黄土高原旱作区糜子-绿豆带状种植农田小气候特征与产量效应

基于黄土高原干旱地区生态环境特性,研究了4种糜子(P)-绿豆(M)间作模式下[2∶2(2P2M)、4∶2(4P2M)、4∶4(4P4M)、2∶4(2P4M)]农田小气候特征及产量效应.结果表明: 糜子-绿豆间作模式显著增加了生育后期糜子的株高、叶面积指数(LAI)和叶绿素含量(SPAD),使其达到最佳的生长状态;由于高位糜子的遮阴,导致矮位绿豆阶段性徒长,株高显著增加,而LAI和SPAD均有所下降.糜子-绿豆间作模式降低了糜子籽粒灌浆过程中的群体上层光照度和空气温度,而相对湿度显著上升.地上部气候环境的变化调控了间作体系地下部的土壤温度,减少了群体的漏光损失,使其表现出冷湿的生态环境.而矮位绿豆较差的通风透光条件形成相对封闭的间作系统,抑制了绿豆植株的生长发育,使其处于间作劣势.与单作相比,2P2M、4P2M、4P4M和2P4M处理的糜子单株穗数、穗长、单株粒重和千粒重分别增加了7.5%～45.0%、2.2%～12.2%、35.4%～94.0%和2.3%～4.7%,产量比单作提高了5.6%～20.7%;间作处理下矮位绿豆的分枝数、单株荚数、单株粒重和百粒重均有不同程度的下降,2P4M间作模式下的绿豆受糜子影响最小,产量比单作降低了34.8%.糜子-绿豆间作存在明显的间作优势,各间作处理下的土地当量比(LER)均大于1,2P4M间作模式下的LER达到最大值(1.86).因此,黄土高原地区糜子-绿豆最佳的间作配比为2P4M.     

Response of Raphanus sativus to the auxin precursor,L-tryptophan applied to soil

Soil microorganisms are capable of producing auxins in the presence of the physiological precursor, L-tryptophan (L-TRP). This study was designed to assess the influence of L-TRP on radish (Raphanus sativus) yield when applied to soil. The amount of L-TRP added to soil to give optimum radish growth in glasshouse studies was 3.0 mg kg^-1 soil which enhanced the root yield by 1.31-fold over the control. The root/shoot ratio was increased by 1.10-fold upon this amendment. One L-TRP application was sufficient to promote growth. The best time to apply L-TRP was at the onset of seedling emergence. The application of L-TRP promoted radish yield comparable to those plants treated with indole-3-acetic acid, indole-3-acetamide and indole-3-lactic acid. Foliar application of L-TRP had no effect on the root and shoot dry weight. A field study was conducted in which L-TRP applications at a rate of 20.4 and 204 mg m^-2 significantly enhanced the radish yield in fertilized plots receiving fertilization. The shoot dry weight was increased by 1.29-fold and the root dry weight by 1.15-fold over the control in response to 20.4 mg L-TRP m^-2. These findings indicate that L-TRP, applied at the appropriate times and concentrations, can increase radish yield. The effect of L-TRP on radish growth could be attributed to i) substrate-dependent auxin production in soil by the indigenous microflora, ii) uptake directly by plant roots followed by metabolism within their tissues, and/or iii) a change in the balance of rhizosphere microflora affecting plant growth.     

L-Tryptophan-dependent biosynthesis of indole-3-acetic acid (IAA) improves plant growth and colonization of maize by <Emphasis Type="BoldItalic">Burkholderia phytofirmans</Emphasis> PsJN

