旱盐交叉胁迫对燕麦幼苗生长和渗透调节物质的影响

采用盆栽土培试验研究不同干旱条件下盐胁迫对燕麦幼苗生长和渗透调节物质含量的影响。结果表明,0.3%或0.6%的土壤含盐量可提高轻度(土壤相对含水量65%)和中度(土壤相对含水量50%)干旱胁迫下燕麦幼苗的生物量和植株含水量,同时叶片可溶性糖、脯氨酸和可溶性蛋白质含量增加,游离氨基酸含量下降,根系和地上部Na+含量增加、K+含量降低;而0.9%的土壤含盐量处理或在重度干旱(土壤相对含水量35%)胁迫下随土壤含盐量的增加,燕麦幼苗生物量和植株含水量降低,叶片可溶性糖和可溶性蛋白质含量下降,脯氨酸和游离氨基酸含量增加,根系和地上部Na+含量进一步提高,K+含量迅速降低。表明适量的土壤含盐量可通过提高渗透调节缓解轻、中度干旱胁迫对燕麦幼苗生长的抑制,而过量的盐分加重干旱胁迫对燕麦幼苗的伤害作用。     

外源氮对NaCl胁迫下库拉索芦荟生理特性的影响

温室盆栽条件下,研究了外施不同浓度硝酸铵对200 mmol/L NaCl 胁迫下库拉索芦荟叶片离子含量、质膜透性、丙二醛含量及脯氨酸和可溶性糖积累的影响。结果表明,外施不同浓度NH4NO3（3.75 ~18.75 mmol/L）能够显著增加200 mmol/L NaCl胁迫下植株干重,明显促进芦荟叶片脯氨酸和可溶性糖积累,提高叶片K+、Ca2+含量,抑制叶片对Na+、Cl-的吸收;同时促进K+ 和Ca2+ 向相对幼嫩叶片、Na+ 和Cl-向相对成熟叶片中的积累。外施氮显著降低盐胁迫下叶片细胞质膜透性和丙二醛含量。各项指标变化表明,外施11.25和15 mmol/L NH4NO3对盐胁迫下芦荟生理特性的调控作用较好;外源氮缓解芦荟盐害与氮促进盐胁迫下叶片离子选择吸收、增加有机渗透物质积累及维持植株体内养分平衡有关。     

硝态氮对盐胁迫下囊果碱蓬幼苗根系生长和耐盐性的影响

在溶液培养条件下,设计了4个盐分（1,150,300或450 mmol/L NaCl）和3个氮素（0.05,5或10 mmol/L NO3--N）水平,研究了盐、氮及其互作对囊果碱蓬（Suaeda physophora Pall.）幼苗的离子吸收、氮营养状况、根系形态特征及耐盐性的影响。结果表明,与低盐或低氮相比,增加盐分或氮水平显著增加了囊果碱蓬根部的干重、根系的侧根长、表面积、总吸收面积和活跃吸收面积;且这些根系的形态指标与地上部的离子及氮的累积存在显著的正相关。高盐胁迫下增加氮营养,显著增加了地上部Na+、NO3-、有机氮的含量和硝酸还原酶的活性;降低了Cl-和K+的含量。高盐胁迫下,硝态氮的增加促进了囊果碱蓬幼苗根系的生长,增加了地上部有机氮、NO3-和Na+的累积,改善了植株的营养状况和渗透调节,从而提高了囊果碱蓬的耐盐能力。     

