Gas Exchange of Carrot Leaves in Response to Elevated CO2 Concentration

Short-term responses of four carrot (Daucus carota) cultivars: Cascade, Caro Choice (CC), Oranza, and Red Core Chantenay (RCC) to CO₂ concentrations (C _a) were studied in a controlled environment. Leaf net photosynthetic rate (P _N), intercellular CO₂ (C _i), stomatal conductance (g _s), and transpiration rate (E) were measured at C _a from 50 to 1 050 mol mol^–1. The cultivars responded similarly to C _a and did not differ in all the variables measured. The P _N increased with C _a until saturation at 650 mol mol^–1 (C _i= 350–400 mol mol^–1), thereafter P _N increased slightly. On average, increasing C _a from 350 to 650 and from 350 to 1 050 mol mol^–1 increased P _N by 43 and 52 %, respectively. The P _N vs. C _i curves were fitted to a non-rectangular hyperbola model. The cultivars did not differ in the parameters estimated from the model. Carboxylation efficiencies ranged from 68 to 91 mol m^–2 s^–1 and maximum P _N were 15.50, 13.52, 13.31, and 14.96 mol m^–2 s^–1 for Cascade, CC, Oranza, and RCC, respectively. Dark respiration rate varied from 2.80 mol m^–2 s^–1 for Oranza to 3.96 mol m^–2 s^–1 for Cascade and the CO₂ compensation concentration was between 42 and 46 mol mol^–1. The g _s and E increased to a peak at C _a= 350 mol mol^–1 and then decreased by 17 and 15 %, respectively when C _a was increased to 650 mol mol^–1. An increase from 350 to 1 050 mol mol^–1 reduced g _s and E by 53 and 47 %, respectively. Changes in g _s and P _N maintained the C _i:C _a ratio. The water use efficiency increased linearly with C _a due to increases in P _N in addition to the decline in E at high C _a. Hence CO₂ enrichment increases P _N and decreases g _s, and can improve carrot productivity and water conservation.     

Simulating Growth and Root-shoot Partitioning in Prairie Grasses Under Elevated Atmospheric CO2and Water Stress

We constructed a model simulating growth, shoot-root partitioning,plant nitrogen (N) concentration and total non-structural carbohydratesin perennial grasses. Carbon (C) allocation was based on theconcept of a functional balance between root and shoot growth,which responded to variable plant C and N supplies. Interactionsbetween the plant and environment were made explicit by wayof variables for soil water and soil inorganic N. The modelwas fitted to data on the growth of two species of perennialgrass subjected to elevated atmospheric CO₂and water stresstreatments. The model exhibited complex feedbacks between plantand environment, and the indirect effects of CO₂and water treatmentson soil water and soil inorganic N supplies were important ininterpreting observed plant responses. Growth was surprisinglyinsensitive to shoot-root partitioning in the model, apparentlybecause of the limited soil N supply, which weakened the expectedpositive relationship between root growth and total N uptake.Alternative models for the regulation of allocation betweenshoots and roots were objectively compared by using optimizationto find the least squares fit of each model to the data. Regulationby various combinations of C and N uptake rates, C and N substrateconcentrations, and shoot and root biomass gave nearly equivalentfits to the data, apparently because these variables were correlatedwith each other. A partitioning function that maximized growthpredicted too high a root to shoot ratio, suggesting that partitioningdid not serve to maximize growth under the conditions of theexperiment.Copyright 1998 Annals of Botany Company plant growth model, optimization, nitrogen, non-structural carbohydrates, carbon partitioning, elevated CO₂, water stress,Pascopyrum smithii,Bouteloua gracilis, photosynthetic pathway, maximal growth     

Changes in Nitrogen Metabolism of Vigna Radiata in Response to Elevated CO2

With the aim to determine the effects of CO₂ on nitrogen metabolism mungbean (Vigna radiata) plants were grown from seedling emergence to maturity inside open top chambers under ambient CO₂ (CA, 350 ± 25 µmol mol^–1) and elevated CO₂ (CE, 600 ± 50 µmol mol^–1) concentrations at the Indian Agricultural Research Institute, New Delhi. Leaflet blades of the same physiological age were sampled at 20, 35 and 50 d after germination. Total nitrogen concentration in dry mass was consistently lower under CE than in CA. Non-protein nitrogen and protein nitrogen were also decreased under CE Total soluble protein content also decreased up to 35 d after germination under CE. However, a 27 % increase in protein content at 50 d after germination due to CE was observed. A significant decrease in total free amino acid under CE at 20 d after germination was observed. CE also brought about a remarkable decrease in the activity of nitrate reductase in leaves at 20 d after germination but increase at 35 d and 50 d after germination. Nitrogenase activity increased at all growth stages due to CE. Although total harvested leaves of CE plants accumulated more nitrogen, the relative amount of nitrogen on a percentage basis was low, probably due to a comparatively greater accumulation of sugars in the leaves of CE plants.     

