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.     

Salicylic Acid-Mediated Regulation of Morpho-Physiological and Yield Attributes of Wheat and Barley Plants in Deferring Salinity Stress

Salinity has been observed to be a global problem that impede the physiological characteristics of plants. Salicylic acid (SA) as a phytohormone play multifaceted role in plants in terms of development as well as stress management. The current study was conducted to evaluate the effect of salinity and salicylic acid on the performance of wheat and barley plants under field experimentation followed by on-farm study to validate the results. This research was firstly conducted in a 4-year research barley field (2012–2013 and 2013–2014) and wheat (2014–2015 and 2015–2016) and subsequently in an on-farm research in four places (2017–2018). Results depicted that salinity decreased plant yield components and altered ion concentrations (Na⁺/K⁺) causing reduced grain and biological yield. However, SA foliar application induced yield components, especially grain number of plants in both years in non-saline and saline conditions. Exogenously SA application not only led to higher grain yield of barley and wheat but also significantly improved their salt tolerance. Our findings revealed that optimum SA concentrations for achieving highest barley yield were 0.85 and 0.78 mM under saline and non-saline conditions, respectively, while on-farm scale studies observed that foliar application of SA increased grain and biological yield of wheat in Ardakan, Ashkzar (saline soil and water) and Mehrabad (non-saline field) regions. There was no significant effect in Tijerd, a completely non-saline field. The grain yields were higher in SA-treated Ardakan, Ashkzar, and Mehrabad plants in field by 19, 16, and 15%, respectively. Based on present detailed studies, it was concluded that SA improved salinity tolerance and increased crop yield. So, optimum concentration (1.0–1.5 mM) with proper time application (double ridges), SA increased wheat and barley yields up to 20%. Therefore, SA priming could be used as a potent strategy to cope up salinity stress from plants.

     

外源脱落酸对干旱胁迫下滇润楠幼苗生长及生理特性的影响

以滇润楠一年生实生苗为试验材料,研究在良好水分条件(土壤含水量为70%～75%田间持水量)、轻度干旱胁迫及重度干旱胁迫处理下(50%～55%和30%～35%田间持水量)进行外源脱落酸(ABA)喷施对其生长及生理特性的影响。结果表明: 干旱胁迫使得滇润楠幼苗叶片的相对含水量、株高和生物量显著下降,净光合速率及叶绿素荧光参数(PSⅡ最大光化学效率,F_v/F_m)有不同程度的下降,而根冠比、膜脂过氧化产物丙二醛(MDA)含量显著增加。外源ABA的喷施可提高干旱胁迫下滇润楠幼苗的适应性,尤其是重度干旱下,外源ABA显著提高了叶片相对含水量21.0%,同时增加了植株株高和生物量的累积,提高了根冠比,为良好水分条件的2.1倍;减少了干旱下膜脂过氧化产物MDA的累积,提高了抗氧化酶过氧化氢酶、超氧化物岐化酶的活性,显著增加了脯氨酸的含量,为良好水分条件的7.7倍。外源ABA的喷施显著缓解了干旱胁迫对植株光合器官的不利影响,减少干旱引起的叶片净光合速率及气孔导度的下降,并且减轻了PSⅡ受到干旱的伤害程度,重度干旱下喷施ABA的植株的F_v/F_m显著高于未喷施ABA的植株。外源ABA的喷施可以减轻干旱对滇润楠植株的伤害,提高其抗旱性。     

The effect of take-all disease on gas-exchange rates and biomass in two winter wheat lines with different drought response

