外生菌根对干旱胁迫的响应

从外生菌根真菌、外生菌根共生体以及外生菌根的间接作用等方面阐述外生菌根如何抵制干旱胁迫,并对未来我国外生菌根的研究提出了建议。干旱可以抑制外生菌根真菌的生长并降低其群落中真菌的多样性,干旱胁迫下外生菌根真菌子实体可以利用深度30cm以下的土壤水,子实体的表面积和体积比可作为筛选抗旱真菌的一个重要因子;在遭受干旱胁迫时,外生菌根共生体可以发生形态变化来应对干旱,同时增加了植株水分的吸收并改善了植物的光合作用、活性氧以及激素等相关代谢;外生菌根对植物生长的促进作用、增加土壤碳汇以及对其他根际微生物生长的促进作用等对宿主植物应对干旱胁迫有利。未来我国外生菌根研究应加强对干旱区优良菌-树组合的筛选工作,同时加大对乡土外生菌根真菌资源的调查力度,未来研究应重点向分子生物学领域推进。     

模拟干旱诱导对藜抗旱力的影响

以藜为研究材料,经过5年人工模拟干旱诱导,测定其耐旱形态结构及生理特征的改变以探讨提高植物抗旱的途径。结果表明,经模拟干旱诱导后藜叶片典型耐旱特征增加:叶片厚度和肉质度增加,比叶面积、饱和渗透势和蒸腾速率下降,渗透调节能力和持水力增强,临界饱和亏值增大,蒸腾效率提高。经干旱诱导形成耐旱特征后收获的种子种植于正常供水环境中长成的植株仍能保持其已形成的耐旱特征,在重度干旱胁迫下经过干旱诱导的植株各抗旱指标与对照相比有明显差异(P<0.01),证明藜是耐旱可变植物,可通过干旱诱导锻炼提高其抗旱性。     

过表达胡杨XTH基因能够提高烟草抗旱性

胡杨是典型的抗旱树种。挖掘和鉴定胡杨的耐旱基因对于提高植物抗旱性具有重要意义。木葡聚糖内转糖苷酶/水解酶（XTH）是植物细胞壁重构过程中的关键酶,在植物逆境胁迫响应中发挥重要作用。我们前期已从胡杨叶片中克隆了PeXTH基因。本文利用Real-time PCR检测PeXTH基因在干旱胁迫下的表达水平。在此基础上,构建植物表达载体pMDC85-PeXTH,通过农杆菌介导法将PeXTH基因转入烟草,分析过表达PeXTH基因烟草的抗旱性。研究发现,胡杨叶片中PeXTH基因的表达受干旱胁迫诱导。干旱处理后,转PeXTH基因烟草的萌发率明显高于野生型烟草;与野生型植株相比,转基因植株的叶片失水速率明显降低。干旱胁迫下,转基因烟草的气孔开度仅为野生型烟草的51.2%～53.6%。结果表明,过表达PeXTH基因能够提高烟草的抗旱性。本研究丰富了对胡杨PeXTH基因功能的认识,为植物抗旱分子育种提供了重要的基因资源。     

施磷对干旱胁迫下箭竹根际土壤养分及微生物群落的影响

以箭竹及其根际土壤作为研究对象,采用两因素随机区组实验,设置2种水分处理（正常浇水和干旱胁迫）和2种施磷量处理（施磷和不施磷）,探究施磷对干旱胁迫下箭竹根际土壤养分及微生物群落结构和多样性的影响。结果表明：（1）干旱胁迫显著降低了箭竹根际土壤中微生物量碳、可溶性有机氮和有效磷的含量,虽对箭竹根际土壤微生物群落的多样性无显著影响,但显著降低了箭竹根际土壤中总PLFA（phospholipid fatty acid contents）的含量和真菌、细菌、革兰氏阳性菌与革兰氏阴性菌的PLFA含量以及革兰氏阳性菌/革兰氏阴性菌的PLFA比值,显著改变了箭竹根际土壤微生物群落结构,结果显著降低了箭竹的生物量。（2）施磷显著增加了受旱箭竹根际土壤中微生物量碳和有效磷的含量,虽大体上对受旱箭竹根际土壤微生物群落的多样性无显著影响,但显著增加了受旱箭竹根际土壤中总PLFA和真菌PLFA的含量,并在一定程度上增加了细菌、革兰氏阳性菌、革兰氏阴性菌和放线菌的PLFA含量以及革兰氏阳性菌/革兰氏阴性菌和真菌/细菌的PLFA比值,也在一定程度上改善了受旱箭竹根际土壤微生物群落结构,从而改善受旱箭竹的生长。（3）主成分分析表明,干旱对箭竹根际土壤微生物群落结构的影响显著,而施磷的影响不明显。（4）相关分析发现,箭竹根际土壤微生物群落结构与箭竹根际土壤微生物量碳、可溶性有机氮及箭竹生物量呈显著正相关。综上,干旱降低了箭竹根际土壤养分含量和微生物生物量,改变了箭竹根际土壤微生物群落结构,抑制了箭竹的生长;施磷能增加受旱箭竹根际土壤养分含量和微生物生物量,改善受旱箭竹根际土壤微生物群落结构,进而改善受旱箭竹的生长。     