Minor Physiological Response to Elevated CO(2) by the CAM Plant Agave vilmoriniana

One-year-old plants of the CAM leaf succulent Agave vilmoriniana Berger were grown outdoors at Riverside, California. Potted plants were acclimated to CO₂-enrichment (about 750 microliters per liter) by growth for 2 weeks in an open-top polyethylene chamber. Control plants were grown nearby where the ambient CO₂ concentration was about 370 microliters per liter. When the plants were well watered, CO₂-induced differences in stomatal conductances and CO₂ assimilation rates over the entire 24-hour period were not large. There was a large nocturnal acidification in both CO₂ treatments and insignificant differences in leaf chlorophyll content. Well watered plants maintained water potentials of −0.3 to −0.4 megapascals. When other plants were allowed to dry to water potentials of −1.2 to −1.7 megapascals, stomatal conductances and CO₂ uptake rates were reduced in magnitude, with the biggest difference in Phase IV photosynthesis. The minor nocturnal response to CO₂ by this species is interpreted to indicate saturated, or nearly saturated, phosphoenolpyruvate carboxylase activity at current atmospheric CO₂ concentrations. CO₂-enhanced diurnal activity of ribulose bisphosphate carboxylase activity remains a possibility.     

Phenotypic Plasticity Conditions the Response of Soybean Seed Yield to Elevated Atmospheric CO2 Concentration

