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1.
This article studied the effects of nitrogen (N) and CO2 enrichment on biomass and N accumulation and partitioning of cucumber grown in open top chambers. At the seedling stage, elevated CO2 increased the biomass and N content of the entire plant. The root had the largest increase in biomass and N content among the organs and more biomass allocation. The largest drops of N concentration showed in root at moderate and high N, in leaf at low N, respectively. Elevated CO2 increased stem biomass allocation at moderate and high N, but decreased leaf biomass allocation at all N levels. At the initial fruit stage, the response to elevated CO2 of biomass and N content decreased. Elevated CO2 increased biomass allocation to leaf and resulted in the largest drop of leaf N concentration at low and moderate N supply. High N supply promoted biomass production and N reallocation from the leaf to fruit, but decreased leaf biomass allocation. Thus, biomass allocation is initially affected by root–shoot growth balance to adapt to enriched CO2, leading to the largest root growth, then biomass allocates to another sink (stem). Long exposure of elevated CO2 results in photosynthetic acclimation in deficient N supply, which probably attributes to excessive stem and leaf biomass allocation and shortage of fruit storage. But high N shifts biomass allocation from leaf to fruit. Practically, sufficient N supply is needed for an efficient transport of carbohydrates to fruits and increases the yields under elevated CO2. 相似文献
2.
Kounosuke Fujita Hiroyuki Nobuyasu Takeshi Kuzukawa Joseph J. Adu-Gyamfi Pravat Kumar Mohapatra 《Soil Science and Plant Nutrition》2013,59(5):745-752
An experiment was conducted to examine the effect of CO2 enrichment on the nitrate uptake, nitrate reduction activity, and translocation of assimilated-N from leaves at varying levels of nitrogen nutrition in soybean using 15N tracer technique. CO2 enrichment significantly increased the plant biomass, apparent leaf photosynthesis, sugar and starch contents of leaves, and reduced-N contents of the plant organs only when the plants were grown at high levels of nitrogen. A high supply of nitrogen enhanced plant growth and increased the reduced-N content of the plant organs, but its effect on the carbohydrate contents and photosynthetic rate were not significant. However, the combination of high CO2 and high nitrogen levels led to an additive effect on all these parameters. The nitrate reductase activity increased temporarily for a short period of time by CO2 enrichment and high nitrogen levels. 15N tracer studies indicated that the increase in the amount of reduced-N by CO2 enrichment was derived from nitrate-N and not from fixed-N of the plant. To examine the translocation of reduced-N from the leaf in more detail, another experiment was conducted by feeding the plants with 15NO3-N through a terminal leaflet of an upper trifoliated leaf under depodding and/or CO2 enrichment conditions. The export rate of 15N from the terminal leaflet to other plant parts decreased by depodding, but it increased by CO2 enrichment. CO2 enrichment increased the percentage of plant 15N in the stem and / or pods. Depodding increased the percentage of plant 15N in the leaf and stem. The results suggested that the increase in the leaf nitrate reduction activity by CO2 enrichment was due to the increase of the translocation of reduced-N from leaves through the strengthening of the sink activity of pods and / or stem for reduced-N. 相似文献
3.
