Physiological water strategy of Artemisia ordosica around soil threshold of drought

The mechanism for plants around the soil threshold of drought (close to the soil wilting water content) is a problem that needs to be further explored. In this paper, Artemisia ordosica, which grows in the Tengri Desert, was selected to analyze the changes in the plant water potentials in the soil-plant-atmosphere continuum (SPAC), the water contents in the roots, shoots and leaves of A. ordosica, and the indices in enzymatic and non-enzymatic systems. Based on the statistics, we discussed the water physiology mechanism around the soil drought threshold. The results show that, around the soil drought threshold, besides absorbing and transporting water, the roots could serve as temporary water reservoirs that enable A. ordosica to continue to transport the SPAC water and survive severe drought. As drought becomes more severe, the activity of superoxide dismutase (SOD) and catalase (CAT) increases and they have significant correlations with the tissue water content. The activity of peroxidase (POD) decreases and it has no significant correlation with the tissue water content. During daytime, when temperature is high, the soluble sugar does not participate in the osmotic adjustment but eliminate the active oxygen free radicals. Thus, around the soil threshold of drought, A. ordosica maintains a physiological water metabolism by harmo-nizing water itself and eliminate the active oxygen and the free radicals by the joint efforts of enzymatic and non-enzymatic systems.     

宁夏河东沙区刺槐和丝绵木水分利用策略

刺槐和丝绵木混交林是宁夏河东沙区防护林建设的主要模式,了解刺槐和丝绵木的水分利用策略,能为区域植被恢复和防护林林分结构调整提供科学依据。以宁夏河东沙区刺槐(Robinia pseudoacacia)和丝绵木(Euonymus bungeanus)混交林为研究对象,通过监测微气象、树干液流和土壤质量含水量,结合大气降水、土壤水、植物木质部水同位素组成,采用Granier及其校正公式,运用贝叶斯混合模型(MixSIAR)和相似性比例指数(PS)研究2个树种的蒸腾耗水、水分来源和水分利用关系。结果表明：刺槐和丝绵木的蒸腾耗水量在生长季中期较高,前期和后期较小,刺槐的蒸腾耗水量是丝绵木的1.55倍;影响刺槐蒸腾耗水的主要环境因子为饱和水汽压差、太阳辐射、0—40 cm土壤质量含水量和40—120 cm土壤质量含水量;影响丝绵木蒸腾耗水的主要环境因子为饱和水汽压差、太阳辐射、平均气温、0—40 cm土壤质量含水量和40—120 cm土壤质量含水量;蒸腾耗水较高时,刺槐主要吸收利用中层土壤水,丝绵木主要吸收利用浅层土壤水,蒸腾耗水较低时,刺槐主要吸收利用浅层土壤水,丝绵木主要吸收利用中层土壤水;在...     

海滨滨麦叶片和根对不同厚度沙埋的生理响应差异分析

以烟台海岸抗风沙植物滨麦为研究材料,通过对不同厚度沙埋下其叶片和根部抗氧化酶活力(超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT))、丙二醛(MDA)含量和渗透调节物含量变化的分析,探讨了叶片和根部对沙埋生理响应的差异。试验按滨麦成株株高(约40 cm)对其进行了轻度沙埋(在株高1/4处)、中度沙埋(2/4处)和重度沙埋(3/4处)。在沙埋第6天,分别测定了不同厚度沙埋处理下,植株各段叶片和根抗氧化酶活力、MDA和渗透调节物含量。结果表明,轻度和中度沙埋均加速植株生长。与对照相比,经轻度、中度沙埋处理6 d,叶片平均MDA含量增加,在重度沙埋下降低。不同厚度沙埋6 d,叶片平均SOD活力和脯氨酸含量增加,而CAT活力、可溶性糖和可溶性蛋白质含量下降。但不同厚度沙埋均使沙上叶片MDA、脯氨酸、可溶性蛋白质含量和SOD和CAT活力增加,尤其是叶片顶部增加最为明显,使沙下叶片MDA、可溶性糖、可溶性蛋白质含量和CAT活力下降,导致同株沙上和沙下叶片MDA、脯氨酸、可溶性糖、可溶性蛋白质含量和SOD和CAT活力差异显著(P0.05)。与叶片相比,根中MDA、可溶性蛋白质含量和SOD和CAT活力较低,而POD活力和可溶性糖含量较高并与叶片差异显著(P0.05)。不同厚度沙埋6 d,滨麦根中MDA和可溶性蛋白质含量变化较小,可溶性糖含量和CAT、POD、SOD活力略有降低。研究表明,滨麦根和叶片对不同厚度沙埋的生理响应不同。沙埋直接作用于叶片并诱发叶内氧自由基积累,但叶片通过快速激活的抗氧化酶保护系统(CAT、SOD)维持氧自由基代谢平衡,以及渗透调节物(脯氨酸、可溶性糖)的积累维护细胞水分代谢平衡,并满足能量的需求和快速生长。但在不同厚度沙埋下,由于根系不受沙埋直接影响而生理变化较小,并且还维持较低的膜脂过氧化水平,这可能是根能维持正常的吸水输水功能并在沙埋处理过程中和沙埋后地上叶片快速生长摆脱沙埋的重要物质基础。     