There have been no studies of the effect of take-all on leaf gas-exchange rates, despite the fact that take-all severely restricts plant water and nutrient uptake, which results in significant biomass and grain yield reduction. Here we describe the effect of inoculation with Gaeumannomyces graminis (Sacc.) var. tritici (Ggt) on carbon assimilation rate (A) and biomass production of wheat plants grown under two water regimes. We show that the impact of Ggt inoculation on plant growth and leaf A may be through reduced photosynthetic capacity of the leaves and not water stress per se. The nature of this reduced photosynthetic capacity remains uncertain but may involve nutrient deficiency and different enzymes produced by the fungus. In each of the 3 years the experiment was conducted, Ggt significantly reduced A, i.e. at anthesis by 18% in 2000, 15% in 2001, and 12% in 2002. In agreement with other field studies, Ggt reduced tiller number and production of all plant components, mostly root dry mass and grain mass per plant. Highly significant negative correlations were found between disease rating and A in all years, showing that at disease ratings equal or higher than 3 (on a scale from 1 to 4) A could practically be zero. While A decreased, intercellular CO₂ concentration increased or did not change, and stomatal conductance was relatively high. In addition, A was more reduced under high than under low soil moisture content. These results support the idea that water stress per se did not contribute to the observed reduction of A. The mechanism of photosynthetic capacity reduction due to the Ggt root-rotting fungus is of interest as it may lead to the molecular mechanisms of plant resistance and ultimately to the development of take-all resistant plants.     

全膜微垄沟穴播对春小麦土壤水热环境的影响及其光合和产量效应

减弱春季寒旱生境限制是提高甘肃中东部旱地春小麦产量的关键要素之一。本研究于2016—2018年在甘肃中部半干旱旱作区开展大田试验,以‘陇春35号’为供试品种,设置全膜微垄沟穴播(PRF)、全膜覆土穴播(PMS)和露地穴播(CK)3个处理,测定春小麦不同生育期0～300 cm土层的土壤含水量、0～25 cm土壤温度、叶片生物量、叶片叶绿素(SPAD)、光合速率、蒸腾速率和作物产量,从土壤水热-冠层发育-产量角度揭示PRF处理对土壤水热环境、水分利用效率(WUE)和产量的影响。结果表明: 与CK相比,PRF和PMS处理0～25 cm土层的土壤温度在苗期分别提高2.8和2.5 ℃,灌浆-成熟期分别降低1.4和0.9 ℃;0～300 cm土壤贮水量在播前-苗期分别增加59.7和41.8 mm;0～300 cm耗水量在苗期-灌浆期分别提高46.1和39.8 mm。与PMS处理相比,PRF处理的小麦苗期温度提高0.3 ℃,灌浆-成熟期降低0.5 ℃;播前-苗期0～300 cm土壤贮水量增加18.0 mm,拔节-成熟期耗水量提高13.0 mm。基于对土壤水热条件的优化,PRF和PMS处理的叶片生物量、SPAD值、苗期-灌浆期叶片净光合速率、蒸腾速率均显著高于CK,且PRF处理均显著高于PMS处理。PRF处理比PMS处理和CK分别增产9.1%和36.5%,WUE分别提高5.9%和30.8%。因此,PRF处理能提高苗期地温,降低灌浆-成熟期地温,促进春小麦苗期-灌浆期的耗水,提高了春小麦叶片SPAD值和生物量,增强春小麦苗期-灌浆期旗叶的光合功能,从而实现增产和水分高效利用,而且这一优势在欠水年份(2016和2017年)更加明显。     

Effects of drought-rewatering-drought on photosynthesis and growth of maize

Aims Our objective was to investigate the responses of maize photosynthesis and growth to repeated drought.Methods Maize seedlings were exposed to different soil water deficit for three weeks, then rewatering for one week, and again to different water deficit for three weeks, to examine the effects of repeated drought on photosynthesis and growth.Important findings After the first water deficit treatments, under severe drought, plant height, total leaf area of individual plant, shoot and root biomass declined significantly, also transpiration rate (T_r), stomatal conductance (G_s), intercellular CO₂ concentration (C_i), net photosynthetic rate (P_n), maximum net photosynthetic rate (A_max), but light compensation point and dark respiration rate increased significantly. Under medium drought, plant height, leaf area, and shoot biomass decreased significantly, but root biomass did not vary, hence, the ratio of roots to shoots (R/S) increased. Moreover, plants did not show significant differences in photosynthetic parameters. After rewatering, photosynthesis and growth rate of plants previously exposed to water deficit could recover to the levels of well-watered plants, but plant height and leaf area did not recover to the levels of the control. When maize were subjected to recurrent drought, plants pre-exposed to medium drought showed no significant difference in plant height, biomass, and photosynthetic parameters, but a significant decrease in leaf area, compared to plants only exposed to second medium drought. Plants pre-exposed to severe drought had significantly higher T_r, G_s, C_i, P_n, A_max, and, apparent quantum yield but significantly lower plant height, leaf area, and biomass than plants without previous exposure. These results indicated that the first severe drought significantly reduced photosynthetic capacity and maize growth, rewatering could recover photosynthesis and growth rate to the levels of well-watered plants, but could not eliminate the adverse influence of the first drought on growth. The first medium drought could stimulate the growth of maize root system and significantly increased R/S, which can enhance maize drought resistance to subsequent repeated drought, and maintain the total biomass in the control level; the first severe drought could enhance maize drought resistance to subsequent repeated drought in the aspect of photosynthesis, but could not compensate for the adverse effect of early drought on plant growth. Hence, in practice, drought hardening should be limited in the level of medium drought, and avoiding severe drought.     