FACE条件下水稻生育后期剑叶光合色素含量及产量构成的响应研究 总被引:1,自引:0,他引:1
为明确CO2浓度增高对水稻叶片光合能力的影响,利用自由CO2富集系统(free-air carbon dioxide enrichment,FACE)研究‘松粳9号’和‘稻花香2号’水稻生育后期剑叶光合色素含量及产量构成的变化趋势;通过测定水稻孕穗—抽穗期剑叶叶绿素a、叶绿素b和类胡萝卜素含量,分析光合色素组成、各组分间相关关系及品种间差异;收获后实测产量构成因素,比较处理及品种间差异。结果表明,与对照相比,高CO2浓度下水稻孕穗和抽穗期叶绿素a含量都极显著升高,‘松粳9号’和‘稻花香2号’的最大增幅分别达28.46%和19.58%;抽穗后20 d分别极显著降低15.25%和23.20%。高浓度CO2极显著降低水稻抽穗后20 d叶绿素b含量,两品种降幅分别为7.57%和5.33%;极显著增加抽穗后30 d叶绿素b含量,增幅分别为4.19%和9.46%。高CO2浓度下两品种水稻抽穗期类胡萝卜素含量显著增加9.47%和13.55%,抽穗后10 d之后显著降低,最高降幅达13.54%和16.67%。高CO2浓度下水稻总叶绿素含量和叶绿素a/b比值在孕穗和抽穗期增加,抽穗后20 d减少。高CO2浓度对产量构成因素均有正面影响,增加了水稻单位面积穗数、结实率和千粒重,显著提高了千粒重,两品种增幅分别达8.6%和4.5%。试验结果明确了高CO2浓度对水稻灌浆前期剑叶光合色素的积累有促进作用,后期有抑制作用,品种间响应差异显著;千粒重增加是增产的主要因素。 相似文献
4.
在短期无氮营养液栽培(28天)条件下,研究缺硼和正常供硼处理对Bragg大豆品种及不结瘤突变体nod49和超结瘤突变体nts382生长、矿质元素吸收与分布及固氮量的影响。试验结果表明:1.在正常供硼的条件下,不结瘤突变体nod的植株生长量,株高、主根生长均高于超结瘤突变体及其亲本。缺硼处理时三种基因型大豆的生长均受到明显的抑制作用。无论是正常供硼还是缺硼处理,超结瘤突变体nts382根系的生长量均明显小于其它基因型。2.正常供硼处理时三种基因型大豆地上部、根及nts382的根瘤中硼的浓度和积累量均高于缺硼处理。缺硼处理,超结瘤突变体及其亲本地上部和根中大部分矿质元素浓度高于正常供硼处理,但积累总量低于正常供硼处理或变化不大。施硼处理的nts382和Bragg,根和根瘤中钙的浓度和积累量明显降低,而地上部变化不大,同时在nts382根瘤中,锌、锰、铁、铜浓度和含量也下降,而钼含量增加。3.施硼处理和Bragg和nts382地上部、根及根瘤中氮的浓度和含量均显著高于缺硼处理,其中超结瘤突变体中氮浓度和总量最高。在缺硼条件下,Bragg和超结瘤突变体能够结瘤,但是Bragg大豆根瘤的固氮作用完全受到抑制,而nts382根瘤还能保持较强的固氮能力。 相似文献
5.
增施CO2降低小白菜硝酸盐积累的机理研究 总被引:2,自引:2,他引:0
以低硝酸盐积累基因型(东妃)和高硝酸盐积累基因型(高雄甜脆)两种小白菜为材料,采用溶液培养法研究了增施CO2降低蔬菜硝酸盐积累的生理机制。结果表明,CO2浓度升高能显著提高2种基因型小白菜的生物量和硝酸还原酶活性,并降低根、茎叶各部位的硝酸盐含量。CO2浓度升高不仅促进了植株对硝态氮的吸收,而且植株吸收硝酸盐的累积量增幅均高于鲜重的增幅。由此可见,除了鲜重增加的稀释作用,处理后生理机制的变化也可能是CO2浓度升高引起硝酸盐含量降低的重要原因。研究还表明,增施CO2后“东妃”的硝酸盐含量降低百分率与硝酸还原酶活性的增加百分率呈极显著相关,而“高雄甜脆”的硝酸盐含量降低百分率则与鲜重的增加百分率的相关性达极显著水平。说明增施CO2后植株各部位硝酸还原酶活性提高及鲜重的增加均为引起硝酸盐含量降低的重要原因,但贡献率具有明显的基因型差异。 相似文献
6.
