植物CytP450和抗氧化酶对土壤低浓度菲、芘胁迫的响应

以小麦(Triticum acstivnm)为供试植物,草甸棕壤为供试土壤,以微粒体细胞色素P450及抗氧化酶SOD、POD和CAT酶活性为指标,进行了土壤中菲、芘单一及复合胁迫响应研究.结果初步表明,菲、芘胁迫引起植物体内解毒代谢和抗氧化防御酶反应.菲、芘单一胁迫浓度为1mg kg-1时对细胞色素P450产生显著诱导;4 mg kg-1时P450酶含量明显被抑制,表明低浓度菲、芘单一胁迫对植物代谢解毒系统产生损伤;而菲、芘复合1mg kg-1时P450酶含量明显被抑制,说明菲、芘复合胁迫对植物的代谢解毒具有协同毒性效应.土壤中菲、芘单一胁迫未引起SOD酶活性的明显改变,复合胁迫下SOD酶活性出现微弱下降;菲、芘单一胁迫对CAT和POD酶活性具有显著抑制作用;复合胁迫对CAT产生抑制作用,而POD酶活性并未对菲、芘复合产生增强毒性响应.研究从代谢解毒和抗氧化防御酶系统两方面,为土壤低浓度PAHs污染诊断提供了实验依据.     

橄榄果实中PPO和POD活性抑制研究

本文研究温度和几种抑制剂对橄榄果实多酚氧化酶(PPO)和过氧化物酶(POD)活性的影响。结果表明,橄榄果实PPO活性最强的温度为27℃,POD活性最强的温度为45℃;低温对PPO活性的抑制较POD显著;抗坏血酸和亚硫酸钠可有效地抑制PPO活性,而抗坏血酸和氯化镁则对POD活性有明显的抑制作用。     

水杨酸和热锻炼诱导的高羊茅幼苗的耐热性与抗氧化的关系

研究了水杨酸（SA）处理和热锻炼（HH）对高羊茅（Festuca arundinacea Schred.)幼苗耐热性的影响和在耐热性诱导过程中植物体内可溶性蛋白含量与超氧化物歧化酶（SOD）,过氧化的酶（POD）和过氧化氢酶（CAT）等3种抗氧化酶的活性变化。结果表明：0.5mmol/L男SA预处理能显著提高高羊茅幼苗在42℃热胁迫（HS）后转至常温下恢复生长18d时的苗高,绿叶数和绿叶指数;在常温下SA提高高羊茅幼苗的CAT活性,降低POD活性,而对SOD的影响不显著;SA和HH均能降低高羊茅幼苗在HS下细胞外渗液电导率,提高可溶性蛋白的含量和SOD、CAT活性,但不能显著提高POD活性。因此,推测SA与HH提高耐热性上具有相似的机理。     

不同光照强度对兴安落叶松几种主要防御蛋白活力的影响

林木组成抗性对抵御害虫危害发挥着重要作用。为了研究环境因子对其组成抗虫性的影响,以兴安落叶松幼苗为试验材料,通过搭建遮阳棚设置3个光照强度(自然光照作为对照、50%和25%自然光照强度),模拟森林幼苗生长的林缘、林窗和林下3种不同的光环境,分析不同光照强度对其针叶内与植物抗虫性有关的几种主要防御蛋白活力的影响。研究结果表明,不同光照强度对针叶内主要防御蛋白活力有显著影响(P<0.05)。50%和25%光照强度下,POD、SOD、PAL、PPO和CI的活性显著高于自然光照下的(P<0.05),POD和CI的活性在50%光照强度下最高,SOD、PAL和PPO的活性在25%光照强度下最高;自然光照条件下CAT的活性显著高于50%和25%光照强度下的(P<0.05);遮荫处理对TI的活性有显著影响(P<0.05),但在不同月份中波动较大,规律性不明显。相同的光照强度条件下,主要防御蛋白活力在3个月中也有显著变化(P<0.05)。7月和8月份保护性酶POD和CAT的活性显著高于6月(P<0.05);防御性酶PAL、PPO以及蛋白酶抑制剂CI的活性在6月份最高。综合以上研究结果,光照可影响兴安落叶松针叶中几种主要防御蛋白活力,这也说明在较荫蔽的光照环境下,兴安落叶松有较强的抗性。其中SOD、CAT、PAL、PPO和POD是植物次生物质生成过程中的关键酶,其活性的改变在一定程度上表征着植物防御体系在变化。研究环境因子与植物防御之间的关系具有重要的理论和实际应用价值。     