干旱-复水-再干旱处理对玉米光合能力和生长的影响

为了探求玉米(Zea mays)光合作用和生长对重复干旱的响应机制, 采用盆栽试验, 分别测定了不同程度土壤干旱处理3周时、随后复水1周时以及再次不同程度干旱处理3周时玉米幼苗光合参数和生长的变化。第一次土壤干旱处理后, 重度干旱处理显著降低玉米株高、单株总叶面积、地上部分及根系生物量以及叶片的蒸腾速率(T_r)、气孔导度(G_s)、胞间CO₂浓度(C_i)、净光合速率(P_n)和最大净光合速率(A_max), 但显著提高光补偿点和暗呼吸速率; 中度干旱处理同样显著降低玉米株高、叶面积和地上部分生物量, 但对根系生物量无影响, 因而根冠比增大, 对上述光合参数的负效应也不具有显著性。复水可使前期经受中度和重度干旱处理的玉米植株的光合能力和生长速率恢复到正常水分条件下生长的植株的水平, 但株高和叶面积没有恢复到对照水平。当玉米再次经受水分亏缺处理时, 与只遭受第二次中度或重度干旱处理的植株相比, 经历过前期中度干旱处理的植株的株高、生物量和光合参数没有显著变化, 但叶面积显著下降; 经历过前期重度干旱处理植株的T_r、G_s、C_i、P_n、A_max和表观量子效率显著升高, 而株高、叶面积和生物量显著降低。综上所述, 第一次重度干旱处理显著降低玉米叶片的光合能力和生长, 复水可使光合能力和生长速率恢复到正常水分条件下生长植株的水平, 但不能消除前期干旱对生长产生的不利影响。前期中度干旱可以刺激玉米根系的生长和显著提高根冠比, 有利于提高对二次干旱的抵抗能力, 并使总的生物量保持在对照水平, 而前期重度干旱处理虽然在光合作用上能提高植株对二次干旱的抵御能力, 但不能弥补前期干旱处理对生长的不利影响。因此, 在生产实践中, 如果进行抗旱锻炼, 应限制在中度干旱水平, 避免重度干旱。     

不同供水条件下冬小麦叶与非叶绿色 器官光合日变化特征

为揭示小麦叶片与非叶绿色器官的光合活性在一日中的变化特性及其在器官间的差异性,探讨群体及不同器官光合日变化对不同供水条件的响应特征,在田间设置生育期不灌水(I0)、灌2水(I2,拔节水＋开花水)和灌4水(I4,起身水+孕穗水+开花水+灌浆水)3个处理,于灌浆期测定了群体光合与呼吸速率的日变化, 旗叶片、叶鞘、穗、穗下节间各器官光合速率、蒸腾速率、气孔导度及叶绿素荧光参数的日变化。结果表明,灌浆期小麦穗和穗下节间光合速率日变化呈单峰曲线,而旗叶叶片与旗叶鞘光合速率均呈双峰型,表现出不同程度的午休。随着灌水次数减少,各器官光合速率降低,叶片对严重水分亏缺的反应大于各非叶器官。器官光合速率的日变化与F_v/F_m变化相一致,而与气孔导度日变化有较大差异。各器官上午的累积光合量均高于下午,上午光合量占日总光合量的比例为51％-62％,随着灌水次数减少而增大。不同灌水处理群体光合速率、呼吸速率日变化均未出现午休现象。春季浇2水处理与春浇4水处理相比,灌浆期群体光合速率及日光合积累量没有显著差异。综合研究认为,小麦叶与非叶器官光合性能及其日变化特征有较大不同,非叶光合对水分亏缺的敏感性低于叶片,生育期浇2水可以获得与浇4水相似的群体日光合积累量。     

