1.16.1.7: ferric-chelate reductase (NADH)
This is an abbreviated version!
For detailed information about ferric-chelate reductase (NADH), go to the full flat file.
Word Map on EC 1.16.1.7
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1.16.1.7
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feiii
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fe-deficient
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feiii-chelate
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chlorosis
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iron-deficiency
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agriculture
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fe-sufficient
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phytosiderophores
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feiii-reducing
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lefro1
- 1.16.1.7
-
feiii
-
fe-deficient
-
feiii-chelate
- chlorosis
-
iron-deficiency
- agriculture
-
fe-sufficient
-
phytosiderophores
-
feiii-reducing
-
lefro1
Reaction
2 Fe(II)-siderophore + + = 2 Fe(III)-siderophore +
Synonyms
AhFRO1, EC 1.6.99.13, FC-R, FCR, Fe deficiency-induced ferric chelate reductase, Fe(III) chelate reductase, Fe(III) reductase, Fe(III)-chelate reductase, Fe(III)-ethylenediaminetetraacetic complex reductase, Fe(III)EDTA reductase, Fe3+-chelate reductase, ferric chelate reductase, ferric reductase oxidase, ferric-chelate reductase, FRO1, FRO2, FRO6, FRO7, iron chelate reductase, NADH-linked FeEDTA reductase, NADH-linked ferric chelate (turbo) reductase, NADH:Fe3+ oxidoreductase, reductase, iron chelate, root Fe(III) reductase, [Fe(III)-EDTA] reductase
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Application on EC 1.16.1.7 - ferric-chelate reductase (NADH)
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agriculture
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increase in ethylene production is accompanied by increase in enzyme activity. Salicylic acid, methionine and ethephon enhance ethylene production, AgNO3 inhibits. Induction of enzyme activity is accompanied by increase in iron, zinc and phosphorus concentration of explants
agriculture
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increase in ethylene production is accompanied by increase in enzyme activity. Salicylic acid, methionine and ethephon enhance ethylene production, AgNO3 inhibits. Induction of enzyme activity is accompanied by increase in iron, zinc and phosphorus concentration of explants
agriculture
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increase in ethylene production is accompanied by increase in enzyme activity. Salicylic acid, methionine and ethephon enhance ethylene production, AgNO3 inhibits. Induction of enzyme activity is accompanied by increase in iron, zinc and phosphorus concentration of explants
agriculture
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lower enzyme activity in leaves of seedlings grown on 0.002 mM iron than in plants grown on 0.022 or 0.045 mM iron, lack of iron decreases the leaf chlorophyll index and iron concentration in recently matured leaves. Iron level in nutrient solution has no effect on fresh and dry weight
agriculture
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lower enzyme activity in leaves of seedlings grown on 0.002 mM iron than in plants grown on 0.022 or 0.045 mM iron, leaves of plants grown without iron become chlorotic within 6 weeks, lack of iron decreases the leaf chlorophyll index and iron concentration in recently matured leaves
agriculture
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main reason for iron deficiency chlorosis of plants grown on calcareous soils is the inhibition of FeIII reduction in the apoplast and hence Fe2+ uptake into the cytosol
agriculture
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Vaccinium corymbosum is less efficient in acquiring nitrate than Vaccinium arboreum, possibly due to decreased enzyme activity. This may partially explain the wider soil adaptation of Vaccinium arboreum
agriculture
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Vaccinium corymbosum is less efficient in acquiring nitrate than Vaccinium arboreum, possibly due to decreased enzyme activity. This may partially explain the wider soil adaptation of Vaccinium arboreum
agriculture
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bicarbonate induced deficiency in iron may cause more severe oxidative stress in the rootstocks, than the absence of iron. Additionally to inhibition of iron-chelate reductase, growth in presence of bicarbonate may lead to decreased activities of peroxidase and Cu/Zn superoxide dismutase, depending on the subspecies of plant
agriculture
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heterologous expression of isoform AtFRO2 in Glycine max significantly enhances Fe3+ reduction in roots and leaves. Root ferric reductase activity is up to tenfold higher in transgenic plants than in control and is not subject to post-transcriptional regulation. In leaves, enzyme activity is threefold higher than in control. Enhanced ferric reductase activity leads to reduced chlorosis, increased chlorophyll concentration and a lessening in biomass loss. However, constitutive heterologous expression of AtFRO2 under non-iron stress conditions may result in decrease in plant productivity
agriculture
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enhancing the Fe3+ chelate reductase activity of rice plants that normally have low endogenous levels confers resistance to Fe deficiency
agriculture
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ferric reductase oxidase 7 is a chloroplast Fe(III) chelate reductase required for survival under ironlimiting conditions, for efficient photosynthesis, and for proper chloroplast iron acquisition in young seedlings
agriculture
virus-induced gene silencing is used to silence the ferric chelate reductase, virus-induced gene silencing system can be employed to investigate gene function associated with plant nutrient uptake in roots