7株放线菌在辣椒根部定殖及对辣椒叶片PAL与PPO活性的影响

采用盆栽接种试验、平皿涂抹法测数及常规酶活测定法研究了7株拮抗性放线菌在辣椒根部的定殖能力及接种24d对辣椒叶片苯丙氨酸解氨酶（PAl。）与多酚氧化酶活性（PPO）的诱导效应。结果表明：（1）供试7株放线菌单独接种均不能在辣椒根内定殖,但与辣椒疫霉P3混合接种时有5株可定殖;供试放线菌在辣椒根部的定殖能力与其体外平皿试验中产生的的拈抗圈大小基本无关;可定殖放线菌的定殖密度随时间延长而降低,至40d时均无活菌检出。（2）在放线菌单接处理中,5株菌接种后可诱导辣椒叶片PAL,活性提高,全部供试菌均能诱导PPO活性提高,其中可使两种酶同步提高的有5株菌;在放线菌＋P3混接处理中,有6株接种后可诱导PAL,活性提高,5株菌能诱导PPO活性提高,其中可使两种酶同步提高的有4株菌;在接入放线菌时同时混接辣椒疫霉,能增强2株供试放线菌对辣椒叶片PAL活性及6株供试放线菌对辣椒叶片PPO活性的诱导作用;供试放线菌的定殖能力与辣椒叶片PAL及PPO活性变化无明显规律性关系。     

香蕉组培苗POD、PPO及SOD活性对银胁迫的反应

用0.1mg/mL硝酸银溶液处理香蕉组培苗,分别测定了多酚氧化酶(PPO)、过氧化物酶(POD)及超氧化物岐化酶(SOD)的活性。结果表明:在银胁迫下,香蕉组培苗的PPO、POD、SOD的活性明显增加(P<0 05或P<0 01),但随着胁迫时间的延长呈下降趋势且趋于稳定,这说明PPO、POD和SOD活性的提高与维持是植物耐受银胁迫的物质基础之一。     

苗龄、光照强度和施氮量对抗褐飞虱水稻品种主要防御酶活性的影响

为探明苗龄、光照强度和施氮量对水稻主要防御酶活性的影响及其与抗褐飞虱的关系,分别就苗龄、光照强度和施氮量等因子对不同抗褐飞虱水稻品种苯丙氨酸解氨酶(PAL)、多酚氧化酶(PPO)和过氧化物酶(POD)活性的影响进行研究。结果表明:IR56、Ptb33和570011对褐飞虱生物型II的抗性与PAL和PPO活性密切相关,RHT对II型的抗性与PAL、PPO和POD活性密切相关,RP1976-18-6-4-2对II型的抗性与PAL活性密切相关,570011对II型的抗性与PAL和PPO活性密切相关;IR56对褐飞虱孟加拉型的抗性与PAL、PPO和POD活性密切相关,Rathu Heenati(RHT)和RP1976-18-6-4-2对孟加拉型的抗性与与PPO密切相关,570011对孟加拉型的抗性与POD活性密切相关。苗龄、光照强度和施氮量的单独作用或交互作用对不同水稻中防御酶活性有明显影响,但品种不同,其影响程度也不同。苗龄、光照强度和施氮量单独或是交互作用显著影响IR56中PAL和PPO、RHT和RP1976-18-6-4-2中PPO、Ptb33中POD及570011中PAL和POD的活性,苗龄显著影响IR56和RP1976-18-6-4-2中POD的活性,光照强度和施氮量单独或交互作用显著影响RHT和RP1976-18-6-4-2中PAL的活性,施氮量显著影响RHT中POD的活性,光照强度显著影响Ptb33中PAL的活性;苗龄和光照强度单独或交互作用显著影响570011中PPO的活性。     

