Effect of cerium on photosynthetic characteristics of soybean seedling exposed to supplementary ultraviolet-B radiation

Effects of cerium （Ce^3＋） on photosynthetic characteristics were investigated by hydroponics under laboratory conditions when soybean seedlings were exposed to two levels of supplementary UV-B radiation. UV-B radiation badly inhibited the photosynthesis in soybean seedling, leading to a reduction in net photosynthetic rate （Pn）, Hill reaction activity, light saturated photosynthetic rate （Ps） and apparent quanta yield （AQY）, as well as the CO2 and light saturated photosynthetic rate （Pro） and carboxulation efficiency （CE）. On the contrary, Ce obviously promoted the photosynthesis of plants by increasing Hill reaction activity, accelerating electron transport and photophosphorylation, and enhancing carboxylation efficiency. For Ce＋UV-B treatments, the values of photosynthetic parameters were still lower than those of the control, but obviously higher than those of UV-B treatment. The results indicated that Ce alleviated the inhibition of UV-B radiation on the photosynthesis in soybean seedling to a certain extent. In correlating of Pn with Hill activity, AQY and CE, we found that the changes of photosynthetic rate were mainly influenced by the regulating effect of Ce on Hill activity and AQY at low level （0.15 W/m^2） of UV-B radiation, but were dominated by the regulating effect of Ce on CE at high level （0.45 W/m^2）. Thus, Ce could regulate many aspects in photosynthesis of soybean seedling under UV-B stress. The regulating mechanism was close related with the dosage of UV-B radiation.     

Low-temperature conversion of ammonia to nitrogen in water with ozone over composite metal oxide catalyst

As one of the most important water pollutants, ammonia nitrogen emissions have increased year by year, which has attracted people's attention. Catalytic ozonation technology, which involves production of ·OH radical with strong oxidation ability, is widely used in the treatment of organic-containing wastewater. In this work, MgO-Co_3O_4 composite metal oxide catalysts prepared with different fabrication conditions have been systematically evaluated and compared in the catalytic ozonation of ammonia(50 mg/L) in water. In terms of high catalytic activity in ammonia decomposition and high selectivity for gaseous nitrogen, the catalyst with MgO-Co_3O_4 molar ratio 8:2, calcined at 500°C for 3 hr, was the best one among the catalysts we tested, with an ammonia nitrogen removal rate of 85.2% and gaseous nitrogen selectivity of44.8%. In addition, the reaction mechanism of ozonation oxidative decomposition of ammonia nitrogen in water with the metal oxide catalysts was discussed. Moreover, the effect of coexisting anions on the degradation of ammonia was studied, finding that SO_2-4 and HCO-3 could inhibit the catalytic activity while CO_2-3 and Br-could promote it. The presence of coexisting cations had very little effect on the catalytic ozonation of ammonia nitrogen. After five successive reuses, the catalyst remained stable in the catalytic ozonation of ammonia.     

Reduction of nitrate from groundwater: powder catalysts and catalytic membrane

The reduction of nitrate contaminant in groundwater has gained renewed and intensive attention due to the environmental problems and health risks. Catalytic denetrification presents one of the most promising approaches for the removal of nitrate from water. Catalytic nitrate reduction from water by powder catalysts and catalytic membrane in a batch reactor was studied. And the effects of the initial concentration, the amounts of catalyst, and the flux H2 on the nitrate reduction were also discussed. The results demonstrated that nitrate reduction activity and the selectivity to nitrogen gas were mainly controlled by diffusion limitations and the mass transfer of the reactants. The selectivity can improved while retaining a high catalytic activity under controlled diffusion condition or the intensification of the mass transfer, and a good reaction condition. The total nitrogen removal efficiency reached above 80%. Moreover, catalytic membrane can create a high effective gas/liquid/solid interface, and show a good selectivity to nitrogen in comparative with the powder catalyst, the selectivity to nitrogen was improved from 73.4 % to 89.4%.     

Ultraviolet irradiation induced oxidative stress and response of antioxidant system in an intertidal macroalgae Corallina o cinalis L.

