Effects of 15N application frequency on nitrogen uptake efficiency in citrus trees

Two irrigation systems were used to compare nitrogen uptake efficiency in citrus trees and to evaluate the NO₃⁻ runoff in «Navelina» orange trees [Citrus sinensis (L.) Osbeck] on Carrizo citrange rootstock (Citrus sinensis × Poncirus trifoliata Raf.). These were fertilized with 125 g N as labelled K¹⁵NO₃ and grown outdoors in containers filled with a sand-loamy soil. Two groups of 3 trees received this N dose either in five equally split applications by a flooding irrigation system or in 66 applications by drip. Trees were harvested at the end of the vegetative cycle (December) and the isotopic ratios of ¹⁵N/¹⁴N were measured in the soil-plant system. The N uptake efficiency of the whole tree was higher with drip irrigation (75 percnt;) than with flooding system (64 percnt;). In the 0-90 cm soil profile, the N immobilized in the organic fraction was similar for both irrigation methods (around 13 percnt;), whereas the N retained as NO₃⁻ was 1 percnt; of the N applied under drip and 10 percnt; under flooding. In the last case, most of NO₃⁻ remained under root system and it could be lost to leaching either by heavy rainfalls or excessive water applications. These results showed that a drip irrigation system was more efficient for improving water use and N uptake from fertilizer, in addition to potentially reduced leaching losses.     

Water relations of Fino lemon plants on two rootstocks under flooded conditions

Potted two-year-old Fino lemon plants (Citrus limon (L.) Burm. fil.) grafted on two different rootstocks: sour orange (C. aurantium) (SO), and C. macrophylla (CM) were submitted to two different treatments: non-flooded (control) and flooded for 8 days, under field conditions. Lemon/CM plants had lower plant plus soil resistance to water flow (R_(p+s)) values for both treatments. The decrease in leaf water potential (Ψ_l) and leaf turgor potential (Ψ_p) values, observed in the last part of the flooding period, in both flooded scion/rootstock combinations, can be related to the increase in the resistance to water flow. The maintenance in Ψ_l and Ψ_p values in flooded plants at values similar to those of the control plants, at the beginning of the flooding period and during the recovery period, can be ascribed to the stomatal control observed (decrease in leaf conductance (g₁) values). The later g₁ recovery in lemon/CM than in lemon/SO flooded plants, could explain the lower vegetative growth of lemon/CM plants by flooding effect. The observed g₁ response to soil flooding suggested that porometry is a reliable indicator of the altered behaviour caused by flooding in lemon plant.     

Physiological responses of the legume model Medicago truncatula cv. Jemalong to water deficit

In Medicago truncatula Gaertn. cv. Jemalong plants some mechanisms involved in drought resistance were analysed in response to a progressive water deficit imposed by suppression of soil irrigation. Withholding water supply until the soil had reached one-half of its maximum water content had no significant effect on leaf RWC, gas exchanges or chlorophyll fluorescence parameters. Under severe drought conditions, the plants resistance to water shortage involved mainly drought avoidance mechanisms through a decrease in stomatal conductance. The consequent decrease in the internal CO₂ concentration (C_i) should have limited the net CO₂ fixation (A). Since A decreased slightly more than C_i under severe water deficit, non-stomatal limitations of photosynthesis may have also occurred. Analysis of A/C_i curves showed reduced carboxylation efficiency due to limitations in RuBP regeneration and Rubisco activity, confirming the presence of non-stomatal limitations of photosynthesis. Drought tolerance mechanisms involving osmotic adjustment and an increase in cell membrane integrity were also present. Altogether, these mechanisms allowed M. truncatula cv. Jemalong plants to still maintain a quite elevated level of net CO₂ fixation rate under severe water deficit conditions. These results may contribute to identify useful physiological traits for breeding programs concerning drought adaptation in legumes.     

