风车草和香根草在人工湿地中迁移养分能力的比较研究

为研究风车草（Cyperus alternifolius）和香根草（Vetiveria zizanioides）迁移养分的能力,建立17.0 m²风车草潜流式人工湿地和13.3 m²香根草潜流式人工湿地处理猪场废水,在四个季节末测定植物生物量和组织氮、磷、铜、锌含量.结果表明,香根草地下部生物量大于风车草,地上部生物量则是风车草大于香根草.风车草年地上部收获量为3406.47 g·m^-2,比香根草的1483.88 g·m^-2高2.3倍;风车草的氮含量为22.69 mg·g^-1,比香根草的15.44 mg·g^-1高7.25 mg·g^-1;风车草的磷含量为6.09 mg·g^-1,比香根草的5.47 mg·g^-1高0.62 mg·g^-1.植株含铜、锌量风车草略比香根草高.风车草每年迁移N 68.72 g·m^-2和P 18.49 g·m^-2,香根草迁移N 8.93 g·m^-2和P 3.69 g·m^-2.风车草人工湿地每年由植物迁移的氮、磷、铜、锌比香根草高4～7倍.     

氮素增加条件下丛枝菌根真菌对陆稻和无芒稗相互作用的调节

采用盆栽方法研究了增氮条件下丛枝菌根真菌(AMF)对无芒稗(Echinochloa crusgallivar.mitis L.)和陆稻(Oryza sativa L.)相互作用的调节.结果表明:在单种条件下,无芒稗的菌根侵染率增加,陆稻的菌根侵染率降低;无AMF和接种AMF处理陆稻的生物量分别提高13.48%和42.35%,总磷吸收分别提高2.55%和4.07%,总氮吸收分别提高62.09%和30.35%;无芒稗的生物量分别提高15.65%和20.24%,总磷吸收分别提高4.06%和3.88%,总氮吸收分别提高30.35%和15.10%.在混种条件下,无芒稗的菌根侵染率增加,而陆稻无显著变化;无AMF和接种AMF的无芒稗与陆稻的生物量比值降低,总氮吸收比值无显著变化,无AMF处理的总磷吸收比值增加,而接种AMF处理降低.表明增氮条件下AMF提高了无芒稗对陆稻的竞争.     

模拟氮沉降对湿地植物生物量与土壤活性碳库的影响

在两种水分条件下(W₁:非淹水,W₂:淹水)分4个氮处理(分别相当于氮沉降率0、1、3、5 g N·m^-2·a^-1)模拟了三江平原典型湿地植物湿草甸小叶章(Deyeuxia angustifolia)植株及土壤活性碳库对氮沉降的响应.结果表明：模拟氮沉降下小叶章的生物量(总生物量、地上生物量、根生物量)均高于对照,其中根生物量的增长程度最大;根中碳含量及分配比例均显著提高,而地上部位的碳含量则显著降低(P<0.05).氮沉降对土壤活性碳库具有显著影响,各活性碳库含量均以5 g N·m^-2·a^-1处理最高,氮沉降对各活性碳库的影响程度依次为CHC(碳水化合物碳)＞LBC(易氧化有机碳)＞DOC(水溶性有机碳)＞MBC(微生物量碳),氮沉降与淹水条件的耦合作用有利于活性碳的释放;回归分析表明,土壤活性碳库与小叶章相关参数间存在显著相关性.氮沉降显著提高了小叶章植株生物量及土壤的活性碳含量.     