The response of the antioxidant defense system of an intertidal macroalgae Corallina officinalis L. to different dosages of UV-B irradiation was investigated. Results showed that superoxide dimutase (SOD) and peroxidase (POX) increased and then maintained at a relatively stable level when subjected to UV-B irradiation. Catalase (CAT) activity under medium dosage of UV-B irradiation (Muv) and high dosage of UV-B irradiation (Huv) treatments were significantly decreased. Ascorbate peroxidase (APX) activity first remained unaltered and then increased in Huv treatment. In addition, the assay on isozymes was carried out using non-denaturing polyacrylamide gel electrophoresis (PAGE). The activities of some SOD isoforms were altered by UV-B. Two new bands (POX V and POX Ⅶ) appeared upon exposure to all three UV-B dosages. CAT Ⅲ activity was increased by low dosage of UV-B irradiation (Luv),whereas CAT Ⅲ and CAT Ⅳ disappeared when the alga was exposed to Muv and Huv. Two bands of APX (APX Ⅵ and APX Ⅶ)were increased and a new band (APX X) was observed under Huv exposure. H2O2 and thiobarbituric acid reacting substance (TBARS)increased under Muv and Huv treatments. Overall, UV-B protection mechanisms are partly inducible and to a certain extent sufficient to prevent the accumulation of damage in C officinalis.     

Effects of cerium on growth and physiological mechanism in plants under enhanced ultraviolet-B radiation

Effect of cerium （Ce^3＋） on the growth, photosynthesis and antioxidant enzyme system in rape seedlings （Brassica juncea L.） exposed to two levels of UV-B radiation （T1： 0.15 W/m^2 and T2：0.35 W/m^2） was studied by hydroponics under laboratory conditions. After 5 d of UV-B treatment, the aboveground growth indices were obviously decreased by 13.2%-44. 1%（T1） and 21.4%-49.3% （T2）, compared to CK, and except active absorption area of roots, the belowground indices by 14.1%-35.6%（T1） and 20.3%-42.6% （T2）. For Ce＋UV-B treatments, the aboveground and belowground growth indices were decreased respectively by 4.1%-23.6%, 5.2% -23.3%（Ce＋T1） and 10.8%-28.4%, 7.0%-27.8%（Ce＋T2）, lower than those of UV-B treatments. The decrease of growth indices appeared to be the result of changes of physiological processes. Two levels of UV-B radiation induced the decrease in chlorophyll content, net photosynthesis rate, transpiration rate, stomatal conductance and water use efficiency by 11.2%-25.9%（T1） and 20.9%- 56.9%（T2）, whereas increase in membrane permeability and activities of antioxidant enzymes including superoxide dismutase（SOD）, catalase （CAT） and peroxidase （POD） by 6.9%, 22.8%, 21.5%, 9.5%（T1） and 36.6%, 122.3%, 103.5%, 208.9%（T2）, respectively. The reduction of the photosynthetic parameters in Ce＋UV-B treatments was lessened to 3.2%-13.8%（Ce＋T1） and 4.9%-27.6%（Ce＋T2）, and the increase of membrane permeability and activities of antioxidant enzymes except POD in the same treatments were lessened to 2.4%, 8.4%, 6.6%（Ce＋T1） and 30.1%, 116.7%, 75.4%（Ce＋T2）. These results indicate that the regulative effect of Ce on photosynthesis and antioxidant enzymatic function is the ecophysiological basis of alleviating the suppression of UV-B radiation on growth of seedlings. Furthermore, the protective effect of Ce on seedlings exposed to TI level of UV-B radiation is superior to T2 level.     