氮肥后移对抽穗后水分胁迫下冬小麦光合特性及产量的影响

采用子母桶栽土培法模拟冬小麦抽穗后不同的水分胁迫状态,研究了氮肥后移对冬小麦光合特性及产量的影响.设置3个氮肥处理,分别为N₁(基肥∶拔节肥∶开花肥=10∶0∶0)、N₂(6∶4∶0)和N₃(4∶3∶3),模拟冬小麦抽穗后2种水分胁迫(渍水胁迫、干旱胁迫),设正常供水为对照.结果表明：相同供水条件下,N₂和N₃处理较N₁处理显著提高冬小麦灌浆期旗叶的SPAD和光合速率,确保了收获时较高的穗数、穗粒数和地上部分生物量;氮肥后移处理显著提高了冬小麦的耗水量,但其籽粒产量和水分利用效率也显著提高.相同氮肥条件下,干旱胁迫和渍水胁迫处理较正常供水显著降低了冬小麦开花期和灌浆期旗叶的光合速率、千粒重、穗粒数和产量.与正常供水相比,各氮肥条件下干旱胁迫和渍水胁迫处理花后旗叶光合速率及籽粒产量的减小幅度均表现为N₁＞N₂＞N₃.表明氮肥后移通过提高旗叶SPAD、减缓花后旗叶光合速率的下降幅度、增加地上部分干物质积累量,调控产量及其构成要素,以减轻逆境灾害(干旱和渍水胁迫)对产量的影响.     

Field response of wheat to arbuscular mycorrhizal fungi and drought stress

Mycorrhizal plants often have greater tolerance to drought than nonmycorrhizal plants. This study was conducted to determine the effects of arbuscular mycorrhizal (AM) fungi inoculation on growth, grain yield and mineral acquisition of two winter wheat (Triticum aestivum L.) cultivars grown in the field under well-watered and water-stressed conditions. Wheat seeds were planted in furrows after treatment with or without the AM fungi Glomus mosseae or G. etunicatum. Roots were sampled at four growth stages (leaf, tillering, heading and grain-filling) to quantify AM fungi. There was negligible AM fungi colonization during winter months following seeding (leaf sampling in February), when soil temperature was low. During the spring, AM fungi colonization increased gradually. Mycorrhizal colonization was higher in well-watered plants colonized with AM fungi isolates than water-stressed plants. Plants inoculated with G. etunicatum generally had higher colonization than plants colonized with G. mosseae under both soil moisture conditions. Biomass and grain yields were higher in mycorrhizal than nonmycorrhizal plots irrespective of soil moisture, and G. etunicatum inoculated plants generally had higher biomass and grain yields than those colonized by G. mosseae under either soil moisture condition. The mycorrhizal plants had higher shoot P and Fe concentrations than nonmycorrhizal plants at all samplings regardless of soil moisture conditions. The improved growth, yield and nutrient uptake in wheat plants reported here demonstrate the potential of mycorrhizal inoculation to reduce the effects of drought stress on wheat grown under field conditions in semiarid areas of the world.     

矿井废水灌溉对小麦生理特性及重金属积累的影响

以井水灌溉为对照 (CK),采用盆栽试验研究了矿井废水灌溉对小麦生理特性和重金属积累的影响.设置了3个矿区废水灌溉处理:洗煤废水(T₁)、经沉淀处理的洗煤废水 (T₂) 和煤矸石淋溶水 (T₃),于返青期开始进行矿区废水灌溉处理.结果表明： 矿井废水灌溉处理对小麦的生长发育和产量均有不同程度的负面影响.到开花期时,T₁、T₂和T₃处理小麦的单茎质量和叶面积、根系活力和光合速率均显著低于对照(P＜0.05),T₃处理小麦株高和叶绿素含量(SPAD值)显著降低(P＜0.05);T₁、T₂和T₃处理的籽粒产量分别比对照下降15.4%、9.8%和17.8%.此外,矿井废水灌溉处理小麦籽粒中Cr、Pb、Cu和Zn的含量均显著高于对照,表明矿井废水灌溉导致重金属在小麦籽粒中积累.
     