Junki Ito Shigeki Hasegawa Kounosuke Fujita Shizuhiko Ogasawara Tamio Fujiwara 《Soil Science and Plant Nutrition》2013,59(2):385-393
Six year-old Japanese pear (Pyrus seratina Reheder cv. Kosui) trees grafted on P. serotina cv. Nihonyamanashi were grown in containers filled with Granite Regosol under glasshouse conditions. At different stages of fruit growth, pear trees were exposed to an elevated CO2 concentration (130 Pa CO2 ) along with a control (35 Pa CO2). For one group of plants, CO2 enrichment was applied for 79 d from 52 d after full bloom (DAB) to fruit maturity (long-term CO2 enrichment) and for another group the same treatment was applied for 35 d from 96 DAB to fruit maturity (short-term CO2 enrichment). The effects of the elevated CO2 concentration on vegetative growth, mineral contents, and fruit production and quality were examined. Long-term CO2 enrichment enhanced vegetative growth, without any significant effect on the mineral contents in either flower bud or fruit except for a remarkable increase in the K content. Long-term CO2 enrichment increased the fruit size and fresh weight, but had no significant effect on the fruit quality. On the other hand, the short-term CO2 enrichment did not induce any significant change in the fruit size but increased the fruit sugar concentration. Along with the reduction of the sorbitol concentration in fruit, the fructose and sucrose concentrations increased and these changes occurred earlier at elevated CO2 than at ambient CO2 concentrations. From these results, we concluded that the effect of CO2 enrichment on fruit growth varies depending upon the growth stages of fruit: during the initial and fruitlet stages when fruit expansion occurs, CO2 enrichment increases the fruit size, whereas, during maturation when fruit expansion has slowed down and sugar accumulation in fruit is active, it increases the fruit sugar concentration. 相似文献
7.
运用开顶式气室(OTCs)模拟大气CO2浓度升高(500、700 μmol/mol),以目前环境背景大气为对照,研究CO2浓度升高对毛竹和四季竹叶片碳(C)、氮(N)、磷(P)和钾(K)化学计量特征的影响.结果表明,毛竹和四季竹叶片C、N、P和K含量在不同的CO2浓度(对照、500、700 μmol/mol)条件下,变化范围分别为512.13~543.30、19.23~22.97、1.26~0.96和8.40~5.88 mg/g,492.13~498.02、17.97~15.37、1.05 ~0.81和4.25~5.62mg/g.相同的CO2浓度条件下,毛竹叶片C、N、P和K含量均高于四季竹,且受CO2浓度升高的影响较四季竹强烈.毛竹和四季竹叶片C/N、C/P、C/K、N/P、N/K和K/P变化范围分别依次为26.64~23.65、406.58~565.93、60.98~92.40、15.26~23.93、2.29~3.91和7.00~6.22,27.39~32.40、468.70~614.84、115.80~88.61、17.07~18.98、4.24~2.73和4.04~6.94.与环境背景大气比较,CO2浓度升高到500 μmol/mol,对毛竹和四季竹叶片C、N、P和K含量及其化学计量比并不会产生明显影响,这反映了毛竹和四季竹对高CO2浓度环境均表现出较强的适应能力.但CO2浓度升高到700 μ mol/mol,除四季竹叶片C含量无明显变化外,毛竹和四季竹叶片主要养分元素含量及其化学计量比会发生明显的适应性变化,且毛竹较四季竹变化剧烈.综上,CO2浓度升高改变了毛竹和四季竹叶片C、N、P、K含量及其化学计量比格局,尤其是CO2浓度升高到700 μmol/mol时极为明显;在养分供应上,对四季竹生长的N、P、K限制性作用和毛竹生长的N、K限制性作用没有明显影响,但明显增强了毛竹生长的P素限制性作用. 相似文献
8.