Responses of chlorophyll fluorescence and nitrogen level of Leymus chinensis seedling to changes of soil moisture and temperature

Controlled experiment of Leymus chinensis seedlings grown in the environmental growth chambers at 3 soil moisture levels and 3 temperature levels was conducted in order to improve the understanding how leaf photosynthetic parameters will respond to climatic change. The results indicated that soil drought and high temperature decreased the photochemical efficiency of photosystem ( Fw/Fm ), the overall photochemical quantum yield of PSIl(yield), the coefficient of photochemical fluorescence quenching(qp), but increased the coefficient of non-photochemical fluorescence quenching( q, ). Severe soil drought would decrease Fv/Fm and yield by 3.12% and 37.04% under 26% condition, respectively, and 6.60% and 73.33% under 32% condition, respectively,suggesting that higher temperature may enhance the negative effects of soil drought. All the soil drought treatments resulted in the decline in leaf nitrogen content. There was no significant effect of temperature on leaf nitrogen level,but higher temperature significantly reduced the root nitrogen content and the ratio of root nitrogen to leaf nitrogen,indicating the different strategies of adaptation to soil drought and temperature. It was also implied that higher temperature would enhance the effect of soil drought on leaf photosynthetic capacity, decrease the adaptability of Leymus chinensis to drought.     

Mercury in some chemical fertilizers and the effect of calcium superphosphate on mercury uptake by corn seedlings(Zea mays L.)

Mercury (Hg) contents in ten chemical fertilizers were determined, and the effect of calcium superphosphate (CSP) on the uptake and translocation of Hg in corn seedlings was investigated by pot experiments. CSP was applied at the levels of 0, 66.7, and 133.4 mg P2O5/kg to Hg-treated (2 mg/kg) and untreated soils. CSP had the highest Hg content (5.1 mg/kg), followed by the NPK compound fertilizer 15-5-5 (15% N, 5% P2O5, 5% K2O) (1.2 mg/kg), then by nitrogen fertilizers (except for ammonia sulfate) and potassium fertilizers. Application of CSP did not obviously iuence the biomass of corn roots, but it significantly increased the biomass of corn shoots in Hg-treated soil. Application of CSP at the levels of 66.7 and 133.4 mg P2O5/kg did not obviously iuence the uptake of Hg by corn seedlings on soils without Hg treatment, but it decreased the Hg uptake of corn seedlings significantly on Hg-treated soils. The transfer coefficient of Hg in corn seedlings improved slightly on soils without Hg treatment, but decreased slightly on Hg-treated soils with the application of CSP. These results implied that CSP could ameliorate Hg toxicity to corn seedlings by inhibiting the uptake and the translocation of Hg in plants on Hg-polluted soils.     

Responses of antioxidant enzyme and photosynthesis in rape seedling to the combined stresses from simulated acid rain and elevated ultraviolet-B radiation

Effects of the simulated acid rain（AR） and ultraviolet-B（UV-B, 280-320 nm） radiation with a single or two ways simultaneously （AR ＋ UV-B） on the antioxidant enzyme and photosynthesis of the rape seedlings were investigated by the hydroponic culture. The results of static experiment indicated that the tolerance of rape seedling to single stress（AR or UV-B） is stronger than that to dual stresses（AR ＋ UV-B）. Furthermore, the dual stresses had additive effect on catalase activity, and a synergistic effect on MDA content, net photosynthesis rate, water use efficiency as well as intercellular CO2 concentration. Meanwhile, it has an independent effect on chlorophyll content, stomatal conductance, and transpiration rate as well as membrane permeability. During 64 h restoration course, the dynamic change in the curves of physiological and biochemical indices were not identical, and none of them show a simple linear variation. According to the static and dynamic experiments, it was found that a responsive sequence of catalase activity, membrane permeability, MDA content and photosynthetic characteristics to the above-mentioned stresses was as follows： AR ＋ UV-B 〉 UV-B 〉 AR.     

