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2. High photosynthesis rates in Brassiceae species are mediated by leaf anatomy enabling high biochemical capacity, rapid CO2 diffusion and efficient light use.

Author

Retta, Moges A., Van Doorselaer, Leen, Driever, Steven M., Yin, Xinyou, de Ruijter, Norbert C. A., Verboven, Pieter, Nicolaï, Bart M., and Struik, Paul C.

Subjects
*PHOTOSYNTHETIC rates, *LEAF anatomy, *MUSTARD, *LIGHT absorbance, *LIGHT intensity
Abstract

Summary: Certain species in the Brassicaceae family exhibit high photosynthesis rates, potentially providing a valuable route toward improving agricultural productivity. However, factors contributing to their high photosynthesis rates are still unknown.We compared Hirschfeldia incana, Brassica nigra, Brassica rapa and Arabidopsis thaliana, grown under two contrasting light intensities.Hirschfeldia incana matched B. nigra and B. rapa in achieving very high photosynthesis rates under high growth‐light condition, outperforming A. thaliana. Photosynthesis was relatively more limited by maximum photosynthesis capacity in H. incana and B. rapa and by mesophyll conductance in A. thaliana and B. nigra. Leaf traits such as greater exposed mesophyll specific surface enabled by thicker leaf or high‐density small palisade cells contributed to the variation in mesophyll conductance among the species. The species exhibited contrasting leaf construction strategies and acclimation responses to low light intensity. High‐light plants distributed Chl deeper in leaf tissue, ensuring even distribution of photosynthesis capacity, unlike low‐light plants.Leaf anatomy of H. incana, B. nigra and B. rapa facilitated effective CO2 diffusion, efficient light use and provided ample volume for their high maximum photosynthetic capacity, indicating that a combination of adaptations is required to increase CO2‐assimilation rates in plants. [ABSTRACT FROM AUTHOR]

Published
2024
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4. The role of chloroplast movement in C4 photosynthesis: a theoretical analysis using a three-dimensional reaction-diffusion model for maize

Author

Research Councils UK, Agencia Estatal de Investigación (España), Retta, Moges A. [0000-0002-4835-7274], Yin, Xinyou [0000-0001-8273-8022], Ho, Quang Tri [0000-0003-3766-0283], Berghuijs, Herman N.C. [0000-0002-1754-5061], Verboven, Pieter [0000-0001-9542-8285], Saeys, Wouter [0000-0002-5849-4301], Cano, F. J. [0000-0001-5720-5865], Ghannoum, Oula [0000-0002-1341-0741], Struik, Paul C. [0000-0003-2196-547X], Nicolaï, Bart M. [0000-0001-5267-1920], Retta, Moges A., Yin, Xinyou, Ho, Quang Tri, Watté, Rodrigo, Berghuijs, Herman N.C., Verboven, Pieter, Saeys, Wouter, Cano, F. J., Ghannoum, Oula, Struik, Paul C., Nicolaï, Bart M., Research Councils UK, Agencia Estatal de Investigación (España), Retta, Moges A. [0000-0002-4835-7274], Yin, Xinyou [0000-0001-8273-8022], Ho, Quang Tri [0000-0003-3766-0283], Berghuijs, Herman N.C. [0000-0002-1754-5061], Verboven, Pieter [0000-0001-9542-8285], Saeys, Wouter [0000-0002-5849-4301], Cano, F. J. [0000-0001-5720-5865], Ghannoum, Oula [0000-0002-1341-0741], Struik, Paul C. [0000-0003-2196-547X], Nicolaï, Bart M. [0000-0001-5267-1920], Retta, Moges A., Yin, Xinyou, Ho, Quang Tri, Watté, Rodrigo, Berghuijs, Herman N.C., Verboven, Pieter, Saeys, Wouter, Cano, F. J., Ghannoum, Oula, Struik, Paul C., and Nicolaï, Bart M.

