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The interactive effects of light, temperature and CO₂/O₂ ratios in photosynthesis of Coix lachryma-jobi LMjwara, Jabulani Michael January 1992 (has links)
A portable infra red gas analyzer was used to investigate the interactive effects of light, temperature, and CO,jO, ratios under controlled environmental conditions in an attempt to model gas exchange characteristics of Coix Iachryma-jobi L. Plotting light response curves as a function of temperature (20, 25 30 and 35°C) revealed no sign of light saturation even at a photosynthetic photon flux density (PPFD) close to 2000 !Lmol m-' sol. High net assimilation rates (A) of approximately 24 !Lmol CO, m"s'! were realized at 30-35°C. Assimilation (A) versus internal CO, partial pressure (C,) curves showed a steep rise with increase in C, but saturated at approximately 150 (JLII-!) and all the results, either in the absence or presence of 0" showed a similar response under all temperature regimes. C. Iachryma-jobi exhibited low CO, compensation points cr ) between 0 and 10 JLlI-! under similar experimental temperatures and either at 0 or 21%0,. The slopes of double reciprocal plots of llA versus llCi, were nearly identical and crossed the yintercept at almost identical points under all 0, concentrations. These data indicate first; that there was no apparent 0, inhibition and second; indicated that the apparent inhIbitor constant (K,) for 0, at the site of carboxylation did not change with increase in [OJ from 0 to 21% oxygen. These observations were further confirmed by results obtained from the analysis of apparent carboxylation efficiency (CE, as defined as the slope of response of A to increasing CO,), as no inhibition of A with increase of [OJ occurred. These characteristics were consistent with typical features of C,photosynthesis. The absence of 0, inhibition and low r values indicated that an efficient CO, concentrating mechanism which eliminates photorespiration exists in C. Iachryma-jobi. At the light microscope level, leaf anatomy exhibited typical C, structure viz. bundle sheath with large chloroplasts and this sheath is further surrounded by a radiate Kranz mesophyU cells. Furthermore the anatomical features suggested that C. wchryma-jobi was an NADP-ME species. Stomatal conductance (g,) to assimilation (g,/A) indicated an increase in A with decrease in g" an essential feature of improving water use efficiency (WUE), but one which drastically reduces CO, diffusion rate. The physical lintitation (stomatal lintitation, t) to CO, diffusion under various [0,] and temperatures, but constant PPFD, did not exhibit statistically significant change in t values at either 0 or 21% a, within each temperature regime, however there was a marked decrease in t as the plant approached its optimum photosynthetic temperature.
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Structural and kinetic analysis of carbon fixation and sucrose metabolism in sugarcaneMeyer, Kristy 03 1900 (has links)
Thesis (MSc (Biochemistry))--Stellenbosch University, 2008. / The aim of this study is the theoretical investigation of carbon fixation in sugarcane
leaves. Sugarcane has a well known reputation for accumulating sucrose in
the stalk to levels as high as 650 mM, almost a fifth of the plant’s fresh weight.
Although this is an efficient accumulating mechanism, there is an even more
efficient ‘carbon pump’ found in C4 plants. This is a well documented carbon
concentrating mechanism and one of the first to be studied. However scientists
are still trying to understand the carboxylating mechanism and the regulation
thereof. It has been speculated that this mechanism is at its saturation level and
elevating carbon dioxide will have little or no effect on further carbon fixation.
Futher, studies suggest that the sucrose accumulating sink is able to regulate photosynthesis.
Therefore a regulatory mechanism should exist from the sink to carbon
fixation in order for such regulation to occur. Thework in this thesis therefore
lays the foundation for investigating regulation of photosynthesis.
The field of systems biology is the study of cellular networks by assemblingmodels.
Pathways are considered as systems and notmerely collections of single components.
This allows the interaction of pathway metabolites and the regulation
that they have on one another to be studied. The questions asked pertaining to a
pathway, will determine the types of model analysis. Structural analysis is useful
for studying stoichiometric models, determining characteristics like energy
consumption, futile cycles and valid pathways through a system at steady-state.