Denitrification and the controlling factors in Yunnan Plateau Lakes (China): Exploring the role of enhanced internal nitrogen cycling by algal blooms

Denitrification plays an important role in nitrogen(N) removal in freshwater ecosystems.This internal process regulates the fluctuations of N concentration, especially for lakes with high nutrients concentrations and long residence time. Lakes in Yunnan plateau(southwestern China) provide typical cases, while studies in this region have been rare.Therefore, we studied denitrification of two lakes(Lake Dianchi in hypereutrophic state and Lake Erhai in mesotrophic) in this region. We used acetylene inhibition technique to quantify potential denitrification rate(PDR) of these lakes in April and August, 2015 and 2016. PDR of the sediments ranged 0–1.21 μmol/(N·m~2·hr), and that of overlying water ranged 0–0.24 μmol/(N·L·hr). Then, we used Least Angle Regression to determine the controlling factors for denitrification. Nutrients controlled PDR from two aspects: providing essential nitrogen sources; and affecting the richness and metabolism of denitrifying bacteria. In April, both aspects limited PDR; while only nitrogen sources limited PDR in August, due to depleted nitrate and enhanced denitrifying bacteria activity. Ammonia was most significant to denitrification, indicating that nitrate from nitrification transported to the bottom of wellmixed lake provide major N source by denitrification. The high PDR and low nitrate concentrate in August were evidence of an enhanced internal N cycling by algal blooms.     

Effects of soil water and nitrogen availability on photosynthesis and water use efficiency of Robinia pseudoacacia seedlings

The efficient use of water and nitrogen (N) to promote growth and increase yield of fruit trees and crops is well studied.However,little is known about their effects on woody plants growing in arid and semiarid areas with limited water and N availability.To examine the effects of water and N supply on early growth and water use efficiency (WUE) of trees on dry soils,one-year-old seedlings of Robinia pseudoacacia were exposed to three soil water contents (non-limiting,medium drought,and severe drought) as well as to low and high N levels,for four months.Photosynthetic parameters,leaf instantaneous WUE (WUEi) and whole tree WUE (WUEb) were determined.Results showed that,independent of N levels,increasing soil water content enhanced the tree transpiration rate (Tr),stomatal conductance (Gs),intercellular CO2 concentration (Ci),maximum net assimilation rate (Amax),apparent quantum yield (AQY),the range of photosynthetically active radiation (PAR) due to both reduced light compensation point and enhanced light saturation point,and dark respiration rate (Rd),resulting in a higher net photosynthetic rate (Pn) and a significantly increased whole tree biomass.Consequently,WUEi and WUEb were reduced at low N,whereas WUE i was enhanced at high N levels.Irrespective of soil water availability,N supply enhanced Pn in association with an increase of Gs and Ci and a decrease of the stomatal limitation value (Ls),while Tr remained unchanged.Biomass and WUEi increased under non-limiting water conditions and medium drought,as well as WUEb under all water conditions;but under severe drought,WUEi and biomass were not affected by N application.In conclusion,increasing soil water availability improves photosynthetic capacity and biomass accumulation under low and high N levels,but its effects on WUE vary with soil N levels.N supply increased Pn and WUE,but under severe drought,N supply did not enhance WUEi and biomass.     

镧对UV-B胁迫下大豆幼苗类黄酮含量与抗氧化能力影响

为进一步认识La(Ⅲ)提高类黄酮含量及减轻UV-B辐射伤害植物机制,以大豆幼苗为材料,采用水培实验的方法研究了La(Ⅲ)对UV-B辐射胁迫下大豆幼苗类黄酮抗氧化能力的动态影响.结果表明, UV-B辐射(T1:0.15W·m-2和T2:0.45W·m-2)胁迫下,大豆幼苗类黄酮含量在胁迫期和恢复期均先升后降,质膜透性、MDA含量先升(1～5d)后降(6～11d),类黄酮对O·-2和·OH的清除率与其含量变化趋势近同.各处理组类黄酮含量La(Ⅲ) UV-B>UV-B>La(Ⅲ)>CK, La(Ⅲ) T1>La(Ⅲ) T2;质膜透性、MDA含量UV-B>La(Ⅲ) UV-B>CK>La(Ⅲ), La(Ⅲ) T2>La(Ⅲ) T1;类黄酮对O-2和·OH清除率La(Ⅲ) UV-B>UV-B>La(Ⅲ)>CK, La(Ⅲ) T1, La(Ⅲ) T2,表明La(Ⅲ)对类黄酮的调控作用,提高了清除活性氧自由基的运行效率,降低了MDA浓度,维持了质膜正常透性,且对低剂量(T1)的防护效果优于高剂量(T2),进而在防御系统层面实现了La(Ⅲ)对UV-B辐射伤害大豆幼苗的防护效应.     