Abstract

Chloroplasts movement within mesophyll cells in C4 plants is hypothesized to enhance the CO2 concentrating mechanism, but this is difficult to verify experimentally. A three-dimensional (3D) leaf model can help analyse how chloroplast movement influences the operation of the CO2 concentrating mechanism. The first volumetric reaction-diffusion model of C4 photosynthesis that incorporates detailed 3D leaf anatomy, light propagation, ATP and NADPH production, and CO2, O2 and bicarbonate concentration driven by diffusional and assimilation/emission processes was developed. It was implemented for maize leaves to simulate various chloroplast movement scenarios within mesophyll cells: the movement of all mesophyll chloroplasts towards bundle sheath cells (aggregative movement) and movement of only those of interveinal mesophyll cells towards bundle sheath cells (avoidance movement). Light absorbed by bundle sheath chloroplasts relative to mesophyll chloroplasts increased in both cases. Avoidance movement decreased light absorption by mesophyll chloroplasts considerably. Consequently, total ATP and NADPH production and net photosynthetic rate increased for aggregative movement and decreased for avoidance movement compared with the default case of no chloroplast movement at high light intensities. Leakiness increased in both chloroplast movement scenarios due to the imbalance in energy production and demand in mesophyll and bundle sheath cells. These results suggest the need to design strategies for coordinated increases in electron transport and Rubisco activities for an efficient CO2 concentrating mechanism at very high light intensities.

Published
2023

5. The role of chloroplast movement in C4 photosynthesis: a theoretical analysis using a three-dimensional reaction–diffusion model for maize

Author

Retta, Moges A, primary, Yin, Xinyou, additional, Ho, Quang Tri, additional, Watté, Rodrigo, additional, Berghuijs, Herman N C, additional, Verboven, Pieter, additional, Saeys, Wouter, additional, Cano, Francisco Javier, additional, Ghannoum, Oula, additional, Struik, Paul C, additional, and Nicolaï, Bart M, additional

Published
2023
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6. The role of chloroplast movement in C4 photosynthesis : a theoretical analysis using a three-dimensional reaction–diffusion model for maize

Author

Retta, Moges A., Yin, Xinyou, Ho, Quang Tri, Watté, Rodrigo, Berghuijs, Herman N.C., Verboven, Pieter, Saeys, Wouter, Cano, Francisco Javier, Ghannoum, Oula, Struik, Paul C., Nicolaï, Bart M., Retta, Moges A., Yin, Xinyou, Ho, Quang Tri, Watté, Rodrigo, Berghuijs, Herman N.C., Verboven, Pieter, Saeys, Wouter, Cano, Francisco Javier, Ghannoum, Oula, Struik, Paul C., and Nicolaï, Bart M.

Abstract

Chloroplasts movement within mesophyll cells in C4 plants is hypothesized to enhance the CO2 concentrating mechanism, but this is difficult to verify experimentally. A three-dimensional (3D) leaf model can help analyse how chloroplast movement influences the operation of the CO2 concentrating mechanism. The first volumetric reaction–diffusion model of C4 photosynthesis that incorporates detailed 3D leaf anatomy, light propagation, ATP and NADPH production, and CO2, O2 and bicarbonate concentration driven by diffusional and assimilation/emission processes was developed. It was implemented for maize leaves to simulate various chloroplast movement scenarios within mesophyll cells: the movement of all mesophyll chloroplasts towards bundle sheath cells (aggregative movement) and movement of only those of interveinal mesophyll cells towards bundle sheath cells (avoidance movement). Light absorbed by bundle sheath chloroplasts relative to mesophyll chloroplasts increased in both cases. Avoidance movement decreased light absorption by mesophyll chloroplasts considerably. Consequently, total ATP and NADPH production and net photosynthetic rate increased for aggregative movement and decreased for avoidance movement compared with the default case of no chloroplast movement at high light intensities. Leakiness increased in both chloroplast movement scenarios due to the imbalance in energy production and demand in mesophyll and bundle sheath cells. These results suggest the need to design strategies for coordinated increases in electron transport and Rubisco activities for an efficient CO2 concentrating mechanism at very high light intensities.

Published
2023

7. Dataset for 'High photosynthesis rates in Brassiceae species are mediated by leaf anatomy enabling high biochemical capacity, rapid CO2 diffusion and efficient light use'

Author

Retta, Moges, Van Doorselaer, Leen, Driever, Steven, Yin, X., de Ruijter, Norbert, Verboven, P., Nicolai, B.M., Struik, Paul, Retta, Moges, Van Doorselaer, Leen, Driever, Steven, Yin, X., de Ruijter, Norbert, Verboven, P., Nicolai, B.M., and Struik, Paul

Abstract

Dataset used in the manuscript 'High photosynthesis rates in Brassiceae species are mediated by leaf anatomy enabling high biochemical capacity, rapid CO2 diffusion and efficient light use'. Please cite the paper presenting this datase.

