Add to ORKGDicots and non-graminaceous monocots have the ability to increase root iron(III) reducing capacity in response to iron (Fe) deficiency stress. In squash (Cucurbita pepo L.) seedlings, Fe(III) reducing capacity was quantified during early vegetative growth. When plants were grown in Fe-free solution, the Fe(III) reducing capacity was greatly elevated, reached peak activity on day 4, then declined through day 6. Root ethylene production exhibited a temporal pattern that closely matched that of Fe(III) reducing capacity through day 6. On the 7th day of Fe deficiency, cluster root morphology developed, which coincided with a sharp increase in the root Fe(III) reducing capacity, although ethylene production decreased. Localization of Fe(III) red...
Plants can cope with Fe deficiency by either acidifying the rhizosphere and enhancing the ferric che...
缺鐵植株之形態變化為幼葉黃化,生長受到抑制,根伸長停止根尖直徑增加,產生多數之側根及根毛且有轉運細胞的發生。生理方面,雙子葉及部份單子葉植物根表皮細胞可增加氫離子釋放,分泌酚類化合物及增進細胞膜還原能...
Plants acquire iron from soil by two specific mechanisms: i) reduction of Fe3+ to Fe2+, a reaction c...
Dicots and non-graminaceous monocots have the ability to increase root iron(III) reducing capacity i...
© 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article dis...
Iron deficiency induces a yellowing in the aerial part of plants, known as iron chlorosis, and reduc...
Iron ranks fourth in the sequence of abundance of the elements in the Earth's crust, but its low bio...
Iron may accumulate in various chemical forms during its uptake and assimilation in roots. The perma...
Iron (Fe) bioavailability in soils is often limited and can be further exacerbated by a non-homogene...
Aims: Iron (Fe) is an essential micronutrient, and plant-available Fe is often limited in alkaline s...
Iron deficiency in plants is caused by a low availability of iron in the soil, and its main visual s...
To acquire iron, many plant species reduce soil Fe(III) to Fe(II) by Fe(III)-chelate reductases embe...
Iron deficiency in plants is caused by a low availability of iron in the soil, and its main visual s...
Iron (Fe) is an essential microelement but is highly toxic when in excess. The response of plant roo...
Iron (Fe) is an essential mineral that has low solubility in alkaline soils, where its deficiency re...
Plants can cope with Fe deficiency by either acidifying the rhizosphere and enhancing the ferric che...
缺鐵植株之形態變化為幼葉黃化,生長受到抑制,根伸長停止根尖直徑增加,產生多數之側根及根毛且有轉運細胞的發生。生理方面,雙子葉及部份單子葉植物根表皮細胞可增加氫離子釋放,分泌酚類化合物及增進細胞膜還原能...
Plants acquire iron from soil by two specific mechanisms: i) reduction of Fe3+ to Fe2+, a reaction c...
Dicots and non-graminaceous monocots have the ability to increase root iron(III) reducing capacity i...
© 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article dis...
Iron deficiency induces a yellowing in the aerial part of plants, known as iron chlorosis, and reduc...
Iron ranks fourth in the sequence of abundance of the elements in the Earth's crust, but its low bio...
Iron may accumulate in various chemical forms during its uptake and assimilation in roots. The perma...
Iron (Fe) bioavailability in soils is often limited and can be further exacerbated by a non-homogene...
Aims: Iron (Fe) is an essential micronutrient, and plant-available Fe is often limited in alkaline s...
Iron deficiency in plants is caused by a low availability of iron in the soil, and its main visual s...
To acquire iron, many plant species reduce soil Fe(III) to Fe(II) by Fe(III)-chelate reductases embe...
Iron deficiency in plants is caused by a low availability of iron in the soil, and its main visual s...
Iron (Fe) is an essential microelement but is highly toxic when in excess. The response of plant roo...
Iron (Fe) is an essential mineral that has low solubility in alkaline soils, where its deficiency re...
Plants can cope with Fe deficiency by either acidifying the rhizosphere and enhancing the ferric che...
缺鐵植株之形態變化為幼葉黃化,生長受到抑制,根伸長停止根尖直徑增加,產生多數之側根及根毛且有轉運細胞的發生。生理方面,雙子葉及部份單子葉植物根表皮細胞可增加氫離子釋放,分泌酚類化合物及增進細胞膜還原能...
Plants acquire iron from soil by two specific mechanisms: i) reduction of Fe3+ to Fe2+, a reaction c...