Differential response of pea (Pisum sativum L.) genotypes to iron deficiency in relation to the growth, rhizosphere acidification and ferric chelate reductase activities

A. Krouma
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引用次数: 3

Abstract

Calcareous soils are known problematic lands for agricultural systems because of the low availability of nutrients, particularly iron (Fe). The so-called strategy I plant (e. g. Pea, Pisum sativum L.) which groups dicotyledons and monocots other than grasses, developed root membrane activities that contribute to the improvement of Fe availability. Among the functions considered to be a critical phase in iron absorption is rhizosphere acidification by H-ATPase and Fe(III) reduced by Fe(III) chelate reducctase (FeCR). In order to experimentally investigate the importance of root FeCR in Fe nutrition, its relationship with rhizosphere acidification and the genotypic differences in response to iron deficiency in pea (Pisum sativum L.), a glasshouse experiment was conducted hydroponically on four genotypes Merveille de Kelvedon (MK); Lincoln (Lin); Douce de Provence (DP) and Alexandra (Alex). Plants of each genotype were distributed into two plots, the first one received full nutrient solution (+ Fe), the second one received nutrient solution devoid of iron (- Fe). Plant growth, Fe distribution, SPAD index and root acidification and ferric chelate reductase activities were evaluated. Fe deficiency decreased plant growth and SPAD index along with the significant increase of H-ATPase and FeCR activities. Some genotypic differences were observed as follows; Alex showed high tolerance to Fe deprivation as compared to other genotypes. Important H-ATPase and FeCR activities, high Fe use efficiency and adequate membrane efficiency are the main reasons for this tolerance. These physiological parameters could be used as tools of tolerance for further breeding programs
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不同基因型豌豆生长、根际酸化和铁螯合还原酶活性对缺铁的差异反应
众所周知,钙质土壤是农业系统存在问题的土地,因为营养物质,特别是铁(Fe)的可用性低。所谓的策略I植物(如豌豆,Pisum sativum L.)是双子叶植物和单子叶植物,而不是禾草,它们的根膜活性有助于提高铁的有效性。被认为是铁吸收的关键阶段的功能包括h - atp酶的根际酸化和铁(III)螯合还原酶(FeCR)还原的铁(III)。为了研究豌豆(Pisum sativum L.)根系FeCR在铁营养中的重要性、与根际酸化的关系以及对铁缺乏反应的基因型差异,对4个基因型Merveille de Kelvedon (MK)进行了温室水培试验;林肯(林);Douce de Provence (DP)和Alexandra (Alex)。每个基因型的植株分布在2个地块中,第1个地块施用全营养液(+ Fe),第2个地块施用缺铁营养液(- Fe)。对植物生长、铁分布、SPAD指数、根系酸化和铁螯合还原酶活性进行了评价。缺铁降低了植物生长和SPAD指数,h - atp酶和FeCR活性显著升高。观察到的基因型差异如下:与其他基因型相比,亚历克斯对缺铁表现出较高的耐受性。重要的h - atp酶和FeCR活性,高铁利用率和足够的膜效率是这种耐受性的主要原因。这些生理参数可以作为进一步育种计划的耐受性工具
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