甘草叶片形态结构和光合作用对干旱胁迫的响应

叶片结构在植物防御生物和非生物胁迫方面起着重要的作用,可通过合成、储存和分泌次生代谢产物提高植物抗性。以甘草幼苗为试材,采用盆栽控水自然干旱法,探讨叶片光合作用、气孔微形态和腺体形态对干旱胁迫的响应。结果表明:①随着干旱胁迫程度的加剧,叶片净光合速率(Pn)、气孔导度(Gs)和蒸腾速率(Tr)均呈先升高后降低的趋势;其中胞间CO2浓度(Ci)在重度干旱胁迫(severe stress,SS)时迅速增高。②随着干旱胁迫程度的加剧,叶片总气孔密度和气孔开张比呈先增大后减小的趋势;而气孔开张宽度呈逐渐减小的趋势。③随着干旱胁迫程度的加剧,叶片上表皮和下表皮腺体密度总数整体上呈增大的趋势,腺体颜色随着干旱胁迫程度的加剧逐渐加深,形状出现不规则褶皱和内陷。总之,甘草叶片表面的腺体特征参与抗旱逆境调节,从而避免干旱胁迫对甘草植株的伤害;在SS下,胁迫程度加速了气孔细胞的程序性死亡(PCD),甘草幼苗失去抗旱能力。     

小麦叶片光合作用与其渗透调节能力的关系

在缓慢干旱条件下,小麦叶片渗透调节能力在一定范围内随胁迫程度的加剧而增加,而在快速干旱下,渗透调节能力丧失。小麦叶片通过渗透调节使光合速率和气孔导度对水分胁迫的敏感性降低,叶片维持较高的电子传递能力、RuBP羧化酶活性和叶绿体光合能量转换系统活性,并推迟了小麦叶片光合速率受气孔因素限制向叶肉细胞光合活性限制转变的时间。     

盐分和水分胁迫对芦荟幼苗渗透调节和渗调物质积累的影响

用不同浓度NaCl和等渗聚乙二醇(PEG 6000)处理芦荟(Aloe vera L.)幼苗,10 d后测定叶片相对生长速率和厚度、叶片中主要有机溶质、无机离子含量及渗透调节能力.结果表明,-0.44、-0.88 MPa NaCl和PEG处理使芦荟叶片的相对生长速率和叶片厚度明显下降,且盐胁迫对幼苗生长的抑制和叶片含水量降低的效应明显高于等渗的水分胁迫,其叶片渗透调节能力随处理渗透势的降低而增加, -0.88 MPa PEG胁迫的芦荟幼苗的渗透调节能力高于等渗盐分胁迫.在主要渗透调节物质可溶性糖、有机酸、K 、Ca2 和Cl-中,-0.88 MPa PEG处理下含量比相同渗透势的NaCl处理下显著增加的是有机溶质,因此推断有机溶质含量高是PEG胁迫下渗透调节能力较强的主要因素.     

NaCl 胁迫对甘草生长及抗氧化酶活性的影响

目的:通过分析不同浓度NaCl胁迫下甘草生长和抗氧化酶活性的变化探讨甘草对盐分胁迫的适应性机理;方法:采用不同浓度的NaCl溶液(配成Hoagland液)处理盆栽一年生甘草,分别于35d、70d和105d取样,测定甘草株高、地上部分鲜、干重、根鲜、干重及甘草叶片SOD、POD、CAT活性,分析各生长指标与抗氧化酶活性的相关性;结果:NaCl胁迫70d和105d,0.6%和0.9%处理组的株高、地上部分鲜、干重及根鲜、干重均显著低于CK,SOD、POD及CAT活性均显著高于CK,经相关性分析得知,SOD、POD及CAT活性与各生长指标均负相关,其中POD活性与各生长指标极显著负相关;结论:甘草对NaCl胁迫的响应有胁迫时间和浓度的依赖性,在遭遇胁迫时,通过改变自身的生长和提高抗氧化酶活性,来提高机体的抗盐能力。     

渗透胁迫对皱果苋叶片渗透调节物质的影响

目的:研究渗透胁迫下皱果苋的渗透调节物质变化,探讨皱果苋的耐旱机理.方法:分别用浓度为5%、10%和20%PEG6000进行渗透胁迫,处 理皱果苋幼苗0、1、3、5和7d,取叶片测定各项生理指标.结果:随着渗 透胁迫时间的延长,皱果苋幼苗叶片中相对含水量(RWC)逐步下降;而脯氨酸和可溶性糖含 量上升;在5d,5%、10%、20%PEG胁迫下的叶片脯氨酸含量分别是对照的3.73、6.27、9.77 倍;而叶中可溶性糖含量分别是对照的2.87、3.68、5.21倍.胁迫3d,20%PEG处理的材料出 现萎焉现象,胁迫5d,10%PEG处理的材料开始萎焉;在5%和10%PEG胁迫下,可溶性蛋白含量 升高,但在20%PEG胁迫下,可溶性蛋白含量先升后降.结论:在适度的渗 透胁迫下,皱果苋叶片中的渗透调节物质使其具有较强的渗透能力,形成皱果苋耐旱性的内在基础.     