UV-B辐射胁迫对大豆幼苗内源激素的影响

为了探索UV-B辐射胁迫对大豆幼苗内源激素的影响,试验以大豆幼苗为材料,采用水培实验的方法研究了UV-B辐射胁迫对大豆幼苗生长素(IAA)、生长素氧化酶(IAAO)、脱落酸(ABA)、赤霉素(GA)的影响.结果表明,UV-B辐射(T1:0.15W.m-2和T2:0.45 W.m-2)胁迫下,大豆幼苗IAAI、AAO、ABA、GA含量在胁迫期(1~5 d)和恢复期(6~11 d)分别呈现"先下降后有所回升"、"先升后降再升"、"先升后降"、"下降"趋势.进而从内源激素层面表明了UV-B辐射伤害大豆幼苗的机理效应。     

Mn对超富集植物短毛蓼和水蓼生长、Mn吸收及氮素代谢的影响

摘要：采用水培的方法,研究了不同浓度Mn（0.0003、0.5、1、2、4、8 mmol•L-1）对Mn超富集植物短毛蓼（Polygonum pubescens Blume）和水蓼（Polygonum hydropiper L.）叶片铵态氮、硝态氮、游离脯氨酸、可溶性蛋白质含量及氮素代谢关键酶：硝酸还原酶（NR）、谷氨酰胺合成酶（GS）、谷氨酸合酶（GOGAT）和谷氨酸脱氢酶（GDH）活性的影响。结果表明,随着Mn处理浓度的增加,短毛蓼和水蓼的根、茎、叶中Mn含量显著增加（p < 0.05）,在相同Mn处理浓度下短毛蓼中的Mn含量均大于同部位水蓼中的Mn含量。在Mn处理浓度小于1 mmol•L-1时,Mn对短毛蓼的株高、株重影响不明显,但对水蓼的影响显著（p < 0.05）,表明短毛蓼比水蓼更耐Mn污染。Mn处理显著降低了短毛蓼硝态氮含量（p < 0.05）,提高了可溶性蛋白质含量,8 mmol•L-1的Mn处理显著提高了水蓼硝态氮、铵态氮、可溶性蛋白质含量以及短毛蓼、水蓼游离脯氨酸含量,在Mn浓度为8 mmol•L-1时,短毛蓼、水蓼叶片中游离脯氨酸的含量分别为对照的1.18倍和1.68倍,表明游离脯氨酸在解Mn毒害过程中起重要作用。Mn引起了短毛蓼和水蓼氮素代谢关键酶活性的变化,显著降低了水蓼叶片NR、短毛蓼叶片GS活性（p < 0.05）;在Mn处理浓度为1 mmol•L-1时,短毛蓼叶片NR活性最高,为对照的1.91倍,而2、4、8 mmol•L-1 Mn处理显著降低了短毛蓼和水蓼GOGAT活性（p<0.05）。另外,Mn处理显著提高了短毛蓼和水蓼叶片GDH活性（p < 0.05）,在Mn处理浓度为8 mmol•L-1时,短毛蓼、水蓼叶片GDH的活性分别为对照的16.29倍和1.29倍。     