江西千烟洲人工针叶林下狗脊蕨群落生物量

 根据野外调查和实验分析研究了江西省千烟洲人工针叶林下狗脊蕨（Woodwardia japonica）群落的生物量、细根生物量、净初级生产力(Net primary productivity, NPP)、 比叶面积（Specific leaf area, SLA） 和叶面积指数（Leaf area index, LAI）等。通过叶片参数和地上生 物量的相关关系建立了狗脊蕨单株地上生物量估算模型,分别 为W1=0.021H^1.545（R²=0.790）和W1=2.518（D²H）^{0 .616}（R²=0.894;H为株高 ,D为地径）。人工针叶林下灌草层地上生物量为367.8 g&;#8226;m^－2（52～932 g&;#8226;m^－2）,凋落物为1 631 g&;#8226;m^－2（672～2 763 g&;#8226;m^－2）,分别占 乔木层地上生物量的4.7%（1.55%～13.2%）和20.7%（7.6%～32.1%）。狗脊蕨群落地上生物量和NPP分别为266.6 g&;#8226;m^－2和88.67 g&;#8226;m^－2&;#8226;a ^-1 ,其中狗脊蕨种群占73.7%;地下生物量为212.6 g&;#8226;m^－2。狗脊蕨的SLA和叶干物质含量（Leaves day mutter content, LDMC）分别为144.0 cm²&;#8226;g^-1和31.99%,二者之间呈显著负相关;最佳叶面积估算模型为S=21.922 6-0.152L²+0.000 9L³（9.0≤L（叶片长度）≤23.5;1.4≤W （ 叶片宽度）≤5.9）。狗脊蕨种群的LAI为1.8。土壤含水量对狗脊蕨生物量有显著影响。群落生物量与土壤有机质和全氮含量正相关     

巢湖富营养化对河蚬和环棱螺分布及种群密度影响

2001年9月和2002年9月两次对巢湖河蚬和环棱螺的调查表明,在富营养化程度较重的西湖区,河蚬生物量分别为17.87和47.29 g·m^-2;环棱螺生物量分别为45.45和12.56 g·m^-2.而在富营养化程度较轻的东湖区,河蚬的生物量分别为67.86和96.18 g·m^-2;环棱螺的生物量分别为32.00和31.21 g·m^-2.河蚬和环棱螺的种群密度和生物量均随水体富营养化的加剧而下降.近岸带河蚬和环棱螺的密度和生物量明显高于敞水区.河蚬的分布型为核心型,而环棱螺更接近随机性分布.河蚬和环棱螺的种群密度和生物量与水深均无明显相关(P>0.05).环棱螺生物量与总氮TN、硝态氮NO₃-N、总磷TP和溶解性磷PO₄-P浓度呈显著负相关,而河蚬生物量仅与PO₄-P呈负相关.现有河蚬资源量与1981年相比有较大幅度的下降.探讨了其它环境因子对河蚬和环棱螺分布和生长的影响.     

青藏高原高寒草甸植物群落生物量对氮、磷添加的响应

青藏高原正经历着明显的温暖化过程, 由此引起的土壤温度的升高促进了土壤中微生物的活性, 同时青藏高原东缘地区大气氮沉降十分明显, 并呈逐年增加的趋势, 这些环境变化均促使土壤中可利用营养元素增加, 因此深入了解青藏高原高寒草甸植物生物量对可利用营养元素增加的响应, 是准确预测未来全球变化背景下青藏高原高寒草甸碳循环过程的重要基础。该研究基于在青藏高原高寒草甸连续4年(2009-2012年)氮、磷添加后对不同功能群植物地上生物量、群落地上和地下生物量的测定, 探讨高寒草甸生态系统碳输入对氮、磷添加的响应。结果表明: (1)氮、磷添加均极显著增加了禾草的地上绝对生物量及其在群落总生物量中所占的比例, 同时均显著降低了杂类草在群落总生物量中的比例, 此外磷添加极显著降低了莎草地上绝对生物量及其在群落总生物量中所占的比例。(2)氮、磷添加均显著促进了青藏高原高寒草甸的地上生物量增加, 分别增加了24%和52%。(3)氮添加对高寒草甸地下生物量无显著影响, 而磷添加后地下生物量有增加的趋势。(4)氮添加对高寒草甸植物总生物量无显著影响, 而磷添加后植物总生物量显著增加。研究表明, 氮、磷添加可缓解青藏高原高寒草甸植物生长的营养限制, 促进植物地上部分的生长, 然而高寒草甸植物的生长极有可能更受土壤中可利用磷含量的限制。     