模拟干旱和盐碱胁迫对碱蓬、盐地碱蓬种子萌发的影响

为研究干旱和盐碱胁迫对碱蓬(Suaeda glauca)、盐地碱蓬(Suaeda salsa)种子萌发的影响,比较碱蓬和盐地碱蓬逆境生理特性的异同,本研究利用PEG6000、NaCl和Na_2CO_3分别模拟干旱、盐和碱胁迫,配制相同渗透势的PEG6000、NaCl、Na_2CO_3处理液,以蒸馏水处理为对照,对碱蓬、盐地碱蓬种子的萌发与胚的生长进行比较研究。结果表明:1)低渗处理(-0.46 MPa)对碱蓬、盐地碱蓬种子的萌发无显著影响;高渗处理(-1.38MPa、-1.84 MPa)抑制碱蓬、盐地碱蓬种子的萌发。2)当溶液渗透势相等时,NaCl处理下碱蓬种子的萌发率显著大于PEG、Na_2CO_3处理;而等渗PEG、NaCl、Na_2CO_3处理对盐地碱蓬种子萌发率的影响无显著差异。3)PEG、NaCl、Na_2CO_3处理组碱蓬、盐地碱蓬种子的最终萌发率与对照无显著差异。4)在幼苗形成阶段,PEG、Na_2CO_3处理对碱蓬、盐地碱蓬胚的抑制作用显著大于等渗NaCl处理。5)碱蓬、盐地碱蓬胚的生长对NaCl、Na_2CO_3胁迫的响应存在差异。-0.92 MPa NaCl处理抑制碱蓬胚的生长,却对盐地碱蓬产生促进作用;-0.46 MPa Na_2CO_3处理对碱蓬胚的抑制作用小于盐地碱蓬。综合分析表明:碱蓬、盐地碱蓬均具有很强的抗盐性。在种子萌发阶段,碱蓬种子的抗旱、抗碱能力低于盐地碱蓬;在幼苗形成阶段,碱蓬胚的抗盐性小于盐地碱蓬,但对轻度碱胁迫的抗性高于盐地碱蓬。     

盐地碱蓬人工栽培与品系选育初报

人工栽培盐地碱蓬及高产品系选育试验研究表明 ,人工栽培盐地碱蓬可提高产量 1～ 2倍 ,且碱蓬产量随土壤盐度的提高而逐渐下降。无灌水条件下采用一定矿化度的盐水过量灌溉 ,可有效提高碱蓬产量。黄河三角洲地区人工栽培碱蓬适宜采收时间为 10月 2 5日左右。选育高产变异碱蓬个体比普通单株产量提高 2～ 3倍。     

盐胁迫对黑麦草幼苗生长的影响及磷肥的缓解作用

采用盆栽试验和生理生化分析方法研究了盐胁迫对黑麦草幼苗生长的影响以及施用磷肥(过磷酸钙)对盐胁迫下黑麦草幼苗生长的缓解作用。结果表明,盐胁迫下黑麦草幼苗干物质积累下降;增施磷肥能促进黑麦草幼苗生长,增加干物质积累,增强黑麦草对Na+、K+吸收的选择性,促进K+的吸收和向叶片运输;能提高叶片叶绿素含量,增强叶片净光合速率和气孔导度,增加可溶性蛋白、可溶性糖及脯氨酸含量,从而增强黑麦草幼苗对盐胁迫的适应能力。     

盐胁迫下AM真菌对紫花苜蓿生长及生理特征的影响

利用盆栽试验研究了NaCl胁迫条件下AM真菌对紫花苜蓿(Medicago sativa L.)植株生长及生理特征的影响。结果显示:随土中加入NaCl浓度增高(0%,0.5%,1.0%),与未接菌紫花苜蓿相比,接种AM真菌显著(P<0.05)促进紫花苜蓿生长,并使其可溶性糖、可溶性蛋白及根系脯氨酸累积量增加。1.0%NaCl接种AM真菌处理下根系鲜重(28.1 mg)为0%NaCl未接种下的1.27倍;不同盐处理接种AM真菌植株丙二醛含量均低于对照株;1.0%NaCl浓度下接种AM菌植株叶片及根系脯氨酸含量分别为对照株的0.82,1.41倍。表明AM真菌在胁迫环境下不仅可促进植株生长发育及渗透调节物质的积累,还可维持植物体丙二醛含量较低水平,降低植株遭受盐胁迫,推测叶片与根系脯氨酸对ABA依赖程度不同而导致其脯氨酸含量不同。     