抗旱相关基因在烟草中的应用研究进展

干旱是影响烟草正常生长、发育、产量和烟叶品质的一个重要逆境因子。在干旱胁迫下,植物体内会通过激发一些抗旱基因的表达来增强植物的抗旱能力。目前,很多抗旱相关的功能蛋白基因和调控蛋白基因已被克隆并在烟草中实现了遗传转化,外源抗旱基因的表达提高了转基因烟草的抗旱能力。抗旱基因的克隆为烟草抗旱新品种的培育奠定了良好的分子基础,系统深入地研究抗旱相关基因在干旱胁迫条件下的表达与调控,可为通过基因工程手段提高烟草的抗旱能力开辟新途径,同时也能为其他农作物的抗旱分子育种和品种改良提供基因资源。     

干旱胁迫对小麦幼苗根系生长和叶片光合作用的影响

采用水培试验方法,以2个耐旱性不同的小麦品种(敏感型望水白和耐旱型洛旱7号)为材料,研究了干旱胁迫对小麦幼苗根系形态、生理特性以及叶片光合作用的影响,以期揭示小麦幼苗对干旱胁迫的适应机制.结果表明： 干旱胁迫下,2个小麦品种幼苗的根系活力显著增大,而根数和根系表面积受到抑制;干旱胁迫降低了望水白的叶片相对含水量,提高了束缚水/自由水,而对洛旱7号无显著影响;干旱胁迫降低了2个小麦品种叶片的叶绿素含量、净光合速率、蒸腾速率、气孔导度和胞间CO2浓度,但随胁迫时间的延长,洛旱7号的叶绿素含量和净光合速率与对照差异不显著;干旱胁迫降低了2个小麦品种幼苗的单株叶面积,以及望水白的根系、地上部和植株生物量,而对洛旱7号无显著影响.水分胁迫下,耐旱型品种可以通过提高根系活力、保持较高的根系生长量来补偿根系吸收面积的下降,保持较高的根系吸水能力,进而维持较高的光合面积和光合速率,缓解干旱对生长的抑制.     

干旱胁迫对小麦幼苗根系生长和叶片光合作用的影响

采用水培试验方法,以2个耐旱性不同的小麦品种(敏感型望水白和耐旱型洛旱7号)为材料,研究了干旱胁迫对小麦幼苗根系形态、生理特性以及叶片光合作用的影响,以期揭示小麦幼苗对干旱胁迫的适应机制.结果表明： 干旱胁迫下,2个小麦品种幼苗的根系活力显著增大,而根数和根系表面积受到抑制;干旱胁迫降低了望水白的叶片相对含水量,提高了束缚水/自由水,而对洛旱7号无显著影响;干旱胁迫降低了2个小麦品种叶片的叶绿素含量、净光合速率、蒸腾速率、气孔导度和胞间CO2浓度,但随胁迫时间的延长,洛旱7号的叶绿素含量和净光合速率与对照差异不显著;干旱胁迫降低了2个小麦品种幼苗的单株叶面积,以及望水白的根系、地上部和植株生物量,而对洛旱7号无显著影响.水分胁迫下,耐旱型品种可以通过提高根系活力、保持较高的根系生长量来补偿根系吸收面积的下降,保持较高的根系吸水能力,进而维持较高的光合面积和光合速率,缓解干旱对生长的抑制.     

转P_(rd29A)-ipt基因对烟草根及侧芽生长的影响

利用异戊烯基转移酶(isopentenyl-transferases,ipt)基因转化植物,可明显提高抗逆性和抗病性,延缓叶片衰老。逆境胁迫常会对植物造成很大的伤害,拟南芥的Prd29A启动子受干旱、盐及冷胁迫诱导。构建了Prd29A-ipt植物表达载体,通过农杆菌介导转化普通烟草,获得了能够正常生长的转基因植株。通过表型观察发现,转Prd29A-ipt烟草具有一定的组成型表达,降低了烟草的顶端优势,促进了烟草侧芽的生长,同时,对根的伸长有一定的抑制作用。     