Published
2023

8. The role of chloroplast movement in C4 photosynthesis: a theoretical analysis using a three-dimensional reaction–diffusion model for maize.

Author

Retta, Moges A, Yin, Xinyou, Ho, Quang Tri, Watté, Rodrigo, Berghuijs, Herman N C, Verboven, Pieter, Saeys, Wouter, Cano, Francisco Javier, Ghannoum, Oula, Struik, Paul C, and Nicolaï, Bart M

Subjects
*CELL motility, *THREE-dimensional modeling, *LEAF anatomy, *LIGHT propagation, *PHOTOSYNTHESIS
Abstract

Chloroplasts movement within mesophyll cells in C4 plants is hypothesized to enhance the CO2 concentrating mechanism, but this is difficult to verify experimentally. A three-dimensional (3D) leaf model can help analyse how chloroplast movement influences the operation of the CO2 concentrating mechanism. The first volumetric reaction–diffusion model of C4 photosynthesis that incorporates detailed 3D leaf anatomy, light propagation, ATP and NADPH production, and CO2, O2 and bicarbonate concentration driven by diffusional and assimilation/emission processes was developed. It was implemented for maize leaves to simulate various chloroplast movement scenarios within mesophyll cells: the movement of all mesophyll chloroplasts towards bundle sheath cells (aggregative movement) and movement of only those of interveinal mesophyll cells towards bundle sheath cells (avoidance movement). Light absorbed by bundle sheath chloroplasts relative to mesophyll chloroplasts increased in both cases. Avoidance movement decreased light absorption by mesophyll chloroplasts considerably. Consequently, total ATP and NADPH production and net photosynthetic rate increased for aggregative movement and decreased for avoidance movement compared with the default case of no chloroplast movement at high light intensities. Leakiness increased in both chloroplast movement scenarios due to the imbalance in energy production and demand in mesophyll and bundle sheath cells. These results suggest the need to design strategies for coordinated increases in electron transport and Rubisco activities for an efficient CO2 concentrating mechanism at very high light intensities. [ABSTRACT FROM AUTHOR]

Published
2023
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12. Microscale modeling of gas exchange during C4 photosythesis

Author

Retta, Moges, Wageningen University, B. Nicolai, Paul Struik, and P. Verboven

Subjects
Crop Physiology, Centre for Crop Systems Analysis, Life Science, PE&RC
Abstract

