Your search keyword '"Bugbee B"' showing total 17 results

1. Steady-state stomatal responses of C 3 and C 4 species to blue light fraction: Interactions with CO 2 concentration.

Author

Zhen S and Bugbee B

Subjects

Brassica metabolism, Helianthus metabolism, Light, Plant Stomata physiology, Plant Stomata radiation effects, Plant Transpiration, Sorghum metabolism, Zea mays metabolism, Carbon Dioxide metabolism, Plant Stomata metabolism

Abstract

Blue light induced stomatal opening has been studied by applying a short pulse (~5 to 60 s) of blue light to a background of saturating photosynthetic red photons, but little is known about steady-state stomatal responses. Here we report stomatal responses to blue light at high and low CO 2 concentrations. Steady-state stomatal conductance (g s ) of C 3 plants increased asymptotically with increasing blue light to a maximum at 20% blue (120 μmol m -2 s -1 ). This response was consistent from 200 to 800 μmol mol -1 atmospheric CO 2 (C a ). In contrast, blue light induced only a transient stomatal opening (~5 min) in C 4 species above a C a of 400 μmol mol -1 . Steady-state g s of C 4 plants generally decreased with increasing blue intensity. The net photosynthetic rate of all species decreased above 20% blue because blue photons have lower quantum yield (moles carbon fixed per mole photons absorbed) than red photons. Our findings indicate that photosynthesis, rather than a blue light signal, plays a dominant role in stomatal regulation in C 4 species. Additionally, we found that blue light affected only stomata on the illuminated side of the leaf. Contrary to widely held belief, the blue light-induced stomatal opening minimally enhanced photosynthesis and consistently decreased water use efficiency., (© 2020 John Wiley & Sons Ltd.)

Published

2020

2. A model of canopy photosynthesis incorporating protein distribution through the canopy and its acclimation to light, temperature and CO2.

Author

Johnson IR, Thornley JH, Frantz JM, and Bugbee B

Subjects

Models, Biological, Models, Theoretical, Carbon Dioxide metabolism, Light, Photosynthesis physiology, Plant Proteins metabolism, Temperature

Abstract

Background and Aims: The distribution of photosynthetic enzymes, or nitrogen, through the canopy affects canopy photosynthesis, as well as plant quality and nitrogen demand. Most canopy photosynthesis models assume an exponential distribution of nitrogen, or protein, through the canopy, although this is rarely consistent with experimental observation. Previous optimization schemes to derive the nitrogen distribution through the canopy generally focus on the distribution of a fixed amount of total nitrogen, which fails to account for the variation in both the actual quantity of nitrogen in response to environmental conditions and the interaction of photosynthesis and respiration at similar levels of complexity., Model: A model of canopy photosynthesis is presented for C(3) and C(4) canopies that considers a balanced approach between photosynthesis and respiration as well as plant carbon partitioning. Protein distribution is related to irradiance in the canopy by a flexible equation for which the exponential distribution is a special case. The model is designed to be simple to parameterize for crop, pasture and ecosystem studies. The amount and distribution of protein that maximizes canopy net photosynthesis is calculated., Key Results: The optimum protein distribution is not exponential, but is quite linear near the top of the canopy, which is consistent with experimental observations. The overall concentration within the canopy is dependent on environmental conditions, including the distribution of direct and diffuse components of irradiance., Conclusions: The widely used exponential distribution of nitrogen or protein through the canopy is generally inappropriate. The model derives the optimum distribution with characteristics that are consistent with observation, so overcoming limitations of using the exponential distribution. Although canopies may not always operate at an optimum, optimization analysis provides valuable insight into plant acclimation to environmental conditions. Protein distribution has implications for the prediction of carbon assimilation, plant quality and nitrogen demand.

Published

2010

3. A multiple chamber, semicontinuous, crop carbon dioxide exchange system: design, calibration, and data interpretation.