模拟氮沉降对杂草生长和氮吸收的影响

以杂草早熟禾、黑麦草、野燕麦、天蓝苜蓿、白车轴草、北美车前、婆婆纳、无芒稗、牛筋草和刺苋为试验材料,以4.0g·m^-2·yr^-1的N输入为模拟氮沉降浓度,研究了不同杂草功能类群对模拟氮沉降的响应.结果表明,模拟氮沉降处理下,杂草的生物量(总生物量、地上部分生物量、根生物量)呈增加趋势,但不同功能类群对氮增加的响应明显不同,C₄禾本科、C₃豆科及C₃禾本科植物的生物量受到氮沉降的显著促进,但C₃非禾本科和C₄非禾本科植物的生物量则受氮沉降的影响不显著;不同功能类群的根冠比、植株含氮及植株吸收氮的总量对模拟氮沉降的响应无明显规律,但物种间差异显著.氮沉降提高野燕麦和北美车前的生物量的根冠比,但对其他生物种类没有显著影响.没有发现氮沉降对植物体内的含氮量有显著的影响,但氮沉降却显著地提高了除刺苋、早熟禾及婆婆纳之外的所有杂草物种对N的摄收.由于物种对氮沉降的响应不同,未来氮沉降的增加将加速杂草群落组成的变化.     

CO2浓度升高与氮沉降对南亚热带森林生态系统植物生物量积累及分配格局的影响

 CO₂浓度升高与氮沉降增加对陆地生态系统的耦合作用已成为全球变化的研究热点。应用大型开顶箱(OTC)人工控制手段研究了人工生态系统在1)高CO₂(700±20 μmol·mol^–1)+高氮沉降(100 kg N·hm^–2·a^–1)(CN); 2)高CO₂(700±20 μmol·mol^–1)+背景氮沉降(C＋); 3)高氮沉降(100 kg N· hm^–2·a^–1)＋背景CO₂(N＋); 4)背景CO₂＋背景氮沉降处理(CK) 4种处理条件下荷木 (Schima superba)、红锥(Castanopsis hystrix)、海南红豆(Ormosia pinnata)、肖蒲桃(Acmena acuminatissima)、红鳞蒲桃(Syzygium hancei)等主要南亚热带森林植物的生物量积累模式及其分配格局。连续近3年的实验结果表明: 不同处理条件下, 各参试植物生物量积累具有不同的响应特征, N＋处理显著促进荷木、肖蒲桃及红鳞蒲桃生物量的积累; C＋处理显著促进肖蒲桃、海南红豆生物量的积累; CN处理显著促进除红锥外其他物种生物量的积累, 并且具有两者单独处理的叠加效应。不同处理改变物种生物量的分配模式, N＋处理降低植物的根冠比, 促进地上部分生物量的积累; C＋处理增加红锥和红鳞蒲桃地下部分生物量的分配, 却促进荷木和海南红豆地上部分的积累; CN处理仅促进红磷蒲桃地下部分的积累。群落生物量的积累与分配格局取决于优势物种的生物量及其分配格局在群落中所占的权重。     

陆生植物生物量分配对模拟氮沉降响应的Meta分析

分析了陆生植物地上、地下各组织中生物量分配对氮沉降的响应,为研究大气氮沉降背景下陆地生态系统的碳、氮循环过程及植物生物量分配、立木收获、定向培育等相关研究和实践提供参考依据。共收集整理了国内外63篇论文的原始数据资料进行Meta分析(Meta-analysis),用以定量评估氮沉降对植物生物量分配的影响,并通过亚组分析进一步探讨了不同生态系统类型、植物种类、氮肥形式、施氮水平和持续时间对生物量分配的影响。结果表明,总体来看施氮会显著促进植物地上部分生物量分配,植物叶生物量和茎生物量在施氮条件下均显著增加;然而地下生物量所受促进作用要低于地上部分,表现为植物细根生物量和粗根生物量在氮输入下并没有显著变化;植物根冠比在氮沉降下显著降低;叶重比、茎重比和根重比在氮沉降下没有显著变化。此外,亚组分析结果表明生态系统类型和植物类型会显著影响植物总生物量和根冠比对氮沉降的响应,草本植物在氮沉降下的生物量累积明显优于木本,这说明短期氮沉降可能会增加草本的覆盖面积;施肥形式对根冠比的影响存在明显差异,相比于尿素,硝酸铵对植物根冠比的作用更显著;不同施氮水平显著影响地上生物量分配,中氮水平(本研究为60—120 kg hm-2a-1)促进作用最大,高氮水平(本研究为≥120 kg hm-2a-1)促进作用明显减弱,这与总生物量的变化一致,表明过高的氮沉降量将抑制植物生长;氮沉降处理时间长短对植物地上生物量的影响也存在显著差异,当施氮时间高于3年,氮沉降对地上生物量的促进作用几乎消失。总之,短期氮沉降会使植物分配更多生物量给地上部分,且氮沉降对草本植物生物量的累积作用明显优于木本,这些发现可为未来大气氮沉降背景下植物地上、地下部分碳存储、植物群落结构、植被动态等相关研究提供科学依据。     