增施CO2对植物修复土壤DEHP污染的影响

修复效率低一直是植物修复技术需要解决的关键问题之一.基于我国的CO2减排压力和CO2对植物生长的必要性,选择C3植物绿豆和C4植物玉米作为修复植物,以DEHP为目标污染物,探索增施CO2对植物修复土壤DEHP污染的影响.结果表明:DEHP对两种植物生长和根际微环境都产生了抑制性影响.增施CO2后,两种植物地上干质量显著增加,叶片SOD酶活性明显下降,根际土壤碱性磷酸酶活性增加,根际微生物群落结构改变,根际耐DE-HP胁迫微生物数量增加,表明增施CO2对促进植物生长、增强植物抗DEHP胁迫能力、改善根际微环境有积极作用.增施CO2还促进了两种植物对DEHP的吸收,特别是植物地下部分.这些共同作用导致增施CO2后的两种植物根际DEHP残留浓度明显下降,土壤污染植物修复效率提高.整体上看,增施CO2对C3植物绿豆的影响明显大于C4植物玉米.可以将增施CO2作为强化植物修复过程的措施之一.     

干旱与盐胁迫对花生根际土壤细菌群落结构和花生产量的影响

以花生品种花育25号为试验材料,采用盆栽试验研究了开花期干旱和盐分胁迫对花生生长发育和荚果产量的影响,并运用高通量测序技术分析干旱、盐胁迫及旱盐双重胁迫下,花生根际土壤细菌群落结构的变化特征。结果表明: 不同胁迫处理花生根际土壤细菌群落均以变形菌门、放线菌门、Saccharibacteria、绿弯菌门、蓝藻菌门和酸杆菌门为主。干旱、盐胁迫及旱盐双重胁迫均不同程度降低了变形菌门和放线菌门的相对丰度,但显著提高了蓝藻菌门的含量,且旱盐双重胁迫较其单一胁迫引起的根际蓝藻菌门丰度变化更显著。土壤细菌功能预测分析显示,信号转导机制、防御机制及翻译后修饰、蛋白质周转和分子伴侣等相关功能在旱盐双重胁迫的细菌中活性更强,可能对花生生长及胁迫应答具有重要影响。统计学分析显示,开花期干旱、盐胁迫和旱盐双重胁迫严重影响花生生长发育,并显著降低产量。研究结果可为通过改良土壤微生物环境来提高植物胁迫耐受性提供参考。     

Induction of abiotic stress tolerance in plants by endophytic microbes

Endophytes are micro‐organisms including bacteria and fungi that survive within healthy plant tissues and promote plant growth under stress. This review focuses on the potential of endophytic microbes that induce abiotic stress tolerance in plants. How endophytes promote plant growth under stressful conditions, like drought and heat, high salinity and poor nutrient availability will be discussed. The molecular mechanisms for increasing stress tolerance in plants by endophytes include induction of plant stress genes as well as biomolecules like reactive oxygen species scavengers. This review may help in the development of biotechnological applications of endophytic microbes in plant growth promotion and crop improvement under abiotic stress conditions.

Significance and Impact of the Study

Increasing human populations demand more crop yield for food security while crop production is adversely affected by abiotic stresses like drought, salinity and high temperature. Development of stress tolerance in plants is a strategy to cope with the negative effects of adverse environmental conditions. Endophytes are well recognized for plant growth promotion and production of natural compounds. The property of endophytes to induce stress tolerance in plants can be applied to increase crop yields. With this review, we intend to promote application of endophytes in biotechnology and genetic engineering for the development of stress‐tolerant plants.     

Microbial rescue to plant under habitat-imposed abiotic and biotic stresses

Habitat-imposed abiotic and biotic stress is a serious condition and is also a land-degradation problem in arid and semi-arid regions, causing major problem for crop productivity. Most of the cultivable and a least half of irrigated lands around the world are severely affected by environmental stresses. However, in these conditions, there are plant populations successfully adapted and evolutionarily different in their strategy of stress tolerance. Vascular plants do not function as autonomous individuals, but house diverse communities of symbiotic microbes. The role of these microbes can no longer be ignored. Microbial interactions are critical not only for host but also for fungal survival in stressed environments. Plants benefit extensively by harboring these associated microbes; they promote plant growth and confer enhanced resistance to various pathogens by producing antibiotics. To date, improvements in plant quality, production, abiotic and biotic stress resistance, nutrient, and water use have relied largely on manipulating plant genomes by breeding and genetic modification. Increasing evidence indicates that the function of symbiotic microbes seems to parallel more than one of these characteristics.     

