Unrevalling phenotypic diversity of root system architecture in ancient wheat species versus modern wheat cultivars

Q3 Medicine

Notulae Scientia Biologicae Pub Date : 2023-11-16 DOI:10.55779/nsb15411703

H. Akman, Emine Yildirim, S. Bağci

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Abstract

Understanding the phenotypic variability in root system architecture and root-shoot relationships across different growth stages of wheat is of utmost importance for the improvement of genotypes with enhanced nutrient uptake and resource-use efficiency. This study focused on identifying variations and relationships in the root and shoot characteristics of seven modern cultivars and twelve ancient wheat accessions of different species, including T. monococcum, T. turanicum, T. polonicum, T. mirabile, T. durum, and T. aestivum, during the early vegetative growth and stem elongation stages. The results demonstrated significant phenotypic variation among the genotypes for shoot traits, root biomass, rooting depth, R/S ratio, and seminal and nodal root numbers. When considering both growth stages, the dry land-adapted cultivar ‘Taner’ and ancient wheat species, such as T. turanicum (2) and T. monococcum (1) accessions, exhibited deeper roots, which can enhance access to water in drought-prone areas. Furthermore, it was observed that modern wheat cultivars and T. turanicum accessions exhibited increased root biomass, suggesting a higher allocation of resources towards root growth, which could potentially enhance nutrient uptake. Conversely, T. monococcum accessions and T. mirabile revealed lower root biomass compared to other ancient species and modern cultivars. Additionally, the unrooted cluster analysis based on root biomass, rooting depth, and root to shoot ratio at both growth stages indicated a distinct separation of T. monococcum accessions and T. mirabile from other genotypes. Overall, these findings underscore the importance of phenotypic diversity in root traits for crop improvement and adaptation to varying environments. Identifying genotypes with desirable root characteristics can enhance nutrient and water uptake efficiencies, leading to increased crop productivity and sustainability.

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古老小麦品种与现代小麦栽培品种根系结构的表型多样性不断变化

了解小麦不同生长阶段根系结构和根-芽关系的表型变异对于改良具有更强养分吸收能力和资源利用效率的基因型至关重要。本研究的重点是鉴定七个现代栽培品种和十二个不同物种的古老小麦品种（包括 T. monococcum、T. turanicum、T. polonicum、T. mirabile、T. durum 和 T. aestivum）在早期无性生长和茎伸长阶段的根和芽特征的变异和关系。结果表明，不同基因型在芽的性状、根的生物量、生根深度、R/S 比、精根和节根数等方面存在明显的表型差异。考虑到两个生长阶段，适应旱地的栽培品种 "Taner "和古老的小麦品种，如T. turanicum（2）和T. monococcum（1），都表现出较深的根系，这可以提高易旱地区的水分利用率。此外，还观察到现代小麦栽培品种和 T. turanicum 品种的根生物量有所增加，这表明根系生长的资源分配较多，有可能提高养分吸收率。相反，与其他古老物种和现代栽培品种相比，T. monococcum 和 T. mirabile 的根生物量较低。此外，根据两个生长阶段的根生物量、扎根深度和根芽比进行的无根聚类分析表明，T. monococcum 和 T. mirabile 与其他基因型有明显的区别。总之，这些发现强调了根系特征表型多样性对作物改良和适应不同环境的重要性。确定具有理想根系特征的基因型可提高养分和水分吸收效率，从而提高作物产量和可持续性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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