Quantifying the impact of current and future tropospheric ozone on tree biomass, growth, physiology and biochemistry: a quantitative meta-analysis

The northern hemisphere temperate and boreal forests currently provide an important carbon sink; however, current tropospheric ozone concentrations ([O₃]) and [O₃] projected for later this century are damaging to trees and have the potential to reduce the carbon sink strength of these forests. This meta‐analysis estimated the magnitude of the impacts of current [O₃] and future [O₃] on the biomass, growth, physiology and biochemistry of trees representative of northern hemisphere forests. Current ambient [O₃] (40 ppb on average) significantly reduced the total biomass of trees by 7% compared with trees grown in charcoal‐filtered (CF) controls, which approximate preindustrial [O₃]. Above‐ and belowground productivity were equally affected by ambient [O₃] in these studies. Elevated [O₃] of 64 ppb reduced total biomass by 11% compared with trees grown at ambient [O₃] while elevated [O₃] of 97 ppb reduced total biomass of trees by 17% compared with CF controls. The root‐to‐shoot ratio was significantly reduced by elevated [O₃] indicating greater sensitivity of root biomass to [O₃]. At elevated [O₃], trees had significant reductions in leaf area, Rubisco content and chlorophyll content which may underlie significant reductions in photosynthetic capacity. Trees also had lower transpiration rates, and were shorter in height and had reduced diameter when grown at elevated [O₃]. Further, at elevated [O₃], gymnosperms were significantly less sensitive than angiosperms. There were too few observations of the interaction of [O₃] with elevated [CO₂] and drought to conclusively project how these climate change factors will alter tree responses to [O₃]. Taken together, these results demonstrate that the carbon‐sink strength of northern hemisphere forests is likely reduced by current [O₃] and will be further reduced in future if [O₃] rises. This implies that a key carbon sink currently offsetting a significant portion of global fossil fuel CO₂ emissions could be diminished or lost in the future.     

Lolium multiflorum density responses under ozone and herbicide stress

Adaptations to overcrowding of individual plants result in density dependant control of growth and development. There is little information on how anthropogenic stresses modify these responses. We investigated whether combinations of diclofop‐methyl herbicide and tropospheric ozone alter the pattern of expected growth compensation with density changes resulting from intraspecific competition in Lolium multiforum Lam (Poacea) plants. Individual plant vegetative parameters and total seed production were assessed for plants growing under various densities and different herbicide rates and ozone treatments. The stressors differently changed the frequency distribution for average individual plant weight resulting from increasing densities. Only herbicide affected seedling mortality. Plants were able to compensate during grain filling maintaining similar seed production – density relationships in all treatments. Our findings contribute to the understanding of the impact of stress factors on the demographic changes in plant populations. Important ecological implications arise: (i) contrasting responses to ozone and herbicide, alone and in combination of individual plants resulted in different biomass – density relationships; (ii) stress effects on plant populations could not be predicted from individual responses; and (iii) changes in competitive outcome by single or combined stress factors may alter the expected genotype frequency in a crowded population with few dominant individuals.     

Reduction of Root-Knot Nematode, Meloidogyne javanica, and Ozone Mass Transfer in Soil Treated with Ozone

Ozone gas (O(3)) is a reactive oxidizing agent with biocidal properties. Because of the current phasing out of methyl bromide, investigations on the use of ozone gas as a soil-fumigant were conducted. Ozone gas was produced at a concentration of 1% in air by a conventional electrical discharge O(3) generator. Two O(3) dosages and three gas flow rates were tested on a sandy loam soil collected from a tomato field that had a resident population of root knot nematodes, Meloidogyne javanica. At dosages equivalent to 50 and 250 kg of O(3)/ha, M. javanica were reduced by 24% and 68%, and free-living nematodes by 19% and 52%, respectively. The reduction for both M. javanica and free-living nematodes was dosage dependent and flow rate independent. The rates of O(3) mass transfer (OMT) through three soils of different texture were greater at low and high moisture levels than at intermediate ones. At any one soil moisture level, the OMT rate varied with soil texture and soil organic matter content. Results suggest that soil texture, moisture, and organic matter content should be considered in determining O(3) dosage needed for effective nematode control.     