Improving the efficiency of photosynthesis could contribute to better food security under an unprecedented rise in global population and climate-change. The photosynthesis pathway in C4 plants, such as maize (Zea mays L.), Miscanthus (Miscanthus x giganteus), and sugarcane (Saccharum officinarum L.), results in higher productivity and photosynthetic nitrogen and water-use efficiencies than in C3 plants. The mechanism of photosynthesis in C4 crops depends on the archetypal Kranz anatomy, which determines the leaf internal environment, for it influences gas diffusion and light distribution. The low permeability of bundle sheath cell walls to CO2 (gbs) and the high CO2 conductance of mesophyll cells (gm) are crucial for a high C4 photosynthetic efficiency. So far, the relationship between leaf anatomical properties and CO2 conductances such as gbs and gm in C4 plants received less attention than in C3 plants. In addition, these conductances lump a number of anatomical features; mechanistic understanding of the role of each microstructure element in the efficiency of photosynthesis is, therefore, limited. Furthermore, there are only few studies addressing the potential limitations of C4 leaf anatomy on light propagation and efficiency of photosynthesis. To investigate the role of leaf anatomy, as altered by leaf nitrogen content and age on the efficiency of C4 photosynthesis, maize (Zea mays L.) plants were grown under three contrasting nitrogen levels. Combined gas exchange and chlorophyll fluorescence measurements were carried out on fully grown leaves at two leaf ages: young and old. The measured data were combined with a biochemical model of C4 photosynthesis to estimate gbs. The leaf microstructure and ultrastructure were quantified using images obtained from micro-computed tomography and microscopy. Increased nitrogen supply resulted in higher leaf nitrogen content and rate of photosynthesis, whereas leaf aging decreased them. There was a strong positive correlation between gbs and leaf nitrogen content (LNC) while old leaves had lower gbs than young leaves. gm also increased with LNC and decreased with leaf aging. The increase of gbs with LNC was little explained by a change in leaf anatomy. By contrast, the combined effects of LNC and leaf age on anatomical features were responsible for differences in gbs between young leaves and old leaves. It is recommended that changes in the leaf ultrastructure at levels of membranes and plasmodesmata should be investigated to unravel the relationship between anatomy and CO2 conductances further. Furthermore, since gbs thus estimated, lumps a number of microstructural features, the contribution of each individual leaf microstructural feature could not be determined. Therefore, a microscale modeling approach that accounts for each leaf microstructural and ultrastructural features is recommended. A two-dimensional microscale model of gas diffusion and photosynthesis in C4 leaves that incorporates the physical obstructions of leaf anatomy and ultrastructure on gas transport was developed. The leaf anatomical geometry was developed from light microscopy images of the same leaf that was also used in gas exchange measurements. Features such as cell walls, biological membranes, plasmodesmata and suberin layers around bundle sheath cell walls were modeled as resistances. Reaction-diffusion equations for CO2 and bicarbonate in liquid phase media were developed and discretized over the two-dimensional leaf geometry. The model predicted the responses of photosynthesis to irradiance and intercellular CO2 in agreement with that obtained from measurement. The impact of components of the CO2 diffusion pathway on photosynthesis was evaluated quantitatively. The CO2 permeability of the mesophyll-bundle sheath and air space-mesophyll interfaces strongly affected the rate of photosynthesis and gbs. Carbonic anhydrase influenced the rate of photosynthesis, especially at low intercellular CO2 levels. In addition, the suberin layer at the exposed surface of the bundle sheath cells was found beneficial in reducing the retro-diffusion of CO2. One or two-dimensional gas transport models, when applied to analyze the gas diffusion in leaves understate the three-dimensional nature of gas exchange. Therefore, a 3-D microscale model incorporating the actual leaf microstructure was developed. The distribution of light through the leaf tissue was modeled using an adapted Monte Carlo photon transport method. Diffusion of CO2 and O2 was coupled with C4 photosynthesis kinetics and a model of light penetration inside the leaf tissue. The temperature dependency of biochemical and biophysical parameters was incorporated. The typical Kranz-anatomy of the leaf tissue caused large gradients of light intensity and concentration of gases. Maximum photosynthesis at low leakiness was obtained when chlorophyll contents of mesophyll and bundle sheath cells were equal. At elevated CO2, photosynthesis in bundle sheath cells of juvenile leaves could potentially be supported by direct diffusion. Simulations also suggest that the effect of temperature on biophysical processes, in contrast to that on biochemical processes, has little influence on the temperature response of C4 photosynthesis and leakiness. In addition, a systematic analysis showed that cytosolic CO2 release due to decarboxylation of C4 acids would reduce the efficiency of photosynthesis only moderately. The model may serve as a tool to further investigate improving C4 photosynthesis in relation to gas exchange and light propagation.

Published
2017

13. In silico study of the role of cell growth factors in photosynthesis using a virtual leaf tissue generator coupled to a microscale photosynthesis gas exchange model.

Author

Retta, Moges A, Abera, Metadel K, Berghuijs, Herman Nc, Verboven, Pieter, Struik, Paul C, and Nicolaï, Bart M

Subjects
*GROWTH factors, *TOMATOES, *PHOTOSYNTHESIS, *GAS exchange in plants, *LEAF anatomy, *PHOTOSYNTHETIC rates, *LEAF area, *CELL growth
Abstract

Computational tools that allow in silico analysis of the role of cell growth and division on photosynthesis are scarce. We present a freely available tool that combines a virtual leaf tissue generator and a two-dimensional microscale model of gas transport during C3 photosynthesis. A total of 270 mesophyll geometries were generated with varying degrees of growth anisotropy, growth extent, and extent of schizogenous airspace formation in the palisade mesophyll. The anatomical properties of the virtual leaf tissue and microscopic cross-sections of actual leaf tissue of tomato (Solanum lycopersicum L.) were statistically compared. Model equations for transport of CO2 in the liquid phase of the leaf tissue were discretized over the geometries. The virtual leaf tissue generator produced a leaf anatomy of tomato that was statistically similar to real tomato leaf tissue. The response of photosynthesis to intercellular CO2 predicted by a model that used the virtual leaf tissue geometry compared well with measured values. The results indicate that the light-saturated rate of photosynthesis was influenced by interactive effects of extent and directionality of cell growth and degree of airspace formation through the exposed surface of mesophyll per leaf area. The tool could be used further in investigations of improving photosynthesis and gas exchange in relation to cell growth and leaf anatomy. [ABSTRACT FROM AUTHOR]