珙桐种子休眠解除和萌发过程中主要抗氧化酶活性和代谢产物含量的变化

珙桐(Davidia involucrata Baill.)种子在休眠解除和萌发过程中,主要的抗氧化酶和代谢产物在有效清除活性氧和保证种子活力方面具有重要作用。研究以马边自然保护区采集的珙桐种子为研究对象,对其从休眠解除进入萌发阶段过程中的主要抗氧化酶的活性和代谢产物含量进行测定和分析。结果显示:层积初期,过氧化物酶(POD)、过氧化氢酶(CAT)、超氧化歧化酶(SOD)和谷胱甘肽还原酶(GR)活性均上升,但总抗氧化能力(T-AOC)下降。可溶性蛋白质(Pr)下降而抗坏血酸(Vc)、游离氨基酸(FAA)含量增大;层积中期,SOD活性和T-AOC呈先升高后下降的变化趋势。尽管CAT和GR活性下降,但POD活性保持较高的水平;层积后期,SOD和CAT活性较低,POD、GR活性和T-AOC,FAA和Vc含量整体呈上升趋势;萌发阶段,各抗氧化酶活性均有显著增加(P0.05),Vc和FAA含量显著增加,Pr含量降低。研究结果表明,珙桐种子可以通过各抗氧化酶活性(POD,CAT,SOD和GR)和代谢产物(Pr,FAA和Vc)间的相互作用,在种子休眠解除和萌发过程中先后有效地消除活性氧对细胞结构完整性的影响,并促进珙桐种子的形态和生理后熟,从而保证种子顺利萌发。     

马占相思树两家系过氧化物酶、多酚氧化酶活性及同工酶比较研究

本文对马占相思(Acacia mangium)Q家系(QLD1983S)、P家系(PLD1983S)的过氧化物酶(POD)、多酚氧化酶(PPO)活性及其同工酶进行比较分析。结果表明,同一家系的不同器官,POD、PPO活性均呈现极显著差异;不同家系同一器官的POD和PPO活性也有极显著差异。通过对POD、PPO同工酶酶谱比较发现,P、Q两家系的根、茎、叶状柄各器官既有着明显的相同特征谱带,又有各自的特殊谱带。     

氨基茚磷酸(AIP)和氨基氧乙酸(AOA)对茉莉酸甲酯诱导的烟草一些酶活性的影响

用茉莉酸甲酯(MJ,1mg ml^-1)处理培养在含0．1mmol／L AIP(水杨酸合成抑制剂)和／或1mmol／L AOA(乙烯合成抑制剂)的MS培养基上的烟草愈伤组织,测定某些酶的活性。结果表明：MJ明显提高过氧化物酶(POD)、β1,3-葡聚糖苷酶和几丁质外切酶的活性,略微促进苯丙氨酸解氨酶(PAL)、多酚氧化酶(PPO)的活性,抑制几丁内切酶的活性,而AOA和AIP则明显抑制MJ对POD和β1,3-葡聚糖苷酶活性的诱导作用,但对MJ诱导的PAL和PPO的活性影响很小,AOA和AIP可能作为逆境因子促进PAL的活性。AOA能部分解除MJ对几丁内切酶的抑制作用,但对MJ诱导的几丁外切酶的影响较小,而AIP抑制几丁内切酶的活性,也抑制MJ对此酶的诱导作用。因此我们认为：MJ对POD、PPO和几丁内切酶的影响可能是通过乙烯途径,对β1,3-葡聚糖苷酶和几丁外切酶的影响可能是通过水杨酸(SA)途径,而对PAL的影响可能是通过其它途径。     

Ascorbic Acid Enhances the Accumulation of Polycyclic Aromatic Hydrocarbons (PAHs) in Roots of Tall Fescue (Festuca arundinacea Schreb.)

Plant contamination by polycyclic aromatic hydrocarbons (PAHs) is crucial to food safety and human health. Enzyme inhibitors are commonly utilized in agriculture to control plant metabolism of organic components. This study revealed that the enzyme inhibitor ascorbic acid (AA) significantly reduced the activities of peroxidase (POD) and polyphenol oxidase (PPO), thus enhancing the potential risks of PAH contamination in tall fescue (Festuca arundinacea Schreb.). POD and PPO enzymes in vitro effectively decomposed naphthalene (NAP), phenanthrene (PHE) and anthracene (ANT). The presence of AA reduced POD and PPO activities in plants, and thus was likely responsible for enhanced PAH accumulation in tall fescue. This conclusion is supported by the significantly enhanced uptake of PHE in plants in the presence of AA, and the positive correlation between enzyme inhibition efficiencies and the rates of metabolism of PHE in tall fescue roots. This study provides a new perspective, that the common application of enzyme inhibitors in agricultural production could increase the accumulation of organic contaminants in plants, hence enhancing risks to food safety and quality.     