青藏高原高寒草甸植物群落物种组成和生物量沿环境梯度的变化

生物多样性与生态系统功能的关系及其机制是生态学领域的重大科学问题. 人们越来越关注环境因子对多样性-生产力关系的影响. 植物群落组成、物种丰富度、物种特征、生物量的分布结构和植物枯枝落叶对高寒草甸物种多样性和生产力有着重要的影响. 因此, 我们利用2001~2004年中国科学院海北生态系统定位站高寒草甸群落的实测资料, 研究了不同环境梯度(土壤含水量和营养)下, 植物群落生物量, 物种丰富度及组成的变化. 结果表明, 植物群落物种组成的不同反应在生物量的分布上, 以藏嵩草为优势种的藏嵩草沼泽化草甸群落总生物量(地上、地下)最高(13196.96±719.69 g/m²), 次之是以杂类草和莎草科为主的小嵩草草甸(2869.58±147.52 g/m₂), 以禾本科和杂类草为主的矮嵩草草甸最低(2153.08±141.95 g/m²). 藏嵩草沼泽化草甸中, 草本植物枯枝落叶显著高于小嵩草、矮嵩草草甸, 土壤含水量对草本植物枯枝落叶有较大的影响. 不同类型草甸群落中, 地上生物量与土壤有机质、全氮和群落盖度之间均呈显著正相关(P < 0.05); 藏嵩草沼泽化草甸中, 总生物量与物种丰富度呈负相关(r_s = -0.907, P < 0.05)、地下生物量与土壤含水量呈正相关(r_s = -0.900, P < 0.05); 而在小嵩草和矮嵩草草甸中它们之间均没有达到显著水平, 说明不同类型高寒草甸群落生产力除受物种多样性、功能群内物种密度和均匀度的影响, 同时也受物种本身特征和外部环境资源的影响. 不同类型草甸群落生物量的分布与土壤含水量和土壤养分的变化相一致.     

Temperature-dependent development and population growth of Tetraneura nigriabdominalis (Homoptera: Pemphigidae) on three host plants

The root aphid Tetraneura nigriabdominalis (Sasaki) (Homoptera: Pemphigidae) is a pest of many Gramineae species; however, little is known about its biology and relationships with host plants. The objectives of this study were to quantify the effects of temperature on development, longevity, fecundity, and population growth of T. nigriabdominalis and to assess the effects of host plant on development of T. nigriabdominalis. The effects of temperature on performance of this root aphid were determined at 10, 15, 20, 25, 30, and 35 +/- 1 degrees C on rice roots, Oryza sativa L. Nymphal stages from birth to adult decreased from 46.3 d at 10 degrees C to 8.5 d at 30 degrees C. Aphid survival and development were lowest at 35 degrees C, and no aphid produced progeny at this temperature. Average adult longevity decreased from 23.3 d at 15 degrees C to 8.2 d at temperatures up to 35 degrees C. Average number of nymphs produced per female was highest at 25 degrees C; averaging near 30 nymphs per female, but it dropped to near zero at both 10 and 35 degrees C. The highest intrinsic rate of increase (r(m)) was 0.241 at 30 degrees C. Net reproductive rate (R(0)) ranged from 29.8 at 25 degrees C to 0.2 at 10 degrees C. The generation time (GT) decreased with increasing temperatures from 60.3 d at 10 degrees C to 13.8 d at 30 degrees C. In addition, root aphids reared at 30 degrees C on three host plants [O. sativa, Zea mays L. and Sorghum bicolor (L.) Moench] revealed that the developmental time of the nymphal stages averaged 6.9 d when reared on O. sativa and 10.7 d when reared on Z. mays. Comparison of the nitrogen content of the three host plants indicated that the root nitrogen content was highest in O. sativa. The effect of nitrogen content on aphid performance, however, is still not clear. Other factors, such as plant secondary chemistry, may play a role in affecting aphid performance.     

