PLANT PHOSPHORUS USE EFFICIENCY IN ACID TROPICAL SOIL

Maria José VILAÇA DE VASCONCELOS, José Edson FONTES FIGUEIREDO, M. F. DE OLIVEIRA, R. Schaffert, Kachandra G. Raghothama
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引用次数: 2

Abstract

Phosphorus is an essential macronutrient for plant growth and development. However, phosphorus availability is low in many soils, and the plant's ability to acquire phosphorus from the rhizosphere is critical in the acid soils of the Brazilian Cerrado. In addition, high levels of fixed phosphate (Pi) in many soils reduce phosphorus availability to plants. Thus, Pi deficiency is a significant concern for crop growth and high yields in tropical soils. The intra- and interspecific variations in plant growth under Pi-limiting conditions are complex traits controlled by many induced or suppressed genes, comprising an intricate epistatic regulatory network interacting within cells and the external environment. The microRNA genes (miRNAs), a class of regulators that induce, degrade or repress mRNA transcription and translation, are another critical aspect of this network. As a result, changes in morphology (growth and root architecture) and physiological (enzymes, organic acids, and anthocyanin) can be observed in plants under Pi stress. Furthermore, symbiotic associations with phosphate-solubilizing bacteria and mycorrhizal fungi increase phosphorus availability to plants. Therefore, understanding mechanisms involved in plant adaptation to phosphorus deficiency is critical for developing cultivars adapted to low phosphorus levels in the Brazilian acid soils. This review addresses P acquisition and use by plants and discusses its implications in genetic breeding programs.
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热带酸性土壤植物磷利用效率研究
磷是植物生长发育所必需的大量营养素。然而,磷在许多土壤中的有效性很低,在巴西塞拉多的酸性土壤中,植物从根际获取磷的能力至关重要。此外,许多土壤中高水平的固定磷酸盐(Pi)降低了植物对磷的有效性。因此,Pi缺乏是热带土壤中作物生长和高产的一个重要问题。Pi限制条件下植物生长的种内和种间变异是由许多诱导或抑制基因控制的复杂性状,包括细胞内和外部环境相互作用的复杂上位调控网络。微小RNA基因(miRNA)是一类诱导、降解或抑制mRNA转录和翻译的调节因子,是该网络的另一个关键方面。因此,在Pi胁迫下,可以观察到植物的形态(生长和根系结构)和生理(酶、有机酸和花青素)的变化。此外,与溶磷细菌和菌根真菌的共生关系增加了植物对磷的利用率。因此,了解植物对缺磷的适应机制对于开发适应巴西酸性土壤低磷水平的品种至关重要。这篇综述论述了植物对磷的获取和利用,并讨论了它在遗传育种计划中的意义。
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审稿时长
40 weeks
期刊最新文献
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