Effects of root addition and foliar application of nitric oxide and salicylic acid in alleviating iron deficiency induced chlorosis of peanut seedlings

Nitric oxide (NO) and salicylic acid (SA) are two important signaling molecules, which could alleviate chlorosis of peanut under iron (Fe) deficiency. Here, we further investigated the mechanism of different combinations of sodium nitroprusside (SNP, a nitric oxide donor) and SA supplying in alleviation Fe deficiency symptoms and selected which is the best combination. Thus, peanut was cultivated in hydroponic culture under iron limiting condition with different combinations of SNP and SA application. After 21 days, Fe deficiency significantly inhibited peanut growth, decreased soluble Fe concentration and chlorophyll contents, and disturbed ionic homeostasis. In addition, the content of reactive oxygen species (ROS) and malondialdehyde (MDA) concentration increased, which led the lipid peroxidation. Application of SNP and SA significantly changed Fe trafficking in cells and organs, which increased Fe uptake from nutrient solution, and transport from root to shoot, enhanced the activity of ferric-chelate reductase (FCR), that increased the available Fe in cell organelles, and the active Fe, chlorophyll contents in leaves. Furthermore, ameliorated the inhibition of calcium (Ca), magnesium (Mg) and zinc (Zn) uptake and promoted plant growth in Fe deficiency. At the same time, it increased the activities of superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT) to protect the plasmolemma from peroxidation. Results demonstrated that different combinations of SNP and SA application could alleviate the chlorosis of peanut in Fe deficiency by various mechanisms. Such as increased the available Fe and chlorophyll concentrations in leaves, improved the activities of antioxidant enzymes and modulated the mineral elements balance and so on. Foliar application of SNP and SA is the best to protect leaves while directly adding them into nutrient solution is the best to protect roots. These results also indicated that the effects of SNP and SA supplying together to leaves or roots are better than respectively adding to roots and spraying to leaves. The best combination is foliar application of SNP and SA.     

Mechanisms of exogenous nitric oxide and 24-epibrassinolide alleviating chlorosis of peanut plants under iron deficiency

Iron(Fe) is a crucial transition metal for all living organisms including plants; however, Fe deficiency frequently occurs in plant because only a small portion of Fe is bioavailable in soil in recent years. To cope with Fe deficiency, plants have evolved a wide range of adaptive responses from changes in morphology to altered physiology. To understand the role of nitric oxide(NO) and 24-epibrassinolide(EBR) in alleviating chlorosis induced by Fe deficiency in peanut(Arachis hypogaea L.) plants, we determined the concentration of chlorophylls, the activation, uptake, and translocation of Fe, the activities of key enzymes, such as ferric-chelate reductase(FCR),proton-translocating adenosine triphosphatase(H~+-ATPase), and antioxidant enzymes, and the accumulation of reactive oxygen species(ROS) and malondialdehyde(MDA) of peanut plants under Fe sufficiency(100 μmol L~(-1)ethylenediaminetetraacetic acid(EDTA)-Fe) and Fe deficiency(0 μmol L~(-1)EDTA-Fe). We also investigated the production of NO in peanut plants subjected to Fe deficiency with foliar application of sodium nitroprusside(SNP), a donor of NO, and/or EBR. The results showed that Fe deficiency resulted in severe chlorosis and oxidative stress, significantly decreased the concentration of chlorophylls and active Fe, and significantly increased NO production. Foliar application of NO and/or EBR increased the activity of antioxidant enzymes, superoxide dismutase,peroxidase, and catalase, and decreased the ROS and MDA concentrations, thus enhancing the resistance of plants to oxidative stress.Application of NO also significantly increased Fe translocation from the roots to the shoots and enhanced the transfer of Fe from the cell wall fraction to the cell organelle and soluble fractions. Consequently, the concentrations of available Fe and chlorophylls in the leaves were elevated. Furthermore, the activities of H~+-ATPase and FCR were enhanced in the Fe-deficient plants. Simultaneously,there was a significant increase in NO production, especially in the plants that received NO, regardless of Fe supply. These suggest that NO or EBR, and, especially, their combination are effective in alleviating plant chlorosis induced by Fe deficiency.     