AM真菌摩西管柄囊霉对干旱胁迫下枳抗氧化酶基因表达的影响

测定分析了接种丛枝菌根（AM）真菌摩西管柄囊霉Funneliformis mosseae对正常供水与干旱处理的盆栽枳Poncirus trifoliata实生苗生长、活性氧代谢及抗氧化酶基因表达量的影响。结果表明,7周干旱处理显著降低了根系菌根侵染率。接种摩西管柄囊霉显著促进了干旱处理的枳植株生长,增加了根系体积和叶片相对含水量,显著降低了叶片脯氨酸含量,同时也上调了干旱处理的枳叶片精氨酸脱羧酶基因（PtADC1和PtADC2）和超氧化物歧化酶基因（PtFe-SOD和PtMn-SOD）、过氧化物酶基因（PtPOD）和过氧化氢酶基因（PtCAT1）的表达,因而维持了一个相对更低的活性氧水平（如过氧化氢）,有利于增强植株的抗旱性。     

不同光合类型牧草对干旱-复水的光合生理响应及生长适应策略

基于干旱频率增加、强度增大这一全球降水变化背景, 探究干旱-复水条件下不同功能群(C₃和C₄)植物的光合生理响应及生长适应策略有助于预测降水格局变化条件下草地的植被组成和生态系统功能。该研究采用盆栽实验, 以松嫩草地生长的一年生C₃ (4种)和C₄ (3种)牧草为实验材料, 设置了对照、中度干旱和重度干旱3个水分处理水平, 在干旱末期及复水期对植物进行气体交换、生物量和比叶质量的测量。在干旱条件下, 各物种净光合速率和气孔导度均呈下降趋势, 水分利用效率呈上升趋势。干旱对不同植物光合指标的影响存在功能群差异, 随干旱程度的增加C₄植物逐渐丧失光合优势, 重度干旱对C₄植物净光合速率的影响较C₃植物更加明显。由于干旱条件下C₃植物光合固碳主要受气孔限制而C₄植物主要受代谢限制, 因此复水后C₄植物净光合速率恢复速度较C₃植物慢。干旱条件下, 各物种的生物量降低, 根冠比和比叶质量升高, 干旱对C₃植物各生长指标的影响均大于C₄植物; 复水处理后, C₃植物生物量随干旱强度增加呈下降趋势, 而C₄植物的生物量与对照相比无显著差异。     

CO2 enrichment, drought stress and growth of Alaska pea plants (Pisum sativum)

The interaction of CO₂ enrichment and drought on water status and growth of pea plants was investigated. Pisum sativum L. (cv. Alaska) plants were grown from seeds in growth chambers using 350 and 675 μl I1 CO₂, a photon flux density of 600 μmol M-2 S-1, a 16 h photoperiod and a temperature regime of 20/14°C. The drought treatment was started at the beginning of branch initiation and lasted for 9 or 11 days. The water status of the plants was monitored daily by measuring total leaf water potential and stomatal conductance. The total leaf water potential of well-watered plants was not affected by the CO₂ level. Under draughting conditions total leaf water potential decreased, with a slower decrease under the high CO₂ regime, due, at least in part, to reduced stomatal conductance. Upon rewatering, total leaf water potential and stomatal conductance recovered within one day. High CO₂ counteracted the reduction in height and, to some extent, leaf area that developed in low CO₂ unwatered plants. Additional CO₂ had no effect on branch number and did not prevent the complete inhibition of branch development that resulted from drought stress. Removing the drought conditions resulted in a rapid recovery of the internal water status and also a rapid recovery of most, but not all, plant growth parameters.     

Effects of dew on eco-physiological traits and leaf structures of Leymus chinensis and Agropyron cristatum grown under drought stress

Aims To investigate the effects of dew on plants, we conducted the experiment to determine the physiological characteristics and leaf structures of Leymus chinensis and Agropyron cristatum in response to increasing dew under drought stress.Methods Four treatments (no dew, three times dew and five times dew per week under drought stress, and well-watering) were designed to examine leaf relative water content, water potential, net photosynthetic rate, water use efficiency, biomass, and leaf structures of L. chinensis and A. cristatum. Important findings There was a significant increase in the relative water content and water potential by simulated dew increase for two plants species under drought stress (p < 0.05). For A. cristatum, simulated dew increase significantly enhanced the net photosynthetic rate, stomatal conductance, and transpiration rate of plants under drought stress (p < 0.05). On the other hand, there was no significant difference in the stomatal conductance and transpiration rate for L. chinensis among treatments. Simulated dew increase improved the aboveground biomass and root biomass of two species. The ratio of yellow leaves to the total leaves was decreased by simulated dew increase for two species. Dew increase also protected leaf structures against the drought stress, suggesting that the dew increase can slow down the death process of leaves resulted from drought stress. Therefore, the study demonstrated that dew increased the available water for the leaves of L. chinensis and A. cristatum grown in the drought stress and thus had positive effects on the photosynthesis, water physiology and plant development.     