Effects of genotype,elevated CO2 and elevated O3 on aspen phytochemistry and aspen leaf beetle Chrysomela crotchi performance

• 1 Trembling aspen Populus tremuloides Michaux is an important forest species in the Great Lakes region and displays tremendous genetic variation in foliar chemistry. Elevated carbon dioxide (CO₂) and ozone (O₃) may also influence phytochemistry and thereby alter the performance of insect herbivores such as the aspen leaf beetle Chrysomela crotchi Brown.
• 2 The present study aimed to relate genetic‐ and atmospheric‐based variation in aspen phytochemistry to C. crotchi performance (larval development time, adult mass, survivorship). The experiment was conducted at the Aspen Free‐Air CO₂ Enrichment (FACE) site in northern Wisconsin. Beetles were reared on three aspen genotypes under elevated CO₂ and/or O₃. Leaves were collected to determine chemical characteristics.
• 3 The foliage exhibited significant variation in nitrogen, condensed tannins and phenolic glycosides among genotypes. CO₂ and O₃, however, had little effect on phytochemistry. Nonetheless, elevated CO₂ decreased beetle performance on one aspen genotype and had inconsistent effects on beetles reared on two other genotypes. Elevated O₃ decreased beetle performance, especially for beetles reared on an O₃‐sensitive genotype. Regression analyses indicated that phenolic glycosides and nitrogen explain a substantial amount (27–45%) of the variation in herbivore performance.
• 4 By contrast to the negative effects that are typically observed with generalist herbivores, aspen leaf beetles appear to benefit from phenolic glycosides, chemical components that are largely genetically‐determined in aspen. The results obtained in the present study indicate that host genetic variation and atmospheric concentrations of greenhouse gases will be important factors in the performance of specialist herbivores, such as C. crotchi, in future climates.

     

Elevated atmospheric carbon dioxide and ozone alter soybean diseases at SoyFACE

Human driven changes in the Earth's atmospheric composition are likely to alter plant disease in the future. We evaluated the effects of elevated carbon dioxide (CO₂) and ozone (O₃) on three economically important soybean diseases (downy mildew, Septoria brown spot and sudden death syndrome‐SDS) under natural field conditions at the soybean free air concentration enrichment (SoyFACE) facility. Disease incidence and/or severity were quantified from 2005 to 2007 using visual surveys and digital image analysis, and changes were related to microclimatic variability and to structural and chemical changes in soybean host plants. Changes in atmospheric composition altered disease expression, but responses of the three pathosystems varied considerably. Elevated CO₂ alone or in combination with O₃ significantly reduced downy mildew disease severity (measured as area under the disease progress curve‐AUDPC) by 39–66% across the 3 years of the study. In contrast, elevated CO₂ alone or in combination with O₃ significantly increased brown spot severity in all 3 years, but the increase was small in magnitude. When brown spot severity was assessed in relation to differences in canopy height induced by the atmospheric treatments, disease severity increased under combined elevated CO₂ and O₃ treatment in only one of the 3 years. The atmospheric treatments had no effect on the incidence of SDS or brown spot throughout the study. Higher precipitation during the 2006 growing season was associated with increased AUDPC severity across all treatments by 2.7 and 1.4 times for downy mildew and brown spot, respectively, compared with drought conditions in 2005. In the 2 years with similar precipitation, the higher daily temperatures in the late spring of 2007 were associated with increased severity of downy mildew and brown spot. Elevated CO₂ and O₃ induced changes in the soybean canopy density and leaf age likely contributed to the disease expression modifications.     

α-萜品醇熏蒸对大麦虫体内抗氧化酶活性的影响

为研究植物挥发性有机化合物α-萜品醇的杀虫活性及作用机理, 本研究采用熏蒸法测定了α-萜品醇对大麦虫Zophobas morio（鞘翅目： 拟步行甲科）4龄幼虫的急性毒性, 并测定了不同熏蒸时间后幼虫体内超氧化物歧化酶（SOD）、 过氧化物酶（POD）和过氧化氢酶（CAT）活性。结果表明： 熏蒸48 h时, α-萜品醇对大麦虫4龄幼虫的LC₅₀和LC₂₀值分别为69.425 μg/L和59.916 μg/L。α-萜品醇（LC₂₀和LC₅₀）处理的4龄幼虫SOD, POD和CAT活性均表现为先升高后降低的趋势。据此推测, α-萜品醇在幼虫体内积累显著影响幼虫体内SOD, POD和CAT活性, 降低虫体内自由基的清除能力, 从而对其产生毒害作用。     