The pepper extracellular peroxidase CaPO2 is required for salt, drought and oxidative stress tolerance as well as resistance to fungal pathogens

In plants, biotic and abiotic stresses regulate the expression and activity of various peroxidase isoforms. Capsicum annuum EXTRACELLULAR PEROXIDASE 2 (CaPO2) was previously shown to play a role in local and systemic reactive oxygen species bursts and disease resistance during bacterial pathogen infection. Here, we report CaPO2 expression patterns and functions during conditions of biotic and abiotic stress. In pepper plants, CaPO2 expression was strongly induced by abscisic acid, but not by defense-related plant hormones such as salicylic acid, ethylene and jasmonic acid. CaPO2 was also strongly induced by abiotic and biotic stress treatments, including drought, cold, high salinity and infection by the hemibiotrophic fungal pathogen Colletotrichum coccodes. Loss-of-function of CaPO2 in virus-induced gene silenced pepper plants led to increased susceptibility to salt- and osmotic-induced stress. In contrast, CaPO2 overexpression in transgenic Arabidopsis thaliana plants conferred enhanced tolerance to high salt, drought, and oxidative stress, while also enhancing resistance to infection by the necrotrophic fungal pathogen Alternaria brassicicola. Taken together, these results provide evidence for the involvement of pepper extracellular peroxidase CaPO2 in plant defense responses to various abiotic stresses and plant fungal pathogens.     

Transgenic tobacco plants expressing grass <Emphasis Type="Italic">AstEXPA1</Emphasis> gene show improved performance to several stresses

Expansins are cell wall-loosening proteins and now widely accepted to associate with the plant resistance against various abiotic stresses. In this study, we cloned an expansin gene of AstEXPA1 from Agrostis stolonifera, a heat-resistant creeping bentgrass cultivar, and transformed it into tobacco plants. Physiological index test showed that the transgenic lines were resistant to various abiotic stresses of drought, heat, cold, and salt in comparison to non-transgenic plants. Comprehensive analysis of four physiological response indices showed that the transgenic plants performed much better resistance to drought, following to heat, cold and salt stress, respectively. Meanwhile soluble sugar content displayed more weight to plant resistance by over-expressing AstEXPA1 gene, followed as proline content, REL, and MDA content. The results here would expand our understanding of the expansin roles and drive better insights into plant molecular breeding against stress.     

Overexpression of a Harpin-encoding gene hrf1 in rice enhances drought tolerance

Harpin proteins are well known as eliciters that induce multiple responses in plants, such as systemic acquired resistance, hypersensitive response, enhancement of growth, resistance to the green peach aphid, and tolerance to drought. Overexpression of Harpin-encoding genes enhances plant resistance to diseases in tobacco, rice, rape, and cotton; however, it is not yet known whether the expression of Harpin-encoding genes in vivo improves plant tolerance to abiotic stresses. The results of this study showed that overexpression of a Harpin-encoding gene hrf1 in rice increased drought tolerance through abscisic acid (ABA) signalling. hrf1- overexpression induces an increase in ABA content and promotes stomatal closure in rice. The hrf1 transgenic rice lines exhibited a significant increase in water retention ability, levels of free proline and soluble sugars, tolerance to oxidative stress, reactive oxygen species-scavenging ability, and expression levels of four stress-related genes, OsLEA3-1, OsP5CS, Mn-SOD, and NM_001074345, under drought stress. The study confirmed that hrf1 conferred enhanced tolerance to drought stress on transgenic crops. These results suggest that Harpins may offer new opportunities for generating drought resistance in other crops.     

Relationship between calcium decoding elements and plant abiotic-stress resistance

Serving as an important second messenger, calcium ion has unique properties and universal ability to transmit diverse signals that trigger primary physiological actions in cells in response to hormones, pathogens, light, gravity, and stress factors. Being a second messenger of paramount significance, calcium is required at almost all stages of plant growth and development, playing a fundamental role in regulating polar growth of cells and tissues and participating in plant adaptation to various stress factors. Many researches showed that calcium signals decoding elements are involved in ABA-induced stomatal closure and plant adaptation to drought, cold, salt and other abiotic stresses. Calcium channel proteins like AtTPC1 and TaTPC1 can regulate stomatal closure. Recently some new studies show that Ca²⁺ is dissolved in water in the apoplast and transported primarily from root to shoot through the transpiration stream. The oscillating amplitudes of [Ca²⁺]_o and [Ca²⁺]_i are controlled by soil Ca²⁺ concentrations and transpiration rates. Because leaf water use efficiency (WUE) is determined by stomatal closure and transpiration rate, so there may be a close relationship between Ca²⁺ transporters and stomatal closure as well as WUE, which needs to be studied. The selection of varieties with better drought resistance and high WUE plays an increasing role in bio-watersaving in arid and semi-arid areas on the globe. The current paper reviews the relationship between calcium signals decoding elements and plant drought resistance as well as other abiotic stresses for further study.