Drought and watering-dependent oxidative stress: effect on antioxidant content in Triticum aestivum L. leaves

The purpose of the present work was to evaluate both oxidative stress and the antioxidant response system in leaves from wheat (Triticum aestivum cv. Buck Poncho) subjected sequentially to drought and watering. Drought was imposed by withholding water until soil water potential reached -2.0 MPa and maintained under those conditions for 24 h. DCFDA oxidation by wheat leaves was not significantly affected by drought, but watering led to an approximately 2-fold increase in DCFDA oxidation rate. However, no significant effect either on lipid radical content or on hydroperoxide content was measured after drought and drought followed by watering. Microsomes isolated from leaves exposed to drought, and from leaves exposed to drought followed by watering, generated a significantly higher amount of hydroxyl radical as compared to microsomes isolated for control leaves suggesting a higher production of hydroxyl radical in the cellular water soluble phase, after drought and watering as compared to control values. The content of -tocopherol in wheat leaves was increased 2.4-fold after drought and -carotene content was increased by 2.6-fold after drought. Hydration lowered lipid-soluble antioxidant content to control values. Total thiol content as increased by 70% after drought, and watering did not significantly alter the enhanced values. Drought decreased by 28.5% the content of reduced ascorbic acid. Taken as a whole, active species formed at wheat membranes after exposure to moderate water stress, are efficiently removed upon rehydration by reaction with an increased content of -tocopherol and -carotene. Moreover a co-ordinated response involving glutathione reductase activity, thiols and ascorbic acid is triggered to limit free radical dependent effects.Key words: Antioxidants, lipid radicals, oxygen radicals, water stress, wheat      

Effects of <Emphasis Type="Italic">Carex rostrata</Emphasis> on soil oxygen in relation to soil moisture

Many wetland plants are faced with severe edaphic problems. Long term flooding effects a sequence of chemical processes that result in soil anoxia and production of several phytotoxic compounds. In order to maintain an aerobic root respiration wetland plants produce aerenchyms that enable oxygen conduction through the plant body to underground organs. Moreover wetland plants are able to release oxygen into the soil. This aeration effect of wetland plants in turn can influence soil chemistry considerably and protects roots by an aerobic rhizosphere. Oxygen release by underground organs of aerenchymous plants has been well documented in laboratory investigations but not under field conditions. In this study, dynamics of oxygen saturation were measured together with soil water content and microclimatic parameters. Measurements were carried out on some lowland peat covered by Carex rostrata Stokes from July to October 2001. Oxygen saturation was quantified using novel optical sensors (microoptrodes). The presence of C. rostrata significantly increased oxygen content in the soil. Mean oxygen saturation under Carex rostrata (56.0%) was significantly higher than in a control plot without vegetation (26.6%). Due to fluctuating water content, oxygen saturation in both plots was characterized by pronounced time variation. Increasing soil water content caused an extreme decline of oxygen saturation in both plots and led to anoxia in the control plot. In the presence of C.rostrata, the decline in soil oxygen took place at significantly higher water content (68.5% compared to 67.5% in the control plot) which is substantial as the mean water contents varied between 67 and 69% during the measurement period.     