Mn对超富集植物短毛蓼和水蓼生长、Mn吸收及氮素代谢的影响

采用水培的方法,研究了不同浓度Mn(0.0003、0.5、1、2、4、8 mmol · L^-1)对Mn超富集植物短毛蓼(Polygonum pubescens Blume)和水蓼(Polygonum hydropiper L.)叶片铵态氮、硝态氮、游离脯氨酸、可溶性蛋白质含量及氮素代谢关键酶:硝酸还原酶(NR)、谷氨酰胺合成酶(GS)、谷氨酸合酶(GOGAT)和谷氨酸脱氢酶(GDH)活性的影响.结果表明,随着Mn处理浓度的增加,短毛蓼和水蓼的根、茎、叶中Mn含量显著增加(p<0.05),在相同Mn处理浓度下短毛蓼中Mn含量均大于同部位水蓼中Mn含量.在Mn处理浓度小于1 mmol · L^-1时,Mn对短毛蓼的株高、株重影响不显著,但对水蓼的影响显著(p<0.05),表明短毛蓼比水蓼更耐Mn污染.Mn处理显著降低了短毛蓼硝态氮含量(p<0.05),提高了可溶性蛋白质含量,浓度为8 mmol · L^-1的Mn处理显著提高了水蓼硝态氮、铵态氮、可溶性蛋白质含量及短毛蓼、水蓼游离脯氨酸含量(p<0.05).Mn引起了短毛蓼和水蓼氮素代谢关键酶活性的变化,显著降低了水蓼叶片NR、短毛蓼叶片GS活性(p<0.05);在Mn处理浓度为1 mmol · L^-1时,短毛蓼叶片NR活性最高,为对照的1.91倍,而2、4、8 mmol · L^-1 Mn处理显著降低了短毛蓼和水蓼GOGAT活性(p<0.05).另外,Mn处理显著提高了短毛蓼和水蓼叶片GDH活性(p<0.05),在Mn处理浓度为8 mmol · L^-1时,短毛蓼、水蓼叶片GDH活性分别为对照的16.29倍和1.29倍.     

Ce(Ⅲ)对UV-B辐射胁迫下大豆幼苗光化学反应的影响

用水培法研究Ce(Ⅲ)对UV-B辐射胁迫下大豆幼苗光化学反应的影响.结果表明, 20 mg·L^-1 CeCl₃使大豆幼苗净光合速率(Pn)、Hill反应、Mg²⁺-ATPase活性与光合磷酸化活力4项指标较对照提高23.2%～14.3%; 有效抑制UV-B辐射(T₁=0.15 W·m^-2和T₂=0.45 W·m^-2)胁迫下4项指标下降, 4项指标降幅［Ce(Ⅲ)+T₁为36.6%～15.9%,Ce(Ⅲ)+T₂为65.6%～33.2%］小于对应的UV-B辐射组(T₁为50.9%～23.3%,T₂为77.3%～51.4%). 动态变化显示, Ce(Ⅲ)减缓了胁迫期4项指标的下降趋势,促进了恢复期4项指标上升幅度. 说明Ce(Ⅲ)通过减轻UV-B辐射对大豆幼苗光化学反应的伤害, 遏制UV-B辐射胁迫下大豆幼苗Pn下降.     

钙对紫外辐射B胁迫下小麦幼苗若干生物学特性的影响

采用模拟紫外辐射(UV-B,280～320nm)的盆栽实验法,研究钙离子对紫外B辐射胁迫下小麦幼苗若干生物学特性的影响.结果显示,在紫外辐射胁迫下(0.35W/m²,每日照射6h,连续照射7d),2mmol/L钙离子处理的小麦,地下与地上部生长指标均明显低于对照植株(降幅为8.1%～36.1%).而6mmol/L钙离子处理的小麦幼苗,各种生长指标的降幅(3.2%～28.6%)低于2mmol/L钙离子处理的小麦幼苗.表明钙离子具有缓解紫外辐射伤害小麦幼苗的效应,这同钙离子对小麦幼苗部分生理生化指标的影响有关.     