几种一年生盐生植物的吸盐能力

【目的】土壤盐渍化在新疆发生面积多,分布广,利用盐生植物对盐分的超富集能力,选育生物量大且体内盐分浓度高的品种,可有效改良盐碱地。本试验比较了几种主要盐生植物的吸收离子类型和盐分积累量,为科学合理利用盐生植物进行盐碱地改良提供科学依据。【方法】选取一年生盐角草(Salicornia europaea)、盐地碱蓬(Suaeda salsa)、高碱蓬(Suaeda altissima)和野榆钱菠菜(Atripex aucheri Moq.)为材料进行人工种植,试验地土壤为壤土和砂壤土,耕层土壤盐分均值为10.23 g/kg,p H为8.36,属于中度盐化土壤。采用完全随机排列设计,在生育早期、中期和末期采样测定植物地上、地下部分干物质量和K+、Na+、Ca2+、Mg2+、Cl-、SO2-4浓度。【结果】生育末期四种盐生植物地上生物量均占整株生物量的89%以上,高碱蓬(23302 kg/hm2)蓬野榆钱菠菜(20379 kg/hm2)盐地碱蓬(18670 kg/hm2)盐角草(9096 kg/hm2)。盐分总浓度盐角草(215 g/kg)盐地碱蓬(152 g/kg)高碱蓬(137 g/kg)野榆钱菠菜(103 g/kg)。不同植物离子含量不同,K+浓度以高碱蓬中最高,Na+、Cl-、SO2-4在盐角草中最高,Ca2+、Mg2+浓度在盐地碱蓬中最高;4种盐生植物对Na+、Cl-、SO2-4的吸收能力极强,按阴离子类型划分盐角草属于SO2-4-Cl-型盐生植物,盐地碱蓬、高碱蓬、野榆钱菠菜属于Cl--SO2-4型盐生植物;盐分积累量为高碱蓬(3499 kg/hm2)盐地碱蓬(3061 kg/hm2)蓬野榆钱菠菜(2180 kg/hm2)盐角草(2080 kg/hm2)。【结论】盐生植物对土壤的改良效果主要以生育末期刈割时单位面积从土壤中吸收的盐分总量来衡量,这取决于此时地上部分生物量与植株体内盐分浓度的大小。植物会根据其生长需求选择吸收土壤中矿物质元素,盐角草对的Na+、Cl-的吸收能力强于盐地碱蓬、高碱蓬和野榆钱菠菜,尤其对Cl-表现出极强的选择吸收能力。     

盐地碱蓬SsDREB基因的克隆与表达分析研究

盐地碱蓬（Suaeda salsa L.）是典型的盐碱地指示性植物。本研究以盐地碱蓬为材料,根据其他植物中干旱应答元件结合蛋白保守区的氨基酸序列设计简并引物,通过PCR扩增到一条长180bp的cDNA片段,继而利用RACE技术克隆了一个盐地碱蓬DREB基因全长cDNA,命名为SsDREB。SsDREBcDNA全长为14...     

盐胁迫下冬枣幼苗对土壤施钾的响应

采用盆栽试验,研究了不同盐胁迫下土壤施钾(K)对冬枣幼苗生物产量、养分含量以及叶片和土壤中K+、Na+分布的影响,以期探讨K素对冬枣Na Cl胁迫的缓解作用,为黄河三角洲滨海盐碱地区冬枣合理施用K肥提供理论依据。结果表明,盐胁迫显著降低了冬枣幼苗的鲜重增加量,施用KCl可以有效缓解Na Cl对植株生长的抑制作用,在盐胁迫下可使叶片干重较未施KCl时提高21.5%~29.8%。土壤施K 0.1 g/kg可使冬枣幼苗的耐盐能力由可耐土壤含盐量2 g/kg提高至3 g/kg。适量施用外源K+可增加叶片中的N、P、K含量,改善树体营养状况,提高叶片中的K+/Na+,在一定程度上减轻盐胁迫造成的离子失衡,减轻Na Cl胁迫对冬枣的伤害作用。土壤盐分会显著影响K素在土壤中的化学行为。     

玻璃中永久应力的理论分析与数值模拟

为了分析玻璃退火过程中永久应力的形成规律以及应力值的大小,基于玻璃永久应力的成因分析,建立了弹性体数值模型,给出了永久应力的计算方法和步骤。根据所建模型,利用ansys软件模拟了玻璃退火过程中结构应力和残余温差应力的形成过程,发现结构应力产生于膨胀系数开始发生变化的温度567℃,停止于膨胀系数稳定时的温度480℃。并根据模拟结果,计算出了玻璃中永久应力值的大小：边部压应力1.022MPa,中部张应力0.602MPa。模拟过程比较准确地反应了实际玻璃退火过程中应力的形成过程,根据模拟值求出的应力值大小基本符合玻璃实际应力值情况。     

