短期驯化对水芹耐低盐胁迫的影响

Effect of short-term domestication on the tolerance of Oenanthe javanica to low-salt stress

  • 摘要: 为探究低盐胁迫对水芹(Oenanthe javanica)生长的影响和短期驯化在提升其耐盐度方面的效果, 本研究评估并对比了54 d内, 盐度为2 PSU (practical salinity units, 实用盐度)、4 PSU、6 PSU和8 PSU的低盐胁迫对驯化与未驯化水芹生长状态和生理生化的影响。在水培条件下, 采用每3 d 提升2 PSU的方法对水芹进行驯化。结果显示, 经过54 d的胁迫, 短期驯化与未驯化的水芹最高均可在6 PSU盐度条件下存活, 而盐度差异和短期驯化显著影响了水芹的生长和生化过程。相比对照组, 胁迫盐浓度超过2 PSU时, 盐胁迫导致水芹的鲜重、株高、根长、叶片数和叶绿素等增长率分别显著下降126.0%~199.4%、67.5%~124.0%、63.4%~83.2%、154.1%~325.0%和21.0%~52.6%, 而驯化后仅分别下降40.7%~185.7%、25.0%~83.5%、37.8%~57.2%、62.7%~294.7% 和7.5%~37.8%; 盐胁迫导致水芹叶片的相对含水率降低率显著升高4.8%~6.4%,而驯化后仅升高2.9%~3.4%;盐胁迫导致水芹叶片的丙二醛和脯氨酸含量分别显著上升39.6%~52.9%和25.1%~30.9%, 而驯化后分别上升25.4%~46.8%和36.1%~43.3%; 盐胁迫导致水芹叶片的活性氧含量显著上升23.4%~29.5%, 而驯化后仅上升7.4%~22.1%; 盐胁迫导致水芹叶片的超氧化物歧化酶、过氧化物酶、抗坏血酸过氧化物酶、谷胱甘肽过氧化物酶和过氧化氢酶活性分别上升20.1%~27.2%、19.2%~25.0%、7.3%~17.0%、15.6%~27.7%和10.3%~18.1%, 而驯化后分别上升29.8%~37.8%、33.9%~39.1%、27.9%~32.3%、28.5%~37.4%和28.0%~33.7%; 盐胁迫导致叶片和根系K+/Na+比值分别显著下降67.5%~97.5%和76.8%~93.8%, 而驯化后仅分别下降39.4%~89.7%和40.9%~82.7%。综上, 低盐胁迫对水芹的生长及其生理生化反应产生不同程度的负面影响, 而短期驯化可减弱这种负面影响。

     

    Abstract: To investigate the effects of low-salt stress on the growth of watercress (Oenanthe javanica) and the effectiveness of short-term domestication in enhancing its salinity tolerance, this study evaluated and compared the impact of low salt stress with salinity levels of 2, 4, 6, and 8 practical salinity units (PSU) and short-term domestication on salinity tolerance, growth, and physiological and biochemical characteristics of domesticated and undomesticated watercress over a 54 d period. The watercress was domesticated under hydroponic conditions by incrementally increasing the salinity by 2 PSU every 3 d. The results exhibited that after 54 d of salt stress, both the short-term domesticated and non-domesticated watercress survived up to 6 PSU salinity. Salinity and short-term domestication significantly affected watercress growth and biochemical processes of watercress. Compared to the control group, salt stress exceeding 2 PSU decreased the growth rates of fresh weight, plant height, root length, leaf number, and chlorophyll content in water dropwort by 126.0%–199.4%, 67.5%–124.0%, 63.4%–83.2%, 154.1%–325.0%, and 21.0%–52.6%, respectively. However, after acclimation, these declines were reduced to 40.7%–185.7%, 25.0%–83.5%, 37.8%–57.2%, 62.7%–294.7%, and 7.5%–37.8%, respectively. The relative water content in water dropwort leaves significantly decreased by 4.8%–6.4% under salt stress, but only increased by 2.9%–3.4% after acclimation. Salt stress significantly increased the malondialdehyde (MDA) and proline contents in water dropwort leaves by 39.6%–52.9% and 25.1%–30.9%, respectively, whereas after acclimation, these increases were 25.4%–46.8% and 36.1%–43.3%, respectively. Reactive oxygen species (ROS) content in water dropwort leaves significantly increased by 23.4%–29.5% under salt stress, but only by 7.4%–22.1% after acclimation. The activities of superoxide dismutase (SOD), peroxidase (POD), ascorbate peroxidase (APX), glutathione peroxidase (GPX), and catalase (CAT) in water dropwort leaves increased by 20.1%–27.2%, 19.2%–25.0%, 7.3%–17.0%, 15.6%–27.7%, and 10.3%–18.1%, respectively, under salt stress, whereas after acclimation, these increases were 29.8%–37.8%, 33.9%–39.1%, 27.9%–32.3%, 28.5%–37.4%, and 28.0%–33.7%, respectively. The K+/Na+ ratios in both leaves and roots of water dropwort significantly decreased by 67.5%–97.5% and 76.8%–93.8%, respectively, under salt stress, but decreased only by 39.4%–89.7% and 40.9%–82.7%, respectively, after acclimation. In conclusion, low salt stress negatively affects watercress growth and its physiological and biochemical responses, but short-term domestication ameliorates the effects of salt stress.

     

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