Published
2020
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14. Microscale modeling of gas exchange during C4 photosythesis

Author

Nicolai, B., Struik, Paul, Verboven, P., Retta, Moges, Nicolai, B., Struik, Paul, Verboven, P., and Retta, Moges

Abstract

Improving the efficiency of photosynthesis could contribute to better food security under an unprecedented rise in global population and climate-change. The photosynthesis pathway in C4 plants, such as maize (Zea mays L.), Miscanthus (Miscanthus x giganteus), and sugarcane (Saccharum officinarum L.), results in higher productivity and photosynthetic nitrogen and water-use efficiencies than in C3 plants. The mechanism of photosynthesis in C4 crops depends on the archetypal Kranz anatomy, which determines the leaf internal environment, for it influences gas diffusion and light distribution. The low permeability of bundle sheath cell walls to CO2 (gbs) and the high CO2 conductance of mesophyll cells (gm) are crucial for a high C4 photosynthetic efficiency. So far, the relationship between leaf anatomical properties and CO2 conductances such as gbs and gm in C4 plants received less attention than in C3 plants. In addition, these conductances lump a number of anatomical features; mechanistic understanding of the role of each microstructure element in the efficiency of photosynthesis is, therefore, limited. Furthermore, there are only few studies addressing the potential limitations of C4 leaf anatomy on light propagation and efficiency of photosynthesis. To investigate the role of leaf anatomy, as altered by leaf nitrogen content and age on the efficiency of C4 photosynthesis, maize (Zea mays L.) plants were grown under three contrasting nitrogen levels. Combined gas exchange and chlorophyll fluorescence measurements were carried out on fully grown leaves at two leaf ages: young and old. The measured data were combined with a biochemical model of C4 photosynthesis to estimate gbs. The leaf microstructure and ultrastructure were quantified using images obtained from micro-computed tomography and microscopy. Increased nitrogen supply resulted in higher leaf nitrogen content and rate of photosynthesis, whereas leaf aging decreased them. There was a strong positive correlati

Published
2017

15. Localization of (photo)respiration and CO2 re-assimilation in tomato leaves investigated with a reaction-diffusion model

Author

Berghuijs, Herman N.C., Yin, Xinyou, Ho, Quang Tri, Retta, Moges A., Verboven, Pieter, Nicolaï, Bart M., Struik, Paul C., Berghuijs, Herman N.C., Yin, Xinyou, Ho, Quang Tri, Retta, Moges A., Verboven, Pieter, Nicolaï, Bart M., and Struik, Paul C.

Abstract

The rate of photosynthesis depends on the CO2 partial pressure near Rubisco, Cc, which is commonly calculated by models using the overall mesophyll resistance. Such models do not explain the difference between the CO2 level in the intercellular air space and Cc mechanistically. This problem can be overcome by reaction-diffusion models for CO2 transport, production and fixation in leaves. However, most reaction-diffusion models are complex and unattractive for procedures that require a large number of runs, like parameter optimisation. This study provides a simpler reaction-diffusion model. It is parameterized by both leaf physiological and leaf anatomical data. The anatomical data consisted of the thickness of the cell wall, cytosol and stroma, and the area ratios of mesophyll exposed to the intercellular air space to leaf surfaces and exposed chloroplast to exposed mesophyll surfaces. The model was used directly to estimate photosynthetic parameters from a subset of the measured light and CO2 response curves; the remaining data were used for validation. The model predicted light and CO2 response curves reasonably well for 15 days old tomato (cv. Admiro) leaves, if (photo)respiratory CO2 release was assumed to take place in the inner cytosol or in the gaps between the chloroplasts. The model was also used to calculate the fraction of CO2 produced by (photo)respiration that is re-assimilated in the stroma, and this fraction ranged from 56 to 76%. In future research, the model should be further validated to better understand how the re-assimilation of (photo)respired CO2 is affected by environmental conditions and physiological parameters.

Published
2017

17. Using a reaction‐diffusion model to estimate day respiration and reassimilation of (photo)respired CO2 in leaves.

Author

Berghuijs, Herman N. C., Yin, Xinyou, Ho, Q. Tri, Retta, Moges A., Nicolaï, Bart M., and Struik, Paul C.