PEG预处理对盐及镉胁迫下黑麦草生理代谢的影响

为了探讨PEG预处理对盐胁迫和镉胁迫下多年生黑麦草幼苗生理特性的影响,将黑麦草幼苗分别用0,5%,10%,15%,20%,25%(对应水势分别为0,-0.05,-0.15,-0.30,-0.50,-0.77 MPa)的PEG-6000营养液进行预处理后,分别用含150 mmol/L NaCl和Cd~(2+)浓度为10 mg/L的胁迫液培养,然后测定黑麦草幼苗叶片的光合色素含量、MDA含量、游离脯氨酸含量、可溶性糖含量及抗氧化酶(SOD、POD、CAT、APX)活性。结果表明:盐胁迫下15%(-0.30 MPa)PEG预处理和镉胁迫下10%(-0.15 MPa)PEG预处理可以有效提高多年生黑麦草的光合色素含量,降低MDA、游离脯氨酸含量,增加可溶性糖含量,提高抗氧化酶活性。PEG预处理下多年生黑麦草在遭受逆境胁迫时,受到多种生理生化的调节,其生理指标的动态变化是黑麦草应答逆境因子胁迫的重要调节机制,体现了其对逆境胁迫的适应能力以及在多种逆境胁迫下的交叉适应能力。     

Effects of saline and alkaline stresses on the germination, growth, photosynthesis, ionic balance and anti-oxidant system in an alkali-tolerant leguminous forage Lathyrus quinquenervius

We compared the effects of saline stress (9:1 molar ratio of NaCl : Na₂SO₄, pH 6.44–6.65) and alkaline stress (9:1 molar ratio of NaHCO₃ : Na₂CO₃, pH 8.71–8.89) on the germination, growth, photosynthesis, ionic balance and activity of anti-oxidant enzymes of Lathyrus quinquenervius to elucidate the physiological adaptive mechanism of plants to alkaline stress (high pH). The results showed that, at a low stress intensity, the effects of saline stress and alkaline stress on L. quinquenervius were similar. Compared with saline stress, high alkaline stress intensity clearly inhibited germination, growth, photosynthesis and root system activity, and led to a sharp increase in Na⁺ and an ion imbalance in the shoots, as well as enhanced H₂O₂ and malondialdehyde content, resulting in severe intracellular oxidative stress. The results indicated that the accumulation of organic acid was a central adaptive mechanism by which L. quinquenervius maintained intracellular ionic balance under alkaline stress. Lathyrus quinquenervius may enhance organic acid synthesis to remedy the shortage of negative charge resulting from the massive influx of Na⁺ and decreased inorganic anions. In addition, saline stress and low alkaline stress slightly enhanced the activities of superoxide dismutase (SOD) and ascorbate peroxidase (APX), but did not affect catalase (CAT) activity. However, strong alkaline stress significantly enhanced the activities of SOD and APX, and reduced CAT activity. We propose that enhancing the activities of SOD and APX may be a vital mechanism by which L. quinquenervius resists oxidative stress caused by alkaline stress.     

Physiological responses and adaptive strategies of wheat seedlings to salt and alkali stresses

Abstract

Effects of salt (NaCl?:?Na₂SO₄) and alkali (NaHCO₃?:?Na₂CO₃) stresses on the contents of inorganic ions and organic solutes in wheat shoots were compared to explore the physiological responses and adaptive strategies of wheat to these stresses. Wheat significantly accumulated Na⁺ and simultaneously accumulated Cl^?, soluble sugars and proline to maintain osmotic and ionic balance under salt stress. Compared with salt stress, the high pH from alkali stress enhanced Na⁺ accumulation and affected the absorption of inorganic anions. To maintain ionic and osmotic balance, wheat accumulated organic acids, soluble sugars and proline. The accumulation of Cl^? and organic acids was the main difference in the physiological responses and adaptive mechanisms to salt and alkali stresses, respectively.     