Author

van Iersel MW and Bugbee B

Subjects

Calibration, Carbon metabolism, Equipment Design, Humidity, Solanaceae growth & development, Carbon Dioxide metabolism, Environment, Controlled, Environmental Monitoring instrumentation, Photosynthesis, Solanaceae metabolism

Abstract

Long-term, whole crop CO2 exchange measurements can be used to study factors affecting crop growth. These factors include daily carbon gain, cumulative carbon gain, and carbon use efficiency, which cannot be determined from short-term measurements. We describe a system that measures semicontinuously crop CO2 exchange in 10 chambers over a period of weeks or months. Exchange of CO2 in every chamber can be measured at 5 min intervals. The system was designed to be placed inside a growth chamber, with additional environmental control provided by the individual gas exchange chambers. The system was calibrated by generating CO2 from NaHCO3 inside the chambers, which indicated that accuracy of the measurements was good (102% and 98% recovery for two separate photosynthesis systems). Since the systems measure net photosynthesis (P-net, positive) and dark respiration(R-dark, negative), the data can be used to estimate gross photosynthesis, daily carbon gain, cumulative carbon gain, and carbon use efficiency. Continuous whole-crop measurements are a valuable tool that complements leaf photosynthesis measurements. Multiple chambers allow for replication and comparison among several environmental or cultural treatments that may affect crop growth. Example data from a 2 week study with petunia (Petunia x hybrida Hort. Vilm.-Andr.) are presented to illustrate some of the capabilities of this system.

Published

2000

4. Photosynthetic capacity and dry mass partitioning in dwarf and semi-dwarf wheat (Triticum aestivum L.).

Author

Bishop DL and Bugbee BG

Subjects

Biomass, Cell Respiration, Chlorophyll analysis, Photosynthesis, Plant Leaves metabolism, Plant Stems growth & development, Triticum genetics, Carbon Dioxide metabolism, Ribulose-Bisphosphate Carboxylase metabolism, Triticum growth & development, Triticum metabolism

Abstract

Efficient use of space and high yields are critical for long-term food production aboard the International Space Station. The selection of a full dwarf wheat (less than 30 cm tall) with high photosynthetic and yield potential is a necessary prerequisite for growing wheat in the controlled, volume-limited environments available aboard long-term spaceflight missions. This study evaluated the photosynthetic capacity and carbon partitioning of a full-dwarf wheat cultivar, Super Dwarf, which is routinely used in spaceflight studies aboard U.S. space shuttle and NASA/Mir missions and made comparisons with other dwarf and semi-dwarf wheat cultivars utilized in other ground-based studies in plant space biology. Photosynthetic capacity of the flag leaf in two dwarf (Super Dwarf, BB-19), and three semi-dwarf (Veery-10, Yecora Rojo, IBWSN 199) wheat cultivars (Triticum aestivum L.) was assessed by measuring: net maximum photosynthetic rate, RuBP carboxylation efficiency, chlorophyll concentration and flag leaf area. Dry mass partitioning of carbohydrates to the leaves, sheaths, stems and ear was also assessed. Plants were grown under controlled environmental conditions in three replicate studies: slightly enriched CO2 (370 micromoles mol-1), high photosynthetic photon flux (1000 micromoles m-2 s-1; 58 mol m-2 d-1) for a 16 h photoperiod, 22/15 degrees C day/night temperatures, ample nutrients and water provided by one-half strength Hoagland's nutrient solution (Hoagland and Arnon, 1950). Photosynthetic capacity of the flag leaf was determined at anthesis using net CO2 exchange rate versus internal CO2 concentration curves measured under saturating light (2000 micromoles m-2 s-1) and CO2 (1000 micromoles mol-1). Dwarf wheat cultivars had greater photosynthetic capacities than the taller semi-dwarfs, they averaged 20% higher maximum net photosynthetic rates compared to the taller semi-dwarfs, but these higher rates occurred only at anthesis, had slightly greater carboxylation efficiencies and significantly increased chlorophyll concentrations per unit leaf area. The reduced-height wheat had significantly less dry mass fraction in the stem but greater dry mass partitioned to the ear than the taller semi-dwarfs (Yecora rojo, IBWSN-199). Studies with detached heads confirm that the head is a significant sink in the shorter wheat cultivars.