Burkholderia phytofirmans PsJN is a well-known plant growth-promoting bacterium that establishes rhizospheric and endophytic colonization in different plants. PsJN inoculation promotes growth of different horticultural crops. L-Tryptophan (L-TRP) application may further improve its effectiveness, due to substrate (L-TRP)-dependent inoculum (PsJN)-derived auxins in the rhizosphere. In the present study, the substrate (L-TRP)-dependent response of PsJN inoculation to maize growth and auxin biosynthesis was evaluated under pot conditions. In vitro auxin biosynthesis by PsJN was determined in the absence and presence of L-TRP, a physiological precursor of auxins. Surface-disinfected seeds were treated with peat-based inoculum and L-TRP solutions (10^?4 and 10^?5 M). Results revealed that L-TRP application and PsJN inoculation, when applied separately, significantly increased the growth parameters of maize compared to untreated control. However, PsJN inoculation supplemented with L-TRP (10^?5 M) gave the most promising results and significantly increased plant height, photosynthesis, chlorophyll content, root biomass and shoot biomass up to 18, 16, 45, 62 and 55 %, respectively, compared to the uninoculated control. Similarly, higher values of N, P and IAA content were observed with precursor (L-TRP)–inoculum (PsJN) interaction. The inoculant strain efficiently colonized maize seedlings and was recovered from the rhizosphere, root and shoot of plants. The results imply that substrate (L-TRP)-derived IAA biosynthesis in the rhizosphere by PsJN inoculation could be a useful approach for improving the growth, photosynthesis and nutrient content of maize plants.     

Salinity tolerance of mung bean (Vigna radiata L.): Seed production

Plant growth and seed yield of mung bean were studied in sand culture at different levels of NaCl [0, 50, 100, 150, 200, 250 mM] in the root medium. Results showed that both dry matter yield and seed yield of plants grown for 14 weeks at 50 mM NaCl and 100 mM NaCl were around 60 % and 25 %, respectively of those for plants grown in control solution. Higher concentrations caused wilting and necrosis of leaves. Very effective exclusion of Na and Cl from salt grown mung bean seed was observed with concommitant high accumulation of Na and Cl in the stem. It is speculated that mung bean plant stem may act as a ‘sink’ for NaCl during the reproductive stage of the plant growth cycle.     

Physiological insights into sulfate and selenium interaction to improve drought tolerance in mung bean

The present study involved two pot experiments to investigate the response of mung bean to the individual or combined SO₄²⁻ and selenate application under drought stress. A marked increment in biomass and NPK accumulation was recorded in mung bean seedlings fertilized with various SO₄²⁻ sources, except for CuSO₄. Compared to other SO₄²⁻ fertilizers, ZnSO₄ application resulted in the highest increase in growth attributes and shoot nutrient content. Further, the combined S and Se application (S + Se) significantly enhanced relative water content (16%), SPAD value (72%), photosynthetic rate (80%) and activities of catalase (79%), guaiacol peroxidase (53%) and superoxide dismutase (58%) in the leaves of water-stressed mung bean plants. Consequently, the grain yield of mung bean was markedly increased by 105% under water stress conditions. Furthermore, S + Se application considerably increased the concentrations of P (47%), K (75%), S (80%), Zn (160%), and Fe (15%) in mung bean seeds under drought stress conditions. These findings indicate that S + Se application potentially increases the nutritional quality of grain legumes by stimulating photosynthetic apparatus and antioxidative machinery under water deficit conditions. Our results could provide the basis for further experiments on cross-talk between S and Se regulatory pathways to improve the nutritional quality of food crops.Supplementary InformationThe online version contains supplementary material available at 10.1007/s12298-021-00992-6.     

Modulation of growth,photosynthetic capacity and water relations in salt stressed wheat plants by exogenously applied 24-epibrassinolide

Brassinosteroids promote the growth of plants and are effective in alleviating adverse effects of abiotic stresses such as salinity and drought. Under saline conditions, improvement in grain yield is more important than simple growth. Previously it was found that although foliar application of brassinosteroids improved growth of wheat plants, it did not increase grain yield. In present study, influence of root applied 24-epibrassinolide was assessed in improving growth and yield of two wheat cultivars. Plants of a salt tolerant (S-24) and a moderately salt sensitive (MH-97) were grown at 0 or 120 mM NaCl in continuously aerated Hoagland’s nutrient solution. Different concentrations of 24-epibrassinolide (0, 0.052, 0.104, 0.156 μM) were also maintained in the solution culture. Exogenous application of 24-epibrassinolide counteracted the salt stress-induced growth and grain yield inhibition of both wheat cultivars. Of the varying 24-epibrassinolide concentrations used, the most effective concentrations for promoting growth were 0.104 and 0.052 μM under normal and saline conditions, respectively. However, root applied 0.052 μM 24-epibrassinolide enhanced the total grain yield and 100 grain weight of salt stressed plants of both cultivars and suggested that total grain yield was mainly increased by increase in grain size which might have been due to 24-epibrassinolide induced increase in translocation of more photoassimilates towards grain. Growth improvement in both cultivars due to root applied 24-epibrassinolide was found to be associated with improved photosynthetic capacity. Changes in photosynthetic rate due to 24-epibrassinolide application were found to be associated with non-stomatal limitations, other than photochemical efficiency of PSII and photosynthetic pigments. Leaf turgor potential found not to be involved in growth promotion.     