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。     

干旱胁迫下沙棘叶片细胞膜透性与渗透调节物质研究

研究了在干旱胁迫下沙棘幼林苗木渗透调节能力与沙棘耐旱性的关系。结果表明：长期轻度及中度干旱胁迫下渗透调节物质中可溶性糖、游离氨基酸、Pro在干旱中、后期累积显著增加而降低渗透势,使沙棘具备较强的渗透调节能力而表现为低水势耐旱特性;K^ 在干旱下无显著累积。渗透调节物质（可溶性糖、游离氨基酸、Pro）的共同作用,使长期轻度、中度干旱下沙棘叶片可溶性蛋白降解少,细胞膜透性和MDA含量增加缓慢,重度二进下也能在一定时间内保持稳定,这些物质是构成沙棘强耐旱性的内在基础。     

长期水分胁迫对小麦生育中后期根叶渗透调节能力、渗透调节物质的影响

以 2个抗旱性强的和 2个抗旱性弱的小麦品种为材料 ,研究了中度及严重水分胁迫对根系及叶片渗透调节能力的影响。结果表明 :随着水分胁迫的加剧 ,叶片的渗透调节能力增强 ,但在籽粒迅速扩大的灌浆期 ,叶片的渗透调节能力下降。去穗处理明显地提高叶片的渗透调节能力。说明叶片渗透调节能力的高低与同化物的供应及分配有关。不同品种根系渗透调节能力与叶片基本一致 ,但根系的渗透调节能力低于叶片。开花、灌浆期根系的渗透调节能力大大降低 ,严重水分胁迫下根系的渗透调节能力低于中度水分胁迫。这一方面与同化物的供应有关 ,另一方面严重水分胁迫还会对根细胞造成损伤 ,对根系的渗透调节能力产生影响。渗透调节物质的变化趋势与渗透调节能力基本一致。叶片中 K+对渗透调节的贡献最大 ;其次是可溶性糖 ,6种渗透调节物质排列顺序为 K+>可溶性糖 >游离氨基酸 >Ca2 +>Mg2 +>Pro。根系中仍以 K+占绝大部分 ,但根系中 Ca2 +也是不可忽视的成分之一。     

NaCl胁迫对甘草生长及抗氧化酶活性的影响

目的：通过分析不同浓度NaCl胁迫下甘草生长和抗氧化酶活性的变化探讨甘草对盐分胁迫的适应性机理;方法：采用不同浓度的NaCl溶液（配成Hoagland液）处理盆栽一年生甘草,分别于35d、70d和105d取样,测定甘草株高、地上部分鲜、干重、根鲜、干重及甘草叶片SOD、POD、CAT活性,分析各生长指标与抗氧化酶活性的相关性;结果：NaCl胁迫70d和105d,0．6％和0．9％处理组的株高、地上部分鲜、干重及根鲜、干重均显著低于CK,SOD、POD及CAT活性均显著高于CK,经相关性分析得知,SOD、POD及CAT活性与各生长指标均负相关,其中POD活性与各生长指标极显著负相关;结论：甘草对NaCl胁迫的响应有胁迫时间和浓度的依赖性,在遭遇胁迫时,通过改变自身的生长和提高抗氧化酶活性,来提高机体的抗盐能力。     

盐胁迫下沙棘的渗透调节效应

分别用含有0、100、200和300mmol LNaCl的Hoagland培养液处理1年生沙棘(HippophaerhamnoidesL.)苗30d后,测定其鲜重,干重,含水量,可溶性糖、脯氨酸和无机离子(Na 、Cl-)的含量及叶片渗透势和渗透调节能力。结果表明:100mmol LNaCl处理的沙棘地上部和根的鲜重和干重最大,其含水量也最大;NaCl浓度超过100mmol L时,沙棘地上部分和根的鲜重和干重随盐浓度增加而逐步下降,其下降的趋势为地上部大于根部。随NaCl浓度不断升高,沙棘体内Na 和Cl-浓度随之升高,茎叶和根系中Cl-含量明显高于Na ,对Na 的相对吸收量多于Cl-。沙棘对盐胁迫有一定的适应能力,随NaCl浓度的升高,沙棘叶内脯氨酸含量升高,可溶性糖含量增加,渗透势降低,渗透调节能力增强。本结果可为盐碱地营造沙棘林提供依据。     