Published

1998

5. Adaptation to high CO2 concentration in an optimal environment: radiation capture, canopy quantum yield and carbon use efficiency.

Author

Monje O and Bugbee B

Subjects

Adaptation, Physiological, Carbon metabolism, Cell Respiration, Chlorophyll metabolism, Environment, Controlled, Nitrogen metabolism, Photosynthesis physiology, Plant Roots growth & development, Plant Roots metabolism, Plant Roots radiation effects, Seeds drug effects, Time Factors, Triticum growth & development, Triticum radiation effects, Biomass, Carbon Dioxide pharmacokinetics, Light, Photosynthesis radiation effects, Triticum metabolism

Abstract

The effect of elevated [CO2] on wheat (Triticum aestivum L. Veery 10) productivity was examined by analysing radiation capture, canopy quantum yield, canopy carbon use efficiency, harvest index and daily C gain. Canopies were grown at either 330 or 1200 micromoles mol-1 [CO2] in controlled environments, where root and shoot C fluxes were monitored continuously from emergence to harvest. A rapidly circulating hydroponic solution supplied nutrients, water and root zone oxygen. At harvest, dry mass predicted from gas exchange data was 102.8 +/- 4.7% of the observed dry mass in six trials. Neither radiation capture efficiency nor carbon use efficiency were affected by elevated [CO2], but yield increased by 13% due to a sustained increase in canopy quantum yield. CO2 enrichment increased root mass, tiller number and seed mass. Harvest index and chlorophyll concentration were unchanged, but CO2 enrichment increased average life cycle net photosynthesis (13%, P < 0.05) and root respiration (24%, P < 0.05). These data indicate that plant communities adapt to CO2 enrichment through changes in C allocation. Elevated [CO2] increases sink strength in optimal environments, resulting in sustained increases in photosynthetic capacity, canopy quantum yield and daily C gain throughout the life cycle.

Published

1998

6. Nitrogen balance for wheat canopies (Triticum aestivum cv. Veery 10) grown under elevated and ambient CO2 concentrations.

Author

Smart DR, Ritchie K, Bloom AJ, and Bugbee BB

Subjects

Absorption drug effects, Biomass, Environment, Controlled, Nitrates metabolism, Nitrogen pharmacokinetics, Plant Roots drug effects, Plant Roots growth & development, Plant Roots metabolism, Plant Shoots drug effects, Plant Shoots growth & development, Plant Shoots metabolism, Plant Transpiration, Triticum growth & development, Carbon Dioxide pharmacology, Nitrates pharmacokinetics, Nitrogen metabolism, Triticum drug effects, Triticum metabolism

Abstract

We examined the hypothesis that elevated CO2 concentration would increase NO3- absorption and assimilation using intact wheat canopies (Triticum aestivum cv. Veery 10). Nitrate consumption, the sum of plant absorption and nitrogen loss, was continuously monitored for 23 d following germination under two CO2 concentrations (360 and 1000 micromol mol-1 CO2) and two root zone NO3- concentrations (100 and 1000 mmol m3 NO3-). The plants were grown at high density (1780 m-2) in a 28 m3 controlled environment chamber using solution culture techniques. Wheat responded to 1000 micromol mol-1 CO2 by increasing carbon allocation to root biomass production. Elevated CO2 also increased root zone NO3- consumption, but most of this increase did not result in higher biomass nitrogen. Rather, nitrogen loss accounted for the greatest part of the difference in NO3- consumption between the elevated and ambient [CO2] treatments. The total amount of NO3(-)-N absorbed by roots or the amount of NO3(-)-N assimilated per unit area did not significantly differ between elevated and ambient [CO2] treatments. Instead, specific leaf organic nitrogen content declined, and NO3- accumulated in canopies growing under 1000 micromol mol-1 CO2. Our results indicated that 1000 micromol mol-1 CO2 diminished NO3- assimilation. If NO3- assimilation were impaired by high [CO2], then this offers an explanation for why organic nitrogen contents are often observed to decline in elevated [CO2] environments.