Effects of the exogenous application of auxin and cytokinin on carbohydrate accumulation in grains of rice under salt stress

Phytohormones, such as auxin and cytokinin, are known to be involved in the regulation of plant responses to salinity stress and counteract the adverse effect of stress conditions. This work investigated the effects of the exogenous spraying of indole-3-acetic acid (IAA) and kinetin (KIN) during the reproductive phase on grain yield by examining the 1000-grain weight and filled-grain percentage as well as the changes in starch, total soluble sugars, sucrose, glucose and fructose concentrations in the grains of two rice cultivars under salt stress. The results indicated that the applied IAA and KIN led to an increased grain yield, 1000-grain weight and filled-grain percentage for both rice cultivars under salt stress. The storage starch content in the grain of the salt-sensitive cultivar was more than that in the salt-tolerant cultivar under IAA application compared with KIN, whereas a decrease in the total soluble sugar content was observed with both IAA and KIN treatments, in comparison to the non-hormone treatment. Interestingly, this study showed that IAA led to a much higher increase in the sucrose content in grain, as compared to the KIN. Furthermore, this experiment suggests that glucose and fructose may play important roles during salt stress because there were clearly higher concentrations of these sugars in the grain of the stressed cultivars under IAA and KIN application: it appears that their accumulation was the earliest response detected during the grain-filling period in rice. Finally, this work indicated that an increase in the rice grain yield, 1000-grain weight and filled-grain percentage are associated with an increase in the contents of starch, sucrose, glucose and fructose in grain caused by the application of IAA and KIN.     

Synergistic interactions of arbuscular mycorrhizal fungi and rhizobia promoted the growth of <Emphasis Type="Italic">Lathyrus sativus</Emphasis> under sulphate salt stress

In order to examine the influence of microsymbionts on plants, arbuscular mycorrhizal (AM) fungi and rhizobia were used to examine the growth of Lathyrus sativus under sulphate salt stress. Seedlings of L. sativus were inoculated with a combination of selected microsymbionts. Plants were grown under greenhouse conditions with five Na₂SO₄ concentrations (0, 1%, 2%, 3% and 4% (weight : weight)). The inoculations combinations used were the AM fungus, Glomus mosseae and/or the rhizobium, Mesorhizobium mediterraneum. The results showed that sulphate salinity inhibited plant growth and biomass production. However, compared with the control treatments, dual-inoculation of G. mosseae and M. mediterraneum reduced the harmful influence of sulphate salinity. Parmeters including plant height, the extent of AM colonization, total biomass, nodules biomass, P concentration, N concentration and proline concentration confirmed that dual inoculation plays a vital role in promoting the growth of L. sativus under sulphate salt stress. The results suggested that the use of this dual inoculation could be exploited in grassland plantation establishment and in pastoral ecosystem reclamation programmes in arid and semi-arid areas subject to moderate salt contamination.     

Basal Application of Zinc to Improve Mung Bean Yield and Zinc-Grains Biofortfication

Worldwide, the dietary deficiency of zinc (Zn) is prevailing in almost all arid and semi-arid regions. Zinc deficiency is not only the major constraint of lower yield, but also dietary Zn deficiency in cereals grains may cause increasing malnutrition and chronic health problems in human. Exogenous application of Zn through basal soil nutrition might be a useful option to recover Zn deficiency in mung bean. Therefore, field study was conducted to optimize the optimum level and method of Zn nutrition to enhance crop yield and Zn biofortification of mung bean through basal application. Zinc was applied at 0, 5, 10 and 15 kg/ha as basal application and side dressing, and in combination (50% basal application + 50% side dressing). The results highlighted that Zn nutrition prominently improved the mung bean yield as compared with control (no Zn applied). The maximum grains yield and Zn concentration in grains were obtained where Zn was applied at 15 kg/ha as basal application as compared with all other combinations. Better improvement in grain yield was due to significant increase in more number of pods and grain size owing to welldeveloped root system, improved leaf area index and high chlorophyll contents in mung beans leaves. Amongst all applied Zn nutrition’s the basal application of Zn (15 kg/ha) was a viable option to get higher yield and Zn biofortification of mung bean.     