Richard C. Sicher 《Journal of plant nutrition》2013,36(13):1995-2005
Effects of carbon dioxide (CO2) enrichment on plant growth and on nitrogen partitioning were examined in tobacco (Nicotiana tabacum L. cv. ‘Samsun’). Dry matter, leaf area and specific leaf weight were unchanged (P > 0.05) by CO2 enrichment. Total soluble protein, soluble amino acids and inorganic nitrate also were unaffected by CO2 enrichment (P > 0.05). Leaf chlorophyll (a + b) levels decreased 13% (P ≤ 0.05) in response to CO2 enrichment. The diurnal accumulation of soluble amino acids was delayed and the initial slope of the A/C i response curve was decreased 14% in the elevated compared to the ambient CO2 treatment. The above findings showed that CO2 enrichment affected leaf chlorophyll levels, diurnal soluble amino acid metabolism and photosynthetic responses to low intercellular CO2 concentrations even though the plants were nitrogen sufficient. Inadequate nitrogen fertility cannot explain all of the effects of CO2 enrichment on photosynthesis by tobacco leaves. 相似文献
9.
Elevated concentration of atmospheric carbon dioxide will affect carbon cycling in terrestrial ecosystems. Possible effects include increased carbon input into the soil through the rhizosphere, altered nutrient concentrations of plant litter and altered soil moisture. Consequently, the ongoing rise in atmospheric carbon dioxide might indirectly influence soil biota, decomposition and nutrient transformations.N-mineralisation and activities of the enzymes invertase, xylanase, urease, protease, arylsulfatase, and alkaline phosphatase were investigated in spring and summer in calcareous grassland, which had been exposed to ambient and elevated CO2 concentrations (365 and 600 μl l−1) for six growing seasons.In spring, N-mineralisation increased significantly by 30% at elevated CO2, while there was no significant difference between treatments in summer (+3%). The response of soil enzymes to CO2 enrichment was also more pronounced in spring, when alkaline phosphatase and urease activities were increased most strongly by 32 and 21%. In summer, differences of activities between CO2 treatments were greatest in the case of urease and protease (+21 and +17% at elevated CO2).The stimulation of N-mineralisation and enzyme activities at elevated CO2 was probably caused by higher soil moisture and/or increased root biomass. We conclude that elevated CO2 will enhance below-ground C- and N-cycling in grasslands. 相似文献
10.
CO2浓度升高对番茄苗根系生长及其吲哚乙酸和乙烯含量的影响 总被引:1,自引:0,他引:1
WANG Yue DU Shao-Ting LI Ling-Ling HUANG Li-Dong FANG Ping LIN Xian-Yong ZHANG Yong-Song WANG Hai-Long 《土壤圈》2009,19(5):570-576
A hydroponic experiment was carried out to study the effect of elevated carbon dioxide (CO2) on root growth of tomato seedlings. Compared with the control (350 μL L-1), CO2 enrichment (800 μL L-1) significantly increased the dry matter of both shoot and root, the ratio of root to shoot, total root length, root surface area, root diameter, root volume, and root tip numbers, which are important for forming a strong root system. The elevated CO2 treatment also significantly improved root hair development and elongation, thus enhancing nutrient uptake. Increased indole acetic acid concentration in plant tissues and ethylene release in the elevated CO2 treatment might have resulted in enhanced root growth and root hair development and elongation. 相似文献
11.
Masafumi OteraMakie Kokubun Hiroko TabeiToshinori Matsunami Tomiya MaekawaMasumi Okada 《Agricultural and Forest Meteorology》2011,151(10):1385-1393
Yield responsiveness to elevated CO2 concentration [CO2] was previously found to be greater when nitrogen (N) was supplied in adequate amounts; however, it remains unclear whether genotypic differences in N2-fixing capacity affect yield responsiveness in soybean. We tested the hypothesis that yield responsiveness to elevated [CO2] in soybean is greater in a genotype with a higher capacity for N2 fixation. We used three near-isogenic genotypes with contrasting nodulation capacities: super-nodulating, normally nodulating and non-nodulating genotypes. Plants were subjected to two levels of [CO2] (ambient or elevated: ambient + 200 μmol mol−1) and two temperature regimes (low or high: low + ca. 4-5 °C) using temperature gradient chambers. The super-nodulating genotype exhibited a higher N content in leaves, regardless of [CO2] and temperature. Photosynthetic rates were enhanced by CO2 enrichment at earlier growth stages, but not at later growth stages, regardless of genotype. This photosynthetic acclimation was reflected in biomass production in all the genotypes examined. Yield responsiveness to elevated [CO2] was greater in the nodulating genotypes than in the non-nodulating genotype, but the genotypic differences were obscured between the normally nodulating and super-nodulating genotype, thus our hypothesis was not fully verified. 相似文献
12.