Subjects
RESPIRATION, CHLOROPHYLL spectra, BRACHYPODIUM, LEAF anatomy, RESPIRATORY measurements, LEAVES
Abstract

Summary: Methods using gas exchange measurements to estimate respiration in the light (day respiration Rd) make implicit assumptions about reassimilation of (photo)respired CO2; however, this reassimilation depends on the positions of mitochondria.We used a reaction‐diffusion model without making these assumptions to analyse datasets on gas exchange, chlorophyll fluorescence and anatomy for tomato leaves. We investigated how Rd values obtained by the Kok and the Yin methods are affected by these assumptions and how those by the Laisk method are affected by the positions of mitochondria.The Kok method always underestimated Rd. Estimates of Rd by the Yin method and by the reaction‐diffusion model agreed only for nonphotorespiratory conditions. Both the Yin and Kok methods ignore reassimilation of (photo)respired CO2, and thus underestimated Rd for photorespiratory conditions, but this was less so in the Yin than in the Kok method. Estimates by the Laisk method were affected by assumed positions of mitochondria. It did not work if mitochondria were in the cytosol between the plasmamembrane and the chloroplast envelope. However, mitochondria were found to be most likely between the tonoplast and chloroplasts.Our reaction‐diffusion model effectively estimates Rd, enlightens the dependence of Rd estimates on reassimilation and clarifies (dis)advantages of existing methods. [ABSTRACT FROM AUTHOR]

Published
2019
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22. Three-dimensional microscale modelling of CO2transport and light propagation in tomato leaves enlightens photosynthesis

Author

Ho, Quang Tri, primary, Berghuijs, Herman N. C., additional, Watté, Rodrigo, additional, Verboven, Pieter, additional, Herremans, Els, additional, Yin, Xinyou, additional, Retta, Moges A., additional, Aernouts, Ben, additional, Saeys, Wouter, additional, Helfen, Lukas, additional, Farquhar, Graham D., additional, Struik, Paul C., additional, and Nicolaï, Bart M., additional

Published
2015
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23. Localization of (photo)respiration and CO2 re-assimilation in tomato leaves investigated with a reaction-diffusion model.

Author

Berghuijs, Herman N. C., Yin, Xinyou, Ho, Q. Tri, Retta, Moges A., Verboven, Pieter, Nicolaï, Bart M., and Struik, Paul C.

Subjects
PHOTOSYNTHESIS, MESOPHYLL tissue, CYTOSOL, BACTERIAL cell walls, CHLOROPLASTS
Abstract

The rate of photosynthesis depends on the CO2 partial pressure near Rubisco, Cc, which is commonly calculated by models using the overall mesophyll resistance. Such models do not explain the difference between the CO2 level in the intercellular air space and Cc mechanistically. This problem can be overcome by reaction-diffusion models for CO2 transport, production and fixation in leaves. However, most reaction-diffusion models are complex and unattractive for procedures that require a large number of runs, like parameter optimisation. This study provides a simpler reaction-diffusion model. It is parameterized by both leaf physiological and leaf anatomical data. The anatomical data consisted of the thickness of the cell wall, cytosol and stroma, and the area ratios of mesophyll exposed to the intercellular air space to leaf surfaces and exposed chloroplast to exposed mesophyll surfaces. The model was used directly to estimate photosynthetic parameters from a subset of the measured light and CO2 response curves; the remaining data were used for validation. The model predicted light and CO2 response curves reasonably well for 15 days old tomato (cv. Admiro) leaves, if (photo)respiratory CO2 release was assumed to take place in the inner cytosol or in the gaps between the chloroplasts. The model was also used to calculate the fraction of CO2 produced by (photo)respiration that is re-assimilated in the stroma, and this fraction ranged from 56 to 76%. In future research, the model should be further validated to better understand how the re-assimilation of (photo)respired CO2 is affected by environmental conditions and physiological parameters. [ABSTRACT FROM AUTHOR]

Published
2017
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25. Three-dimensional microscale modelling of CO2 transport and light propagation in tomato leaves enlightens photosynthesis.

Author

Ho, Quang Tri, Berghuijs, Herman N. C., Watté, Rodrigo, Verboven, Pieter, Herremans, Els, Yin, Xinyou, Retta, Moges A., Aernouts, Ben, Saeys, Wouter, Helfen, Lukas, Farquhar, Graham D., Struik, Paul C., and Nicolaï, Bart M.