Published

1998

7. Evidence that elevated CO2 levels can indirectly increase rhizosphere denitrifier activity.

Author

Smart DR, Ritchie K, Stark JM, and Bugbee B

Subjects

Ammonia metabolism, Carbon Dioxide metabolism, Culture Media, Dose-Response Relationship, Drug, Environment, Controlled, Fertilizers, Hydroponics, Nitrogen metabolism, Plant Roots growth & development, Plant Roots metabolism, Plant Shoots drug effects, Plant Shoots growth & development, Plant Shoots metabolism, Soil Microbiology, Triticum growth & development, Triticum metabolism, Carbon Dioxide pharmacology, Nitrates pharmacology, Plant Roots drug effects, Plant Roots microbiology, Triticum drug effects

Abstract

We examined the influence of elevated CO2 concentration on denitrifier enzyme activity in wheat rhizoplanes by using controlled environments and solution culture techniques. Potential denitrification activity was from 3 to 24 times higher on roots that were grown under an elevated CO2 concentration of 1,000 micromoles of CO2 mol-1 than on roots grown under ambient levels of CO2. Nitrogen loss, as determined by a nitrogen mass balance, increased with elevated CO2 levels in the shoot environment and with a high NO3- concentration in the rooting zone. These results indicated that aerial CO2 concentration can play a role in rhizosphere denitrifier activity.

Published

1997

8. Very high CO2 reduces photosynthesis, dark respiration and yield in wheat.

Author

Reuveni J and Bugbee B

Subjects

Biomass, Cell Respiration, Dose-Response Relationship, Drug, Ecological Systems, Closed, Environment, Controlled, Ethylenes metabolism, Life Support Systems, Plant Growth Regulators metabolism, Plant Proteins metabolism, Space Flight, Triticum cytology, Triticum growth & development, Carbon Dioxide pharmacology, Photosynthesis drug effects, Seeds growth & development, Triticum drug effects, Triticum metabolism

Abstract

Although terrestrial CO2 concentrations, [CO2] are not expected to reach 1000 micromoles mol-1 for many decades, CO2 levels in closed systems such as growth chambers and glasshouses, can easily exceed this concentration. CO2 levels in life support systems in space can exceed 10000 micromoles mol-1 (1%). Here we studied the effect of six CO2 concentrations, from ambient up to 10000 micromoles mol-1, on seed yield, growth and gas exchange of two wheat cultivars (USU-Apogee and Veery-l0). Elevating [CO2] from 350 to 1000 micromoles mol-1 increased seed yield (by 33%), vegetative biomass (by 25%) and number of heads m-2 (by 34%) of wheat plants. Elevation of [CO2] from 1000 to 10000 micromoles mol-1 decreased seed yield (by 37%), harvest index (by 14%), mass per seed (by 9%) and number of seeds per head (by 29%). This very high [CO2] had a negligible, non-significant effect on vegetative biomass, number of heads m-2 and seed mass per head. A sharp decrease in seed yield, harvest index and seeds per head occurred by elevating [CO2] from 1000 to 2600 micromoles mol-1. Further elevation of [CO2] from 2600 to 10000 micromoles mol-1 caused a further but smaller decrease. The effect of CO2 on both wheat cultivars was similar for all growth parameters. Similarly there were no differences in the response to high [CO2] between wheat grown hydroponically in growth chambers under fluorescent lights and those grown in soilless media in a glasshouse under sunlight and high pressure sodium lamps. There was no correlation between high [CO2] and ethylene production by flag leaves or by wheat heads. Therefore, the reduction in seed set in wheat plants is not mediated by ethylene. The photosynthetic rate of whole wheat plants was 8% lower and dark respiration of the wheat heads 25% lower when exposed to 2600 micromoles mol-1 CO2 compared to ambient [CO2]. It is concluded that the reduction in the seed set can be mainly explained by the reduction in the dark respiration in wheat heads, when most of the respiration is functional and is needed for seed development.