Stress responses in Salix gracilistyla cuttings subjected to repetitive alternate flooding and drought

To determine the tolerance of Salix gracilistyla to repetitive alternate flooding and drought, we measured leaf stomatal conductance, pre-dawn water potential, osmotic adjustment, and biomass production under greenhouse conditions. We used a control and nine crossed treatments (F1-D1–F3-D3) in which we combined 1-, 2-, or 3-week floodings (F) and droughts (D). Leaf stomatal conductance was lowest in 3 weeks of flooding or drought when the preceding event (flood or drought) was also of a 3-week duration. Leaf pre-dawn water potential was reduced in 3 weeks of drought when preceded by 2 or 3 weeks of flooding. Cuttings had slight osmotic adjustments in repetitions of long floodings and droughts. During longer durations of drought in crossed experiments, plants had low root and shoot mass, few hypertrophic lenticels, and reduced leaf mass; when flooding duration increased in crossed experiments, root mass was reduced, there were more hypertrophic lenticels, and the leaf area was reduced. Cuttings achieved stress tolerance by inhibition of transpiration, osmotic adjustment, reduction of transpiration area, and development of hypertrophic lenticels. Stress tolerance was weak when repetitive 2- or 3-week floodings were combined with 3-week droughts. The duration of flooding and drought periods under which S. gracilistyla achieves stress tolerance may be critical in determining distributions along riverbanks.     

Physiological and biochemical tools useful in drought-tolerance detection in genotypes of winter triticale: accumulation of ferulic acid correlates with drought tolerance

BACKGROUND AND AIMS: The objectives of this study were to investigate whether a classification of triticale genotypes into drought-tolerant and drought-sensitive types based on field performance trials correlates with a classification based on measurements of some physiological and biochemical parameters in greenhouse conditions. In addition, an examination was carried out of whether ferulic acid, as the main origin of the blue fluorescence produced, contributes to drought tolerance. METHODS: Ten winter triticale genotypes were examined, five known to be drought tolerant and five drought sensitive. Measurements of the osmotic potential, leaf gas exchange, chlorophyll fluorescence, and blue and red fluorescence were performed. In addition, analysis of the total pool of phenolic compounds and ferulic acid as well as the measurements of PAL (l-phenylalanine ammonia-lyase) activity were carried out. KEY RESULTS: In agreement with field trials, three out of five cultivars ('Lamberto', 'Timbo' and 'Piano') were classified as drought tolerant. However, in the case of cultivar 'Babor', included in the group of drought-sensitive cultivars, the values obtained for some measured parameters were close to (F(v)(')/F(m)('), phenolics content, osmotic potential) or even better than (non-photochemical quenching, red and blue fluorescence, ferulic acid content) those for drought-tolerant genotypes. Cultivars 'Imperial', 'Ticino', 'Trimaran' and 'Boreas' were included in the drought-sensitive group, whereas cultivars 'Focus' and 'Kitaro' were included in the moderately sensitive group. CONCLUSIONS: The experiments confirmed that the period of flowering, the critical phase for plants as far as water demand is concerned, is suitable for plant screening and differentiation due to their tolerance to drought. The most important criteria which enabled creation of the ranking list of plants, from those sensitive to drought to those tolerant to drought, were the ability to perform the process of osmoregulation, the efficiency of the utilization of excitation energy by the photosynthetic apparatus and the functioning of protective mechanisms involving the level of ferulic acid in leaf tissues.     

荒漠绿洲过渡带一年生草本植物对干旱胁迫的响应

选取河西走廊荒漠绿洲过渡带典型一年生草本植物雾冰藜（Bassia dasyphylla）、虎尾草（Chloris virgata）和狗尾草（Setaria viridis）为研究对象,设置5个水分梯度（正常水分（CK）,轻度干旱（5d）、中度干旱（10d）、重度干旱（15d）,重度干旱（15d）复水）,分析了3种一年生草本植物生理和形态等性状对干旱胁迫的响应。结果表明：一年生草本植物可以通过生理反应（渗透调节）适应轻度和中度干旱胁迫,而通过个体形态来适应重度干旱胁迫。在轻度和中度干旱处理下,一年生草本植物通过调控叶片渗透调节物质脯氨酸、可溶性蛋白和可溶性糖维持叶片渗透压,提高保水能力,叶绿素含量增加,使丙二醛含量维持在较低的水平,同时,根系活力增强,有效促进了根系水分吸收;而在重度胁迫下,渗透调节物质作用降低,丙二醛含量迅速增加,导致可溶性蛋白含量下降,叶绿素分解加速,植物生长受到抑制,在有限的生物量下,一年生草本植物主要通过根系伸长、根长与茎长的比增加和减小茎长来适应重度干旱胁迫,最终导致了种子百粒重和结种数量下降。     