Kinetic analysis on the other hand, gives insight into system dynamics and the
control exerted by the system components, predicting time-course and steady
states.
In this thesis we begin to investigate photosynthesis in sugarcane leaves and
the role it has in accumulating sucrose in the plant. Firstly, a structural model
was developed incorporating carbon fixation, sucrose production in the leaf and subsequent transport of sucrose to the storage parenchyma and accumulation.
The model was analysed using elementary mode analysis, showing that there are
twelve routes for producing sucrose with no pathway beingmore energy efficient
than any other. Further, it highlighted a futile cycle transporting triose phosphates
and phosphoglycerate between the two photosynthetic compartments in
the leaf. In the storage parenchyma, manymore futile cycleswere revealed,many
of them energetically wasteful. Three other sets of elementary modes describe
sucrose’s destination in either the vacuole or use in glycolysis or fibre formation,
each with a different amount of required energy equivalents. The fourth set describes
how sucrose cannot be converted to fibre precursors without also being
used for glycolyis building blocks.
Secondly, a kinetic model of carbon fixation in the leaf was assembled with the
primary goal of characterising thismoiety-conserved cycle. This included the collation
of kinetic data, incorporating volumes of the compartments and the areas
of the location of the transporters into the model. This model was then analysed
using metabolic control analysis. The model was able to predict metabolite concentration
in the pathway at steady-state which were compared to those found
experimentally. However, modifications need to be made to the model before
further analysis is done so that the model predicted values match the experimental
values more accurately. Time course analysis and response coefficients were
also calculated for the carbon fixation cycle.
Thework in this thesis therefore paves the way for understanding photosynthesis
and its regulation in sugarcane leaves. Such work has the potential to pinpoint
genetic engineering target points, allowing for better hybrid selection and propagation.
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The effect of elevated atmospheric carbon dioxide mixing ratios on the emission of Volatile organic compounds from Corymbia citriodora and Tristaniopsis laurinaCamenzuli, Michelle January 2008 (has links)
Thesis (MSc) -- Macquarie University, Division of Environmental and Life Sciences, Dept. of Chemistry and Biomolecular Sciences, 2008. / Bibliography: p. 120-124. / Introduction -- Environmental factors affecting the emission of biogenic Volatile organic compounds -- Materials and experimental procedures -- Quantification using sold-phase microextraction in a dynamic system: technique development -- The emission profile of Tristaniopsis laurina -- Study of the effect of elevated atmospheric CO₂ levels on the emission of BVOCS from Australian native plants -- Conclusions and future work. / Biogenic Volatile Organic Compounds (BVOCs) emitted by plants can affect the climate and play important roles in the chemistry of the troposphere. As ambient atmospheric carbon dioxide (CO₂) levels are rapidly increasing knowledge of the effect of elevated atmospheric CO₂ on plant BVOC emissions is necessary for the development of global climate models. -- During this study, the effect of elevated atmospheric CO2 mixing ratios on BVOC emissions from Corymbia citriodora (Lemon Scented Gum) and Tristaniopsis laurina (Water Gum) was determined for the first time through the combination of Solid-Phase Microextraction (SPME), Gas Chromatography-Flame Ionisation Detection (GC-FID), Gas Chromatography-Mass Spectrometry (GC-MS) and an environment chamber. For C. citriodora elevated atmospheric CO₂ led to a decrease in the emission rate of α-pinene, β-pinene, eucalyptol, citronellal and β-caryophyllene, however, elevated CO₂ had no effect on the emission rate of citronellol. The emission profile of T. laurina has been determined for the first time. For T. laurina elevated CO₂ led to a decrease in the emission rate of α-pinene but the emission rates of β-pinene, limonene, eucalyptol and citronellol were unaffected. The results obtained in this work confirm that the effect of elevated atmospheric CO₂ on plant BVOC emissions is species-specific. / Mode of access: World Wide Web. / 124 leaves ill. (some col.)