Grain yield of common bean (<Emphasis Type="Italic">Phaseolus vulgaris</Emphasis> L.) varieties is markedly increased by rhizobial inoculation and phosphorus application in Ethiopia

A field experiment was conducted to assess plant growth, symbiotic performance and grain yield of common bean in response to rhizobial incoculation and phosphorus application at Galalicha in Southern Ethiopia during the 2012 and 2013 cropping seasons under rain-fed conditions. The treatments consisted of 2 released common bean varieties (Hawassa Dume and Ibbado), 3 levels of Rhizobium inoculation (uninoculated, inoculated with strain HB-429 or GT-9) and 4 levels of phosphorus application (0, 10, 20 and 30 kg P ha^?1) using a split-split plot design with four replications. Here, phosphorus levels, Rhizobium inoculation and common bean varieties were assigned as main, sub- and sub-sub treatments, respectively. The results revealed marked varietal differences in plant growth, grain yield and symbiotic performance. Of the two common bean varieties studied, Hawassa Dume generally showed superior performance in most measured parameters in 2013. Rhizobium inoculation significantly (p?≤?0.05) increased plant growth, symbiotic performance and grain yield. Applying Rhizobium strain HB-429 to bean crop respectively increased plant growth, %Ndfa, amount of N-fixed and grain yield by 19, 17, 54 and 48% over uninoculated control. Similarly, the application of 20 kg P ha^?1 to bean plants respectively resulted in 36, 20, 96 and 143% increase in plant growth, %Ndfa, N-fixed and grain yield when compared to the control. These results clearly indicate that plant growth, symbiotic performance and grain yield of common bean can be significantly increased by Rhizobium inoculation and phosphorus fertilization in Ethiopia. Rhizobium inoculants are a cheaper source of nitrogen than chemical fertilizers and when combined with moderate phosphorus application can markedly increase grain yield for resource-poor farmers.     

Preliminary investigations on inducing salt tolerance in maize through inoculation with rhizobacteria containing ACC deaminase activity

Twenty rhizobacterial strains containing 1-aminocyclopropane-1-carboxylate deaminase were isolated from the rhizosphere of salt-affected maize fields. They were screened for their growth-promoting activities under axenic conditions at 1, 4, 8, and 12 dS x m-1 salinity levels. Based upon the data of the axenic study, the 6 most effective strains were selected to conduct pot trials in the wire house. Besides one original salinity level (1.6 dS x m-1), 3 other salinity levels (4, 8, and 12 dS x m-1) were maintained in pots and maize seeds inoculated with selected strains of plant growth-promoting rhizobacteria, as well as uninoculated controls were sown. Results showed that the increase in salinity level decreased the growth of maize seedlings. However, inoculation with rhizobacterial strains reduced this depression effect and improved the growth and yield at all the salinity levels tested. Selected strains significantly increased plant height, root length, total biomass, cob mass, and grain yield up to 82%, 93%, 51%, 40%, and 50%, respectively, over respective uninoculated controls at the electrical conductivity of 12 dS x m-1. Among various plant growth-promoting rhizobacterial strains, S5 (Pseudomonas syringae), S14 (Enterobacter aerogenes), and S20 (Pseudomonas fluorescens) were the most effective strains for promoting the growth and yield of maize, even at high salt stress. The relatively better salt tolerance of inoculated plants was associated with a high K+/Na+ ratio as well as high relative water and chlorophyll and low proline contents.     