Selection for cultivars with superior responsiveness to elevated atmospheric CO₂ concentrations (eCO₂) is a powerful option for boosting crop productivity under future eCO₂. However, neither criteria for eCO₂ responsiveness nor prescreening methods have been established. The purpose of this study was to identify traits responsible for eCO₂ responsiveness of soybean (Glycine max). We grew 12 Japanese and U.S. soybean cultivars that differed in their maturity group and determinacy under ambient CO₂ and eCO₂ for 2 years in temperature gradient chambers. CO₂ elevation significantly increased seed yield per plant, and the magnitude varied widely among the cultivars (from 0% to 62%). The yield increase was best explained by increased aboveground biomass and pod number per plant. These results suggest that the plasticity of pod production under eCO₂ results from biomass enhancement, and would therefore be a key factor in the yield response to eCO₂, a resource-rich environment. To test this hypothesis, we grew the same cultivars at low planting density, a resource-rich environment that improved the light and nutrient supplies by minimizing competition. Low planting density significantly increased seed yield per plant, and the magnitude ranged from 5% to 105% among the cultivars owing to increased biomass and pod number per plant. The yield increase due to low-density planting was significantly positively correlated with the eCO₂ response in both years. These results confirm our hypothesis and suggest that high plasticity of biomass and pod production at a low planting density reveals suitable parameters for breeding to maximize soybean yield under eCO₂.The atmospheric concentration of carbon dioxide ([CO₂]) increased from the preindustrial level of 271 µmol mol^–1 to 391 µmol mol^–1 in 2011, owing primarily to emissions from combustion of fossil fuels. [CO₂] is predicted to rise from the current level to approximately 600 µmol mol^–1 by 2050 (Ciais et al., 2013). Elevated atmospheric CO₂ concentration (eCO₂) is well known to increase leaf photosynthesis by increasing the availability of CO₂ as a substrate for the carboxylation reaction with Rubisco; this can increase crop productivity, a phenomenon known as the CO₂ fertilization effect, especially for C₃ plants such as rice (Oryza sativa), wheat (Triticum aestivum), and soybean (Glycine max; e.g. Kimball et al., 2002), since [CO₂] is a growth-limiting resource for C₃ plants. There is a large genotypic variation in the yield response to eCO₂, both among cultivars and between species, with responses ranging from –15% to +20% per 100 µmol mol^–1 CO₂ increase from the current level for rice (Ziska et al., 1996; Moya et al., 1998; Baker, 2004; Shimono et al., 2009; Hasegawa et al., 2013), –6% to +35% for wheat (Manderscheid and Weigel, 1997; Ziska et al., 2004; Ziska, 2008; Tausz-Posch et al., 2015), –5% to +55% for soybean (Ziska and Bunce, 2000; Ziska et al., 2001; Bishop et al., 2015; Bunce, 2015), and –6% to +21% for field bean (Phaseolus vulgaris; Bunce, 2008). These large differences in eCO₂ responsiveness within crop species suggest that active selection and breeding for genotypes that respond strongly to gradual but steadily increasing [CO₂] may ensure sustained productivity and improve food security in a future eCO₂ world (Ainsworth et al., 2008; Ziska et al., 2012; Tausz et al., 2013).Several hypotheses have been proposed about which traits should be targeted by breeders because they are related to intraspecific variation in the responsiveness of seed yield to eCO₂. For example, a cultivar’s maturity group is an important growth trait for determining crop productivity. Late-maturing rice cultivars as a result of the longer period in which they can grow could increase grain yield relatively by eCO₂ and may therefore benefit more from eCO₂ than early-maturing cultivars (Hasegawa et al., 2013). Also, phenological changes by eCO₂ could be another good indicator of genotypic variation in eCO₂ responsiveness. Recently, Bunce (2015) showed that extension of the duration of vegetative growth until flowering at the apical node of the main stem caused by eCO₂ was correlated with an increase in seed yield among some soybean genotypes.The source-sink relationship is another important aspect of genotypic variation in the responsiveness of a plant to eCO₂. CO₂ enrichment can increase photosynthesis, especially during the early growth stage of leaves, and the magnitude of the increase of photosynthesis decreases with increasing growth stage because leaf senescence accelerates under eCO₂, which has been referred to as acclimation (for review, see Moore et al., 1999). Genotypes with slower acclimation to eCO₂ had a greater response of seed yield (Zhu et al., 2014, for rice; Hao et al., 2012, for soybean). Determinacy is strongly related to the source-sink relationship, especially for legume species. Indeterminate soybean cultivars that have more sinks are likely to be superior in responsiveness to eCO₂, compared with determinate cultivars (Ainsworth et al., 2004). Aspinwall et al. (2015) emphasized the importance of phenotypic plasticity (the ability of a genotype to alter its phenotype in response to environmental changes) under eCO₂ as a key trait for eCO₂ responsiveness. Many researchers have suggested that a higher sink plasticity under eCO₂ would lead to greater plasticity of tillering, branching, and biomass production, and could therefore be more important than photosynthesis per unit leaf area for adaptation to eCO₂ by rice (Shimono et al., 2009; Zhu et al., 2014), soybean (Ziska and Bunce, 2000; Ziska et al., 2001), wheat (Manderscheid and Weigel, 1997; Ziska et al., 2004; Ziska, 2008), and field bean (Bunce, 2008); an exception would occur when other resources are limited, such as during a drought (Tausz-Posch et al., 2015). It is difficult to categorize biomass per se as a function of sink or source factors, but a plant’s final biomass results from efficient formation of sinks in vegetative and reproductive organs, and from efficient filling of these sinks with the products of photosynthesis. This would be a promising hypothesis, and if the hypothesis is confirmed, the phenotypic plasticity would become a useful criterion for identifying eCO₂-responsive cultivars.The first objective of the current study was to examine the genotypic variation of yield enhancement caused by eCO₂ in diverse soybean cultivars, as soybean is a major source of plant protein and oil and a major contributor to the world’s food supply. In addition to characterizing the variation, we attempted to identify the factors responsible for it. The soybean genotypes that we chose covered a wide range of maturity groups and determinacy, including near-isogenic lines. We concluded that soybean cultivars varied widely in their responsiveness to eCO₂, and that variation in the yield enhancement by eCO₂ was determined primarily by the plasticity of biomass and pod production. This suggests that both are suitable parameters for screening cultivars with a strong response to eCO₂. However, it is not easy to characterize plasticity of biomass and pod production under eCO₂ of each cultivar since CO₂ enhancement facilities such as controlled enclosed chambers are extremely expensive and not easily accessible.Our second objective was to develop a methodology to characterize intraspecific variation in plasticity. Shimono (2011) proposed a simple and novel idea: to use planting density for prescreening to identify eCO₂-responsive cultivars. Solar radiation is the driving force for photosynthesis and plant growth, and crops are grown as a population (not as individual plants) to maximize productivity per unit area rather than per plant. Individual plant growth is usually restricted by interplant competition for solar radiation, soil nutrients, and water, so a lower planting density could potentially increase the source strength for individual plants by increasing the availability of resources. Thus, lower plant density can imitate the greater resource availability that would occur under eCO₂. This approach is potentially useful but is insufficient, because Shimono et al. (2014) applied it only to rice, measured only panicle number (not yield) as the phenotype, and combined independent experimental data from different locations and years. Here, we tested the hypothesis using a diverse range of soybean cultivars at a single site and for 2 years, and found a good relationship between the responsiveness to eCO₂ and the responsiveness to low planting density (LD) in terms of the seed yield per plant.     