松油烯-4-醇光学异构体及外消旋体对家蝇的杀虫活性比较

【目的】比较松油烯-4-醇光学异构体对家蝇 Musca domestica 的熏蒸活性差异,为其光学异构体的应用提供理论依据。【方法】以家蝇4日龄成虫为供试昆虫,采用三角瓶熏蒸法比较测定了松油烯-4-醇光学异构体和外消旋体对其的熏蒸与击倒活性,并测定了松油烯-4-醇光学异构体及外消旋体对家蝇头部Na⁺ , K⁺-ATPase活性的影响。【结果】松油烯-4-醇外消旋体对家蝇的熏蒸活性和击倒活性最强,右旋异构体次之,左旋异构体最差,外消旋体、右旋异构体和左旋异构体对家蝇的致死中浓度（LC₅₀）分别为2.5,2.9和3.7 μL/L;在LC₉₀ 剂量下的击倒中时（KT₅₀）分别为12.6,16.7和18.9 min;松油烯-4-醇光学异构体及外消旋体均可显著抑制Na⁺, K⁺-ATPase的活性,活体条件下,松油烯-4-醇光学异构体及外消旋体对Na⁺, K⁺-ATPase活性的抑制作用随着中毒症状的加剧而增强,具有时间效应,其中左旋异构体的抑制作用最强;离体条件下,松油烯-4-醇光学异构体及外消旋体对Na⁺, K⁺-ATPase活性的抑制作用具有浓度依赖效应,其中外消旋体对Na⁺, K⁺-ATPase活性的抑制能力最强,明显高于同浓度下的右旋异构体和左旋异构体。【结论】松油烯-4-醇的光学异构体对家蝇的杀虫活性存在差异,外消旋体的活性明显高于异构体单体。开发松油烯-4-醇类杀虫剂,应以光学异构体的混合物作为有效成分。     

高浓度臭氧对大豆生长发育及产量的影响

采用开顶式同化箱(open-top chambers,OTCs)装置,设置活性碳过滤大气(CF,［O₃］<10 μg·kg^-1)和高臭氧(O₃)浓度(HO,约为80 μg·kg^-1)两个处理,研究开花后高浓度O₃对大豆农艺性状、叶面积、叶绿素、抗氧化系统与产量的影响.结果表明： 与对照(CF)同期相比,HO处理植株的叶面积和叶绿素含量显著降低(P<0.05);过氧化物酶、过氧化氢酶和超氧化物歧化酶活性极显著增强(P<0.01),但随着处理时间的延长,其活性逐渐降低;HO处理下植株叶片中可溶性蛋白质和抗坏血酸(AsA)含量降低,丙二醛含量显著升高,表明膜脂过氧化进程加快;大豆的单株干物质量、有效结荚数、籽粒数、百粒重和产量都有所降低,其中产量降低了47%,差异达极显著水平(P<0.01).     

Minor effects of long-term ozone exposure on boreal peatland species Eriophorum vaginatum and Sphagnum papillosum

The effects of long-term ozone fumigation on two common peatland plant species, a sedge Eriophorum vaginatum L. and a moss Sphagnum papillosum Lindb., were studied applying peatland microcosms. The peat cores with intact vegetation were cored from an oligotrophic pine fen and partially embedded into the soil of an open-air experimental field for four growing seasons. The open-air ozone exposure field consists of eight circular plots of which four were fumigated with elevated ozone concentration (doubled ambient) and four were ambient controls. The results showed that E. vaginatum and S. papillosum can tolerate ozone better than expected. Elevated ozone concentration did not affect overall relative length growth of E. vaginatum or S. papillosum. The leaf cross-section area of E. vaginatum leaves was 8% bigger in the ozone treatment compared to that in the ambient control. Ultrastuctural variables did not show any significant treatment effect in E. vaginatum or in S. papillosum. Total chlorophyll (a + b) concentration tended to increase in early growing season under ozone exposure. During the first growing season, elevated ozone concentration decreased methanol-extractable, UV-absorbing compounds in E. vaginatum. The results suggest that E. vaginatum and S. papillosum are ozone tolerant plant species and are likely able to cope with expected increase in tropospheric ozone concentration.