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Interactive Effects of Elevated CO2 and Salinity on Three Common Grass SpeciesMoxley, Donovan J. 14 August 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Carbon dioxide (CO2) level in the atmosphere has increased steadily since Pre-Industrial times. The need for a better understanding of the effects of elevated CO2 on plant physiology and growth is clear. Previous studies have focused on how plants are affected by either elevated CO2 or salinity, one of many environmental stresses for plants. However, little research has been focused on the interaction of these two factors. In my project, three common grass species were exposed to both elevated CO2 and salinity, so that the effects of either of these factors and the interaction of the two on these species could be examined. The CO2 levels were set to 400 µmol mol-1, close to the current concentration, or 760 µmol mol-1, projected to be reached by the end of this century. Salt solutions of 0, 25, 50, 75, and 100 mM NaCl with CaCl2 at lower rates (1% of each respective molarity for NaCl) were used to water the grasses, which are unlikely to experience prolonged exposure to salt conditions beyond this range in their natural habitats. The three common grass species studied in my experiment were Kentucky bluegrass (Poa pratensis L.) and red fescue (Festuca rubra L.), both C3 cool season grasses, as well as buffalo grass (Buchloe dactyloides (Nutt.) Engelm.), a C4 warm season
grass. Each treatment had five replicates, bringing the total number of experimental pots to 150. Various growth parameters were monitored, and all data was statistically analyzed for statistical significance. My results showed that elevated CO2 had a stimulating effect on most growth parameters, particularly when plants were given more time to grow. In a 100-day growth experiment, CO2 affected the number and dry biomass of plants of all species, regardless of their C3 or C¬4 photosynthetic pathways. Salinity consistently inhibited germination and growth at all stages, from germination through plant emergences, numbers of established plants, and dry biomasses at harvest. Interactive effects of CO2 and salinity did occur, though often in seemingly specific instances rather than forming clear and consistent trends. My findings suggested that growth of common grasses would be enhanced by the rising level of CO2 in the atmosphere, but the effect would be modified by environmental stresses, such as salinity.
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Biogeochemical study of coccolithophorid blooms in the context of climate change / Etude biogéochimique des efflorescences de coccolithophores dans le contexte des changements climatiquesHarlay, Jérôme 20 March 2009 (has links)
Coccolithophores are unicellular microscopic algae (Haptophyta) surrounded by calcium carbonate plates that are produced during their life cycle. These species, whose contemporary contributor is Emiliania huxleyi, are mainly found in the sub-polar and temperate oceans, where they produce huge blooms visible from space. Coccolithophores are sensitive to ocean acidification that results from the ongoing accumulation of anthropogenic carbon dioxide (CO2) in the atmosphere. The response of these organisms to global change appears to be related to the reduction of their ability to produce calcium carbonate at the cellular level. At the community levels, one anticipates changes in the carbon fluxes associated to their blooms as calcification is reduced. However, the consequences of such environmental changes on this species are speculative and require improvements in the description of the mechanisms controlling the organic and inorganic carbon production and export.<p><p>The first aspect of this work was to study the response of these organisms to artificially modified CO2 concentrations representative of the conditions occurring in the past (glacial) and those expected by the end of the century (2100). Two different levels were examined: the continuous monospecific cultures (chemostats) allowed us to work at the cellular level while the mesocosms gave light to the mechanisms taking place in an isolated fraction of the natural community. The second aspect of this work consisted of field studies carried out during four cruises (2002, 2003, 2004 and 2006) in the northern Bay of Biscay, where the occurrence of E. huxleyi blooms were observed in late spring and early summer. We describe the vertical profiles of biogeochemical variables (nutrients, chlorophyll-a, dissolved inorganic chemistry, particulate carbon, transparent exopolymer particles (TEP)) and study processes such as primary production, calcification and bacterial production. The properties of these blooms are compared with those reported in the literature and enriched with original measurements such as the abundance and concentration of TEP that could play an important role in carbon export to the deep ocean, modifying the properties of the settling ballasted aggregates.<p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
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