Seasonal Changes of Selected Parameters of CO2 Fixation Biochemistry of Norway Spruce Under the Long-Term Impact of Elevated CO2

Twelve-year-old Norway spruce (Picea abies [L.] Karst.) trees were exposed to ambient (AC) or elevated (EC) [ambient + 350 µmol(CO₂) mol^-1] CO₂ concentrations in open-top-chamber (OTC) experiment under the field conditions of a mountain stand. Short-term (4 weeks, beginning of the vegetation season) and long-term (4 growing seasons, end of the vegetation season) effects of this treatment on biochemical parameters of CO₂ assimilation were evaluated. A combination of gas exchange, fluorescence of chlorophyll a, and application of a mathematical model of ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCO) activity was used. The analysis showed that the depression of photosynthetic activity by long-term impact of elevated CO₂ was mainly caused by decreased RuBPCO carboxylation rate. The electron transport rate as well as the rate of ribulose-1,5-bisphosphate (RuBP) formation were also modified. These modifications to photosynthetic assimilation depended on time during the growing season. Changes in the spring were caused mainly by local deficiency of nitrogen in the assimilating tissue. However, the strong depression of assimilation observed in the autumn months was the result of insufficient carbon sink capacity.     

Seasonal Changes of Selected Parameters of CO2 Fixation Biochemistry of Norway Spruce Under the Long-Term Impact of Elevated CO2

Twelve-year-old Norway spruce (Picea abies [L.] Karst.) trees were exposed to ambient (AC) or elevated (EC) [ambient + 350 μmol(CO₂) mol^-1] CO₂ concentrations in open-top-chamber (OTC) experiment under the field conditions of a mountain stand. Short-term (4 weeks, beginning of the vegetation season) and long-term (4 growing seasons, end of the vegetation season) effects of this treatment on biochemical parameters of CO₂ assimilation were evaluated. A combination of gas exchange, fluorescence of chlorophyll a, and application of a mathematical model of ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCO) activity was used. The analysis showed that the depression of photosynthetic activity by long-term impact of elevated CO₂ was mainly caused by decreased RuBPCO carboxylation rate. The electron transport rate as well as the rate of ribulose-1,5-bisphosphate (RuBP) formation were also modified. These modifications to photosynthetic assimilation depended on time during the growing season. Changes in the spring were caused mainly by local deficiency of nitrogen in the assimilating tissue. However, the strong depression of assimilation observed in the autumn months was the result of insufficient carbon sink capacity. This revised version was published online in June 2006 with corrections to the Cover Date.     

The Photosynthetic Response to Elevated CO2 in High Altitude Potato Species (Solanum curtilobum)

Plants of Solanum curtilobum (from high altitude) and Solanum tuberosum (from low altitude) were grown in open-top chambers in a greenhouse at either ambient (AC, 360 µmol mol^–1) or ca. twice ambient (EC, 720 µmol mol^–1) CO₂ concentrations for 30 d. CO₂ treatments started at the reproductive stage of the plants. There were similar patterns in the physiological response to CO₂ enrichment in the two species. Stomatal conductance was reduced by 59 % in S. tuberosum and by 55 % in S. curtilobum, but such a reduction did not limit the net photosynthetic rate (P _N), which was increased by approximately 56 % in S. curtilobum and 53 % in S. tuberosum. The transpiration rate was reduced by 16 % in both potato species while instantaneous transpiration efficiency increased by 80 % in S. tuberosum and 90 % in S. curtilobum. Plants grown under EC showed 36 and 66 % increment in total dry biomass, whereas yields (dry mass of tubers) were increased by 40 and 85 % in S. tuberosum and S. curtilobum, respectively. EC promoted productivity by increasing P _N. Thus S. tuberosum, cultivated around the world at low altitudes, and S. curtilobum, endemic of the highland Andes, respond positively to EC during the tuberisation stage.     