Does Seed Priming Induce Changes in the Levels of Some Endogenous Plant Hormones in Hexaploid Wheat Plants Under Salt Stress？

In order to assess whether salt tolerance could be Improved In spring wheat （Triticum aestivum L.）, the present study was performed by soaking the seeds of two cultlvars, namely MH-97 （salt sensitive） and Inqlab-91 （salt tolerant）, for 12 h In distilled water or 100 mol/m^3 CaCl2, KCI, or NaCI. Primed seeds from each treatment group and non-primed seeds were sown In a field In which NaCI salinity of 15 dS/m was developed. Priming of seeds with CaCl2, followed by priming with KCI and NaCI, was found to be effective In alleviating the adverse effects of salt stress on both wheat cultivars In terms of shoot fresh and dry weights and grain yield. Priming with CaCl2 alleviated the adverse effects of salt stress on hormonal balance In plants of both cultlvars. In MH-97 plants, CaCl2 pretreatment considerably reduced leaf absclslc acid （ABA） concentrations and Increased leaf free salicylic acid （SA） concentrations under both saline and non-saline conditions. In contrast, In the Inqlab-91 plant, CaCl2 Increased free Indoleacetic acid （IAA） and indolebutyrlc acid （IBA） content. However, priming of seeds with CaCl2 did not alter free polyamlne levels in either cultlvar, although spermldlne levels were considerably lower In plants raised from seeds treated with CaCl2 for both cultlvars under saline conditions. Priming with KCI Increased growth In Inqlab-91 plants, but not In MH-97 plants, under saline conditions. The salinity Induced reducUon In auxins （IAA and IBA） was alleviated by NaCI priming In both cultlvars under saline conditions. However, NaCI Increased leaf free ABA content and lowered leaf SA and putresclne levels In Inqlab-91 plants under saline conditions. In conclusion, although all three priming agents （I.e. CaCl2, KCI, and NaCI） were effective In alleviating the adverse effects of salt stress on wheat plants, their effects on altering the levels of different plant hormones were different In the two cuItlvars.     

Leaf gas exchange and grain yield of common bean exposed to spermidine under water stress

Three prevalent aliphatic polyamines (PAs) include putrescine, spermidine, and spermine; they are low-molecular-mass polycations involved in many physiological processes in plants, especially, under stressful conditions. In this experiment, three bean (Phaseolus vulgaris L.) genotypes were subjected to well-watered conditions and two moderate and severe water-stressed conditions with and without spermidine foliar application. Water stress reduced leaf relative water content (RWC), chlorophyll contents, stomatal conductance (gs), intercellular CO₂ concentration (C_i), transpiration rate, maximal quantum yield of PSII (F_v/F_m), net photosynthetic rate (P_N), and finally grain yield of bean plants. However, spermidine application elevated RWC, gs, C_i, F_v/F_m, and P_N, which caused an increase in the grain yield and harvest index of bean plants under water stress. Overall, exogenous spermidine could be utilized to alleviate water stress through protection of photosynthetic pigments, increase of proline and carotenoid contents, and reduction of malondialdehyde content.

     