Soybean (Glycine max L. Merr.) cvs. Akisengoku and Peking, and cowpea (Vigna unguiculata Walp.) cv. Kegonnotaki were inoculated with Bradyrhizobium japonicum AlO17, Shinorhizobium fredii USDAI93, and B. sp. Vigna MAFF03-03063, respectively and were cultured hydroponically with supply of CO2-free air, 3dm3 m-3 CO2 air, or 25 dm3 m-3 CO2 air to study the effects of the CO2 concentration in the rhizosphere on plant growth, nodulation, and nitrogen fixation. Increase of the CO2 concentration in the rhizosphere led to the increase of the plant dry weight in the symbiosis between Peking and USDAI93, and that between Kegonnotaki and MAFF03-03063. On the other hand, dry matter accumulation in the symbiosis between Akisengoku and AI017 decreased under the supply of 25 dm3 m-3 CO2 air aimed at increasing the CO2 concentration in the rhizosphere beyond the optimum CO2 concentration for growth. Nodule mass and nodule number per plant were highest in Akisengoku, followed by Kegonnotaki and lowest in Peking. Also the increase of the CO2 concentration in the rhizosphere led to the increase of the nodule mass and number in Kegonnotaki, while no changes were observed in Akisengoku and Peking. Biological nitrogen fixation (BNF) was highest in Akisengoku, followed by Kegonnotaki, and lowest or near zero in Peking. BNF in Akisengoku and Kegonnotaki showed a similar tendency to that of dry matter accumulation. BNF of Peking was especially low under the supply of CO2-free air, and it increased with the increase of the CO2 concentration in the rhizosphere. For the symbiosis of Bradyrhizobium strains with soybean and cowpea, the most suitable CO2 concentration for N2 fixation and plant growth was estimated to be about 10 dm3 m-3, while for the symbiosis of S. fredii with soybean, the value was estimated to be above 30 dm3 m-3. 相似文献
13.
Photosynthesis of attached sun and shade grown leaves of poplar (Populus euramericana (Dode) Guinier cv. ‘Robusta') has been measured at 0.03 and 0.5% CO2 at light limitation and light saturation. Photosynthetic rates were compared for plants grown at normal and low Mg‐supply and related to leaf Mg content.
Photosynthetic rates at high CO2 level were affected at Mg concentration lower than about 50 μmoles/g dry leaf tissue at both photosynthetic irradiations. This was paralleled by a decrease in chlorophyll concentration. At a low CO2 level photosynthesis was affected at the same Mg concentration but the degree of the inhibition was higher. This indicates that synthesis of chlorophyll as well as CO2 fixation are affected at the same “critical”; Mg concentration.
Shade leaves contain more chlorophyll per unit leaf weight than sun leaves but the percentual‐ decrease of chlorophyll in Mg deficient leaves Is similar for sun and shade leaves at the same Mg leaf concentration. As a consequence, in Mg deficient shade leaves extraordinary high portions of leaf Mg are bound to chlorophyll (up to 57%; in contrast: up to 37% in sun leaves). 相似文献
14.
利用OTC-1型开顶式气室进行了CO2浓度倍增对冬小麦影响的诊断试验,结果表明,CO2浓度倍增对冬小麦生长发育、叶面积变化、生物量及产量形成等影响显著,且均为正效应。 相似文献
15.