海岸不同生态断带植物根叶抗逆生理变化与其Na+含量的关系

以烟台海岸生态断带滨麦(Leymus mollis)和肾叶打碗花(Calystegia soldanella)为材料,在远离高潮线不同位置上取土样和植物材料,通过测定土壤Na+和两植物根叶Na+含量、丙二醛(MDA)含量、抗氧化酶(SOD、POD、CAT)活性和渗透调节物含量,以揭示滨麦和肾叶打碗花根叶中Na+在其适应海岸盐环境中的生理调控机制。结果表明,在高潮线土壤Na+含量最高,滨麦根叶Na+含量较高,两植物根叶中MDA和水分含量、抗氧化酶活力均较低,但渗透调节物含量均较高。随远离高潮线土壤Na+含量下降,滨麦根叶Na+含量下降,而肾叶打碗花根中Na+含量上升,其根叶Na+含量较滨麦分别高637%和319%。同时两植物根叶MDA含量、叶片含水量增加;两植物根中POD和SOD活力增加;两植物根叶可溶性糖和脯氨酸含量下降。但不同生态断带滨麦叶片平均含水量相对较低,MDA含量、POD和CAT和SOD活力、脯氨酸和可溶性糖含量相对较高。在盐土环境中滨麦通过降低Na+的吸收和提高抗氧化酶活力和有机渗透调节物含量维持氧自由基代谢平衡和水分平衡。而肾叶打碗花是泌盐植物,在不同生态断带其叶片Na+含量、平均含水量相对较高,叶MDA含量、POD和CAT活力、脯氨酸和可溶性糖含量均相对较低。泌盐植物的肾叶打碗花依赖根叶中积累的Na+作为无机渗透调节剂维护其离子平衡和水分平衡及正常生长。因此,积累在根叶中的Na+离子既作为无机渗透调节剂维护细胞离子平衡和水分平衡,又引发细胞生理干旱促进有机渗透调节物合成;另外还作为氧自由基诱发剂促使活性氧自由基(ROS)积累,通过积累的ROS激活抗氧化保护酶系统抑制膜脂过氧化、维护氧自由基代谢平衡。海岸沙地土壤中高浓度Na+是海滨滨麦和肾叶打碗花能长期在盐土环境中生存的依靠元素,其对植物的生理调控作用可能是滨麦和肾叶打碗花适应盐土生存的重要生理适应机理。     

土壤水分梯度对灰胡杨光合作用与抗逆性的影响

以塔里木盆地珍稀渐危种灰胡杨(Populus pruinosa Schrenk)幼苗为材料,采用盆栽方法研究土壤水分梯度对灰胡杨光合特征及抗逆性的影响。结果表明:(1)灰胡杨净光合速率(P_n)、蒸腾速率、气孔导度、胞间CO_2浓度和光能利用率均随土壤水分递减而降低,重度干旱比适宜水分依次降低了35.53%、25.32%、48.18%、15.62%和40.92%;而光合午休程度则明显增强,P_n下降主要是由非气孔因素限制造成。轻度干旱能够提高灰胡杨水分利用效率(WUE)3.05%,维持相对较高的P_n和WUE。(2)随土壤水分递降,灰胡杨光照生态幅缩窄,CO_2补偿点升高,RuBP再生受限,光与CO_2利用效率、Rubisco活性和光合效率降低。与适宜水分相比,中度与重度干旱下最大净光合速率(P_(nmax))、表观量子效率、光饱和点、羧化效率、光合能力(A_(max))、光呼吸速率、最大羧化效率、最大电子传递速率和磷酸丙糖利用率均显著降低(P0.05),其中P_(nmax)、A_(max)和生化参数分别降低了42.65%、38.26%、57.10%;63.01%、65.88%、73.43%。(3)土壤干旱显著降低了灰胡杨的枝水势和光合色素含量(P0.01),并且改变了光系统反应中心色素的组成比例,膜脂过氧化程度显著增强(P0.01)。灰胡杨主要通过积累大量脯氨酸和可溶性蛋白质参与渗透调节来减轻土壤干旱对光合机构的损伤。重度干旱对灰胡杨叶片光合系统造成了不可逆的伤害,严重抑制了其正常生长和光合作用。综上所述,塔里木干旱荒漠区灰胡杨生长适宜的土壤相对含水量为60%—65%符合极端干旱区植被恢复与高效节水的管理原则。     

Photosynthesis and Water Use Efficiency of Platycladus Orientalis and Robinia Pseudoacacia Saplings under Steady Soil Water Stress during Different Stages of Their Annual Growth Period