外源NO对缺铁胁迫下花生生理特性的影响

为探讨外源NO对缺铁胁迫下花生生理特性的影响,采用溶液培养方法,研究了营养液中Fe(Ⅲ)-EDTA 浓度分别为0、10、100 mol/L 条件下,外施250 mol/L硝普钠（SNP, 一种NO 供体）对花生生理特性以及矿质元素含量的影响。结果表明,在相同供铁水平下,外施NO可促进花生幼苗的生长,提高根系活力、净光合速率、蒸腾速率、气孔导度和叶片抗氧化酶活性,降低胞间CO2 浓度和MDA 含量,抑制花生对P 的吸收;在Fe(Ⅲ)-EDTA 浓度分别为0、10 mol/L 条件下综合效果更显著。在0、10、100 mol/L Fe(Ⅲ)-EDTA 中施加SNP 处理20d 后,叶片活性铁含量分别比未施加SNP处理提高了130.7%、136.4%、56.1%,差异显著;同时植株全铁含量及地上部吸铁量占植株总量的百分率也显著提高。说明外源NO可促进铁从根部向植株地上部的运输以及植株体内铁的有效性,提高了铁的运输和利用效率,有效缓解缺铁胁迫的抑制。同时,外施NO还可提高花生叶片叶绿素、类胡萝卜素含量和叶绿素a/b值。在Fe(Ⅲ)-EDTA 浓度分别为0、10 mol/L 条件下,添加SNP 可以明显降低生长介质的pH,比较 1d 内生长介质中pH 变化看出,花生在14h左右分泌H+ 的能力最强。     

铜、镉毒害对番茄生长和膜功能蛋白酶活性的影响及外源NO的缓解效应

为探讨外源NO（SNP为供体）对50 mol/L铜、镉毒害的缓解效应,采用营养液培养方法,研究了不同程度的铜、镉毒害（5 mol/L和50 mol/L）对番茄幼苗生物量、根系活力、硝酸还原酶、光合特性及生物膜ATPase、H+-PPase等功能蛋白酶活性的影响。结果表明,铜、镉胁迫显著抑制番茄生长。随处理浓度增加,番茄根系活力、硝酸还原酶活性显著降低,番茄长势越差; 铜、镉胁迫对根系离子吸收的影响远远大于叶片,尤其是铜胁迫,50 mol/L铜胁迫使番茄根系铜含量增加了12倍。铜浓度的增加对镉含量无影响,镉浓度的增加降低了铜的吸收。铜、镉胁迫使番茄净光合速率（Pn）、气孔导度（Gs）和蒸腾速率（Tr）显著降低,胞间CO2浓度（Ci）显著增加,表现为非气孔限制。50 mol/L 铜、镉处理显著降低叶片、根系质膜H+-ATPase、Ca2+-ATPase和根系液泡膜H+-ATPase、Ca2+-ATPase和H+-PPase活性; 提高了5和50 mol/L部分处理叶片液泡膜H+-ATPase、Ca2+-ATPase和H+-PPase的活性。表明生物膜功能蛋白对不同程度铜、镉胁迫的响应时间和部位存在差异。铜毒害对细胞质膜ATPase的影响较大,而镉毒害对液泡膜伤害的程度较大。100 mol/L SNP可以显著缓解铜、镉胁迫导致的番茄生长受抑,铜、镉总吸收量显著高于胁迫处理。     

