近日，華中農(nóng)業(yè)大學資源與環(huán)境學院植物營養(yǎng)生物學課題組聯(lián)合中國農(nóng)業(yè)大學在油菜適應緊實土壤脅迫適應性機制研究中取得新進展，相關成果以“Compacted soil adaptability of Brassica napus driven by root mechanical traits”為題發(fā)表在Soil & Tillage Research上。

 

　　由機械化耕作、土壤干旱、長期免耕和農(nóng)業(yè)集約化生產(chǎn)等造成的土壤壓實會嚴重破壞土壤結構，同時顯著阻礙作物生長和產(chǎn)量提高，但目前學術界對土壤壓實如何影響植物功能和生態(tài)策略仍不清楚?；诖吮尘?，課題組以我國重要油料作物—甘藍型油菜為研究對象，探究具有不同機械特征的油菜品種如何影響土壤緊實脅迫適應性、根系性狀之間的權衡和養(yǎng)分獲取能力，以及不同油菜品種的基因型響應特征。

 

　　結果表明，土壤壓實顯著抑制了根系下扎深度和根系生長，降低養(yǎng)分吸收和植物生物量累積。然而，土壤壓實顯著促進甘藍型油菜根系平均直徑和根冠比增加。在緊實土壤中，具有較強根系力學性質(zhì)（根系拉力、抗拉強度和彈性模量）的甘藍型油菜品種根系具有較高濃度的纖維素和木質(zhì)素，且具有顯著較大的根系下扎深度和比根長，同時根系分泌顯著較多的有機酸和多糖類物質(zhì)。土壤壓實導致土壤中具有較多的小孔隙，根-土界面分布較多的細根促進根系下扎，同時誘導產(chǎn)生較多根系分泌物（有機酸和糖類物質(zhì)）在根系下扎中起潤滑作用，促進根系形態(tài)的建立和生物量累積。因此，較強根系力學性質(zhì)的甘藍型油菜品種中更多的細根和根系分泌較多的有機酸和糖類物質(zhì)，對甘藍型油菜根系在壓實土壤中的下扎至關重要。

 

　　我校博士研究生段賢杰為論文第一作者，石磊教授和中國農(nóng)業(yè)大學金可默副教授為共同通訊作者。我校博士生劉玲、何陽波副教授、徐芳森教授，法國農(nóng)學院毛準研究員、中國農(nóng)科院西雙版納熱帶植物園夏尚文副研究員、英國雷丁大學John P. Hammond教授和英國詹姆斯？赫頓研究所Philip J. White教授也參與了該項研究。該研究得到了國家自然科學基金和蘇格蘭政府戰(zhàn)略研究計劃等項目的支持。

 

　　【英文摘要】

 

　　Soil compaction due to mechanized farming operations is a recurrent issue affecting crop growth and yield. Yet, how soil compaction affects plant functions and ecological strategies is poorly known. With Brassica napus, i.e. a widespread crop species as study object, we aim to understand （i） how soil compaction impacts root and shoot traits related to the plant's well-being, nutrient acquisition of Brassica napus with different mechanical robustness, as well as their trade-offs, and （ii） how such impacts vary among different cultivars. To do this, we cultivated six cultivars of Brassica napus in non-compacted （control） and compacted （treatment） soils, respectively, in a sand culture system. After harvesting, a series of mechanical, morphological and chemical traits of roots and/or shoots were measured. Results showed that soil compaction significantly limited root penetration depth and root system establishment in morphological traits, leading further to significant reduction in nutrients acquisition and plant biomass accumulation. However, soil compaction significantly increases the average root diameter and root/shoot ratio, and facilitate more root exudates secretion （e.g. organic acids and polysaccharides） of Brassica napus cultivars. The Brassica napus cultivars with large root mechanical traits （e.g. root tensile force, root tensile strength and modulus of elasticity） had higher root cellulose and lignin concentrations and showed a stronger response in maximum root depth and specific root length compared with Brassica napuscultivars with small root mechanical traits in compacted treatment, which resulted in the greater fine root length and more root exudates secretion at root-soil interface. Furthermore, deep rooting enhanced nutrients acquisition and further biomass accumulation in compacted soil. Totally, the Brassica napus cultivars with large root mechanical traits with more fine roots and root exudates were critical for Brassica napusroot penetration into a deep soil layer in compacted soil.

 

　　論文鏈接：https://doi.org/10.1016/j.still.2023.105785