A simulated drought experiment was conducted in a rain-free shed to test the physiological response of Platycladus orientalis and Robinia pseudoacacia saplings to steady soil water stress during different stages. The five soil water treatments were： 100%, 87.84%, 70%, 52.16% and 40% of field capacity. The results showed that the net photosynthetic rate of R. pseudoacacia decreased as soil water potential decreased in the range between -0.041 MPa and -0.292 MPa. The threshold value at which the net photosynthetic rate changed significantly was -0.12 MPa. The relationship between net photosynthetic rate of P. orientalis and soil water potential could be described as a quadratic parabola in the range between -0.041 MPa and -0.648 MPa. Analysis of variance showed significant differences in the net photosynthetic rate of P. orientalis between soil water potentials of -0.061 MPa ~, -0.648 MPa. Average water use efficiency （WUE） increased as soil water potential decreased, but the influence mechanism of soil water stress on leaf WUE and photosynthetic rate for the two species were different evidently.     

Soil-Water Threshold Range of Chemical Signals and Drought Tolerance Was Mediated by ROS Homeostasis in Winter Wheat During Progressive Soil Drying

The soil-water threshold range of chemical signals and reactive oxygen species (ROS) homeostasis could have a profound impact on drought tolerance in wheat. A pot experiment was used to investigate the homeostasis between ROS and antioxidant defense at five harvest dates, and its role in the correlation between soil-water threshold range of chemical signals and drought tolerance in three wheat (Triticum aestivum) cultivars during progressive soil drying. The cultivars were bred at different periods, cv. BM1 (old), cv. Xiaoyan6 (recent), and cv. Shan229 (modern). They were treated with progressive soil drying. Shoot biomass was affected by drought imposed by two water treatments (90% and 55% field water capacity). The modern wheat cultivar had a lower ROS content and higher ROS-scavenging antioxidant capacity with greater soil drying (68–25% soil water content) compared with the older cultivar. The modern cultivar also had excellent adaptation to drought, with a longer survival of 22.7 days and less reduction in shoot biomass of 20.9% due to early chemical signals and better balance between ROS production and antioxidants. The older cultivar had survival of 15.3 days and 37.3% reduction of shoot biomass. A wider soil-water threshold range of chemical signals was positively correlated with improved drought tolerance and better ROS homeostasis. These results suggest that ROS homeostasis acts as a regulator in relationships between the soil-water threshold range of chemical signals and drought tolerance.     

Effects of fulvic acid on the photosynthetic and physiological characteristics of Paeonia ostii under drought stress

ABSTRACTPaeonia ost iihas become an economically important oil crop in recent years, but its growth is seriously affected by drought stress in dry areas. In this study, the alleviating effect of fulvic acid (FA) on potted P. ostii under natural drought stress was investigated. The natural drought stress adopted in this experiment was mainly characterized by the low soil water content, and the roots of plants cannot absorb enough water to compensate for the consumption of transpiration, which affects the normal physiological activities and causes damage. The results showed that FA treatment significantly increased the leaf water content and antioxidant enzyme activities and decreased reactive oxygen species (ROS) accumulation, the proline (Pro) content, and the relative electrical conductivity (REC). Moreover, FA treatment improved photosynthetic parameters and chlorophyll (Chl) fluorescence parameters, maintained the integrity of chloroplasts and mesophyll cells, and increased the expression level of drought-tolerant genes. These results indicated that FA treatment could induce antioxidant enzymes to eliminate ROS, reduce membrane lipid peroxidation and decrease damage to photosynthesis in P. ostii under drought stress, which would provide a measure for alleviating the damage of P. ostii caused by drought stress.KEYWORDS: P. ostii, fulvic acid, drought stress, antioxidant enzymes, photosynthesis     

Effect of NaCl,water stress or both on gas exchange and growth of wheat

Responses of wheat (Triticum aestivum L.) to various concentrations of NaCl and levels of drought were followed. With the rise of NaCl or drought, or NaCl and drought together, growth was retarded. The water content of shoots and roots was mostly unchanged. The chlorophyll and carotenoid contents were increased in plants subjected to salinity or drought or both. Only high salinity level induced a considerable decrease in net photosynthetic rate (P_N) and dark respiration rate (R_D). P_N and R_D were decreased with the decrease of soil moisture content. The content of Na⁺ in the shoots and roots of wheat plants increased with increasing salinity or decreasing soil moisture content or both treatments. Considerable variations in the content of K⁺, Ca²⁺ or Mg²⁺ were induced by the NaCl, drought or both treatments.     