Published

1997

9. Super-optimal CO2 reduces seed yield but not vegetative growth in wheat.

Author

Grotenhuis TP and Bugbee B

Subjects

Biomass, Carbon Dioxide toxicity, Dose-Response Relationship, Drug, Ethylenes metabolism, Light, Photons, Photosynthesis, Plant Growth Regulators metabolism, Seeds growth & development, Seeds metabolism, Triticum metabolism, Carbon Dioxide pharmacology, Environment, Controlled, Seeds drug effects, Triticum drug effects, Triticum growth & development

Abstract

Although terrestrial atmospheric CO2 levels will not reach 1000 micromoles mol-1 (0.1%) for decades, CO2 levels in growth chambers and greenhouses routinely exceed that concentration. CO2 levels in life support systems in space can exceed 10000 micromoles mol-1(1%). Numerous studies have examined CO2 effects up to 1000 micromoles mol-1, but biochemical measurements indicate that the beneficial effects of CO2 can continue beyond this concentration. We studied the effects of near-optimal (approximately 1200 micromoles mol-1) and super-optimal CO2 levels (2400 micromoles mol-1) on yield of two cultivars of hydroponically grown wheat (Triticum aestivum L.) in 12 trials in growth chambers. Increasing CO2 from sub-optimal to near-optimal (350-1200 micromoles mol-1) increased vegetative growth by 25% and seed yield by 15% in both cultivars. Yield increases were primarily the result of an increased number of heads per square meter. Further elevation of CO2 to 2500 micromoles mol-1 reduced seed yield by 22% (P < 0.001) in cv. Veery-10 and by 15% (P < 0.001) in cv. USU-Apogee. Super-optimal CO2 did not decrease the number of heads per square meter, but reduced seeds per head by 10% and mass per seed by 11%. The toxic effect of CO2 was similar over a range of light levels from half to full sunlight. Subsequent trials revealed that super-optimal CO2 during the interval between 2 wk before and after anthesis mimicked the effect of constant super-optimal CO2. Furthermore, near-optimal CO2 during the same interval mimicked the effect of constant near-optimal CO2. Nutrient concentration of leaves and heads was not affected by CO2. These results suggest that super-optimal CO2 inhibits some process that occurs near the time of seed set resulting in decreased seed set, seed mass, and yield.

Published

1997

10. Super-optimal CO2 reduces wheat yield in growth chamber and greenhouse environments.

Author

Grotenhuis T, Reuveni J, and Bugbee B

Subjects

Biomass, Carbon Dioxide metabolism, Dose-Response Relationship, Drug, Ecological Systems, Closed, Ethylenes metabolism, Life Support Systems, Light, Lighting, Plant Growth Regulators metabolism, Seeds growth & development, Seeds metabolism, Triticum growth & development, Triticum metabolism, Carbon Dioxide pharmacology, Environment, Controlled, Seeds drug effects, Triticum drug effects

Abstract

Seven growth chamber trials (six replicate trials using 0.035, 0.12, and 0.25% CO2 in air and one trial using 0.12, 0.80, and 2.0% CO2 in air) and three replicate greenhouse trials (0.035, 0.10, 0.18, 0.26, 0.50, and 1.0% CO2 in air) compare the effects of super-optimal CO2 on the seed yield, harvest index, and vegetative growth rate of wheat (Triticum aestivum L. cvs. USU-Apogee and Veery-10). Plants in the growth chamber trials were grown hydroponically under fluorescent lamps, while the greenhouse trials were grown under sunlight and high pressure sodium lamps and in soilless media. Plants in the greenhouse trials responded similarly to those in the growth chamber trials; maximum yields occurred near 0.10 and 0.12% CO2 and decreased significantly thereafter. This research indicates that the toxic effects of elevated CO2 are not specific to only one environment and has important implications for the design of bio-regenerative life support systems in space, and for the future of terrestrial agriculture.

