Angelica Santacroce, Sajani Kothari, Mutian Wang, Bibizan Thiyagarajah, Su Hyun Ko, Swetharajan Gunasekar, Sumaiya A. Ridi, Michelle J. Chin, Jason C. L. Brown
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Oxidative stress tolerance was assessed by growing plants in water or 30 mM H<sub>2</sub>O<sub>2</sub> and measuring i) mitochondrial uncoupling, via measurements of intact leaf respiration in the presence and absence of an uncoupling agent, ii) catalase activity, and iii) peroxide-induced cell membrane damage, via an electrolyte leakage assay. Endogenous salicylic acid (SA) levels were also measured since SA regulates both oxidative stress tolerance and flowering time. Early- and normal-flowering populations did not differ significantly for any of these parameters, suggesting that <i>L. usitatissimum</i> has evolved such low oxidative stress tolerance (as an annual species) that it cannot be further reduced. Differences were found between the two cultivars. Mitochondrial uncoupling was < 100% in R plants but > 100% in L plants, suggesting that oxidative phosphorylation was inhibited by the uncoupling agent in the latter but uncoupled in the former; catalase activity was higher in L plants than R plants, especially in early-flowering populations grown in H<sub>2</sub>O<sub>2</sub>, suggesting L plants eliminate ROS more rapidly; and peroxide-induced cell membrane damage was higher in L plants than R plants, suggesting that R plants experience less oxidative damage to their membrane phospholipids. SA may play some role in these cultivar-specific responses. 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引用次数: 0
摘要
活性氧(ROS)的积累会导致氧化应激。寿命长的生物应该比寿命短的生物表现出更强的氧化应激耐受性。对于亚麻(Linum usitatissimum L.)等一年生植物来说,开花时间和寿命呈正相关。据此预测,两个亚麻栽培品种(Royal [R]和 Stormont Cirrus [L])的早花群体比正常开花的对照群体表现出更低的氧化应激耐受性。评估氧化胁迫耐受性的方法是让植物在水或 30 mM H2O2 中生长,并通过测量 i)线粒体解偶联(在有和没有解偶联剂的情况下测量完整叶片的呼吸)、ii)过氧化氢酶活性和 iii)过氧化物诱导的细胞膜损伤(通过电解质渗漏试验)。由于水杨酸对氧化应激耐受性和开花时间都有调节作用,因此还测定了内源水杨酸(SA)水平。早花和正常花期的种群在这些参数上都没有显著差异,这表明莴苣(L. usitatissimum)的氧化胁迫耐受性很低(作为一年生物种),无法进一步降低。两个栽培品种之间存在差异。R 植物的线粒体解偶联率为 100%,而 L 植物的线粒体解偶联率为 100%,这表明氧化磷酸化在后者受到解偶联剂的抑制,而在前者则未被偶联;L 植物的过氧化氢酶活性高于 R 植物,尤其是在 H2O2 中生长的早花群体,这表明 L 植物消除 ROS 的速度更快;过氧化物诱导的细胞膜损伤在 L 植物中高于 R 植物,这表明 R 植物的膜磷脂受到的氧化损伤较小。在这些栽培品种特异性反应中,SA 可能起了一些作用。由于 R 栽培品种和 L 栽培品种分别是为获得种子油和纤维而培育的,它们之间的差异可能反映了氧化胁迫耐受性和性状选择之间的权衡。
Oxidative stress tolerance and salicylic acid levels in early-flowering populations derived from two cultivars of annual flax (Linum usitatissimum L.)
The accumulation of reactive oxygen species (ROS) causes oxidative stress. Long-lived organisms should exhibit greater oxidative stress tolerance than short-lived organisms. For annual plants, such as flax (Linum usitatissimum L.), flowering time and lifespan are positively correlated. On this basis, early-flowering populations of two flax cultivars (Royal [R] and Stormont Cirrus [L]) were predicted to exhibit lower oxidative stress tolerance than normal-flowering controls. Oxidative stress tolerance was assessed by growing plants in water or 30 mM H2O2 and measuring i) mitochondrial uncoupling, via measurements of intact leaf respiration in the presence and absence of an uncoupling agent, ii) catalase activity, and iii) peroxide-induced cell membrane damage, via an electrolyte leakage assay. Endogenous salicylic acid (SA) levels were also measured since SA regulates both oxidative stress tolerance and flowering time. Early- and normal-flowering populations did not differ significantly for any of these parameters, suggesting that L. usitatissimum has evolved such low oxidative stress tolerance (as an annual species) that it cannot be further reduced. Differences were found between the two cultivars. Mitochondrial uncoupling was < 100% in R plants but > 100% in L plants, suggesting that oxidative phosphorylation was inhibited by the uncoupling agent in the latter but uncoupled in the former; catalase activity was higher in L plants than R plants, especially in early-flowering populations grown in H2O2, suggesting L plants eliminate ROS more rapidly; and peroxide-induced cell membrane damage was higher in L plants than R plants, suggesting that R plants experience less oxidative damage to their membrane phospholipids. SA may play some role in these cultivar-specific responses. As R and L cultivars are bred for seed oil and fibres, respectively, their differences may reflect trade-offs between oxidative stress tolerance and trait selection.
期刊介绍:
Plant Growth Regulation is an international journal publishing original articles on all aspects of plant growth and development. We welcome manuscripts reporting question-based research using hormonal, physiological, environmental, genetical, biophysical, developmental or molecular approaches to the study of plant growth regulation.
Emphasis is placed on papers presenting the results of original research. Occasional reviews on important topics will also be welcome. All contributions must be in English.