Effect of Phytohormone Pretreatment on Nitrogen Metabolism in Vigna radiata Under Salt Stress

Application of NaCl (electrical conductivity 4.0 mS cm^–1) resulted in about 52, 50 and 55 % reduction in total nitrogen contents in mung bean [Vigna radiata (L.) Wilczek] leaf, root and nodule, respectively. In nodule, nitrogenase activity was reduced by about 84 % under stress as compared with the control set. Glutamine synthetase activity was reduced by about 31, 16 and 23 %, glutamate oxoglutarate aminotransferase activity was reduced by 78, 57 and 42 % and glutamate dehydrogenase activity was reduced by 9, 8 and 42 % in leaf, root and nodule, respectively, under salt stress. The pretreatment with indole-3-acetic acid, gibberellic acid and kinetin, each ranging from 0.1 to 10 µM, in restoring the metabolic alterations imposed by NaCl salinity was investigated in mung bean. The three phytohormones used were able to overcome to variable extents the adverse effects of stress imposed by NaCl solution.     

Increasing the okra salt threshold value with biochar amendments

Soil salinity is a severe worldwide environmental problem that adversely affects soil properties and the crop growth such as okra. We hypothesized that biochar soil amendments could increase the okra salt threshold, alleviate salt stress and improve soil productivity. In this study, a pot experiment was conducted to investigate whether biochar could ameliorate the effects of salinity on okra plants. Three biochar amendment (BA) soil applications (0%, 5% and 10% by mass of soil) were considered for seven irrigation water salinity levels (0.75, 1.0, 2.0, 4.0, 5.0, 6.0 and 7.0?dS?m^?1) in a randomized block design with three replications. The Maas and Hoffman salt tolerance model was used to evaluate the effects of BA on okra plant growth parameters (e.g. yield, biomass) and water use efficiency for each salinity treatment. The results showed that increasing the soil salinity levels caused significant decreases in plant yields and yield components. However, biochar application rates of 5% and 10% increased the okra threshold by 19.7% and 81.2%, respectively, compared to the control (0%). The 10% biochar application rate also resulted in the greatest okra plant growth and increased yield, indicating that the effects of salt stress were ameliorated; moreover, the soil bulk density was decreased, and the water content was increased. Hence, biochar soil amendments could be considered as an important agronomic practice that could potentially overcome the adverse effects of salt stress.     

Effect of salt stress on nodulation and nitrogen fixation in legumes

It is now well established that almost all phases of root nodule development in legumes are adversely affected by saline conditions in the rooting medium. There is also a general agreement that the rhizobia are more tolerant to salt stress than the host plant, but they show considerable strain variability in growth and survival under saline conditions. Inhibitory effect of salinity on nodulation has been attributed to decrease in rhizobial colonisation and shrinkage and lack of root hair formation. Salt stress also induces premature senescence of already formed nodules. Both N2-fixation activity and nodule respiration are inhibited sharply on exposure of plants to saline conditions. The decrease in N2-fixation has been ascribed to direct effect on nitrogenase activity or an indirect effect through decrease in leghemoglobin content, respiratory rate, malate concentrations in nodules and photosynthate availability. Salinity increases oxygen diffusion resistance in the nodules and alters their ultrastructure. Decrease in N2-fixation in nodules under salinity is also accompanied by parallel decrease in the activity of H2O2-scavenging enzymes like catalase, ascorbate peroxidase and the level of antioxidants like ascorbic acid. Nodules appear to undergo osmoregulation under saline conditions by accumulating physiologically compatible solutes like proline, sugars (pinnitol) and lactic acid. The intensity of the adverse effects of salinity on nodule functioning depends on plant species, rhizobial strain, duration of exposure to saline conditions, nature, concentration and mode of salt application.     

Salinity effects over growth and yield of IR8 rice and its mutant

Abstract

IRm6, an improved useful, EMS induced mutant of IR8 rice exhibits higher salt tolerance than the parent variety at all the growth stages. High salinity levels reduced germination per cent, early seedling growth and mature plant height in both the genotypes. Roots were more sensitive to salinity than shoots. Within seven days from germination, IRm6 accumulated three times more proline than IR8. Toxicity of individual salt concentrations was in order of NaCl>Na₂SO₄>CaCl₂. At germination and early seedling stages, dry weight of the seedling increased while fresh weight decreased with the rise in salinity unlike later growth stages when both fresh and dry weights of mature plants decreased under salt stress. All the yield components were adversely affected by varying degrees of saline treatments. The order of their contributions in final grain yield reduction was, productive tiller number>fertile grain number>grain specific density>1,000 grain weight. Tillering stage was most sensitive to salinity. Grain yield losses between 27-43% in IR8 and 14-30% in IRm6 occurred after salt treatments at flowering and tillering stages, respectively.     