Published

1997

11. Controlled environments alter nutrient content of soybeans.

Author

Jurgonski LJ, Smart DJ, Bugbee B, and Nielsen SS

Subjects

Dietary Carbohydrates analysis, Dietary Fiber analysis, Dietary Proteins analysis, Dose-Response Relationship, Drug, Ecological Systems, Closed, Lipids analysis, Nitrates analysis, Nutritive Value, Plant Leaves chemistry, Plant Leaves drug effects, Plant Leaves growth & development, Plant Leaves metabolism, Plant Stems chemistry, Plant Stems drug effects, Plant Stems growth & development, Plant Stems metabolism, Seeds chemistry, Seeds drug effects, Seeds growth & development, Seeds metabolism, Glycine max growth & development, Glycine max metabolism, Carbon Dioxide pharmacology, Environment, Controlled, Minerals analysis, Nitrogen analysis, Glycine max chemistry, Glycine max drug effects

Abstract

Information about compositional changes in plants grown in controlled environments is essential for developing a safe, nutritious diet for a Controlled Ecomological Life-Support System (CELSS). Information now is available for some CELSS candidate crops, but detailed information has been lacking for soybeans. To determine the effect of environment on macronutrient and mineral composition of soybeans, plants were grown both in the field and in a controlled environment where the hydroponic nutrient solution, photosynthetic flux (PPF), and CO2 level were manipulated to achieve rapid growth rates. Plants were harvested at seed maturity, separated into discrete parts, and oven dried prior to chemical analysis. Plant material was analyzed for proximate composition (moisture, protein, lipid, ash, and carbohydrate), total nitrogen (N), nonprotein N (NPN), nitrate, minerals, amino acid composition, and total dietary fiber. The effect of environment on composition varied by cultivar and plant part. Chamber-grown plants generally exhibited the following characteristics compared with field-grown plants: 1) increased total N and protein N for all plant parts, 2) increased nitrate in leaves and stems but not in seeds, 3) increased lipids in seeds, and 4) decreased Ca:P ratio for stems, pods, and leaves. These trends are consistent with data for other CELSS crops. Total N, protein N, and amino acid contents for 350 ppm CO2 and 1000 ppm CO2 were similar for seeds, but protein N and amino acid contents for leaves were higher at 350 ppm CO2 than at 1000 ppm CO2. Total dietary fiber content of soybean leaves was higher with 350 ppm CO2 than with 1000 ppm CO2. Such data will help in selecting of crop species, cultivars, and growing conditions to ensure safe, nutritious diets for CELSS.

Published

1997

12. Mass transfer in the biological fast lane: high CO2 and a shallow root zone.

Author

Smart D, Ritchie K, and Bugbee B

Subjects

Culture Media, Environment, Controlled, Hydroponics, Oxygen metabolism, Plant Leaves drug effects, Plant Leaves metabolism, Plant Roots drug effects, Plant Roots microbiology, Triticum, Ammonia metabolism, Carbon Dioxide pharmacology, Ecological Systems, Closed, Nitrogen metabolism, Plant Roots metabolism, Water Microbiology

Abstract

Elevated atmospheric CO2, which is common in regenerative systems, increases photosynthesis, plant growth, and root respiration, which increases the O2 demand in the root zone. Closed systems must make efficient use of volume and thus have shallow root zones. The root density and O2 demand in these artificial systems is 10 to 100 times higher than in field environments. Rapid hydroponic flow rates supply O2 to the root zone, but anaerobic microsites occur because of nonuniform flow rates. Our measurements suggest that, probably because of low O2 in such microsites, up to 30% of the nitrogen can volatilize from denitrification. We improved nitrogen recovery to about 85% by increasing the solution flow rate and reducing the nitrate concentration in solution to 100 micromoles.