外源SA和NO对NaCl胁迫下番茄幼苗生长、光合及离子分布的影响

以番茄(Lycopersicon esculentum Mill.)品种‘秦丰保冠’为试材,采用营养液培养法,研究单独和复配施用外源水杨酸(SA)、一氧化氮(NO)供体硝普钠(SNP)对100mmol/L NaCl胁迫下番茄幼苗生长、光合及离子分布的影响。结果表明:(1)单独和复配外施SA、SNP均能有效抑制NaCl胁迫下番茄幼苗叶片光合色素(Chla、Chlb、Chla+b和Car)含量、Chla/b值、净光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)、瞬时水分利用效率(WUEt)、表观光能利用效率(LUEapp)和表观CO2利用效率(CUEapp)的下降及Car/Chla+b值和胞间CO2浓度(Ci)的升高,并以SA和SNP复配处理效果最明显。(2)NaCl胁迫下,外源SA、SNP单独和复配处理的番茄幼苗各器官(叶、茎和根)中Cl-、Na+含量和Na+/K+、Na+/Ca2+、Na+/Mg2+值显著降低,而K+、Ca2+和Mg2+的含量却不同程度提高,其中以SA和SNP复配处理效果最好。(3)单独和复配外施SA、SNP均能有效减轻NaCl胁迫对番茄幼苗生长的抑制作用,并促进各器官生物量的积累和壮苗的形成,且以SA和SNP复配处理效果更佳。研究表明,复配外施SA和SNP在诱导番茄幼苗提高抗(耐)盐能力方面具有协同增效作用。     

Physiological effects of the induction of resistance by compost or Trichoderma asperellum strain T34 against Botrytis cinerea in tomato

Certain types of compost used as growth media can induce resistance to foliar pathogens in above-ground parts of a plant. The induction of resistance can sometimes be associated with growth impairment and yield reduction. The objective of this study was to establish whether plants grown in olive marc compost had enhanced resistance against Botrytis cinerea at the cost of growth or physiological performance.Tomato plants grown in mature olive marc compost had approximately 60% less disease severity than plants grown in perlite. As a reference, plants grown in perlite enriched with the known inducer of resistance Trichoderma asperellum strain T34 (T34) had 35% less disease severity than plants grown in perlite. The salicylic acid (SA) pathway/abscisic acid (ABA) is involved in compost induced systemic resistance. Instead, perlite enriched with T34 is not linked to SA pathway/ABA. Physiological measures of water status, root/shoot ratio, stable isotopes of C and chlorophyll fluorescence showed that the plants grown in compost were close to a stress situation. However, growth measured as biomass and plant height of plants grown in compost was higher than in plants grown in perlite suggesting that plants in compost were not grown in a stress situation, but in a eustress. Tomato plants grown in perlite enriched with T34 had better growth, measured as total leaf area, biomass, height and nutrient uptake, than plants grown in perlite. Physiological measures showed that plants grown either in perlite or perlite enriched with T34 did not show any abiotic stress situation.     

Physiological mechanisms contributing to the increased water-use efficiency in winter wheat under deficit irrigation

Deficit irrigation in winter wheat has been practiced in the areas with limited irrigation water resources. The objectives of this study were to (i) understand the physiological basis for determinations of grain yield and water-use efficiency in grain yield (WUE) under deficit irrigation; and (ii) investigate the effect of deficit irrigation on dry matter accumulation and remobilization of pre-anthesis carbon reserves during grain filling. A field experiment was conducted in the Southern High Plains of the USA and winter wheat (cv. TAM 202) was grown on Pullman clay loam soil (fine mixed thermic Torretic Paleustoll). Treatments consisted of rain-fed, deficit irrigation from jointing to the middle of grain filling, and full irrigation. The physiological measurements included leaf water potential, net photosynthetic rate (Pn), stomatal conductance (Gs), and leaf area index. The rain-fed treatment had the lowest seasonal evapotranspiration (ET), biomass, grain yield, harvest index (HI) and WUE as a result of moderate to severe water stress from jointing to grain filling. Irrigation application increased seasonal ET, and ET increased as irrigation frequency increased. The seasonal ET increased 20% in one-irrigation treatments between jointing and anthesis, 32-46% in two-irrigation treatments, and 67% in three- and full irrigation treatments. Plant biomass, grain yield, HI and WUE increased as the result of increased ET. The increased yield under irrigation was mainly contributed by the increased number of spikes, and seeds per square meter and per spike. Among the irrigation treatments, grain yield increased significantly but the WUE increased slightly as irrigation frequency increased. The increased WUE under deficit irrigation was contributed by increased HI. Water stress during grain filling reduced Pn and Gs, and accelerated leaf senescence. However, the water stress during grain filling induced remobilization of pre-anthesis carbon reserves to grains, and the remobilization of pre-anthesis carbon reserves significantly contributed to the increased grain yield and HI. The results of this study showed that deficit irrigation between jointing and anthesis significantly increased wheat yield and WUE through increasing both current photosynthesis and the remobilization of pre-anthesis carbon reserves.     