植物对水中菲和芘的吸收

以菲和芘为多环芳烃（PAHs）代表物,采用水培体系研究了黑麦草（Lolium multiflorum Lam）对水中PAHs的吸收作用,重点研究了植物吸收菲和芘的时间动态.水中菲和芘起始浓度分别为1.00mg/L和0.12mg/L.0～288h内,黑麦草根和茎叶中菲和芘含量均先快速增加而后降低,积累量不断增大,植物根系和茎叶富集系数则先快速升高而后趋于稳定.茎叶中菲和芘含量、茎叶对菲和芘的富集系数比根低1～3数量级,积累量也明显小于根系.黑麦草根系对水中芘有更强的富集能力,其根系富集系数比菲大85%～179%;而其茎叶对菲的富集作用则略强.菲和芘在植物体内有明显的传导作用.0～288h,传导系数（TF）先显著升高而后趋于恒定;但实验条件下,菲和芘的TF值均很小,分别不高于0.031和0.009,且芘的TF值明显小于菲,表明供试植物对芘的传导能力更弱.     

Metabolism and subcellular distribution of anthracene in tall fescue (Festuca arundinacea Schreb.)

Aim

Understanding the uptake processes of organic contaminants by plants is essential when assessing crop contamination and subsequent human exposure. Unfortunately, limited information is available on plant metabolism and subcellular distribution of polycyclic aromatic hydrocarbons (PAHs), a group of highly toxic organic contaminants with carcinogenic, mutagenic, and teratogenic properties. Thus we seek to investigate the metabolism and intracellular distribution of PAH in tall fescue (Festuca arundinacea Schreb.).

Methods

This work was conducted utilizing greenhouse hydroponical experiments. Seedlings of tall fescue were firstly cultured in half-strength Hoagland solution with anthracene (ANT). Then treated plants were removed from the ANT-spiked solution, and transplanted into solutions free of ANT. After 0–16 days, the seedlings were sampled and prepared for ANT analysis. Seedlings were washed using Milli-Q water and then separated into different parts to measure ANT distributions at the subcellular level.

Results

ANT concentrations and dissipation amounts in root and shoot of tall fescue decreased in 0–16 days after transplantation from an ANT-spiked culture solution to a solution free of PAH, revealing ANT metabolism in the plant. The accumulation of the examined primary metabolites of ANT, i.e., anthrone and anthraquinone, against time also supported plant metabolism of ANT. About 10 % of ANT resided in the plants at 8–16 days due to the formation of ANT-bound residues with plant tissues. ANT concentrations in the cell walls and organelles of plant roots and shoots decreased significantly during the 16-day period. Cell walls and organelles were the dominant storage compartments for ANT and anthraquinone in plants at 16 days, whereas the distribution of anthrone at 16 days in root cells was ordered as cell organelles >cell soluble fraction >cell wall and in shoot cells as cell soluble fraction >> cell organelle ? cell wall. Although the organelle content is smaller, the concentrations of ANT and metabolites in the organelle fraction were much higher than those in cell walls.

Conclusions

This was a primary investigation into the metabolism and intracellular distribution of PAH in plant. We demonstrated the metabolism of ANT in tall fescue based on the observed reduced concentrations, dissipated amounts, and detected metabolites. ANT and its metabolites were distributed into the cell water-soluble fraction, cell walls, and organelles. Results of this work will enhance the understanding of PAH transfer and transformation in plants and will be valuable for risk assessments of plant contamination at polluted sites.     

Impact of microbial/plant interactions on the transformation of polycyclic aromatic hydrocarbons in rhizosphere of Festuca arundinacea

The promotion of polycyclic aromatic hydrocarbon (PAH) degradation was demonstrated in the rhizosphere of Festuca arundinacea with Pseudomonas fluorescens. P. fluorescens 5RL more significantly interacted with salicylate and dextrose in the agar containing tall fescue than agar without plant roots. Although the presence of tall fescue did not promote catabolic enzyme induction in the absence of salicylate, an increase in dioxygenase activity relative to no plant controls implies that this plant may enhance the degradation of PAHs or facilitate the genotypes that are capable of transforming PAH in the rhizosphere.     