Does exogenous application of salicylic acid through the rooting medium modulate growth and photosynthetic capacity in two differently adapted spring wheat cultivars under salt stress?

In order to assess whether exogenous application of salicylic acid (SA) through the rooting medium could modulate the photosynthetic capacity of two wheat cultivars differing in salinity tolerance, a hydroponic experiment was conducted under greenhouse conditions. Seeds of a salt tolerant (S-24) and a moderately salt sensitive (MH-97) cultivar were germinated at 0 or 150 mM NaCl in Hoagland's nutrient solution containing different levels of salicylic acid (SA) (0, 0.25, 0.50, 0.75 and 1.00 mM) for 7d. Seven-day old wheat seedlings were transferred to hydroponics and grown at 0, or 150 mM NaCl for for further 30 d. Different levels of salicylic acid (SA) were also maintained in the solution culture. After 30 d, four plants out of six were harvested and the remaining plants were left for the estimation of yield attributes Salt stress reduced the growth and grain yield of both cultivars. However, cv. S-24 performed better than MH-97 under salt stress with respect to leaf area, and grain yield. Exogenous application of SA promoted growth and yield, and counteracted the salt stress-induced growth inhibition of salt tolerant S-24, whereas for MH-97 there was no improvement in growth or grain yield with SA application. Of the varying SA levels used, the most effective levels for promoting growth and grain yield were 0.75 and 0.25 mM under normal and saline conditions, respectively. The improvement in growth and grain yield of S-24 due to SA application was associated with improved photosynthetic capacity. Changes in photosynthetic rate due to SA application were not due to stomatal limitations, but were associated with metabolic factors, other than photosynthetic pigments and leaf carotenoids.     

A Bacterial Indole-3-acetyl-L-aspartic Acid Hydrolase Inhibits Mung Bean (Vigna radiata L.) Seed Germination Through Arginine-rich Intracellular Delivery

Indole-3-acetyl-L-aspartic acid (IAA-Asp) is a natural product in many plant species and plays many important roles in auxin metabolism and plant physiology. IAA-Asp hydrolysis activity is, therefore, believed to affect plant physiology through changes in IAA metabolism in plants. We applied a newly discovered technique, arginine-rich intracellular delivery (AID), to deliver a bacterial IAA-Asp hydrolase into cells of mung bean (Vigna radiata) seeds and measured its effects on mung bean seed germination. IAA-Asp hydrolase inhibited seed germination about 12 h after the enzyme was delivered into cells of mung bean seeds both covalently and noncovalently. Mung bean seed germination was delayed by 36 h when the enzyme protein was noncovalently attached to the AID peptide and longer than 60 h when the enzyme protein was covalently attached to the AID peptide. Root elongation of mung bean plants was inhibited as much as 90% or 80%, respectively, when the IAA-Asp hydrolase was delivered with the AID peptide by covalent or noncovalent association. Further thin-layer chromatography analysis of plant extracts indicated that the levels of IAA increased about 12 h after treatment and reached their peak at 24 h. This result suggests that IAA-Asp hydrolase may increase IAA levels and inhibit seed germination of mung bean plants and that the AID peptide is a new, rapid, and efficient experimental tool to study the in vivo activity of enzymes of interest in plant cells.     

Foliar application of zinc improves morpho-physiological and antioxidant defense mechanisms,and agronomic grain biofortification of wheat (Triticum aestivum L.) under water stress