Growth,photosynthesis and water relations as affected by different drought regimes and subsequent recovery in <Emphasis Type="Italic">Medicago laciniata</Emphasis> (L.) populations

The aims of this study were to investigate the effects of water deficit and recovery on growth, photosynthesis and water relations in four Medicago laciniata populations from saharian (Ml-90), inferior arid (Ml-204), superior arid (Ml-306) and semi-arid (Ml-376) Tunisian regions. After 28 d of sowing with ample irrigation, the plants were subjected to 4 water regimes: optimal irrigation (100% of field capacity, FC), moderate drought (75% FC), severe drought (35% FC) and rewatering (plants submitted to 35% FC during 7 d, afterwards the plants were rewatered to 100% FC). Harvest was carried out after 28 d of treatments. The drought tolerance in M. laciniata populations was found to be increased particularly with increasing temperatures of collection site of the population. The Ml-204 and Ml-90 populations used mainly physiological strategies for survival under moderate water shortage. Higher severe drought tolerance in both signaled populations would be related to their lower photosynthesis metabolic impairment, relatively higher leaf RWC and greater osmotic potential decrease. The results suggest that plants with low values of leaf features are likely to maintain higher leaf RWC under sever drought. The largest decrease of osmotic potential was found associated with the solute accumulations such as proline and K⁺.     

Arbuscular mycorrhizal influence on leaf water potential, solute accumulation, and oxidative stress in soybean plants subjected to drought stress

This study investigated several aspects related to drought tolerance in arbuscular mycorrhizal (AM) soybean plants. The investigation included both shoot and root tissues in order to reveal the preferred target tissue for AM effects against drought stress. Non-AM and AM soybean plants were grown under well-watered or drought-stressed conditions, and leaf water status, solute accumulation, oxidative damage to lipids, and other parameters were determined. Results showed that AM plants were protected against drought, as shown by their significantly higher shoot-biomass production. The leaf water potential was also higher in stressed AM plants (-1.9 MPa) than in non-AM plants (-2.5 MPa). The AM roots had accumulated more proline than non-AM roots, while the opposite was observed in shoots. Lipid peroxides were 55% lower in shoots of droughted AM plants than in droughted non-AM plants. Since there was no correlation between the lower oxidative damage to lipids in AM plants and the activity of antioxidant enzymes, it seems that first the AM symbiosis enhanced osmotic adjustment in roots, which could contribute to maintaining a water potential gradient favourable to the water entrance from soil into the roots. This enabled higher leaf water potential in AM plants during drought and kept the plants protected against oxidative stress, and these cumulative effects increased the plant tolerance to drought.     

The role of solute accumulation, osmotic adjustment and changes in cell wall elasticity in drought tolerance in Ziziphus mauritiana (Lamk.)

Ber (Ziziphus mauritiana Lamk.) is a major fruit tree crop of the north-west Indian arid zone. In a study of the physiological basis of drought tolerance in this species, two glasshouse experiments were conducted in which trees were droughted during single stress-cycles. In the first experiment, during a 13 d drying cycle, pre-dawn leaf water (leaf) and osmotic () potentials in droughted trees declined from -0.5 and -1.4 MPa to -1.7 and -2.2 MPa, respectively, for a decrease in relative water content () of 14%. During drought stress, changes in sugar metabolism were associated with significant increases in concentrations of hexose sugars (3.8-fold), cyclitol (scyllo-inositol; 1.5-fold), and proline (35-fold; expressed per unit dry weight), suggesting that altered solute partitioning may be an important factor in drought tolerance of Ziziphus. On rewatering pre-dawn leaf and recovered fully, but remained depressed by 0.4 MPa relative to control values, indicating that solute concentration per unit water content had changed during the drought cycle.Evidence for osmotic adjustment was provided from a second study during which a gradual drought was imposed. Pressure-volume analysis revealed a 0.7 MPa reduction in osmotic potential at full turgor, with leaf at turgor loss depressed by 1 MPa in drought-stressed leaves. Coupled with osmotic adjustment, during gradual drought, was a 65% increase in bulk tissue elastic modulus (wall rigidity) which resulted in turgor loss at the same in both stressed and unstressed leaves. The possible ecological significance of maintenance of turgor potential and cell volume at low water potentials for drought tolerance in Ziziphus is discussed.Keywords: Ziziphus mauritiana, drought, solute accumulation, osmotic adjustment, proline.      