Subjects
LIGHT propagation, PHOTOSYNTHESIS, SYNCHROTRON radiation, PLANT photorespiration, TOMOGRAPHY, CARBON dioxide
Abstract

We present a combined three-dimensional (3-D) model of light propagation, CO2 diffusion and photosynthesis in tomato (Solanum lycopersicum L.) leaves. The model incorporates a geometrical representation of the actual leaf microstructure that we obtained with synchrotron radiation X-ray laminography, and was evaluated using measurements of gas exchange and leaf optical properties. The combination of the 3-D microstructure of leaf tissue and chloroplast movement induced by changes in light intensity affects the simulated CO2 transport within the leaf. The model predicts extensive reassimilation of CO2 produced by respiration and photorespiration. Simulations also suggest that carbonic anhydrase could enhance photosynthesis at low CO2 levels but had little impact on photosynthesis at high CO2 levels. The model confirms that scaling of photosynthetic capacity with absorbed light would improve efficiency of CO2 fixation in the leaf, especially at low light intensity. [ABSTRACT FROM AUTHOR]

Published
2016
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26. High photosynthesis rates in Brassiceae species are mediated by leaf anatomy enabling high biochemical capacity, rapid CO 2 diffusion and efficient light use.

Author

Retta MA, Van Doorselaer L, Driever SM, Yin X, de Ruijter NCA, Verboven P, Nicolaï BM, and Struik PC

Subjects
Diffusion, Arabidopsis physiology, Arabidopsis radiation effects, Mesophyll Cells radiation effects, Mesophyll Cells physiology, Mesophyll Cells metabolism, Species Specificity, Chlorophyll metabolism, Acclimatization, Photosynthesis radiation effects, Plant Leaves physiology, Plant Leaves anatomy & histology, Plant Leaves radiation effects, Carbon Dioxide metabolism, Light, Brassicaceae physiology, Brassicaceae radiation effects, Brassicaceae anatomy & histology
Abstract

Certain species in the Brassicaceae family exhibit high photosynthesis rates, potentially providing a valuable route toward improving agricultural productivity. However, factors contributing to their high photosynthesis rates are still unknown. We compared Hirschfeldia incana, Brassica nigra, Brassica rapa and Arabidopsis thaliana, grown under two contrasting light intensities. Hirschfeldia incana matched B. nigra and B. rapa in achieving very high photosynthesis rates under high growth-light condition, outperforming A. thaliana. Photosynthesis was relatively more limited by maximum photosynthesis capacity in H. incana and B. rapa and by mesophyll conductance in A. thaliana and B. nigra. Leaf traits such as greater exposed mesophyll specific surface enabled by thicker leaf or high-density small palisade cells contributed to the variation in mesophyll conductance among the species. The species exhibited contrasting leaf construction strategies and acclimation responses to low light intensity. High-light plants distributed Chl deeper in leaf tissue, ensuring even distribution of photosynthesis capacity, unlike low-light plants. Leaf anatomy of H. incana, B. nigra and B. rapa facilitated effective CO 2 diffusion, efficient light use and provided ample volume for their high maximum photosynthetic capacity, indicating that a combination of adaptations is required to increase CO 2 -assimilation rates in plants., (© 2024 The Author(s). New Phytologist © 2024 New Phytologist Foundation.)

Published
2024
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27. Using a reaction-diffusion model to estimate day respiration and reassimilation of (photo)respired CO 2 in leaves.

Author

Berghuijs HNC, Yin X, Ho QT, Retta MA, Nicolaï BM, and Struik PC

Subjects
Cell Respiration radiation effects, Computer Simulation, Diffusion, Mesophyll Cells metabolism, Mesophyll Cells radiation effects, Carbon Dioxide metabolism, Light, Models, Biological, Plant Leaves metabolism, Plant Leaves radiation effects
Abstract