An assessment of the role of ethylene in mediating lettuce (Lactuca sativa) root growth at high temperatures

Growth of temperate lettuce (Lactuca sativa) plants aeroponically in tropical greenhouses under ambient root-zone temperatures (A-RZTs) exposes roots to temperatures of up to 40 degrees C during the middle of the day, and severely limits root and shoot growth. The role of ethylene in inhibiting growth was investigated with just-germinated (24-h-old) seedlings in vitro, and 10-d-old plants grown aeroponically. Compared with seedlings maintained at 20 degrees C, root elongation in vitro was inhibited by 39% and root diameter increased by 25% under a temperature regime (38 degrees C/24 degrees C for 7 h/17 h) that simulated A-RZT in the greenhouse. The effects on root elongation were partially alleviated by supplying the ethylene biosynthesis inhibitors aminooxyacetic acid (100-500 microM) or aminoisobutyric acid (5-100 microM) to the seedlings. Application of the ethylene precursor 1-aminocyclopropane-1-carboxylic acid to seedlings grown at 20 degrees C mimicked the high temperature effects on root elongation (1 microM) and root diameter (1 mM). Compared with plants grown at a constant 20 degrees C root-zone temperature, A-RZT plants showed decreased stomatal conductance, leaf relative water content, photosynthetic CO(2) assimilation, shoot and root biomass, total root length, the number of root tips, and root surface area, but increased average root diameter. Addition of 10 microM ACC to the nutrient solution of plants grown at a constant 20 degrees C root-zone temperature mimicked the effects of A-RZT on these parameters but did not influence relative water content. Addition of 30 microM aminoisobutyric acid or 100 microM aminooxyacetic acid to the nutrient solution of A-RZT plants increased stomatal conductance and relative water content and decreased average root diameter, but had no effect on other root parameters or root and shoot biomass or photosynthetic CO(2) assimilation. Although ethylene is important in regulating root morphology and elongation at A-RZT, the failure of ethylene biosynthesis inhibitors to influence shoot carbon gain limits their use in ameliorating the growth inhibition induced by A-RZT.     

Effect of growth temperature on biomass production of nearly isonuclear triazine-resistant and -susceptible common groundsel (Senecio vulgaris L.)

Abstract. The effect of growth temperature on biomass production and photosynthesis of nearly-isonuclear triazine-resistant and -susceptible Senecio vulgaris L. bio-types was investigated. Plants were grown in growth chambers with day/night temperatures of 13/8, 20/15 and 30/25°C, and were harvested 35, 42, 49 and 56d after planting (DAP). The S biotype produced more shoot dry weight than the R × S_BC6 biotype, and the S × R_BC6 biotype produced more shoot dry weight than the R biotype at all DAP and growth temperature combinations. The S and S × R_BC6 biotypes had greater photosynthetic rates than the R X S_BC6 and R biotypes, respectively. Thus, plants containing the susceptible chloroplast genome produced more biomass and had greater photosynthetic rates than those with the resistant chloroplast genome, when in association with the same nuclear genome. There was no differential temperature effect on biomass production of isonuclear plants possessing resistant or susceptible chloroplast genomes. However, there was a large differential temperature effect on the amount of biomass produced by plants containing different nuclear genomes (R or S) in association with the same chloroplast genome. The R nuclear genome appeared to be better adapted to cooler growth temperatures while the S nuclear genome was better adapted to warmer growth conditions.     

Increase in respiratory cost at high growth temperature is attributed to high protein turnover cost in Petunia x hybrida petals

It is widely believed that turnover of nitrogenous (N) compounds (especially proteins) incurs a high respiratory cost. Thus, if protein turnover costs change with temperature, this would influence the dependence of respiration rate on growth temperature. Here, we examined the extent to which protein turnover cost explained differences in N-utilization costs (nitrate uptake/reduction, ammonium assimilation, amino acid and protein syntheses, protein turnover and amino acid export) and in respiration rate with changes in growth temperature. By measurements and literature data, we evaluated each N-utilization cost in Petunia x hybrida petals grown at 20, 25 or 35 degrees C throughout their whole lifespans. Protein turnover cost accounted for 73% of the integrated N-utilization cost on a whole-petal basis at 35 degrees C. The difference in this cost on a dry weight basis between 25 and 35 degrees C accounted for 75% of the difference in N-utilization cost and 45% of the difference in respiratory cost. The cost of nitrate uptake/reduction was high at low growth temperatures. We concluded that respiratory cost in petals was strongly influenced by protein turnover and nitrate uptake/reduction, and on the shoot basis, C investment in biomass was highest at 25 degrees C.     