Physiological responses and adaptive strategies of wheat seedlings to salt and alkali stresses

Effects of salt (NaCl : Na₂SO₄) and alkali (NaHCO₃ : Na₂CO₃) stresses on the contents of inorganic ions and organic solutes in wheat shoots were compared to explore the physiological responses and adaptive strategies of wheat to these stresses. Wheat significantly accumulated Na⁺ and simultaneously accumulated Cl⁻, soluble sugars and proline to maintain osmotic and ionic balance under salt stress. Compared with salt stress, the high pH from alkali stress enhanced Na⁺ accumulation and affected the absorption of inorganic anions. To maintain ionic and osmotic balance, wheat accumulated organic acids, soluble sugars and proline. The accumulation of Cl⁻ and organic acids was the main difference in the physiological responses and adaptive mechanisms to salt and alkali stresses, respectively.     

锶及柴油胁迫下3种杨树对土壤锶的富集特征

为探究杨树对土壤锶污染的修复能力,以白杨、俄罗斯杨和青杨为试材,在100 mg·kg~(-1)Sr~(2+),15mg·kg~(-1)柴油,15 mg·kg~(-1)柴油+100 mg·kg~(-1)Sr~(2+)条件下处理60 d,通过测定杨树的生长指标及各器官Sr~(2+)富集浓度,探讨比较不同种的杨树对土壤Sr~(2+)的富集特征和富集能力差异。结果表明,单一Sr~(2+)胁迫能够促进俄罗斯杨和青杨幼苗的生长,对白杨的生长表现出一定抑制效应;而柴油污染胁迫对杨树的生长均具有明显的抑制作用,其中白杨对柴油胁迫的耐受性优于俄罗斯杨和青杨。单独Sr~(2+)胁迫下3种杨树幼苗各器官Sr~(2+)富集为叶根茎,其中白杨的总富集浓度最高,达到2.369 mg·g~(-1)DW,青杨最低,为1.203 mg·g~(-1)DW。在柴油和Sr~(2+)的复合胁迫下,白杨、俄罗斯杨和青杨对Sr~(2+)的富集浓度明显减小,分别为1.344、1.145和0.604 mg·g~(-1)DW;但白杨和俄罗斯杨富集特征变化不大,青杨Sr~(2+)富集浓度最大的器官由叶变为根。此外,柴油的施加对3种杨树转运能力的影响具有显著差异,其中白杨的转运能力增强了15.76%,青杨显著降低了61.83%,说明杨树对土壤Sr~(2+)及其与柴油复合污染胁迫都有较好的耐受及Sr~(2+)富集能力,其中白杨更适合作为污染治理树种。本研究结果为锶及柴油污染土壤的植物修复提供了参考依据。     

The impact of selenium application on enzymatic and non-enzymatic antioxidant systems in Zea mays roots treated with combined osmotic and heat stress

Selenium (Se), regarded as an antioxidant, has been found beneficial for plants growing under stressed conditions. To investigate whether the Se application helps to improve stress tolerance, sodium selenite (Na₂SeO₃ · 5H₂O, 5–15 μM) was hydroponically applied to Zea mays variety OSSK-713-roots under heat and/or PEG-induced osmotic stress (25% PEG-6000) for 8 h. The individual/combined stress caused accumulation of reactive oxygen species (ROS). While only superoxide dismutase (SOD) increased with heat stress alone, the activities of SOD, catalase (CAT) and ascorbate peroxidase (APX) increased under PEG exposure. The combination of these stresses resulted in an induction of both SOD and CAT activities. Lipid peroxidation (TBARS) levels were also high in all the stress treatments, especially under the combination treatment. Addition of Se not only improved the activities of SOD, APX and glutathione reductase (GR) in stress-treated roots, but it also changed the activities of monodehydroascorbate reductase (MDHAR) and dehydroascorbate reductase (DHAR). The findings reveal that Se has a positive effect on heat and/or osmotic stress mitigation mainly by regulating the ascorbate-glutathione cycle, especially in PEG-treated plants. Under the combined stress treatment, addition of 5 µM of exogenous Se was most effective.     