外源一氧化氮对NaCl胁迫下番茄幼苗活性氧代谢的影响

研究了在100 mmol/L NaCl胁迫下,外源NO供体硝普钠（SNP）处理对耐盐性不同的2个番茄品种（沪番‘1480’和沪番‘2496’）幼苗叶片活性氧（ROS）水平和保护酶活性的影响。结果表明,外源NO提高了盐胁迫下SOD、POD、CAT和APX活性,AsA和GSH含量以及脯氨酸和可溶性糖含量,降低了MDA含量和O2- 产生速率;与耐盐品种‘1480’相比,NO处理对盐敏感品种‘2496’效果更明显。表明外源NO通过促进盐胁迫下保护酶活性、抗氧化剂和渗透调节物质的提高,降低ROS水平,缓解NaCl胁迫对番茄幼苗生长的抑制作用,增强植株的耐盐能力。     

外源NO对不同作物种子萌发、幼苗生长及抗氧化酶活性的影响

以浓度分别为0、0.01、0.1、1.0 mmol/L的硝普钠（Sodium nitroprusside, SNP; NO供体）处理玉米、小麦、花生、小白菜、萝卜、黄瓜的种子和幼苗,研究了以上几种浓度的SNP对作物种子萌发和幼苗生长及抗氧化酶活性的影响。结果表明:SNP对多数种子萌发影响表现为低浓度（0.01 mmol/L和0.1 mmol/L）促进,高浓度（1.0 mmol/L）抑制,其中对萝卜发芽率的促进作用最显著;低浓度SNP可有效促进植物幼苗地上部的生长,其中对小麦、黄瓜的促进效果最显著,同时可显著促进根系的伸长,其中对萝卜的促进效果最显著,且对植物幼苗生长的影响与作物种类有关;SNP对多数植物的根系活力有明显的促进作用,其中对萝卜的促进效果最显著;适宜浓度的SNP可以提高作物CAT、POD和SOD活性以及可溶性蛋白含量,并降低MDA含量,不同作物SNP的适宜浓度不同,其中0.1 mmol/L SNP对多数作物处理效果最好。     

Effects of exogenous SA supplied with different approaches on growth,chlorophyll content and antioxidant enzymes of peanut growing on calcareous soil

To assess the role of salicylic acid (SA) supplied with 5 approaches in alleviating chlorosis induced by iron (Fe) deficiency in peanut plants growing on calcareous soil, SA was supplied as soil incorporation, making slow-release particles, seed soaking, irrigation and foliar application. SA application, particularly, SA supplied by slow release particles, dramatically increased growth parameters, yield and quality of peanut, and increased Fe concentration in peanut grain. Meanwhile, SA application increased the H⁺-ATPase activity, reduced pH of soil, increased Fe³⁺-Chelate Reductase (FCR) activity in roots, and increased Fe concentration in roots. Furthermore, SA increased active Fe content and increased chlorophyll content. In addition, SA improved enzymes activities containing superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT), and protected Fe deficiency induced oxidative stress. Therefore, SA has a good effect on alleviating chlorosis induced by Fe deficiency on calcareous soil. However, in the 5 SA supplied approaches, foliar application and making slow release particles were more effective.     

外源NO对铜胁迫下番茄光合、生物发光特性及矿质元素吸收的影响

采用营养液培养,研究了外源一氧化氮（NO）供体硝普钠(Sodium nitroprusside, SNP)对50 μmol/L铜（Cu）胁迫下番茄叶片叶绿素含量、光合特性、生物发光强度和矿质营养元素的影响。结果表明,在Cu胁迫下,外施100 μmol/L SNP显著提高番茄叶片叶绿素a、叶绿素b、叶绿素a+b含量、叶绿素a/b比值、净光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)和叶片中Cu、Ca、Fe、Zn、Mn以及根系中Cu、K、Fe、Zn的含量; 显著降低叶片超微弱发光强度、荧光强度、磷光强度、胞间CO2浓度(Ci)和根系中Ca的含量。然而,SNP对Cu胁迫下的缓解效应可被NO的清除剂血红蛋白所抑制。在Cu处理液中加入100 μmol/L NO-x（NO的分解产物）或100 μmol/L亚铁氰化钠（SNP的相似物或分解产物）,与Cu胁迫处理差异不显著。表明外源NO可以通过改善Cu胁迫下番茄叶片光合特性,降低超微弱发光、荧光、磷光强度,维持矿质营养元素平衡,缓解Cu胁迫对番茄的抑制作用。     