Effect of temperature on yield and night biomass loss in Spirulina platensis grown outdoors in tubular photobioreactors

Outdoor experiments carried out in Florence, Italy (latitude 43.8° N, longitude 11.3° E), using tubular photobioreactors have shown that in summer the average net productivity of a Spirulina platensis culture grown at the optimal temperature of 35 °C was superior by 23% to that observed in a culture grown at 25 °C. The rates of night biomass loss were higher in the culture grown at 25 °C (average 7.6% of total dry weight) than in the one grown at 35 °C (average 5%). Night biomass loss depended on the temperature and light irradiance at which the cultures were grown, since these factors influenced the biomass composition. A net increase in carbohydrate synthesis occurred when the culture was grown at a low biomass concentration under high light irradiance or at the suboptimal temperature of 25 °C. Excess carbohydrate synthesized during the day was only partially utilized for night protein synthesis.     

Importance of N source on heat stress tolerance due to the accumulation of proline and quaternary ammonium compounds in tomato plants

Proline and quaternary ammonium compounds (QAC), in addition to being N-rich, are known to accumulate in plants under different environmental stress conditions. The accumulation of N-rich compounds in plants has been shown to confer stress resistance. The aim of our work is two-fold: first, to study the influence of temperature on proline, QAC, and choline metabolism in tomato leaves; and second, to investigate the relationship between N source applied (NO3- or NH4+) and thermal stress resistance in these plants. To do this, experiments were conducted at three different temperatures (10 degrees C, 25 degrees C, 35 degrees C); at each temperature half of the plants received NO3-, and the other half received NH4+. At 35 degrees C the plants had the lowest biomass production with respect to 25 degrees C (optimal temperature) and 10 degrees C (cold stress), suggesting that tomato plants were most affected by heat stress. At 35 degrees C, there were also high levels of choline and proline due to the activation of Delta1-pyrroline-5-carboxylate synthetase (P5CS) and ornithine aminotransferase (OAT), and simultaneous inhibition of proline dehydrogenase (PDH) and proline oxidase (PO). However, plants with NH4+ as the N source exhibited reduced growth with respect to the plants fed with NO3-. This is interesting because, under heat stress (35 degrees C), biomass production, as well as proline and choline accumulation, in NH4+ fed plants was higher than in NO3- fed plants. From this, we concluded that tomato plants fed with NH4+ as the N source show higher tolerance to heat stress (35 degrees C) than plants fed with NO3-.     

UV-B辐射增强对水稻生长发育及其产量形成的影响

在盆载条件下,研究UV-B辐射（280-320nm）增强对3个不同类型水稻品种（组合）的生长发育及其产量构成的影响。结果表明,UV-B辐射增强明显抑制水稻生长,使株高变矮、分蘖数减少、叶面积和干物质量下降,但其抑制程度依品种、水稻所处的生长阶段的不同而不同;株高在苗期下降幅度最大,为9.4%-12.2%,干物质量在分蘖期下降幅度最大,地下部和地上部干物质量分别下降45.3%-59.8%、54.9%-59.0%,增强的UV-B辐射使水稻主茎不同叶位的出叶时间延迟,生育期延长,汕优63、南川、IR65600-85的抽穗时间分别比对照延迟2d、3d和7d,成熟期分别推迟3d、4d和9d,UV-B辐射增强明显降低水稻叶片的叶绿素和类胡萝卜素含量,叶片叶绿素a荧光诱导动力学参数Fv、Fv/Fm、Fv/Fo下降,与对照相比,汕优6.3、南川、IR65600-85叶片的净光合速率分别下降了11.9%、12.8%、29.7%,UV-B辐射增强使水稻每株有效穗、每穗总粒数、结实率、千粒重下降,最终导致水稻籽粒产量下降25.2%-31.1%。