Published

1996

13. The components of crop productivity: measuring and modeling plant metabolism.

Author

Bugbee B

Subjects

Carbon Dioxide adverse effects, Crops, Agricultural radiation effects, Ecological Systems, Closed, Environment, Controlled, Life Support Systems, Light, Models, Biological, Photosynthesis physiology, Plant Roots metabolism, Plant Transpiration physiology, Space Flight, Temperature, Triticum growth & development, Triticum radiation effects, Biomass, Carbon Dioxide metabolism, Crops, Agricultural growth & development, Crops, Agricultural metabolism, Photons, Triticum metabolism

Abstract

Several investigators in the CELSS program have demonstrated that crop plants can be remarkably productive in optimal environments where plants are limited only by incident radiation. Radiation use efficiencies of 0.4 to 0.7 g biomass per mol of incident photons have been measured for crops in several laboratories. Some early published values for radiation use efficiency (1 g mol-1) were inflated due to the effect of side lighting. Sealed chambers are the basic research module for crop studies for space. Such chambers allow the measurement of radiation and CO2 fluxes, thus providing values for three determinants of plant growth: radiation absorption, photosynthetic efficiency (quantum yield), and respiration efficiency (carbon use efficiency). Continuous measurement of each of these parameters over the plant life cycle has provided a blueprint for daily growth rates, and is the basis for modeling crop productivity based on component metabolic processes. Much of what has been interpreted as low photosynthetic efficiency is really the result of reduced leaf expansion and poor radiation absorption. Measurements and models of short-term (minutes to hours) and long-term (days to weeks) plant metabolic rates have enormously improved our understanding of plant environment interactions in ground-based growth chambers and are critical to understanding plant responses to the space environment.

Published

1995

14. An approach to crop modeling with the energy cascade.

Author

Volk T, Bugbee B, and Wheeler RM

Subjects

Biomass, Crops, Agricultural growth & development, Darkness, Energy Metabolism physiology, Triticum growth & development, Triticum metabolism, Carbon Dioxide metabolism, Light, Models, Biological, Photosynthesis physiology, Triticum physiology

Abstract

Use of plants in advanced life support requires models of crop growth to analyze data, to evaluate areas for improvement, and, for design and engineering, to predict the gas exchanges of crops. We used data from experiments at Utah State University and the Kennedy Space Center for wheat (Triticum aestivum L.) and examined it for time dependence of the major three components in the energy cascade: photosynthetic photon absorption, canopy quantum yield, and carbon use efficiency. From the Utah State data, we developed a model with a total of five trends: absorption increasing until canopy closure, then constant; quantum yield as constant, then decreasing during senescence; carbon use as constant. This system probably is the lower limit of simplicity to which a model can be reduced and yet provide substantial utility. We demonstrated this utility by using the model to predict photosynthesis and respiration for experiments at Kennedy Space Center. The most uncertainty arose in predicting a start time for the senescent decrease of canopy quantum yield. The model should be generally applicable to other crops grown in controlled environments, as a generic tool for the design of life support systems.

Published

1995

15. CO2 crop growth enhancement and toxicity in wheat and rice.

Author

Bugbee B, Spanarkel B, Johnson S, Monje O, and Koerner G

Subjects

Biomass, Carbon Dioxide metabolism, Dose-Response Relationship, Drug, Ecological Systems, Closed, Ethylenes metabolism, Light, Oryza enzymology, Oryza growth & development, Oryza metabolism, Photosynthesis drug effects, Plant Growth Regulators metabolism, Plant Transpiration physiology, Seeds drug effects, Seeds growth & development, Seeds physiology, Triticum enzymology, Triticum growth & development, Triticum metabolism, Water metabolism, Carbon Dioxide pharmacology, Environment, Controlled, Oryza drug effects, Ribulose-Bisphosphate Carboxylase metabolism, Temperature, Triticum drug effects