Biophysical and morphological leaf adaptations to drought and salinity in salt marsh grasses

Leaf energy budgets were constructed for 13 species of estuarine C₄ grasses (Poaceae) to elucidate the biophysical effects of drought and salinity on the interception and dissipation of solar energy. Spartina alterniflora, S. anglica, S. argentinensis, S. bakeri, S. cynosuroides, S. densiflora, S. foliosa, S. foliosa × S. alterniflora hybrids, S. gracilis, S. patens, S. pectinata, S. spartinae, and Distichlis spicata plants were grown under controlled soil water potential gradients in a greenhouse. Species were grouped into four major ecological functional types, based on elevational zonation ranges: low marsh species, middle marsh species, high marsh species, and freshwater species. Different functional types are adapted to different environmental conditions, and responded differently to reduced water potentials. Latent heat flux decreased similarly across species in response to decreasing water potential. Latent heat loss was found to decrease by as much as 65% under decreasing water potential, leading to an increase in leaf temperature of up to 4 °C. Consequently, radiative and sensible heat losses increased under decreasing water potential. Sensible heat flux increased as much as 336% under decreasing water potential. Latent heat loss appeared to be an important mode of temperature regulation in all species, and sensible heat loss appeared to be more important in high marsh species compared to low marsh species. High marsh species are characterized by narrower leaves than middle and low marsh species, leading to a smaller boundary layer, and providing higher conductance to sensible heat loss. This may be an adaptation for high marsh species to regulate leaf temperature without access to large amounts of water for transpirational cooling. Stomatal conductance decreased with decreasing water potential across species: leaf conductances to water vapor and CO₂ decreased as much as 69% under decreasing water potential. Additionally, oxidative stress appeared to increase in these plants during times of drought or salinity stress. Ascorbate peroxidase activities increased with decreasing soil water potential, indicating increased cellular reactive oxygen species. High marsh species had higher ascorbate peroxidase activities compared to low marsh species, indicating higher tolerance to drought- or salinity-induced stresses. It was concluded that different species of marsh grasses are adapted for growth in different zones of salt marshes. Adaptations include biophysical, biochemical, and morphological traits that optimize heat exchange with the environment.     

Proteins, non-structural carbohydrates and organic acids in the flowers of sweet orange (Citrus sinensis (L.) osbeck)

The concentration of soluble proteins in open flowers of sweet orange (Citrus sinensis (L.) Osbeck) was about 35% of the protein content found in green leaves, while ovary and stigma, with attached style, contained up to 85%. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) indicates that flowers and leaves contained ribulose bisphosphate carboxylase-oxygenase (Rubisco). At least 12 polypeptides, ranging from 22 to 100 kDa, were more distinct in flowers than in leaves. The polypeptide band at about 100 kDa in the flower extract suggests the presence of phosphoenolpyruvate carboxylase (PEPCase) in citrus flowers. Activity of Rubisco and PEPCase, expressed in μmol g tissue fresh weight⁻¹ hr⁻¹, averaged 14.2 and 64.6 for intact open flowers, and 547.9 and 63.3 for the leaves, respectively. Starch and reducing sugars were 1.2- and 8.4-fold higher, respectively, and dark respiration rates were about five-fold greater for open flowers than fully expanded, sun leaves. Quinic and malic acids made up about 96% of the organic acids found in flowers and leaves. Ascorbic, citric, fumaric, and shikimic acids were in small or trace amounts. The large accumulation of starch and soluble sugars, in addition to the presence and activity of Rubisco and PEPCase, indicates that the flowers of sweet orange would have some capability to perform photosynthetic CO₂ assimilation, the metabolites of which might play some important role in flower development and fruit setting.     

Photochemical response to drought acclimation in two sunflower genotypes

The effects of drought acclimation on CO₂ assimilation and light utilization were investigated in two sunflower genotypes ( Helianthus annuus L., T32 and Viki) in relation to water deficit and/or high light conditions. Drought interaction with PSII efficiency was observed in the genotype T32 with a sustained decrease in the potential photochemical efficiency of PSII, F_n/F_m. In response to drought acclimation, T32 displayed some tendency to accumulate closed PSII traps (higher value of 1-qp) without an enhancement of thermal deactivation (Stem-Volmer non-photochemical quenching, NPQ). Irrespective of the growth conditions (growth chamber or greenhouse), only Viki was responsive to drought acclimation, with (1) increased net photosynthesis in well-watered plants, (2) higher maintenance of photochemical electron transfer under water deficit and/or high light, (3) limited PSII inactivation (lower value of 1-qp) through increased non-photochemical energy dissipation (Stern-Volmer NPQ) which was readily reversible even at low leaf water potentials, and (4) higher F_v/F_m recovery after high light treatment. Additionally, drought acclimation delayed turgor loss during subsequent water stress in Viki. Thus, the response to drought acclimation, with an adjustment of water relations and of energy utilization by PSII, was observed under both growth conditions and was mainly genotype dependent.     