Impact of elevated CO<Subscript>2</Subscript>, flooding,and temperature interaction on heterotrophic nitrogen fixation in tropical rice soils 总被引:1,自引:0,他引:1
Response of N2 fixation to elevated CO2 would be modified by changes in temperature and soil moisture because CO2 and temperature or water availability has generally opposing effects on N2 fixation. In this study, we assessed the impacts of elevated CO2 and temperature interactions on nitrogenase activities, readily mineralizable C (RMC), readily available N (NRN) contents
in an alluvial and a laterite rice soil of tropical origin. Soil samples were incubated at ambient (370 μmol mol-1) and elevated (600 μmol mol-1) CO2 concentration at 25oC, 35oC, and 45oC under non-flooded and flooded conditions for 60 days. Elevated CO2 significantly increased nitrogenase activities and readily mineralizable C in both alluvial and laterite soils. All these
activities were further stimulated at higher temperatures. Increases in nitrogenase activity as a result of CO2 enrichment effect over control were 16.2%, 31.2%, and 66.4% and those of NRN content were 2.0%, 1.8%, and 0.5% at 25oC, 35oC
and 45oC, respectively. Increases in RMC contents were 7.7%, 10.0%, and 10.6% at 25°C, 35°C and 45°C, respectively. Soil flooding
resulted in a more clear impact of CO2 enrichment than the non-flooded soil. The results suggest that in tropical rice soils, elevated CO2 increased readily available C content in the soil, which probably stimulates growth of diazotrophic bacteria with enhanced
N2 fixation and thereby higher available N. 相似文献
16.
The response of wheat to elevated carbon dioxide concentration (e[CO2]) is likely to be dependent on nitrogen supply. To investigate the underlying mechanism of growth response to e[CO2], two wheat cultivars were grown under different carbon dioxide concentration [CO2] in a chamber experimental facility. The changes in leaf photosynthesis, C and N concentration, and biomass were investigated under different [CO2] and N supply. The result showed an increase in photosynthesis under e[CO2] at all N level except the one with the lowest N supply. Furthermore, a significant decrease in gs and Tr for both the cultivars was also observed under e[CO2] at all N levels. A considerable increase in WUEi was observed for both the cultivars under e[CO2] at all N levels except for the lowest concentration one. Therefore, the study shows that a stimulation of plant growth under e[CO2] to be marginal at higher N supply. 相似文献
17.
Hans M. Hanslin Leiv M. Mortensen 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2013,63(5):437-449
Abstract Plant responses to elevated CO2 are governed by temperature, and at low temperatures the beneficial effects of CO2 may be lost. To document the responses of winter cereals grown under cold conditions at northern latitudes, autumn growth of winter wheat exposed to ambient and elevated levels of temperature (+2.5°C), CO2 (+150 µmol mol?1), and shade (?30%) was studied in open-top chambers under low light and at low temperatures. Throughout the experiment, temperature dominated plant responses, while the effects of CO2 were marginal, except for a positive effect on root biomass. Increased temperature resulted in increased leaf area, total biomass, total root biomass, total stem biomass, and number of tillers, but also a lower content of total sugars and a weaker tolerance to frost. The loss of frost tolerance was related to the larger size of plants grown at elevated temperature. The 30% light reduction under shading did not affect the growth, sugar content, or frost tolerance of winter wheat. At the low temperatures found at high latitudes during autumn, the atmospheric CO2 increase is unlikely to enhance autumn growth of winter wheat to any significant extent, while a temperature increase may have important and major effects on its development and growth. 相似文献
18.
