Growth, Photosynthesis, and Respiration of the Aquatic Floating Fern Salvinia minima

Pub Date : 2023-06-16 DOI:10.1640/0002-8444-113.2.61
O. R. Oger, A. N. Biology, Paleo Environment
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Abstract

Abstract. Salvinia minima is a relatively small, floating aquatic leptosporangiate fern in the family Salviniaceae. It is widely distributed in the horticultural trade as an ornamental plant for aquaria and aquatic gardens. Consequently, it has escaped into the natural environment where it produces large, dense mats of branching ramets that are often deleterious to other aquatic biota, particularly in tropical and mild temperate regions. This is a report of a laboratory experimental study of the growth, photosynthesis and dark respiration of S. minima, particularly addressing the variables in a way that is potentially relevant for environmental and ecological research applications. Photosynthetic carbon assimilation rates are inversely related to the leaf area of the ramets, and approximates a second-order polynomial function defined by non-linear regression analysis (p < 0.01); namely, A = 6.3761 - 0.3381 * L + 0.005 * L2, where A is CO2 assimilation rate (µmol m–2 s–1) and L is leaf area of the ramets (cm2). Data are also presented on the quantum yield efficiency (Fv/Fm) and electron transfer (ET0/RC) for ramet leaves of different sizes, indicating that low quantum yield efficiency most likely accounts for lower CO2 assimilation rates in more mature ramets with larger leaves. The dark respiration is approximately equivalent to 30% of the net photosynthesis CO2 assimilation rate. The relative growth rate (RGR) is 0.03 accounting for about a 4% gain in weight per day relative to the initial weight of the S. minima ramets.
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水生浮蕨的生长、光合作用和呼吸作用
摘要小鼠尾草(Salvinia minima)是鼠尾草科中一种相对较小的、漂浮的水生细孢子蕨。它广泛分布于园艺行业,作为水族馆和水生花园的观赏植物。因此,它已经逃逸到自然环境中,在那里它产生了巨大而密集的分枝灯节,这些灯节通常对其他水生生物有害,特别是在热带和温和温带地区。这是一份关于S. minima生长、光合作用和暗呼吸的实验室实验研究报告,特别是以一种可能与环境和生态研究应用相关的方式解决这些变量。光合碳同化速率与分株叶面积呈负相关,近似于非线性回归分析定义的二阶多项式函数(p < 0.01);即A = 6.3761 - 0.3381 * L + 0.005 * L2,其中A为CO2同化速率(µmol m-2 s-1), L为分株叶面积(cm2)。不同大小分株叶片的量子产率效率(Fv/Fm)和电子转移(ET0/RC)数据也表明,低量子产率效率很可能是叶片较大的成熟分株CO2同化率较低的原因。暗呼吸大约相当于净光合作用CO2同化率的30%。相对生长率(RGR)为0.03,相对于最小s品种的初始体重,每天增加约4%。
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