt) loci abolish pigment production in Arabidopsis seed coats. The TT4, TT5, and TT3 loci encode chalcone synthase, chalcone isomerase, and dihydroflavonol 4-reductase, respectively, which are essential for anthocyanin accumulation and may form a macromolecular complex. Here, we show that the products of the maize (Zea mays) C2, CHI1, and A1 genes complement Arabidopsis tt4, tt5, and tt3 mutants, restoring the ability of these mutants to accumulate pigments in seed coats and seedlings. Overexpression of the maize genes in wild-type Arabidopsis seedlings does not result in increased anthocyanin accumulation, suggesting that the steps catalyzed by these enzymes are not rate limiting in the conditions assayed. The expression of the maize A1 gene in the flavonoid 3Ј hydroxylase Arabidopsis tt7 mutant resulted in an increased accumulation of pelargonidin. We conclude that enzymes involved in secondary metabolism can be functionally exchangeable between plants separated by large evolutionary distances. This is in sharp contrast to the notion that the more relaxed selective constrains to which secondary metabolic pathways are subjected is responsible for the rapid divergence of the corresponding enzymes.
“…The protein content of each microsome preparation was assayed using the Bradford protein microassay (Bio-Rad). The in vitro microsomal enzyme assay was carried out as previously described (Yu et al, 2000). Briefly, approximately 80 mg of microsomal proteins were incubated at 30°C in a reaction buffer containing 80 mM K 2 HPO 4 (pH 8.0), 0.5 mM glutathione, with 100 mM naringenin as the substrate and 0.4 mM NADPH as the cofactor.…”
Section: In Vitro Mtfnsii Enzyme Activity Assaymentioning confidence: 99%
Zhang
1
,
Subramanian
2
,
Zhang
3
et al. 2007
Plant Physiology Self Cite
Flavones are important copigments found in the flowers of many higher plants and play a variety of roles in plant adaptation to stress. In Medicago species, flavones also act as signal molecules during symbiotic interaction with the diazotropic bacterium Sinorhizobium meliloti. They are the most potent nod gene inducers found in root exudates. However, flavone synthase II (FNS II), the key enzyme responsible for flavone biosynthesis, has not been characterized in Medicago species. We cloned two FNS II genes from Medicago truncatula using known FNS II sequences from other species and named them MtFNSII-1 and MtFNSII-2. Functional assays in yeast (Saccharomyces cerevisiae) suggested that the catalytic mechanisms of both cytochrome P450 monooxygenases were similar to the other known legume FNS II from licorice (Glycyrrhiza echinata). MtFNSII converted flavanones to 2-hydroxyflavanones instead of flavones whereas FNS II from the nonlegume Gerbera hybrida, converted flavanones to flavones directly. The two MtFNSII genes had distinct tissue-specific expression patterns. MtFNSII-1 was highly expressed in roots and seeds whereas MtFNSII-2 was highly expressed in flowers and siliques. In addition, MtFNSII-2 was inducible by S. meliloti and methyl jasmonate treatment, whereas MtFNSII-1 was not. Histochemical staining of transgenic hairy roots carrying the promoter-reporter constructs indicated that the MtFNSII-2 induction was tissue specific, mostly localized to vascular tissues and root hairs. RNA interference-mediated suppression of MtFNSII genes resulted in flavone depleted roots and led to significantly reduced nodulation when inoculated with S. meliloti. Our results provide genetic evidence supporting that flavones are important for nodulation in M. truncatula.
“…In soybean glycosidic forms are abundant while the aglycones are found only in small amount. Two genes encoding isoflavone synthase were identified from soybean exploiting the nature of enzyme as a protein of cytochrome P450 family by screening yeast ESTs of soybean and expressed it in Arabidopsis resulting in production of isoflavones in A. thalina which otherwise doesn't synthesise isoflavones (Jung et al, 2000). This further established the role of IFS as a key enzyme in isoflavone synthesis.…”
Section: Biosynthesismentioning confidence: 97%
“…Isoflavone synthase (IFS) is a cytochrome P450 monooxygenase bound to endoplasmic reticulum is the ultimate enzyme involved in the pathway. In soybean, two isoforms of this enzyme are present (Jung et al, 2000). An increased activity of IFS may cause increased generation of isoflavones because it is the key regulatory enzyme involved in isoflavone production (Pregelj et al, 2010).…”
Section: Biosynthesismentioning confidence: 99%
Kumar
1
2017
Int.J.Curr.Microbiol.App.Sci
No abstract
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