Responses of Rice Cultivars to the Elevated CO2

The effect of CO₂ concentration elevated to 575 – 620 µmol mol^–1 on growth, tillering, grain yield, net photosynthetic rate, dark respiration rate, stomatal conductance, sugar content and protein profile of two rice (Oryza sativa L.) cultivars Pusa Basmati-1 and Pusa-677 at flowering stage was studied using open top chambers. The cultivar Pusa Basmati-1 responded more markedly for most of the growth and physiological parameters compared to Pusa-677. The increase in grain yield in Pusa Basmati-1 attributed largely to increased grain number. The increased net photosynthetic rate and greater accumulation of sugar contributed significantly to the accelerated development of leaves and tillers in both the cultivars. The reduction in the low molecular mass proteins including Rubisco and increase in high molecular mass photosystem 2 proteins was observed in both the cultivars. Additional sugars may possibly help in balancing the profile of photosynthetic proteins and sustain greater growth and productivity in rice cultivars.     

Controlled Environment Chambers for Investigating Tree Response to Elevated CO2 and Temperature Under Boreal Conditions

A closed CO₂ and temperature-controlled, long-term chamber system has been developed and set up in a typical boreal forest of Scots pine (Pinus sylvestris L.) near the Mekrijärvi Research Station (62°47N, 30°58E, 145 m above sea level) belonging to the University of Joensuu, Finland. The main objectives of the experiment were to provide a means of assessing the medium to long-term effects of elevated atmospheric CO₂ concentration (EC) and temperature (ET) on photosynthesis, respiration, growth, and biomass at the whole-tree level and to measure instantaneous whole-system CO₂ exchange. The system consists of 16 chambers with individual facilities for controlling CO₂ concentration, temperature, and the combination of the two. The chambers can provide a wide variety of climatic conditions that are similar to natural regimes. In this experiment the target CO₂ concentration in the EC chambers was set at a fixed constant of 700 µmol mol^–1 and the target air temperature in the ET chambers to track the ambient temperature but with a specified addition. Chamber performance was assessed on the base of recordings covering three consecutive years. The CO₂ and temperature control in these closed chambers was in general accurate and reliable. CO₂ concentration in the EC chambers was within 600–725 µmol mol^–1 for 90 % of the exposure time during the "growing-season" (15 April – 15 September) and 625–725 µmol mol^–1 for 88 % of the time in the "off-season" (16 September – 14 April), while temperatures in the chambers were within ±2.0 °C of the ambient or target temperature in the "growing season" and within ±3.0 °C in the "off season". There were still some significant chamber effects. Solar radiation in the chambers was reduced by 50–60 % for 82 % of the time in the "growing season" and 55–65 % for 78 % of the time in the "off season", and the relative humidity of the air was increased by 5–10 % for 72 % of the time in the "growing season" and 2–12 % for 91 % of the time in the "off season". The crown architecture and main phenophase of the trees were not modified significantly by enclosure in the chambers, but some physiological parameters changed significantly, e.g., the radiant energy-saturated photosynthesis rate, transpiration rate, maximum photochemical efficiency of photosystem 2, and chlorophyll content.     

Ectomycorrhizal Colonization, Biomass, and Production in a Regenerating Scrub Oak Forest in Response to Elevated CO2

The effects of CO₂ elevation on the dynamics of fine root (FR) mass and ectomycorrhizal (EM) mass and colonization were studied in situ in a Florida scrub oak system over four years of postfire regeneration. Soil cores were taken at five dates and sorted to assess the standing crop of ectomycorrhizal and fine roots. We used ingrowth bags to estimate the effects of elevated CO₂ on production of EM roots and fine roots. Elevated CO₂ tended to increase EM colonization frequency but did not affect EM mass nor FR mass in soil cores (standing mass). However, elevated CO₂ strongly increased EM mass and FR mass in ingrowth bags (production), but it did not affect the EM colonization frequency therein. An increase in belowground production with unchanged biomass indicates that elevated CO₂ may stimulate root turnover. The CO₂-stimulated increase of belowground production was initially larger than that of aboveground production. The oaks may allocate a larger portion of resources to root/mycorrhizal production in this system in elevated rather than ambient CO₂.     