避雨环境下苹果幼树水分状态指标对干旱胁迫的响应

在避雨环境下进行土壤水势渐进式下降处理,研究了苹果树体水分状态指标对土壤干旱胁迫响应的敏感性,分析了不同水分状态指标与树体水分平衡之间的关系.结果表明: 树干直径日较差(MDS)及中午树干水势(Ψ_stem)对干旱胁迫最敏感.MDS对参考蒸散(ET₀)有明显的响应,且对干旱胁迫比较敏感,与ET₀呈显著正相关,相对树干直径日较差(MDS_r)与相对土壤水势(Ψ_{r soil})呈显著负相关,树干直径可实现连续性测量及自动化记录.Ψ_stem对土壤干旱胁迫较敏感,且与ET₀呈显著负相关,相对中午树干水势(Ψ_{r stem})与Ψ_{r soil}呈显著相关,目前叶水势和树干水势难以实现自动化连续性观测.其他树体水分状态指标,如黎明前叶水势(Ψ_pd)、树干直径日生长量(DG)和气孔导度(g_s)等对中度或重度干旱胁迫也有不同程度的响应,但总体上对土壤水势变化的响应不敏感.     

CO2浓度、氮和水分对春小麦光合、蒸散及水分利用效率的影响

研究了不同土壤氮和土壤水分条件下,大气CO₂浓度升高对春小麦光合作用、气孔导度、蒸散和水分利用效率的影响.结果表明,CO₂浓度升高,干旱处理的春小麦(Triticum aestivum L.)叶片光合作用速率幅度增加大于湿润处理,随着氮肥用量增加光合速率相应增加,而不施氮肥增加有限;干旱处理气孔导度幅度减少大于湿润处理,不施氮肥的大于氮肥充足的.CO₂浓度升高,干旱处理的蒸散量减少比湿润处理多,不施氮肥的蒸散量减少较为明显;但干旱处理单叶WUE增加大于湿润处理;随着氮肥用量增加,冠层WUE提高,而不施氮肥的冠层WUE最低.因而CO₂浓度升高、光合速率增加和蒸散量减少会减缓干旱的不利影响,增强作物对干旱胁迫的抵御能力.     

Photorespiration in C4 grasses remains slow under drought conditions

The CO₂-concentrating mechanism present in C₄ plants decreases the oxygenase activity of ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) and, consequently, photorespiratory rates in air. Under drought conditions, the intercellular CO₂ concentration may decrease and cause photorespiration to increase. The C₄ grasses Paspalum dilatatum Poiret, Cynodon dactylon (L.) Pers. and Zoysia japonica Steudel were grown in soil and drought was imposed by ceasing to provide water. Net CO₂ assimilation ( A ) and stomatal conductance to water vapour decreased with leaf dehydration. Decreased carbon and increased oxygen isotope composition were also observed under drought. The response of A to CO₂ suggested that the compensation point was zero in all species irrespective of the extent of drought stress. A slight decrease of A as O₂ concentration increased above 10% provided evidence for slow photorespiratory gas exchanges. Analysis of amino acids contained in the leaves, particularly the decrease of glycine after 30 s in darkness, supported the presence of slow photorespiration rates, but these were slightly faster in Cynodon dactylon than in Paspalum dilatatum and Zoysia japonica . Although the contents of glycine and serine increased with dehydration and mechanistic modelling of C₄ photosynthesis suggested slightly increased photorespiration rates in proportion to photosynthesis, the results provide evidence that photorespiration remained slow under drought conditions.     

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。     

CO2浓度升高对大豆干旱胁迫的缓解效应

CO2浓度升高和干旱带来的气候变化势必对大豆的生长造成影响.目前,CO2浓度升高对干旱胁迫下大豆生理生化的影响研究较少.本试验研究了不同CO2浓度(400、600 pumol ? mol-1)和水分处理下(正常水分:叶片相对含水量为83％-90％;干旱:叶片相对含水量为64％-70％)大豆开花期的光合能力、光合色素积累...     