Takuji Nakamura Mitsuru Osaki Takayoshi Koike Yuko T. Hanba Eitaro Wada Toshiaki Tadano 《Soil Science and Plant Nutrition》2013,59(4):789-798
Effect of CO2 enrichment on the carbon-nitrogen balance in whole plant and the acclimation of photosynthesis was studied in wheat (spring wheat) and soybean (A62-1 [nodulated] and A62-2 [non-nodulated]) with a combination of two nitrogen application rates (0 g N land area m-2 and 30 g N land area m-2) and two temperature treatments (30/20°C (day/night) and 26/16°C). Results were as follows. 1. Carbon (dry matter)-nitrogen balance of whole plant throughout growth was remarkably different between wheat and soybean, as follows: 1) in wheat, the relationship between the amount of dry matter (DMt) and amount of nitrogen absorbed (Nt) in whole plant was expressed by an exponential regression, in which the regression coefficient was affected by only the nitrogen application rate, and not by CO2 and temperature treatments, and 2) in soybean the DMt-Nt relationship was basically expressed by a linear regression, in which the regression coefficient was only slightly affected by the nitrogen treatment (at 0N, DMt-Nt balance finally converged to a linear regression). Thus, carbon-nitrogen interaction in wheat was strongly affected by the underground environment (nitrogen nutrition), but not by the above ground environment (CO2 enrichment and temperature), while that in soybean was less affected by both under and above ground environments. 2. The photosynthetic response curve to CO2 concentration in wheat and soybean was less affected by the CO2 enrichment treatment, while that in wheat and soybean (A62-2) was affected by the nitrogen treatment, indicating that nitrogen nutrition is a more important factor for the regulation of photosynthesis regardless of the CO2 enrichment. 3. Carbon isotope discrimination (..:1) in soybean was similar to that in wheat under ambient CO2, while lower than that in wheat under CO2 enrichment, suggesting that the carbon metabolism is considerably different between wheat and soybean under the CO2 enrichment conditions. 相似文献
19.
Gilles Pinay Patricia Barbera Nathalie Fromin Marie Madeleine Couteaux Laurent Philippot 《Soil biology & biochemistry》2007,39(1):33-42
From the global change perspective, increase of atmospheric CO2 and land cover transformation are among the major impacts caused by human activities. In this study, we are addressing the combined issues of the effect of CO2 concentration increase and plant type on soil microbial activities by asking how annual and perennial plant groups affect soil microbial processes under elevated CO2. The experimental design used a mix of species of different growth forms for both annuals and perennials. Our objective was: (1) to determine how two years of annual or perennial plant cover and CO2 enrichment could affect Mediterranean soil microbial processes; (2) to test the resistance and the resilience of these soil functional processes after a natural perturbation. We determined the effects of 2 years atmospheric CO2 enrichment on soil potential respiration (SIR), denitrification (DEA) and nitrification (NEA) activities. We could not find any significant effect of CO2 increase on SIR, DEA and NEA. However, we found a strong effect of the plant cover type, i.e. annuals versus perennials, on the potential microbial activity related to N cycling. DEA and NEA were significantly higher in soil under annual plants while SIR was not significantly different. To determine whether these changes would survive a natural perturbation, we carried out a rain event experiment once the experimental treatments (i.e. different plant cover and atmospheric CO2 concentration) were stopped. The soil potential respiration, as expressed by the SIR, was not affected and remained stable. DEA rates converged rapidly under annuals and perennials after the rain event. Under both annuals and perennials NEA increased significantly after the rain event but remained significantly higher in the soil with annual plants. The relative change of the soil microbial processes induced by annual and perennial plants was inversely related to the density and the diversity of the corresponding microbial functional groups. 相似文献
20.
《植物养料与土壤学杂志》2017,180(4):474-481
Potassium (K) deficiency reduces photosynthesis and biomass production of crop plants and also renders them vulnerable to drought stress, whereas elevated carbon dioxide (CO2) has a positive effect on photosynthesis and yield and ameliorates the adverse effects of drought stress. This study aimed to characterize the physiological responses of wheat (Triticum aestivum L.) stressed with K deficiency under elevated CO2 and drought conditions. Increased biomass production caused by elevated CO2 as a consequence of increased photosynthesis and water use efficiency was absent in young K‐deficient wheat plants. Shoot K concentration was negatively affected by elevated CO2 particularly under K‐deficient conditions, whereas K content per plant was greatest in plants supplied with adequate K and adequate water. Specific leaf weight was increased as a consequence of carbohydrate accumulation in the source leaves of K‐deficient plants particularly under elevated CO2 and drought stress. Potassium deficiency clearly impeded the impact of elevated CO2 in both well watered as well as drought‐stressed plants. Adequate K fertilization is a prerequisite for efficient harvesting of atmospheric CO2 through increased photosynthesis, decreased transpiration, and increased biomass production under changing atmospheric CO2 and soil moisture conditions. 相似文献