Your search keyword '"Harrison, Emily L."' showing total 13 results

1. The influences of stomatal size and density on rice abiotic stress resilience

Author

Caine, Robert S., primary, Harrison, Emily L., additional, Sloan, Jen, additional, Flis, Paulina M., additional, Fischer, Sina, additional, Khan, Muhammad S., additional, Nguyen, Phuoc Trong, additional, Nguyen, Lang Thi, additional, Gray, Julie E., additional, and Croft, Holly, additional

Published

2023

2. Induced Genetic Variations in Stomatal Density and Size of Rice Strongly Affects Water Use Efficiency and Responses to Drought Stresses

Author

Pitaloka, Mutiara K., primary, Caine, Robert S., additional, Hepworth, Christopher, additional, Harrison, Emily L., additional, Sloan, Jennifer, additional, Chutteang, Cattleya, additional, Phunthong, Chutima, additional, Nongngok, Rangsan, additional, Toojinda, Theerayut, additional, Ruengphayak, Siriphat, additional, Arikit, Siwaret, additional, Gray, Julie E., additional, and Vanavichit, Apichart, additional

Published

2022

3. Rice Stomatal Mega-Papillae Restrict Water Loss and Pathogen Entry

Author

Pitaloka, Mutiara K., primary, Harrison, Emily L., additional, Hepworth, Christopher, additional, Wanchana, Samart, additional, Toojinda, Theerayut, additional, Phetluan, Watchara, additional, Brench, Robert A., additional, Narawatthana, Supatthra, additional, Vanavichit, Apichart, additional, Gray, Julie E., additional, Caine, Robert S., additional, and Arikit, Siwaret, additional

Published

2021

4. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions

Author

Caine, Robert, Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya, Dionora, Jacqueline, Chater, Caspar, Coe, Robert, Bandyopadhyay, Anindya, Murchie, Erik, swarup, Ranjan, Quick, W. Paul, Gray, Julie, Caine, Robert, Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya, Dionora, Jacqueline, Chater, Caspar, Coe, Robert, Bandyopadhyay, Anindya, Murchie, Erik, swarup, Ranjan, Quick, W. Paul, and Gray, Julie

Abstract

Much of humanity relies on rice (Oryza sativa) as a food source, but cultivation is water intensive and the crop is vulnerable to drought and high temperatures. Under climate change, periods of reduced water availability and high temperature are expected to become more frequent, leading to detrimental effects on rice yields

Published

2019

5. The influence of stomatal morphology and distribution on photosynthetic gas exchange

Author

Harrison, Emily L., primary, Arce Cubas, Lucia, additional, Gray, Julie E., additional, and Hepworth, Christopher, additional

Published

2019

6. The influence of stomatal morphology and distribution on photosynthetic gas exchange.

Author

Harrison, Emily L., Arce Cubas, Lucia, Gray, Julie E., and Hepworth, Christopher

Subjects

*GAS exchange in plants, *STOMATA, *CHLOROPLASTS, *GAS distribution, *CHEMICAL energy conversion, *CARBON fixation, *MORPHOLOGY, *CHEMICAL energy

Abstract

Summary: The intricate and interconnecting reactions of C3 photosynthesis are often limited by one of two fundamental processes: the conversion of solar energy into chemical energy, or the diffusion of CO2 from the atmosphere through the stomata, and ultimately into the chloroplast. In this review, we explore how the contributions of stomatal morphology and distribution can affect photosynthesis, through changes in gaseous exchange. The factors driving this relationship are considered, and recent results from studies investigating the effects of stomatal shape, size, density and patterning on photosynthesis are discussed. We suggest that the interplay between stomatal gaseous exchange and photosynthesis is complex, and that a disconnect often exists between the rates of CO2 diffusion and photosynthetic carbon fixation. The mechanisms that allow for substantial reductions in maximum stomatal conductance without affecting photosynthesis are highly dependent on environmental factors, such as light intensity, and could be exploited to improve crop performance. Significance Statement: Plant photosynthesis relies on diffusion of CO2 from the atmosphere to the chloroplasts through the stomatal pores. The distribution and morphological characteristics of stomata influence this and are of particular importance when attempting to understand or improve on rates of carbon fixation. Nonetheless, alterations expected to affect stomatal conductance do not always cause corresponding alterations in photosynthetic carbon assimilation. This review explores the factors that are likely to cause this observed disconnect between maximum stomatal conductance and photosynthesis. [ABSTRACT FROM AUTHOR]

