挺水态圆叶节节菜扦插繁育基质筛选

doi:10.13287/j.1001-9332.202506.034

摘要/Abstract

摘要： 圆叶节节菜是一种可挺水和沉水生长的水生植物,利用挺水态转变为沉水态的特性,可快速构建沉水植物群落,具有较强的水生态修复潜力。本试验以黄壤(T₁)、稻田土(T₂)、河沙(T₃)、河道底泥(T₄)及营养土-河沙(T₅,体积比1∶1)为基质,进行扦插繁殖,研究圆叶节节菜的株高、分枝数、生物量、根系形态及叶绿素荧光特性等对不同基质的响应特征,筛选挺水态圆叶节节菜最适培育基质。结果表明: T₅组插穗于15 d全部死亡,不适于植株生长繁殖。T₂组株高(27.06±3.08 cm)和鲜重(1870±304 mg)分别较T₁、T₃、T₄组提高25.5%、47.1%、100.9%和111.3%、124.8%、251.3%,总根长、根表面积、根体积及根系活力分别提高41.7%～164.7%、38.8%～164.7%、31.6%～177.8%和16.2%～113.3%,分枝数、光合色素含量、实际光化学效率和最大光化学效率均显著高于其他组。T₃、T₄组植株株型矮小,叶片出现不同程度的失绿和萎蔫。圆叶节节菜根系生长发育与基质中的速效磷和速效钾呈显著正相关。采用主成分分析对各基质的综合评价排序为T₂>T₁>T₃>T₄,表明稻田土更适宜于作为圆叶节节菜扦插繁育的基质。

关键词: 圆叶节节菜, 育苗基质, 根系生长, 理化性质

Abstract: Rotala rotundifolia is an aquatic plant as an emergent and submerged species. By leveraging its unique ability to transition from emergent to submerged growth, it can rapidly establish submerged plant communities and thus holds strong potential for water ecological restoration. We used five different substrates for cutting propagation, namely yellow soil (T₁), paddy soil (T₂), river sand (T₃), river sediment (T₄), and a mixture of nutrient soil and river sand (T₅, in a volume ratio of 1:1), to investigate the growth responses of R. rotundifolia, focusing on variables including plant height, number of branches, biomass, root morphology, and chlorophyll fluorescence characteristics. Then, we identified the most suitable substrate for cultivating emergent R. rotundifolia. The results showed that all cuttings in the T₅ group died within 15 days, which was not suitable for cultivation. Plant height (27.06±3.08 cm) and fresh weight (1870±304 mg) of the T₂ group were increased by 25.5%, 47.1%, 100.9% and 111.3%, 124.8%, 251.3% compared with the T₁, T₃, and T₄ groups, respectively. Total root length, root surface area, root volume, and root activity of the T₂ group were increased by 41.7%-164.7%, 38.8%-164.7%, 31.6%-177.8%, and 16.2%-113.3%, respectively. The number of branches, chlorophyll content, actual photochemical efficiency, and maximum photochemical efficiency of the T₂ group were significantly higher than those of the other groups. Plants in groups T₃ and T₄ exhibited dwarf phenotypes with varying degrees of chlorosis and wilting. Root growth and development of R. rotundifolia were significantly positively correlated with the available phosphorus and available potassium in the substrate. The comprehensive evaluation of the substrates by principal component analysis was ranked as T₂>T₁>T₃>T₄, indicating that paddy soil is more suitable as a substrate for the cutting propagation of R. rotundifolia.

Key words: Rotala rotundifolia, propagation substrate, root growth, physical and chemical property

彭倩倩, 肖继波, 褚淑祎, 林琛博, 吕旭健. 挺水态圆叶节节菜扦插繁育基质筛选[J]. 应用生态学报, 2025, 36(6): 1871-1879.

PENG Qianqian, XIAO Jibo, CHU Shuyi, LIN Chenbo, LYU Xujian. Substrate screening for cutting propagation of emergent Rotala rotundifolia[J]. Chinese Journal of Applied Ecology, 2025, 36(6): 1871-1879.

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