Effect of Mechanical Loading on Ventilatory Response to CO2 and CO2 Excretion

The ventilatory response to CO₂ (S) and respiratory exchange ratio have been measured in 10 healthy subjects breathing naturally and through added resistive loads. The changes in these values produced by the added loads were shown to be correlated with the unloaded CO₂ responsiveness. The results indicated that poorly responsive individuals had a greater depression of ventilatory response to CO₂ and were more liable to retain CO₂.These observations raise the possibility that the constitutional CO₂ responsiveness of an individual influences the alveolar ventilation achieved in the presence of airways obstruction. The propensity to develop respiratory failure may thus be conditioned by the premorbid CO₂ responsiveness.     

Growth Response of a Succulent Plant, Agave vilmoriniana, to Elevated CO(2)

Large (about 200 grams dry weight) and small (about 5 grams dry weight) specimens of the leaf succulent Agave vilmoriniana Berger were grown outdoors at Phoenix, Arizona. Potted plants were maintained in open-top chambers constructed with clear, plastic wall material. Four CO₂ concentrations of 350, 560, 675, and 885 microliters per liter were used during two growth periods and two water treatments. Small and large plants were grown for 6 months, while a few large plants were grown for 1 year. Wet-treatment plants received water twice weekly, whereas dry-treatment plants received slightly more water than they would under natural conditions. Plant growth rates in all treatments were significantly different between small and large specimens, but not between 6 month and 1 year large plants. Only the dry-treatment plants exhibited statistically different growth rates between the CO₂ treatments. This productivity response was equivalent to a 28% and 3-fold increase when mathematically interpolated between CO₂ concentrations of 300 and 600 microliters per liter for large and small plants, respectively.     

Ponderosa Pine Responses to Elevated CO2and Nitrogen Fertilization

The effects of elevated CO₂ (ambient, +175, and +350 μl l⁻¹) and nitrogen fertilization (0, 100, and 200 kg N ha⁻¹ yr⁻¹ as ammonium sulfate) on C and N accumulations in biomass and soils planted with ponderosa pine (Pinus ponderosa Laws) over a 6-year study period are reported. Both nitrogen fertilization and elevated CO₂ caused increases in C and N contents of vegetation over the study period. The pattern of responses varied over time. Responses to CO₂ decreased in the +175 μl l⁻¹ and increased in the +350 μl l⁻¹ after the first year, whereas responses to N decreased after the first year and became non-significant by year six. Foliar N concentrations were lower and tree C:N ratios were higher with elevated CO₂ in the early years, but this was offset by the increases in biomass, resulting in substantial increases in N uptake with elevated CO₂. Nitrogen budget estimates showed that the major source of the N for unfertilized trees, with or without elevated CO₂, was likely the soil organic N pool. There were no effects of elevated CO₂ on soil C, but a significant decrease in soil N and an increase in soil C:N ratio in year six. Nitrogen fertilization had no significant effect on tree C:N ratios, foliar N concentrations, soil C content, soil N content, or soil C:N ratios. There were no significant interactions between CO₂ and N treatments, indicating that N fertilization had no effect on responses to CO₂ and that CO₂ treatments had no effect on responses to N fertilization. These results illustrate the importance of long-term studies involving more than one level of treatment to assess the effects of elevated CO₂.     

水稻的光合作用、生长、碳同位素分辨作用及抗渗透胁迫性对CO2浓度增高的响应

四个水稻(Oryza sativa L.)品种"IR72"、"特三矮2号"、"桂朝2号"和"Ⅱ优4480"在田间栽于含35 μmol/mol 和60 μmol/mol CO2的塑料大棚中,自然光照.高浓度CO2下供试水稻品种的光合速率变化表现为提高型("IR72"、"特三矮2号")、稳定型("桂朝2号"的Pn几无变化)和下调型("Ⅱ优4480").生长速率、穗重、由Δ13C计算而得的长期水分利用效率和清除DPPH@自由基的能力皆增加.除"Ⅱ优4480"外,其他3个品种明显增高总生物量.供试品种的穗重/总生物量比不同程度地受到高浓度CO2的改变.叶片段经PEG渗透胁迫后,不同的生长于高浓度CO2者的电解质渗漏率较小.结果表明高浓度CO2可改变水稻的光合作用和水分关系特性,品种间不同的响应显示了选育适于未来高浓度CO2下具有高产和抗逆性品种的可能性.     