Agronomic biofortification with zinc (Zn) may be engaged to improve the nutritious value of food crops along-with tolerance to water deficit conditions. The Zn may increase plant resistance to water stress by boosting physiological and enzymatic antioxidants defense mechanisms. Major objective of this study was to investigate the effect of foliar applied Zn on grain zin biofortification and drought tolerance in wheat. Treatments include application of Zinc at terminal growth phases (BBCH growth stage 49 and BBCH growth stage 65) with five levels: 0 (control-ck), water spray, 5, 10 and 15 mM under two levels of water regimes; well-watered (where 80% water holding capacity (WHC) was maintained in the soil) and water stress, (where 40% WHC was maintained in the soil). Results revealed that water stress significantly reduced relative water contents, gas exchange attributes, plant height, yield and yield related attributes of wheat. In contrast, hydrogen peroxide, free proline levels, activities of malondialdehyde, and concentration of soluble protein were markedly increased under water stress condition. Application of various levels of Zn significantly improved the CAT, SOD, POD and ASP activities at 40% WHC compared with control treatment. Foliarly applied 10 and 15 mM Zn predominantly reduced the damaging impact of water stress by improving the plant status in the form of plant height, RWC and gas exchange attributes. Likewise, wheat plant treated with 10 mM Zn under water stress condition increased the grain yield by improving number of grains per spike, 100 grain weight and biological yield compared with control. Moreover, increasing Zn levels also increased Zn concentration in grains and leaves. Overall, this study suggests that optimum level of Zn (10 mM) might be promising for alleviating the adverse impacts of water stress and enhance the grain biofortification in wheat.     

褪黑素对盐胁迫下普通菜豆芽期核酸修复的调控机制

普通菜豆(Phaseolus vulgaris)是重要的食用豆作物, 然而其极易受盐胁迫危害, 导致产量下降。褪黑素能提高植物耐盐能力。为探明外源褪黑素调控普通菜豆耐盐能力的机制, 以普通菜豆品种奶花芸豆(GZ-YD014)为实验材料, 设置水(W, 对照)、盐胁迫(S)和盐胁迫+100 µmol∙L^-1褪黑素(M+S) 3个处理。结果发现, 盐胁迫抑制了普通菜豆胚根的生长, 使其长度、表面积、体积以及直径显著降低, 外源褪黑素可缓解盐胁迫对普通菜豆胚根生长的抑制。外施褪黑素显著降低盐胁迫下活性氧积累和丙二醛(MDA)含量, 提高保护酶(过氧化物酶、超氧化物歧化酶、过氧化氢酶以及抗坏血酸过氧化物酶)活性, 增加渗透调节物质(可溶性糖和可溶性蛋白)以及生长素(IAA)、赤霉素(GA)和玉米素(ZT)的含量, 降低脱落酸(ABA)含量。通过转录组分析挖掘出217个差异表达基因(DEGs), DEGs在GO富集中显著(P-value<0.05)富集到核酸相关条目上, 在KEGG富集中显著(P-value<0.05)富集到核酸损伤修复(包括碱基切除修复、错配修复以及核苷酸切除修复)通路。qRT-PCR以及RAPD分析结果表明, 核酸损伤修复通路为外源褪黑素调控普通菜豆耐盐能力的一种机制。该研究揭示了外源褪黑素对普通菜豆芽期耐盐能力的调控机制, 可为褪黑素应用于盐胁迫下普通菜豆增产提供理论依据。     

Role of Triacontanol in Counteracting the Ill Effects of Salinity in Plants: A Review

Soil salinity is one among the common environmental threats to agriculture. It adversely affects the physio-biochemical processes of plants that eventually lead to the reduction in growth, development and crop productivity. To cope with such adverse conditions, plants develop certain internal mechanisms, but under severe conditions these mechanisms fail to tolerate the salt stress. To overcome this problem, various strategies have been employed that help plants to mitigate salinity effects. Among the various strategies, the application of plant growth regulators (PGRs) has gained significant attention to induce salt tolerance in plants. A number of PGRs have been used so far. Among these, triacontanol (TRIA), a new PGR is gaining a lot of importance to enhance the plant growth, productivity and salinity tolerance in different crops. The utility of TRIA is dependent on its applied concentration. Its lower concentrations generally alleviate the salinity effects. However, the knowledge of its biosynthesis, signalling and its role particularly to mitigate salinity effect remains scanty. In the present article, the focus has been given on the role of exogenous applications of TRIA in the regulation of physio-biochemical characteristics especially plant growth, photosynthesis, nutrient acquisition, oxidative stress, antioxidant systems, compatible solutes, yield attributes and its mode of action in plants under salinity conditions. The salient features of the review may provide new insights on the role of TRIA in countering the ill effect of salinity in different crop plants.