Physiological Responses of Leymus Chinensis to Long-Term Salt,Alkali and Mixed Salt-Alkali Stresses

The aim of this study was to evaluate the physiological responses of Leymus chinensis (Trin.) Tzvel exposed to long-term salt, salt-alkali, and alkali stress in order to elucidate how L. chinensis can survive under alkaline-sodic soils. L. chinensis (30 days after germination) were stressed with salt [SS; sodium chloride (NaCl)], mixed salt-alkali [MS; molar ratio of NaCl: sodium carbonate (Na₂CO₃) = 2:1] and alkali salt (AS; Na₂CO₃) at four different levels of sodium (Na⁺) concentration (0, 75, 150, and 300 mM) for 60 days. L. chinensis showed 100% survival rate at all treatments except 300 mM SS (33.3%) and AS (18.9%). The growth and physiological parameters of survival plants were measured. As anticipated, growth of L. chinensis was inhibited after stresses, which reflected in the decline of plant height, dry weight and tiller number following the increased Na⁺ concentration. The content of Na⁺, proline, and soluble sugar in L. chinensis increased with the increasing Na⁺ concentration, suggesting that L. chinensis need to accumulate inorganic and organic solutes for resisting osmotic stress induced by various salt stresses. These processes ensure the water balance that can provide a relative normal physiological environment for L. chinensis. Potassium (K⁺) content of L. chinensis kept at a relative lower level than control to ensure the normal physiological processes. Chlorophyll content of stressed plant increased slightly compared to control plants, which can produce more energy for L. chinensis resisting various stresses. The increased malondialdehyde (MDA) content of stressed plants showed the damage of various stresses. Among the three treatments (SS, MS, and AS), the injury extent for L. chinensis can be expressed by AS>SS>MS, and MS was the most complicated for the counterbalance effects of soil electrical conduction and pH.     

Effects of plant growth-promoting rhizobacteria on the molecular responses of maize under drought and heat stresses: A review

Drought and heat are major environmental stresses that continually influence plant growth and development. Under field conditions, these stresses occur more frequently in combination than alone, which magnifies corresponding detrimental effects on the growth and productivity of agriculturally important crops. Plant responses to such abiotic stresses are quite complex and manifested in a range of developmental, molecular, and physiological modifications that lead either to stress sensitivity or tolerance/resistance. Maize (Zea mays L.) is known for its sensitivity to abiotic stresses, which often results in substantial loss in crop productivity. Bioaugmentation with plant growth-promoting rhizobacteria (PGPR) has the potential to mitigate the adverse effects of drought and heat stresses on plants. Hence, this is considered a promising and eco-friendly strategy to ensure sustainable and long-term maize production under adverse climatic conditions. These microorganisms possess various plant growth-promoting (PGP) characteristics that can induce drought and heat tolerance in maize plants by directly or indirectly influencing molecular, metabolic, and physiological stress responses of plants. This review aims to assess the current knowledge regarding the ability of PGPR to induce drought and heat stress tolerance in maize plants. Furthermore, the drought and heat stress-induced expression of drought and heat stress response genes for this crop is discussed with the mechanisms through which PGPR alter maize stress response gene expression.     

高铝低磷胁迫对胡枝子生长及矿质元素吸收的影响

限制酸性土壤作物生长的最重要、最普遍的因子是Al3+ 的毒害和 P 的缺乏.本文用溶液培养试验研究两种不同生态型的二色胡枝子在高Al低P胁迫下的矿质营养元素积累情况.试验表明,江西胡枝子比河北胡枝子更耐低 P 低 pH 的生长环境,但两者间耐Al性无显著差异;100 μm/L Al 处理显著地抑制了两种胡枝子对 Ca 的吸收,降低了根系 Mg 的积累量,对植株的 K、P、Fe、Zn、Cu 含量没有显著影响;低 P 处理没有显著降低两种胡枝子对 Ca、K、Fe、Zn、Cu 和江西胡枝子对 Mg 的吸收,但是低 P 处理显著降低了河北胡枝子对 Mg 的吸收和转运.二色胡枝子植株吸收的 Al 主要积累在根部,地上部分Al含量仅是根系的1% 左右.