Methods using gas exchange measurements to estimate respiration in the light (day respiration R d ) make implicit assumptions about reassimilation of (photo)respired CO 2 ; however, this reassimilation depends on the positions of mitochondria. We used a reaction-diffusion model without making these assumptions to analyse datasets on gas exchange, chlorophyll fluorescence and anatomy for tomato leaves. We investigated how R d values obtained by the Kok and the Yin methods are affected by these assumptions and how those by the Laisk method are affected by the positions of mitochondria. The Kok method always underestimated R d . Estimates of R d by the Yin method and by the reaction-diffusion model agreed only for nonphotorespiratory conditions. Both the Yin and Kok methods ignore reassimilation of (photo)respired CO 2 , and thus underestimated R d for photorespiratory conditions, but this was less so in the Yin than in the Kok method. Estimates by the Laisk method were affected by assumed positions of mitochondria. It did not work if mitochondria were in the cytosol between the plasmamembrane and the chloroplast envelope. However, mitochondria were found to be most likely between the tonoplast and chloroplasts. Our reaction-diffusion model effectively estimates R d , enlightens the dependence of R d estimates on reassimilation and clarifies (dis)advantages of existing methods., (© 2019 The Authors. New Phytologist © 2019 New Phytologist Trust.)

Published
2019
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28. Mesophyll conductance and reaction-diffusion models for CO 2 transport in C 3 leaves; needs, opportunities and challenges.

Author

Berghuijs HN, Yin X, Ho QT, Driever SM, Retta MA, Nicolaï BM, and Struik PC

Subjects
Biological Transport, Diffusion, Models, Theoretical, Partial Pressure, Plant Leaves metabolism, Plant Physiological Phenomena, Ribulose-Bisphosphate Carboxylase metabolism, Carbon Dioxide metabolism, Mesophyll Cells physiology, Photosynthesis physiology
Abstract

One way to increase potential crop yield could be increasing mesophyll conductance g m . This variable determines the difference between the CO 2 partial pressure in the intercellular air spaces (C i ) and that near Rubisco (C c ). Various methods can determine g m from gas exchange measurements, often combined with measurements of chlorophyll fluorescence or carbon isotope discrimination. g m lumps all biochemical and physical factors that cause the difference between C c and C i . g m appears to vary with C i . This variability indicates that g m does not satisfy the physical definition of a conductance according to Fick's first law and is thus an apparent parameter. Uncertainty about the mechanisms that determine g m can be limited to some extent by using analytical models that partition g m into separate conductances. Such models are still only capable of describing the CO 2 diffusion pathway to a limited extent, as they make implicit assumptions about the position of mitochondria in the cells, which affect the re-assimilation of (photo)respired CO 2 . Alternatively, reaction-diffusion models may be used. Rather than quantifying g m , these models explicitly account for factors that affect the efficiency of CO 2 transport in the mesophyll. These models provide a better mechanistic description of the CO 2 diffusion pathways than mesophyll conductance models. Therefore, we argue that reaction-diffusion models should be used as an alternative to mesophyll conductance models, in case the aim of such a study is to identify traits that can be improved to increase g m ., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)

Published
2016
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29. Three-dimensional microscale modelling of CO2 transport and light propagation in tomato leaves enlightens photosynthesis.

Author

Ho QT, Berghuijs HN, Watté R, Verboven P, Herremans E, Yin X, Retta MA, Aernouts B, Saeys W, Helfen L, Farquhar GD, Struik PC, and Nicolaï BM

Subjects
Cell Respiration radiation effects, Chlorophyll metabolism, Computer Simulation, Diffusion, Fluorescence, Light, Solanum lycopersicum radiation effects, Photosynthesis radiation effects, Plant Leaves metabolism, Plant Leaves radiation effects, Plant Transpiration radiation effects, Carbon Dioxide metabolism, Solanum lycopersicum metabolism, Models, Biological
Abstract

We present a combined three-dimensional (3-D) model of light propagation, CO2 diffusion and photosynthesis in tomato (Solanum lycopersicum L.) leaves. The model incorporates a geometrical representation of the actual leaf microstructure that we obtained with synchrotron radiation X-ray laminography, and was evaluated using measurements of gas exchange and leaf optical properties. The combination of the 3-D microstructure of leaf tissue and chloroplast movement induced by changes in light intensity affects the simulated CO2 transport within the leaf. The model predicts extensive reassimilation of CO2 produced by respiration and photorespiration. Simulations also suggest that carbonic anhydrase could enhance photosynthesis at low CO2 levels but had little impact on photosynthesis at high CO2 levels. The model confirms that scaling of photosynthetic capacity with absorbed light would improve efficiency of CO2 fixation in the leaf, especially at low light intensity., (© 2015 John Wiley & Sons Ltd.)

Published
2016
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