Li Bingjun, Deng Mi, Pan Yanmei, Chen Wenchen, He Tianyou, Chen Liguang, Zheng Yushan, Rong Jundong
College of Forestry, Fujian Agriculture and Forestry University, Fuzhou, China.
College of Landscape Architecture and Art, Fujian Agriculture and Forestry University, Fuzhou, China.
Front Plant Sci. 2024 Jan 17;14:1327322. doi: 10.3389/fpls.2023.1327322. eCollection 2023.
Critical changes often occur in seedlings during the process of growth owing to differences in the surrounding environment. The most common differences are heterogeneous nutrient environments and competition from neighboring plants.
In this study, we selected one-year-old, high-quality seedlings as experimental materials. Three planting patterns were established to simulate different competitive treatments, and seedlings were also exposed to three heterogeneous nutrient environments and a homogeneous nutrient environment (control) to determine their effect on the root morphology and structure of seedlings.
Heterogeneous nutrient environments, compared with a homogeneous environment, significantly increased the dry matter accumulation and root morphology indexes of the root system of , which proliferated in nutrient-rich patches, and the P heterogeneous environment had the most significant enhancement effect, with dry matter accumulation 70.2%, 7.0%, and 27.0% higher than that in homogeneous and N and K heterogeneous environments, respectively. Homogeneous environments significantly increased the specific root length and root area of the root system; the dry matter mass and morphological structure of the root system of . with a heterospecific neighbor were higher than those under conspecific neighbor and single-plant treatments, and the root area of the root system under the conspecific neighbor treatment was higher than that under the heterospecific neighbor treatment, by 20% and 23%, respectively. Moreover, the root system under heterospecific neighbor treatment had high sensitivity; the heterogeneous nutrient environment increased the mean diameter of the fine roots of the seedlings of and the diameter of the vascular bundle, and the effect was most significant in the P heterogeneous environment, exceeding that in the N and K heterogeneous environments. The effect was most significant in the P heterogeneous environment, which increased fine root diameter by 20.5% and 10.3%, respectively, compared with the homogeneous environment; in contrast, the fine root vascular ratio was highest in the homogeneous environment, and most of the indicators of the fine root anatomical structure in the nutrient-rich patches were of greater values than those in the nutrient-poor patches in the different heterogeneous environments; competition promoted most of the indicators of the fine root anatomical structure of seedlings. According a principal component analysis (PCA), the N, Pm and K heterogeneous environments with heterospecific neighbors and the P heterogeneous environment with a conspecific neighbor had higher evaluation in the calculation of eigenvalues of the PCA.
The root dry matter accumulation, root morphology, and anatomical structure of . seedlings in the heterogeneous nutrient environment were more developed than those in the homogeneous nutrient environment. The effect of the P heterogeneous environment was the most significant. The heterospecific neighbor treatment was more conducive to the expansion and development of root morphology of seedlings than were the conspecific neighbor and single-plant treatments.
由于周围环境的差异,幼苗在生长过程中常常会发生关键变化。最常见的差异是养分环境异质性和来自邻近植物的竞争。
在本研究中,我们选择一年生优质幼苗作为实验材料。建立了三种种植模式以模拟不同的竞争处理,并且将幼苗暴露于三种异质养分环境和一种同质养分环境(对照)中,以确定它们对幼苗根系形态和结构的影响。
与同质环境相比,异质养分环境显著增加了[植物名称]根系的干物质积累和根系形态指标,[植物名称]在养分丰富的斑块中增殖,并且磷异质环境具有最显著的增强作用,其干物质积累分别比同质环境以及氮和钾异质环境高70.2%、7.0%和27.0%。同质环境显著增加了根系的比根长和根面积;与同种邻株和单株处理相比,异种邻株[植物名称]根系的干物质质量和形态结构更高,同种邻株处理下根系的根面积比异种邻株处理高,分别高20%和23%。此外,异种邻株处理下的根系具有高敏感性;异质养分环境增加了[植物名称]幼苗细根的平均直径和维管束直径,并且在磷异质环境中效果最显著,超过了氮和钾异质环境。在磷异质环境中效果最显著,与同质环境相比,细根直径分别增加了20.5%和10.3%;相反,同质环境中细根维管束比最高,并且在不同异质环境中,养分丰富斑块中细根解剖结构的大多数指标值大于养分贫瘠斑块中的指标值;竞争促进了[植物名称]幼苗细根解剖结构的大多数指标。根据主成分分析(PCA),异种邻株的氮、磷和钾异质环境以及同种邻株磷异质环境在PCA特征值计算中具有较高评价。
异质养分环境中[植物名称]幼苗的根干物质积累、根系形态和解剖结构比同质养分环境中更发达。磷异质环境的影响最显著。异种邻株处理比同种邻株和单株处理更有利于[植物名称]幼苗根系形态的扩展和发育。