库布齐沙地两种植被恢复类型根际土壤微生物和土壤化学性质比较研究

油蒿(Artemisia ordosica)与中间锦鸡儿(Caragana intermedia)是库布齐沙地分布广泛的优良固沙植被类型,在植被恢复过程中受到关注。以库布齐沙地自然恢复的油蒿群落与人工种植的中间锦鸡儿群落为研究对象,以流动沙地为对照,采用野外调查、室内生化实验与统计分析相结合的方法,分析两种植被恢复类型根际与非根际土壤微生物、土壤化学性质的差异,研究土壤微生物与土壤化学性质间的相关关系,并运用综合指数法评价两种植被恢复类型对土壤生态系统的恢复效果,为库布齐沙地植被恢复与重建提供科学依据。主要结论如下:(1)与流沙对照相比,两种植被恢复类型根际、非根际土壤微生物数量、微生物生物量碳、氮含量均有不同程度的提高,其中,自然恢复的油蒿群落根际土壤微生物总数、细菌数量、微生物量碳和氮含量均显著高于中间锦鸡儿根际,真菌和放线菌数量分布表现为中间锦鸡儿油蒿;(2)两种植被恢复类型根际、非根际土壤有机质、全氮、全磷、速效氮、速效钾含量均比流动沙地有不同程度地提高,其中,油蒿根际、非根际土壤有机质、全氮、速效氮含量显著高于中间锦鸡儿;(3)影响油蒿和中间锦鸡儿群落土壤微生物数量、生物量碳和氮的土壤因子是有机质、p H值、全氮、速效氮、速效钾、速效磷,其中,对两种植被恢复类型土壤微生物数量和生物量有正向促进作用的主要因子是土壤有机质、速效钾和全氮含量;(4)运用综合指数法计算出基于14个土壤指标的土壤质量综合指数(SQI),SQI值排序为:油蒿根际中间锦鸡儿根际油蒿非根际中间锦鸡儿非根际流沙对照。自然恢复的油蒿群落对土壤质量的改良效果显著优于人工种植的中间锦鸡儿群落,是库布齐沙地生态恢复的适合途径之一。     

堇菜叶片草酸钙晶体与水分维持的关系

随着全球气候变化加重,干旱强度和持续时间逐渐增加,严重影响植物生长和作物产量。喀斯特为典型的干旱和高钙生境,植物叶片富集大量的草酸钙晶体,而该晶体与植物耐旱性之间的关系并不清楚。该研究以喀斯特适生植物堇菜(Viola verecumda)为材料,土壤进行自然干旱,分析堇菜叶片的草酸钙晶体变化特征与水分之间的关系。结果表明:在土壤自然干旱条件下,堇菜主要通过细胞内束缚水的释放,维持细胞内水分平衡;而在干旱后期,叶片通过关闭气孔,将部分自由水转变为束缚水,防止水分流失。此外,草酸钙晶体的密度与束缚水含量具有极其显著的强正相关线性回归关系(r=0.825 3,P0.000 1),表明草酸钙晶体作为主要的束缚水物质。因此,堇菜植物在耐旱过程中可能协调草酸钙晶体和气孔的生理行为忍耐干旱胁迫。     

Dehydration of isolated roots of seven <Emphasis Type="Italic">Lupinus</Emphasis> species induces synthesis of different amounts of free,but not conjugated,abscisic acid

Abscisic acid (ABA) is recognised as an important hormone involved in root-to-shoot communication of drought stress in plants. This study aimed to determine whether isolated roots can produce both free and conjugated ABA (ABA–glucose ester) and whether Lupinus species vary in the synthesis of ABA in the roots when dehydrated. The concentration of free and conjugated ABA at 100 and 50% root water content was measured in the distal 10 mm of the roots of 3- to 5-day-old seedlings of seven Lupinus species with and without 10⁻⁵ M tetcyclacis, an inhibitor of the oxidative breakdown of ABA. When the root tips were exposed to tetcyclacis, the concentration of free ABA increased by 20% on average, suggesting that oxidative breakdown of free ABA was limited in the isolated Lupinus roots. The concentration of free ABA of the fully hydrated plants varied significantly among genotypes and more than doubled on average across genotypes with dehydration of the root tips to 50% water content. The concentration of conjugated ABA also varied significantly with species, but was only one-tenth the concentration of free ABA in the roots and did not change significantly with root dehydration or the inhibition of oxidative metabolism. The production of free ABA in response to the water deficit varied with species from +470% in L. digitatus to +33% in L. angustifolius. The small concentration and lack of increase of conjugated ABA with water deficit suggests that it is unlikely to have an important role as a root signal in response to soil drying in Lupinus species.     