Stomatal responses of pearl millet (Pennisetum americanum [L.] Leeke) to leaf water status and environmental factors in the field

Abstract. Factors affecting stomatal conductance (g₁) of pearl millet ( Pennisetum americanum [L.] Leeke), cultivar BJ 104, were examined in the field in India during the dry season.
Diurnal changes in g₁ were evaluated for upper expanded leaves at flowering on two occasions using plants subjected to varying degrees of water stress. Except for the most severely stressed treatment, diurnal changes in g₁ closely matched changes in irradiance ( I ), the promotive effect of which largely overcame opposing influences on g₁ of increasing atmospheric vapour pressure deficit, and decreasing leaf water and turgor potentials (Ψ, Ψ_p).
Two main effects of water stress on g₁ were evident: (i) a decrease in the amplitude of the mid-day peak in g₁, and (ii) a decrease in the time over which high g₁ was maintained, resulting in early (mid-day) closure and hysteresis in the relationship between g₁ and I .
Leaf conductance was greatest for upper leaves and decreased down the canopy. At equivalent depths in the canopy g₁ was higher in flowering than in photoperiodically-retarded plants of the same age. The magnitude of water stress-induced stomatal closure increased down the plant, and was more marked in retarded than in flowering plants.
Within individual stress treatments Ψ of upper leaves decreased linearly as transpiration flux increased. It is concluded that stomatal behaviour of upper leaves of pearl millet at flowering largely operates to maximize assimilation rather than to minimize water loss.     

干旱胁迫对转PtPIP2;8基因84K杨苗木光合、生长和根系结构的影响

为研究水通道蛋白PtPIP2;8基因功能, 了解其不同表达水平的转基因84K杨(Populus alba × P. glandulossa)应对干旱胁迫的响应, 该文以转PtPIP2;8 84K杨抑制表达株系(抑制表达)、野生型(WT)和转PtPIP2;8 84K杨超表达株系(超表达)为试验材料, 测定PtPIP2;8表达水平、根系导度、光响应曲线、气体交换参数、生长及根系形态指标。结果显示: (1) WT植株PtPIP2;8仅在根系表达; 超表达植株PtPIP2;8除在根部显著表达外, 在茎和叶片中也显著表达; 抑制表达植株PtPIP2;8仅在根部有微量表达, 表达量分别是WT和超表达植株的1/20和1/80。(2)根系结构分析发现, 超表达植株总根长、总根表面积、总根体积、总根尖数显著低于WT和抑制表达植株, 根系导水率显著高于WT和抑制表达植株, 表明PtPIP2;8参与了植物根系水分运输, 提高了水分运输效率。(3)正常水分条件下, 抑制表达植株苗高、叶面积显著低于WT和超表达植株, 根冠比显著高于WT和超表达植株。干旱胁迫后, 抑制表达植株净光合速率(P_n)、气孔导度(G_s)下降幅度小, 仍能维持较高的P_n。气体交换参数显示抑制表达植株P_n、G_s日变化为“单峰”型, 属气孔因素引起的净光合速率下降;WT和超表达植株P_n、G_s日变化为“双峰”型, 干旱胁迫后, 抑制表达植株P_n略微下降, WT和超表达植株P_n均下降, 尤其是13:00、15:00下降显著, 表明WT和超表达植株对干旱胁迫更加敏感, 干旱对其影响更大。(4)干旱胁迫后, 抑制表达植株相对生长速率、总生物量降低的最少, 根冠比最高; 总根表面积、总根体积、总根尖数显著高于WT植株。表明PtPIP2;8直接参与水分运输并提高水分运输效率, 其转化影响了植株根系发育和生长。超表达植株根系发育的下降和叶面积的增大减弱了它的抗旱性, 而抑制表达植株矮小, 降低的叶面积, 增加的根系生长和根冠比提高了它的抗旱能力。从研究结果来看, 水通道蛋白提高了水分跨膜运输效率, 而非水通道蛋白导水机制对干旱有较强的耐受性。     