Abstract

The effects of elevated CO2 on plant growth are reviewed and the implications for crop yields in regenerative systems are discussed. There is considerable theoretical and experimental evidence indicating that the beneficial effects of CO2 are saturated at about 0.12% CO2 in air. However, CO2 can easily rise above 1% of the total gas in a closed system, and we have thus studied continuous exposure to CO2 levels as high as 2%. Elevating CO2 from 340 to 1200 micromoles mol-1 can increase the seed yield of wheat and rice by 30 to 40%; unfortunately, further CO2 elevation to 2500 micromoles mol-1 (0.25%) has consistently reduced yield by 25% compared to plants grown at 1200 micromoles mol-1; fortunately, there was only an additional 10% decrease in yield as the CO2 level was further elevated to 2% (20,000 micromoles mol-1). Yield increases in both rice and wheat were primarily the result of increased number of heads per m2, with minor effects on seed number per head and seed size. Yield increases were greatest in the highest photosynthetic photon flux. We used photosynthetic gas exchange to analyze CO2 effects on radiation interception, canopy quantum yield, and canopy carbon use efficiency. We were surprised to find that radiation interception during early growth was not improved by elevated CO2. As expected, CO2 increased quantum yield, but there was also a small increase in carbon use efficiency. Super-optimal CO2 levels did not reduce vegetative growth, but decreased seed set and thus yield. The reduced seed set is not visually apparent until final yield is measured. The physiological mechanism underlying CO2 toxicity is not yet known, but elevated CO2 levels (0.1 to 1% CO2) increase ethylene synthesis in some plants and ethylene is a potent inhibitor of seed set in wheat.

Published

1994

16. The influence of elevated CO2 on non-structural carbohydrate distribution and fructan accumulation in wheat canopies.

Author

Smart DR, Chatterton NJ, and Bugbee B

Subjects

Carbon Dioxide pharmacology, Environment, Controlled, Glucose metabolism, Light, Photons, Starch metabolism, Temperature, Time Factors, Triticum drug effects, Triticum growth & development, Carbohydrate Metabolism, Carbon Dioxide metabolism, Fructans metabolism, Sucrose metabolism, Triticum metabolism

Abstract

We grew 2.4 m2 wheat canopies in a large growth chamber under high photosynthetic photon flux (1000 micromoles m-2 s-1) and using two CO2 concentrations, 360 and 1200 micromoles mol-1. Photosynthetically active radiation (400-700 nm) was attenuated slightly faster through canopies grown in 360 micromoles mol-1 than through canopies grown in 1200 micromoles mol-1, even though high-CO2 canopies attained larger leaf area indices. Tissue fractions were sampled from each 5-cm layer of the canopies. Leaf tissue sampled from the tops of canopies grown in 1200 micromoles mol-1 accumulated significantly more total non-structural carbohydrate, starch, fructan, sucrose, and glucose (p < 0.05) than for canopies grown in 360 micromoles mol-1. Non-structural carbohydrate did not significantly increase in the lower canopy layers of the elevated CO2 treatment. Elevated CO2 induced fructan synthesis in all leaf tissue fractions, but fructan formation was greatest in the uppermost leaf area. A moderate temperature reduction of 10 degrees C over 5 d increased starch, fructan and glucose levels in canopies grown in 1200 micromoles mol-1, but concentrations of sucrose and fructose decreased slightly or remained unchanged. Those results may correspond with the use of fructosyl-residues and release of glucose when sucrose is consumed in fructan synthesis.

Published

1994

17. Steady-state canopy gas exchange: system design and operation.

Author

Bugbee B

Subjects

Air analysis, Carbon Dioxide analysis, Equipment Design, Plant Development, Plant Transpiration, Plants chemistry, Water, Carbon Dioxide metabolism, Life Support Systems instrumentation, Oxygen Consumption, Photosynthesis, Plants metabolism

Abstract

This paper describes the use of a commercial growth chamber for canopy photosynthesis, respiration, and transpiration measurements. The system was designed to measure transpiration via water vapor fluxes, and the importance of this measurement is discussed. Procedures for continuous measurement of root-zone respiration are described, and new data is presented to dispel myths about sources of water vapor interference in photosynthesis and in the measurement of CO2 by infrared gas analysis. Mitchell (1992) has described the fundamentals of various approaches to measuring photosynthesis. Because our system evolved from experience with other types of single-leaf and canopy gas-exchange systems, it is useful to review advantages and disadvantages of different systems as they apply to various research objectives.

Published

1992