毛乌素沙地油蒿叶性状对光能利用效率动态的影响

目前对于荒漠灌木光能利用效率（LUE）的季节变异及其调控因素,尤其是其生物调控因素的认识非常有限,导致了荒漠生态系统生产力模型的不确定性。拟验证假设：长期干旱环境下,典型荒漠灌木油蒿光能利用效率日均值（LUE_day）的动态变化与叶片性状的季节性调整有关。试验采用Li-6400便携式光合仪定期测量了油蒿生长季叶片LUE_day的季节动态及相关叶性状指标,探究叶性状对LUE_day的影响。结果表明：LUE_day的季节波动范围为0.003-0.017 mol/mol,整体变异系数（CV）为38.75%。完全展叶期LUE_day均值相比生长季平均值降低17.37%,相比展叶期和落叶期时降低30%;8个叶性状的季节变异幅度差异较大,其中总叶绿素含量（Chl）、类胡萝卜素含量（Car）和叶氮含量（LNC）均表现出较大的季节变异性（CV ≥ 20%）,叶碳含量（LCC）和叶片相对含水量（LRWC）的变异程度最低（CV<7%）。LRWC与所有叶片化学性状（Chl、Chl a/b、Car、LNC和LCC）均存在显著相关,表明其变化与叶片的养分吸收、光合色素合成以及碳同化的运输过程密切相关;油蒿LUE_day的相对变化与LRWC、Chl a/b和LNC显著正相关,而LRWC和LNC的季节动态受空气温度（T_a）和土壤含水量（VWC）的共同调节,Chl a/b的季节波动主要由浅层土壤含水量（10 cm VWC）控制。以上研究结果强调,在未来预计极端的气候事件（如极端干旱和持续热浪事件）发生更频繁的旱地场景中,时间尺度植物叶性状对于土壤干旱和高温的适应性调整应当被充分考虑到旱地生态系统的通量建模方案中。该结果将为构建叶片尺度的光合生理模型与厘清LUE的生物调控机制提供理论依据。     

玉米早期根系构型及其生理特性对土壤水分的响应

为了探明玉米早期根系结构及其对土壤水分的生理响应,揭示玉米幼苗的抗旱机理,以蠡玉18为材料,采用盆栽试验,设置轻度胁迫(LS)、中度胁迫(MS)、重度胁迫(SS)和正常供水(CK)4个水分处理,系统研究从播种开始持续水分处理对夏玉米苗期根系形态结构及活力、保护酶系统及生理调节物质的影响。结果表明:随着水分胁迫程度的加剧,玉米根长、根表面积、根体积和根干重等各形态指标较CK下降幅度逐渐增大,不同水分胁迫使夏玉米苗期根系结构存在差异。轻度和中度胁迫显著增加了细根(0.05—0.25 mm)根长和根表面积比例,重度水分胁迫显著降低粗根(0.50 mm)根长与根表面积比例。玉米苗期根冠比、根系活力和丙二醛(MDA)含量随水分胁迫程度的增强而上升,随着胁迫时间的延长,根冠比逐渐降低。根系可溶性蛋白含量随土壤水分含量的下降而下降,MS、SS处理较CK显著降低(P0.05)。夏玉米根系中SOD对水分胁迫较CAT、POD更敏感,轻度水分胁迫下主要依赖CAT、中度水分胁迫下主要依赖POD、重度水分胁迫下主要依赖SOD来降低氧化伤害;且重度胁迫下,随着胁迫时间的延长保护酶活性下降。苗期玉米通过增加根冠比、增强根系活力和不同保护酶活性及降低可溶性蛋白等渗透调节物质来协同减少水分胁迫的危害。     