不同倍性冬小麦种内竞争能力的比较研究

通过3个不同倍性冬小麦材料(两倍体栽培一粒、四倍体栽培两粒、六倍体现代品种长武134),在不同水分条件下进行密度实验,研究了不同材料的株高、生物量累积和分蘖动态的变化,以及产量对密度变化的反应。结果表明随着群体的增大,不同倍性材料个体间竞争明显加剧,相互抑制作用增强,种群内部个体大小等级差异增大;在不同群体下各倍性材料的个体生长存在差异,表现为四倍体栽培两粒竞争能力两倍体栽培一粒六倍体现代品种长武134,且长武134受种群大小影响最为显著,但长武134产量累积的投入比例最高,产量最高,低竞争能力的个体更适合生产上的需求,是群体高产的基础。研究结果为旱地小麦的高产栽培和育种提供了理论基础。     

盐旱复合胁迫对小麦幼苗生长和水分吸收的影响

为明确盐害、干旱及盐旱复合胁迫对小麦幼苗生长和水分吸收的影响,从而为盐害和干旱胁迫下栽培调控提供理论依据。以2个抗旱性不同的小麦品种(扬麦16和耐旱型洛旱7号)为材料,采用水培试验,以NaCl和PEG模拟盐旱复合胁迫,研究了盐旱复合胁迫下小麦幼苗生长、根系形态、光合特性及水分吸收特性的变化。结果表明,盐、旱及复合胁迫下小麦幼苗的生物量、叶面积、总根长与根系表面积、叶绿素荧光和净光合速率均显著下降,但是复合胁迫处理的降幅却显著低于单一胁迫。盐旱复合胁迫下根系水导速率和根系伤流液强度显著大于单一胁迫,从而提高了小麦幼苗叶片水势和相对含水量。盐胁迫下小麦幼苗Na~+/K~+显著大于复合胁迫,但复合胁迫下ABA含量却显著小于单一的盐害和干旱胁迫。因此,盐旱复合胁迫可以通过增强根系水分吸收及降低根叶中ABA含量以维持较高光合能力,这是盐旱复合胁迫提高小麦适应性的重要原因。洛旱7号和扬麦16对盐及盐旱复合胁迫的响应基本一致,但在干旱胁迫下洛旱7号表现出明显的耐性。     

Enhanced salt tolerance of tomatoes by exogenous salicylic acid applied through rooting medium

In Tunisia, like in the other countries of the Mediterranean, tomato is ranked among the important vegetables in the economic sphere. Tunisia ranks as the first consumer of this vegetable in the world. However, tomatoes are exposed to multiple environmental stresses. In particular, salinity is the most stressful limiting factor to productivity. Salt tolerance of the tomato is susceptible to be ameliorated by genetic and physiologic ways. Salicylic acid (SA), a plant phenolic, is now considered as a hormone-like endogenous regulator, and its role in the defense mechanisms against biotic and abiotic stressors has been well documented. So, the aim of this study was to investigate the impact of exogenous application of SA (0.01 mM) on growth, nutritional behavior, and some metabolic parameters (total chlorophyll, soluble sugars, proline, and proteins) of tomato plants cv. Moneymaker exposed to NaCl (100 mM). Our results showed that the application of 0.01 mM SA to tomato plants via root drenching attenuate the depressive effect of salinity on plants. This amelioration results in stimulation of growth and development of plant. Under stress conditions, SA-treated plants exhibited more accumulation of photosynthetic pigments and K(+) contents. Thus, SA induces an increase in soluble sugars in roots and leaves; also, we noted the increase of proteins only in roots. Overall, the adverse effects of salt stress tomato plants were alleviated by the exogenous application of SA at vegetative stage, which upregulated nutrition and the accumulation of some organic solutes and osmoprotectors such sugars, proline, and proteins. So salicylic acid can be greatly used to enhance salt tolerance of tomato plants.