Comparative Water Relations of Phaseolus vulgaris L. and Phaseolus acutifolius Gray

Leaf area expansion, dry weight, and water relations of Phaseolus vulgaris L. and P. acutifolius Gray were compared during a drying cycle in the greenhouse to understand the characteristics which contribute to the superior drought tolerance of P. acutifolius. Stomates of P. acutifolius closed at a much higher water potential than those of P. vulgaris, delaying dehydration of leaf tissue. P. acutifolius had a more deeply penetrating root system, which also contributes to its drought tolerance. Root-shoot ratios did not differ between the two species either under well watered or water stressed conditions. Leaf osmotic potential was also similar in the two species, with no apparent osmotic adjustment during water stress. These results indicate that P. acutifolius postpones dehydration and suggest that sensitive stomates and a deeply penetrating root system are characteristics which, if incorporated into cultivated beans, might increase their drought tolerance.     

Molecular mapping of quantitative trait loci for drought tolerance in maize plants

Drought tolerance is one of the most important but complex traits of crops. We looked for quantitative trait loci (QTLs) that affect drought tolerance in maize. Two maize inbreds and their advanced lines were evaluated for drought-related traits. A genetic linkage map developed using RFLP markers was used to identify QTLs associated with drought-related traits. Twenty-two QTLs were detected, with a minimum of one and a maximum of nine for drought-related traits. A single-QTL was detected for sugar concentration accounting for about 52.2% of the phenotypic variation on chromosome 6. A single-QTL was also identified for each of the traits root density, root dry weight, total biomass, relative water content, and leaf abscisic acid content, on chromosomes 1 and 7, contributing to 24, 0.2, 0.4, 7, and 19% of the phenotypic variance, respectively. Three QTLs were identified for grain yield on chromosomes 1, 5, and 9, explaining 75% of the observed phenotypic variability, whereas four QTLs were detected for osmotic potential on chromosomes 1, 3, and 9, together accounting for 50% of the phenotypic variance. Nine QTLs were detected for leaf surface area on chromosomes 3 and 9, with various degrees of phenotypic variance, ranging from 25.8 to 42.2%. Four major clusters of QTLs were identified on chromosomes 1, 3, 7, and 9. A QTL for yield on chromosome 1 was found co-locating with the QTLs for root traits, total biomass, and osmotic potential in a region of about 15 cM. A cluster of QTLs for leaf surface area were coincident with a QTL for osmotic potential on chromosome 3. The QTLs for leaf area also clustered on chromosome 9, whereas QTLs for leaf abscisic acid content and relative water content coincided on chromosome 7, 10 cM apart. Co-location of QTLs for different traits indicates potential pleiotropism or tight linkage, which may be useful for indirect selection in maize improvement for drought tolerance.     

Co-existence of salt and drought tolerance in Triticeae

Cell membrane stability (CMS) technique was used to screen for drought tolerance, salt tolerant accessions of three Aegilops species, Ae. tauschii, Ae. cylindrica, Ae. geniculata and two hexaploid wheat (Tricitum aestivum L.) cultivars comprising salt tolerant LU-26 and drought tolerant Chakwal-86. The objectives were to see how valid it is for a salt tolerant plant to be drought tolerant as well and to identify the character(s) that may contribute to drought tolerance. Three moisture levels equal to 100, 50 and 25% saturation capacity of the soil were used for plant cultivation. Injury percentage (IP) based on in-vitro desiccation induced by polyethylene glycol (PEG) in leaf tissue was measured through the conductivity of the electrolyte leakage. Injury percentage decreased in all the test material with decrease in soil moisture contents. Ae. cylindrica exhibited minimum injury at 100% soil moisture level followed by Ae. tauschii and Ae. geniculata while drought tolerant wheat cultivars exhibited the maximum. The wheat cultivar Chakwal-86 has been developed for dry areas, with low soil moisture levels, and high water potential enhances the injury percentage. Aegilops cylindrica is a salt tolerant species and can thus tolerate water deficit conditions created due to low osmotic potential. Potassium appeared to play an important role in drought tolerance which was evident from high K+ contents and low K+ leakage from Aegilops cylindrica and drought tolerant wheat cultivar Chakwal-86. It was inferred from the study that salt tolerant species might prove drought tolerant in the areas where water deficit prevails due to the ability to create low intracellular osmotic potentials.