喀斯特干旱环境对青冈栎叶片生长及叶绿素荧光动力学参数的影响

为了探讨喀斯特植被恢复树种青冈栎对干旱环境的适应机制,以当年生青冈栎实生幼苗为材料进行盆栽控水试验,设置正常浇水(-0.1 MPa,对照)、轻度干旱(-0.5 MPa)、中度干旱(-0.9 MPa)和重度干旱(-1.5 MPa)胁迫处理,研究持续干旱处理(15、30、45、60和90天)对其幼苗叶片生长及叶绿素荧光参数的影响.结果表明: 随着干旱胁迫强度的加剧, 叶片的单叶面积、健康叶片数量、叶片含水率、总叶绿素、类胡萝卜素、最大荧光、最大光化学量子产量和潜在光化学效率均显著下降,而枯叶数量和初始荧光显著增加.这些参数在轻度干旱胁迫处理和对照之间均无显著差异.在轻度干旱胁迫处理下,青冈栎幼苗叶片PSⅡ单位反应中心吸收的光能(ABS/RC)、捕获用于还原q_A的能量(TR_o/RC)、单位面积内有活性的反应中心数目(RC/CS)、单位面积捕获的光能(TR_o/CS)和单位面积内用于电子传递的光能(ET_o/CS)均与对照无显著差异,其中RC/CS总是略高于对照,TR_o/CS和ET_o/CS均在第45天达到峰值,分别为606.12和440.78;而中度和重度干旱胁迫处理叶片的ABS/RC、TR_o/RC、ET_o/RC、DIR_o/RC、RC/CS、TR_o/CS和ET_o/CS均低于对照,且随干旱胁迫时间的延长,重度干旱胁迫处理下降更显著.随干旱胁迫的加剧和时间的延长,叶片最大量子效率、其他电子受体的概率和电子传递的量子比率均下降,而用于热耗散的量子比率增加.轻度干旱胁迫下青冈栎幼苗表现出较强的适应性,中度干旱胁迫引起部分叶绿素荧光参数和光合色素指标下降,导致幼苗生长缓慢,而重度干旱则对幼苗生长的影响较为严重,但幼苗未出现死亡现象.因此,青冈栎幼苗有较强的干旱忍受能力,适合在喀斯特地区植被恢复重建和造林工程中应用.     

Effects of drought stress on photosynthesis,growth and root structure of transgenic PtPIP2;8 poplar 84K (Populus alba × P. glandulosa)

为研究水通道蛋白PtPIP2;8基因功能, 了解其不同表达水平的转基因84K杨(Populus alba × P. glandulossa)应对干旱胁迫的响应, 该文以转PtPIP2;8 84K杨抑制表达株系(抑制表达)、野生型(WT)和转PtPIP2;8 84K杨超表达株系(超表达)为试验材料, 测定PtPIP2;8表达水平、根系导度、光响应曲线、气体交换参数、生长及根系形态指标。结果显示: (1) WT植株PtPIP2;8仅在根系表达; 超表达植株PtPIP2;8除在根部显著表达外, 在茎和叶片中也显著表达; 抑制表达植株PtPIP2;8仅在根部有微量表达, 表达量分别是WT和超表达植株的1/20和1/80。(2)根系结构分析发现, 超表达植株总根长、总根表面积、总根体积、总根尖数显著低于WT和抑制表达植株, 根系导水率显著高于WT和抑制表达植株, 表明PtPIP2;8参与了植物根系水分运输, 提高了水分运输效率。(3)正常水分条件下, 抑制表达植株苗高、叶面积显著低于WT和超表达植株, 根冠比显著高于WT和超表达植株。干旱胁迫后, 抑制表达植株净光合速率(P_n)、气孔导度(G_s)下降幅度小, 仍能维持较高的P_n。气体交换参数显示抑制表达植株P_n、G_s日变化为“单峰”型, 属气孔因素引起的净光合速率下降;WT和超表达植株P_n、G_s日变化为“双峰”型, 干旱胁迫后, 抑制表达植株P_n略微下降, WT和超表达植株P_n均下降, 尤其是13:00、15:00下降显著, 表明WT和超表达植株对干旱胁迫更加敏感, 干旱对其影响更大。(4)干旱胁迫后, 抑制表达植株相对生长速率、总生物量降低的最少, 根冠比最高; 总根表面积、总根体积、总根尖数显著高于WT植株。表明PtPIP2;8直接参与水分运输并提高水分运输效率, 其转化影响了植株根系发育和生长。超表达植株根系发育的下降和叶面积的增大减弱了它的抗旱性, 而抑制表达植株矮小, 降低的叶面积, 增加的根系生长和根冠比提高了它的抗旱能力。从研究结果来看, 水通道蛋白提高了水分跨膜运输效率, 而非水通道蛋白导水机制对干旱有较强的耐受性。