不同水分梯度下UV-B辐射对2个稻田土壤碳氮转化的影响

UV-B辐射对土壤碳氮转化的影响与土壤物理化学性质有关,为明确土壤水分状态对UV-B辐射的影响,以有机质含量不同的两个水稻土(有机质含量低的记为L,高的记为H)为研究材料,在室内研究了含水量为25%(W1)、50%(W2)和100%(W3)时,UV-B辐射对土壤总有机碳(TOC)、可溶性有机碳(DOC)、铵态氮(NH_4~+-N)、硝态氮(NO_3~--N)以及累积净矿化氮量的影响.结果表明:120 h后,与避光(对照,CK)相比,UV-B辐射显著降低了土壤TOC的含量(P0.05);UV-B辐射下,水分从低到高,L土壤的TOC分别降低了9.9%、4.5%和6.3%,H土壤降低了10.9%、5.6%和6.3%.但与对照相比,UV-B辐射却促使土壤DOC增加;且在UV-B辐射下水分为100%的处理中,土壤DOC含量高于25%和50%的处理,120 h时,L土壤的DOC分别增加了21.5%(W1)、9.4(W2)和26.3%(W3),H土壤分别降低了26.7%(W1)、14.2%(W2)和33.8%(W3).与对照相比,UV-B辐射使NH_4~+-N含量有所下降;且在UV-B辐射中,NH_4~+-N含量的变化幅度在不同水分条件下的整体表现为W1W2W3.较对照处理,UV-B辐射促进NO_3~--N的累积,NO_3~--N变化幅度在不同水分条件下的表现为:W1W3W2.24 h后与对照相比,UV-B辐射对土壤累积净矿化氮量有显著影响(P0.05),且UV-B辐射下累积净矿化氮量在不同水分之间差异显著(P0.05).这表明光降解在土壤有机质的稳定中扮演着重要角色,UV-B辐射会加速土壤有机碳的损失,影响土壤矿质态氮的转化,且水分不同,UV-B辐射对土壤碳氮转化的影响存在一定差异.     

模拟酸雨和稀土镧对大豆幼苗的复合影响

采用水培法通过测定大豆幼苗叶片和根的POD活性、MDA含量、H2O2含量,研究了酸雨(AR)和稀土La(Ⅲ)对大豆幼苗POD活性和脂膜过氧化的复合影响。结果表明:单一La(Ⅲ)(RE1/20 mg/L、RE2/60 mg/L、RE3/100 mg/L、RE4/300 mg/L)处理时,低剂量La(Ⅲ)(RE1/20 mg/L)处理下,叶和根中POD活性高于CK而MDA和H2O2含量较之降低,高剂量La(Ⅲ)(RE2/60 mg/L、RE3/100 mg/L、RE4/300 mg/L)处理下,叶和根3项指标均升高。在酸雨(ARl/pH2.5、AR2/pH3.5和AR3/pH4.5)单独作用和RE+AR复合作用影响下,叶和根3项指标均升高;而且AR的pH越低,RE的浓度越高,叶和根中的3项指标增幅越大。RE1和AR复合处理下叶和根中3项指标的增幅低于AR单一处理,其它浓度RE和AR复合处理叶和根中的3项指标增幅高于各自单独作用。单一酸雨处理组各指标变幅为叶>根,单一镧和复合处理组各指标变幅为根>叶。     

Cd对小白菜生长及氮素代谢的影响研究

采用水培的方法,研究了不同Cd2 水平(0、1、2.5、5、10 mg·L-1)对小白菜叶片中铵态氮、硝态氮、可溶性蛋白质、游离脯氨酸、叶绿素、部分营养元素含量以及蛋白水解酶、硝酸还原酶、谷氨酰胺转化酶与合成酶活性的影响.结果表明,低浓度的Cd处理(1 mg·L-1)刺激了小白菜的生长,提高了小白菜的生物量、叶绿素含量以及硝酸还原酶、谷氨酰胺合成酶与转化酶活性.Cd处理降低了小白菜对Cu、Ca、Fe、Mg的吸收,但促进了P的吸收.10 mg·L-1的Cd处理显著降低了可溶性蛋白质含量、硝酸还原酶、谷氨酰胺合成酶和转化酶活性(p＜0.05),提高了蛋白水解酶活性,不利于叶片中铵态氮与硝态氮的同化,造成叶片中铵态氮和硝态氮的累积.小白菜叶片中游离脯氨酸含量与铵态氮含量成极显著正相关(p＜0.01),说明小白菜叶片中游离脯氨酸的累积在一定程度上缓解了铵的毒害.