Published

2020

7. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions

Author

Caine, Robert S., primary, Yin, Xiaojia, additional, Sloan, Jennifer, additional, Harrison, Emily L., additional, Mohammed, Umar, additional, Fulton, Timothy, additional, Biswal, Akshaya K., additional, Dionora, Jacqueline, additional, Chater, Caspar C., additional, Coe, Robert A., additional, Bandyopadhyay, Anindya, additional, Murchie, Erik H., additional, Swarup, Ranjan, additional, Quick, W. Paul, additional, and Gray, Julie E., additional

Published

2018

8. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions.

Author

Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, and Gray, Julie E.

Subjects

DROUGHT tolerance, PHOTOSYNTHESIS, PHYSIOLOGICAL effects of heat, WATER conservation, CLIMATE change

Abstract

Summary: Much of humanity relies on rice (Oryza sativa) as a food source, but cultivation is water intensive and the crop is vulnerable to drought and high temperatures. Under climate change, periods of reduced water availability and high temperature are expected to become more frequent, leading to detrimental effects on rice yields.We engineered the high‐yielding rice cultivar 'IR64' to produce fewer stomata by manipulating the level of a developmental signal. We overexpressed the rice epidermal patterning factor OsEPF1, creating plants with substantially reduced stomatal density and correspondingly low stomatal conductance.Low stomatal density rice lines were more able to conserve water, using c. 60% of the normal amount between weeks 4 and 5 post germination. When grown at elevated atmospheric CO2, rice plants with low stomatal density were able to maintain their stomatal conductance and survive drought and high temperature (40°C) for longer than control plants. Low stomatal density rice gave equivalent or even improved yields, despite a reduced rate of photosynthesis in some conditions.Rice plants with fewer stomata are drought tolerant and more conservative in their water use, and they should perform better in the future when climate change is expected to threaten food security. [ABSTRACT FROM AUTHOR]

Published

2019

9. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions

Author

Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, Gray, Julie E., Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, and Gray, Julie E.

Abstract

Much of humanity relies on rice (Oryza sativa) as a food source, but cultivation is water intensive and the crop is vulnerable to drought and high temperatures. Under climate change, periods of reduced water availability and high temperature are expected to become more frequent, leading to detrimental effects on rice yields. We engineered the high-yielding rice cultivar ‘IR64’ to produce fewer stomata by manipulating the level of a developmental signal. We overexpressed the rice epidermal patterning factor OsEPF1, creating plants with substantially reduced stomatal density and correspondingly low stomatal conductance. Low stomatal density rice lines were more able to conserve water, using c. 60% of the normal amount between weeks 4 and 5 post germination. When grown at elevated atmospheric CO2, rice plants with low stomatal density were able to maintain their stomatal conductance and survive drought and high temperature (40°C) for longer than control plants. Low stomatal density rice gave equivalent or even improved yields, despite a reduced rate of photosynthesis in some conditions. Rice plants with fewer stomata are drought tolerant and more conservative in their water use, and they should perform better in the future when climate change is expected to threaten food security.

10. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions

Author

Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, Gray, Julie E., Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, and Gray, Julie E.

Abstract

Much of humanity relies on rice (Oryza sativa) as a food source, but cultivation is water intensive and the crop is vulnerable to drought and high temperatures. Under climate change, periods of reduced water availability and high temperature are expected to become more frequent, leading to detrimental effects on rice yields. We engineered the high-yielding rice cultivar ‘IR64’ to produce fewer stomata by manipulating the level of a developmental signal. We overexpressed the rice epidermal patterning factor OsEPF1, creating plants with substantially reduced stomatal density and correspondingly low stomatal conductance. Low stomatal density rice lines were more able to conserve water, using c. 60% of the normal amount between weeks 4 and 5 post germination. When grown at elevated atmospheric CO2, rice plants with low stomatal density were able to maintain their stomatal conductance and survive drought and high temperature (40°C) for longer than control plants. Low stomatal density rice gave equivalent or even improved yields, despite a reduced rate of photosynthesis in some conditions. Rice plants with fewer stomata are drought tolerant and more conservative in their water use, and they should perform better in the future when climate change is expected to threaten food security.

11. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions

Author

Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, Gray, Julie E., Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, and Gray, Julie E.

Abstract

Much of humanity relies on rice (Oryza sativa) as a food source, but cultivation is water intensive and the crop is vulnerable to drought and high temperatures. Under climate change, periods of reduced water availability and high temperature are expected to become more frequent, leading to detrimental effects on rice yields. We engineered the high-yielding rice cultivar ‘IR64’ to produce fewer stomata by manipulating the level of a developmental signal. We overexpressed the rice epidermal patterning factor OsEPF1, creating plants with substantially reduced stomatal density and correspondingly low stomatal conductance. Low stomatal density rice lines were more able to conserve water, using c. 60% of the normal amount between weeks 4 and 5 post germination. When grown at elevated atmospheric CO2, rice plants with low stomatal density were able to maintain their stomatal conductance and survive drought and high temperature (40°C) for longer than control plants. Low stomatal density rice gave equivalent or even improved yields, despite a reduced rate of photosynthesis in some conditions. Rice plants with fewer stomata are drought tolerant and more conservative in their water use, and they should perform better in the future when climate change is expected to threaten food security.

12. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions

Author

Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, Gray, Julie E., Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, and Gray, Julie E.

Abstract

Much of humanity relies on rice (Oryza sativa) as a food source, but cultivation is water intensive and the crop is vulnerable to drought and high temperatures. Under climate change, periods of reduced water availability and high temperature are expected to become more frequent, leading to detrimental effects on rice yields. We engineered the high-yielding rice cultivar ‘IR64’ to produce fewer stomata by manipulating the level of a developmental signal. We overexpressed the rice epidermal patterning factor OsEPF1, creating plants with substantially reduced stomatal density and correspondingly low stomatal conductance. Low stomatal density rice lines were more able to conserve water, using c. 60% of the normal amount between weeks 4 and 5 post germination. When grown at elevated atmospheric CO2, rice plants with low stomatal density were able to maintain their stomatal conductance and survive drought and high temperature (40°C) for longer than control plants. Low stomatal density rice gave equivalent or even improved yields, despite a reduced rate of photosynthesis in some conditions. Rice plants with fewer stomata are drought tolerant and more conservative in their water use, and they should perform better in the future when climate change is expected to threaten food security.

13. Rice with reduced stomatal density conserves water and has improved drought tolerance under future climate conditions

Author

Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, Gray, Julie E., Caine, Robert S., Yin, Xiaojia, Sloan, Jennifer, Harrison, Emily L., Mohammed, Umar, Fulton, Timothy, Biswal, Akshaya K., Dionora, Jacqueline, Chater, Caspar C., Coe, Robert A., Bandyopadhyay, Anindya, Murchie, Erik H., Swarup, Ranjan, Quick, W. Paul, and Gray, Julie E.

Abstract

Much of humanity relies on rice (Oryza sativa) as a food source, but cultivation is water intensive and the crop is vulnerable to drought and high temperatures. Under climate change, periods of reduced water availability and high temperature are expected to become more frequent, leading to detrimental effects on rice yields. We engineered the high-yielding rice cultivar ‘IR64’ to produce fewer stomata by manipulating the level of a developmental signal. We overexpressed the rice epidermal patterning factor OsEPF1, creating plants with substantially reduced stomatal density and correspondingly low stomatal conductance. Low stomatal density rice lines were more able to conserve water, using c. 60% of the normal amount between weeks 4 and 5 post germination. When grown at elevated atmospheric CO2, rice plants with low stomatal density were able to maintain their stomatal conductance and survive drought and high temperature (40°C) for longer than control plants. Low stomatal density rice gave equivalent or even improved yields, despite a reduced rate of photosynthesis in some conditions. Rice plants with fewer stomata are drought tolerant and more conservative in their water use, and they should perform better in the future when climate change is expected to threaten food security.