夏玉米叶片水分变化与光合作用和土壤水分的关系

叶片是光合作用的重要器官,其含水量的变化必将影响光合作用,但关于叶片水分变化对光合作用的影响报道较少。以华北夏玉米为研究对象,利用三叶期不同水分梯度的持续干旱模拟试验资料,分析夏玉米叶片水分变化及其与叶片净光合速率和土壤水分的关系。结果表明:夏玉米叶片净光合速率对叶片水分变化的响应显著且呈二次曲线关系,叶片含水量约为70.30%时,叶片净光合速率为零;叶片含水量与土壤相对湿度呈非直角双曲线关系,叶片最大含水量约为85.14%。研究结果可为准确描述叶片水分变化对光合作用的影响及客观辨识夏玉米干旱的发生发展及监测预警提供参考。     

Nitrate uptake ability by maize roots during and after drought stress

The effects of different intensities and durations of soil drought and re-watering on the nitrate uptake ability of maize roots were studied. Plants were grown in split-root containers with one part of the root system subjected to different intensities and durations of soil drought and re-watering while the other part of the root system was continuously watered to 23% (w/w) soil water content (70% water capacity). Experiments were performed in split-root containers to maintain a high growth rate, thus ensuring high nutrient demand of the shoot irrespective of the soil water regime. To avoid limitation of nitrate uptake by transport processes in the dry soil, and to ensure a uniform ¹⁴N/¹⁵N ratio at the root surface, ¹⁵N was applied to the roots by placing them into an aerated nutrient solution with 0.5 mM Ca(¹⁵NO₃)₂. Shoot elongation and biomass were only slightly affected by drought in one root compartment when the soil in the other root compartment was kept wet. Therefore, the growth-related nutrient demand of the shoot remained at a high level. At moderate levels of soil drought (10% w/w water content) the ability of the roots for N-uptake was not affected even after 10 d of drought. N-uptake ability was reduced to about 20% of the well-watered control only when the soil water content was decreased to 5%. Total soluble sugar content of the roots increased with increasing soil drought, indicating that low N-uptake ability of roots subjected to severe soil drought was not caused by low assimilate supply from the shoot. Nitrate uptake ability of roots maintained in very dry soil (5% soil water content w/w) even for a prolonged period of 8 d, recovered within 3 d following re-watering. Root growth increased one day after re-watering. A short-term experiment with excised roots formerly subjected to severe soil drought showed that nitrate uptake ability recovered in old and young root segments after 2 d of re-watering. Obviously, the increase in N-uptake ability after re-watering was caused not only by new root growth but also by recovery of the uptake ability of formerly stressed roots.     

Changes in antioxidant enzyme activity in the fine roots of black poplar (Populus nigra L.) and cottonwood (Populus deltoides Bartr. ex Marsch) in a heavy-metal-polluted environment

The effect of heavy metal deposition onto soil from a copper smelter on lipid peroxidation and antioxidant enzyme activity in the fine roots of two poplars (Populus nigra L. and Populus deltoides Bartr. ex Marsch) was analyzed. The subjects were mature trees growing in real environments. In both analyzed species, heavy metals stimulated the overproduction of free radicals in fine roots (measured as malondialdehyde level), which was directly proportional to advancing senescence. In young fine roots, heavy metals caused a decrease in guaiacol peroxidase activity and presumably disturbed the lignification process. Catalase was highly sensitive to the presence of heavy metals in the soil. In contrast, ascorbate peroxidase and glutathione reductase activities were unaffected by heavy metals. In the case of superoxide dismutase, a clear increase in enzyme activity was observed only in P. nigra under drought conditions, whereas it was inhibited in polluted stands.     

植物水分传输过程中的调控机制研究进展

农田土壤水分的转化利用与调控是以土壤-植物-大气连续体(SPAC)为基础,以植物为核心,其中水分在植物体内的传输与调控研究一直是国际学术研究的前沿性热点课题。本文概述了植物水分传输的驱动力和传输途径,重点从植物的气孔调节、水容调节、渗透调节、水孔蛋白调节、贮水调节、气穴和栓塞调节等方面综述了植物水分传输过程中的调控机制研究进展。通过对植物存在优化调控水分平衡的潜在能力的研究,不仅可充实SPAC系统水分传输理论,而且有助于明确植物对环境的适应机制和高效用水的潜力及其节水调控的效应,对指导干旱半干旱地区农业生产提供理论依据。