接种功能内生细菌Diaphorobacter sp.Phe15减少蔬菜亚细胞菲积累的体外试验研究

[目的]土壤中的多环芳烃(polycyclic aromatic hydrocarbons, PAHs)可被蔬菜根系吸收并在可食部分积累进而通过食物链威胁人群健康。接种功能内生细菌能有效减低蔬菜中PAHs的积累,而关于其对蔬菜亚细胞组分中PAHs积累的影响却鲜有报道。[方法]采用体外实验,研究了接种具有菲降解功能的菌株Diaphorobacter sp. Phe15对空心菜茎叶亚细胞组分中菲积累的影响及PAHs代谢相关酶活性的响应。[结果]接种Phe15可以可加速空心菜茎叶亚细胞中菲的降解,显著削减空心菜亚细胞组分中菲的含量,接菌后空心菜亚细胞组分中菲降解率达90%以上。此外,接种功能菌Phe15可以影响空心菜亚细胞组分中PAHs代谢相关酶系的活性,空心菜亚细胞水平POD、PPO、C230活性整体得到提高,且酶系活性与空心菜体内菲积累呈负相关关系。[结论]接种具有菲降解功能的菌株Phe15增加了空心菜亚细胞水平PAHs代谢相关酶系活性,进而降低空心菜体内菲的积累,研究结果为利用功能内生细菌削减蔬菜中多环芳烃污染提供了一定的参考和理论依据。     

Distribution of polycyclic aromatic hydrocarbons in subcellular root tissues of ryegrass (Lolium multiflorum Lam.)

Background

Because of the increasing quantity and high toxicity to humans of polycyclic aromatic hydrocarbons (PAHs) in the environment, several bioremediation mechanisms and protocols have been investigated to restore PAH-contaminated sites. The transport of organic contaminants among plant cells via tissues and their partition in roots, stalks, and leaves resulting from transpiration and lipid content have been extensively investigated. However, information about PAH distributions in intracellular tissues is lacking, thus limiting the further development of a mechanism-based phytoremediation strategy to improve treatment efficiency.

Results

Pyrene exhibited higher uptake and was more recalcitrant to metabolism in ryegrass roots than was phenanthrene. The kinetic processes of uptake from ryegrass culture medium revealed that these two PAHs were first adsorbed onto root cell walls, and they then penetrated cell membranes and were distributed in intracellular organelle fractions. At the beginning of uptake (< 50 h), adsorption to cell walls dominated the subcellular partitioning of the PAHs. After 96 h of uptake, the subcellular partition of PAHs approached a stable state in the plant water system, with the proportion of PAH distributed in subcellular fractions being controlled by the lipid contents of each component. Phenanthrene and pyrene primarily accumulated in plant root cell walls and organelles, with about 45% of PAHs in each of these two fractions, and the remainder was retained in the dissolved fraction of the cells. Because of its higher lipophilicity, pyrene displayed greater accumulation factors in subcellular walls and organelle fractions than did phenanthrene.

Conclusions

Transpiration and the lipid content of root cell fractions are the main drivers of the subcellular partition of PAHs in roots. Initially, PAHs adsorb to plant cell walls, and they then gradually diffuse into subcellular fractions of tissues. The lipid content of intracellular components determines the accumulation of lipophilic compounds, and the diffusion rate is related to the concentration gradient established between cell walls and cell organelles. Our results offer insights into the transport mechanisms of PAHs in ryegrass roots and their diffusion in root cells.     

Involvement of antioxidants and lipid peroxidation in the adaptation of two cool-season grasses to localized drought stress

In natural environments, drought often occurs in surface soil while water is available for plant uptake deeper in the soil profile. The objective of the study was to examine the involvement of antioxidant metabolism and lipid peroxidation in the responses of two cool-season grasses to surface soil drying. Kentucky bluegrass (Poa pratensis L) and tall fescue (Festuca arundinacea Schreb.) were grown in split tubes, consisting of two sections (each 10 cm in diameter and 20 cm long). Grasses were subjected to three soil moisture regimes: (a) well-watered control: whole soil profile was watered; (b) surface drying: surface 20 cm of soil was dried by withholding irrigation and the lower 20 cm of soil was watered; (c) full drying: whole soil profile was dried. Surface drying had no effects on relative water content (RWC) and chlorophyll content (Chl) for both grasses and only slightly reduced shoot growth for tall fescue. Superoxide dismutase (SOD) activity increased, while catalase (CAT) and peroxidase (POD) activities remained unchanged during most periods of surface drying. Malondialdehyde (MDA) content was unaffected by surface drying for tall fescue, but increased initially and then decreased to the control level for Kentucky bluegrass. Under full drying, RWC, Chl content, and shoot dry weight decreased, but MDA content increased in both grasses; SOD and POD activities initially increased transiently and then decreased; CAT remained unchanged for 25 days and then decreased. These results suggested that both Kentucky bluegrass and tall fescue were capable of surviving surface soil drying. This capability could be related to increases in antioxidant activities, particularly SOD and CAT. However, full drying suppressed antioxidant activities and induced lipid peroxidation.     