Elevated CO2 affects plant responses to variation in boron availability

Aim

Effects of elevated CO₂ on N relations are well studied, but effects on other nutrients, especially micronutrients, are not. We investigated effects of elevated CO₂ on response to variation in boron (B) availability in three unrelated species: seed geranium (Pelargonium x hortorum), barley (Hordeum vulgare), and water fern (Azolla caroliniana).

Methods

Plants were grown at two levels of CO₂ (370, 700?ppm) and low, medium, and high B. Treatment effects were measured on biomass, net photosynthesis (P_n) and related variables, tissue nutrient concentrations, and B transporter protein BOR1.

Results

In geranium, there were interactive effects (P?<?0.05) of B and CO₂ on leaf, stem, and total plant mass, root:shoot ratio, leaf [B], B uptake rate, root [Zn], and P_n. Elevated CO₂ stimulated growth at 45?μM B, but decreased it at 450?μM B and did not affect it at 4.5?μM B. P_n was stimulated by elevated CO₂ only at 45?μM B and chlorophyll was enhanced only at 450?μM B. Soluble sugars increased with high CO₂ only at 4.5 and 45?μM B. High CO₂ decreased leaf [B] and B uptake rate, especially at 450?μM B. Though CO₂ and B individually affected the concentration of several other nutrients, B x CO₂ interactions were evident only for Zn in roots, wherein [Zn] decreased under elevated CO₂. Interactive effects of B and CO₂ on growth were confirmed in (1) barley grown at 0, 30, or 1,000?μM B, wherein growth at high CO₂ was stimulated more at 30?μM B, and (2) Azolla grown at 0, 10, and 1,000?μM B, wherein growth at high CO₂ was stimulated at 0 and 10?μM B.

Conclusion

Thus, low and high B both may limit growth stimulation under elevated vs. current [CO₂], and B deficiency and toxicity, already common, may increase in the future.     

禾本科植物响应非生物胁迫的转录调控网络

分子和遗传研究表明,转录因子在响应非生物胁迫的基因表达调控中起着重要的作用,并且大部分转录因子在禾本科植物和拟南芥中是相同的.禾本科植物包括许多重要的农作物,对禾本科植物的转录因子进行研究,可增强重要农作物对非生物胁迫的耐受性.综述了禾本科植物响应非生物胁迫的转录调控网络,包括响应寒冷胁迫的DREB1/CBF调节子、响应脱水和高盐胁迫的DREB2调节子,ABA介导反应的ABRE及其伴侣元件、响应ABA的AREB/ABF调节子,响应脱水、高盐和寒冷胁迫的NAC调节子.     

Nematode Genera in Forest Soil Respond Differentially to Elevated CO2

Previous reports suggest that fungivorous nematodes are the only trophic group in forest soils affected by elevated CO₂. However, there can be ambiguity within trophic groups, and we examined data at a genus level to determine whether the conclusion remains similar. Nematodes were extracted from roots and soil of loblolly pine (Pinus taeda) and sweet gum (Liquidambar styraciflua) forests fumigated with either ambient air or CO₂-enriched air. Root length and nematode biomass were estimated using video image analysis. Most common genera included Acrobeloides, Aphelenchoides, Cephalobus, Ditylenchus, Ecphyadorphora, Filenchus, Plectus, Prismatolaimus, and Tylencholaimus. Maturity Index values and diversity increased with elevated CO₂ in loblolly pine but decreased with elevated CO₂ in sweet gum forests. Elevated CO₂ treatment affected the occurrence of more nematode genera in sweet gum than loblolly pine forests. Numbers were similar but size of Xiphinema decreased in elevated CO₂. Abundance, but not biomass, of Aphelenchoides was reduced by elevated CO₂. Treatment effects were apparent at the genus levels that were masked at the trophic level. For example, bacterivores were unaffected by elevated CO₂, but abundance of Cephalobus was affected by CO₂ treatment in both forests.