钙和NO对NaCl胁迫下黄瓜幼苗生长和活性氧代谢的影响

采用营养液培养的方法,研究了Ca2+对外源一氧化氮(Nitric oxide,NO)所诱导的NaCl胁迫下黄瓜幼苗生长、活性氧代谢的影响。结果表明,添加外源NO或Ca2+显著缓解了NaCl胁迫对黄瓜幼苗生长的抑制,叶片和根系超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)活性较单独NaCl胁迫处理显著提高,丙二醛(MDA)和过氧化氢(H2O2)的含量、超氧阴离子(O.-2)产生速率明显下降;添加NO的同时添加Ca2+通道抑制剂La3+抑制了NO的这些调节作用。结果表明Ca2+对NO诱导的NaCl胁迫下黄瓜幼苗植株活性氧清除能力的提高起重要作用,NO的作用可能依赖于胞浆Ca2+。     

外源一氧化氮介导铜胁迫下番茄幼苗中铁、锌、锰的累积及亚细胞分布

采用营养液培养方法,以改良毛粉802F1番茄为材料, 研究外源一氧化氮（NO,SNP为供体）对铜（Cu）胁迫下番茄幼苗铁（Fe）、 锌（Zn）、 锰（Mn）吸收分配的影响。结果显示, 50 mol/ L的 Cu2+ 胁迫下,番茄幼苗的生物量和株高显著降低了33.7% 和23.1%,外施100 mol/L SNP可显著缓解这种抑制作用, 提高Cu 胁迫下番茄幼苗根系、 茎中Fe、 Mn含量及叶柄、 叶片中Fe、 Zn含量,降低茎中Zn含量及叶柄、 叶片中Mn含量; 根系、 茎、 叶柄、 叶片Fe、 Zn及根系和茎中Mn的累积相应增加; 根系吸收的Fe、 Zn、 Mn向地上部的转运降低。Cu 胁迫下, 外源NO可显著提高番茄液泡、 细胞器的Fe、 Zn 含量, 降低根系和叶片细胞壁Fe、 Zn、 Mn含量。在作为转运组织的茎和叶柄中,Mn主要分布在细胞壁上,而在叶柄和叶片液泡、 细胞器中也有增加。表明外源NO可以调控番茄幼苗各部位及亚细胞中Fe、 Zn、 Mn的合理分布,维持胞质离子稳态和矿质营养元素平衡,缓解铜胁迫,保证番茄幼苗正常的生理代谢。     

Effect of different foliar zinc application at different growth stages on seed zinc concentration and its impact on seedling vigor in rice

This study evaluated how zinc (Zn) concentration of rice (Oryza sativa L.) seed may be increased and subsequent seedling growth improved by foliar Zn application. Eight foliar Zn treatments of 0.5% zinc sulfate (ZnSO₄?·?7H₂O) were applied to the rice plant at different growth stages. The resulting seeds were germinated to evaluate effects of seed Zn on seedling growth. Foliar Zn increased paddy Zn concentration only when applied after flowering, with larger increases when applications were repeated. The largest increases of up to ten-fold were in the husk, and smaller increases in brown rice Zn. In the first few days of germination, seedlings from seeds with 42 to 67?mg Zn?kg^?1 had longer roots and coleoptiles than those from seeds with 18?mg Zn?kg^?1, but this effect disappeared later. The benefit of high seed Zn in seedling growth is also indicated by a positive correlation between Zn concentration in germinating seeds and the combined roots and shoot dry weight (r?=?0.55, p?相似文献