丛枝菌根真菌与高羊茅协同修复镉污染土壤

本研究采用温室盆栽试验,利用丛枝菌根（AM）真菌摩西管柄囊霉Funneliformis mosseae进行接种试验,研究了在Cd胁迫下（0、5、15和30mg/kg）接种AM真菌对高羊茅Festuca elata ‘Crossfire II’的生物量、防御酶活性、磷和镉（Cd）含量的影响。结果表明,随着Cd浓度的增加,高羊茅的菌根侵染率和菌根相对依赖性有所增加。接种AM真菌改善了磷从植株根系向地上部的转运,有助于植株在地上部积累更多的磷。此外,AM真菌和Cd胁迫对高羊茅植株抗氧化酶活性都有显著影响,在镉胁迫下,与未接种植株相比,接种AM真菌显著提高了植株的过氧化氢酶活性,而显著降低了植株的丙二醛含量。与未接种植株相比,接种摩西管柄囊霉显著提高了寄主植物对Cd的富集能力,有利于重金属在根部的积累,同时降低了地上部的Cd含量。本研究表明,高羊茅-丛枝菌根共生体在Cd污染土壤的修复中具有潜在应用价值。     

植物根对土壤中PAHs的吸收及预测

研究了多种植物根对土壤中多环芳烃(PAHs)的吸收作用,阐述了根系吸收与土壤污染强度、污染物性质、植物组成等的关系,并用实验数据检验了限制分配模型对植物吸收土壤中PAHs的预测性能。供试土壤中菲和芘的起始浓度分别为0~457和0~489mg/kg;45d后,随土壤中菲和芘浓度提高,根中菲和芘含量明显增大,根系富集系数则减小。不同植物根中菲和芘含量和根系富集系数与根的脂肪含量呈显著正相关。由于芘的Kow较大,同种植物根中芘含量、芘的根系富集系数则远大于菲。经45d处理,尽管土壤中菲浓度变化很大(从不足1mg/kg到约45mg/kg),限制分配模型能较好地预测供试植物根中菲的含量,黑麦草和菜心根中菲含量的预测误差低于81%。作为限制分配模型预测植物吸收的关键参数,不同植物根吸收菲的αpt值与根脂肪含量显著正相关。     

Protective effects of complementary Ca2+ on low-light-induced oxidative damage in tall fescue

Low-light (LL) intensity is a primary abiotic stressor that negatively influences turf grass quality. In the present experiment, we studied the effect of exogenous Ca²⁺ (0, 10, 50, 100, and 200 mM) on the antioxidant system, the accumulation of MDA and proline, the content of photosynthetic pigments in plant leaves in order to investigate whether exogenous Ca²⁺ treatment improves LL tolerance in tall fescue (Festuca arundinacea Schreb.). We have found that LL significantly reduced a number of growth parameters (plant height, leaf width, leaf fresh weight, root fresh weight, leaf dry weight, and root dry weight), chlorophyll (Chl) a and Chl b contents, and carotenoid (Car) levels, while considerably enhancing electrolyte leakage (EL), MDA accumulation, calcium (Ca²⁺) concentration, and generation of reactive oxygen species (ROS), such as hydrogen peroxide (H₂O₂) and superoxide radical (O ₂ ^·? ). Moreover, LL significantly induced the activities of antioxidant enzymes, such as peroxidase (POD) and catalase (CAT), and slightly increased the activity of superoxide dismutase (SOD) in tall fescue leaves. In contrast, POD and SOD activities declined considerably while CAT activity significantly increased in plant roots under LL stress. The application of 50 mM Ca²⁺ significantly improved the aforementioned growth parameters, the content of photosynthetic pigments, and further enhanced the activities of POD, SOD, and CAT, but decreased electrolyte leakage and MDA and H₂O₂ levels in the leaves and roots of tall fescue under LL stress. These results suggest that Ca²⁺ is likely involved in a resistance to LL by regulating antioxidant enzyme action in tall fescue leaves and roots.