Your search keyword '"McAdam, Scott [0000-0002-9625-6750]"' showing total 4 results

1. Mechanical advantage makes stomatal opening speed a function of evaporative demand

Author

National Science Foundation (US), National Institute of Food and Agriculture (US), Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Commission, Pichaco, Javier [0000-0002-5202-9994], Manandhar, Anju [0000-0001-5687-2957], McAdam, Scott [0000-0002-9625-6750], Pichaco, Javier, Manandhar, Anju, McAdam, Scott, National Science Foundation (US), National Institute of Food and Agriculture (US), Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Commission, Pichaco, Javier [0000-0002-5202-9994], Manandhar, Anju [0000-0001-5687-2957], McAdam, Scott [0000-0002-9625-6750], Pichaco, Javier, Manandhar, Anju, and McAdam, Scott

Abstract

Stomatal opening in the light, observed in nearly all vascular land plants, is essential for providing access to atmospheric CO2 for photosynthesis. The speed of stomatal opening in the light is critical for maximizing carbon gain in environments in which light intensity changes, yet we have little understanding of how other environmental signals, particularly evaporative demand driven by vapor pressure deficit (VPD) influences the kinetics of this response. In angiosperms, and some fern species from the family Marsileaceae, a mechanical interaction between the guard cells and the epidermal cells determines the aperture of the pore. Here, we examine whether this mechanical interaction influences the speed of stomatal opening in the light. To test this, we investigated the speed of stomatal opening in response to light across a range of VPDs in seven plant species spanning the evolutionary diversity of guard cell and epidermal cell mechanical interactions. We found that stomatal opening speed is a function of evaporative demand in angiosperm species and Marsilea, which have guard cell and epidermal cell mechanical interactions. Stomatal opening speeds did not change across a range of VPD in species of gymnosperm and fern, which do not have guard cell mechanical interactions with the epidermis. We find that guard cell and epidermal cell mechanical interactions may play a key role in regulating stomatal responsiveness to light. These results provide valuable insight into the adaptive relevance of mechanical advantage.

Published

2023

2. Leaf water potential measurements using the pressure chamber: Synthetic testing of assumptions towards best practices for precision and accuracy

Author

European Commission, Austrian Research Promotion Agency, National Science Foundation (US), Rodríguez Domínguez, Celia M. [0000-0003-2352-0829], Forner, Alicia [0000-0002-7123-6403], Choat, B.[0000-0002-9105-640X], López, Rosana [0000-0003-3553-9148], Peters, J.M.R. [0000-0003-4627-7788], Pfautsch, S. [0000-0002-4390-4195], Carins Murphy, Madeline R. [0000-0003-4370-9485], McAdam, Scott [0000-0002-9625-6750], Richardson, Freya [0000-0003-2460-3423], Díaz-Espejo, Antonio [0000-0002-4711-2494], Hernández Santana, V. [0000-0001-9018-8622], Menezes-Silva, Paulo E. [0000-0002-8122-3489], Torres Ruiz, José Manuel [0000-0003-1367-7056], Sack, Lawren [0000-0002-7009-7202], Rodríguez-Domínguez, Celia M., Forner, Alicia, Martorell, Sebastià, Choat, B., López, Rosana, Peters, J.M.R., Pfautsch, S., Mayr, Stefan, Carins Murphy, Madeline R., McAdam, Scott, Richardson, Freya, Díaz-Espejo, Antonio, Hernández Santana, V., Menezes-Silva, Paulo E., Torres Ruiz, José Manuel, Batz, Timothy A, Sack, Lawren, European Commission, Austrian Research Promotion Agency, National Science Foundation (US), Rodríguez Domínguez, Celia M. [0000-0003-2352-0829], Forner, Alicia [0000-0002-7123-6403], Choat, B.[0000-0002-9105-640X], López, Rosana [0000-0003-3553-9148], Peters, J.M.R. [0000-0003-4627-7788], Pfautsch, S. [0000-0002-4390-4195], Carins Murphy, Madeline R. [0000-0003-4370-9485], McAdam, Scott [0000-0002-9625-6750], Richardson, Freya [0000-0003-2460-3423], Díaz-Espejo, Antonio [0000-0002-4711-2494], Hernández Santana, V. [0000-0001-9018-8622], Menezes-Silva, Paulo E. [0000-0002-8122-3489], Torres Ruiz, José Manuel [0000-0003-1367-7056], Sack, Lawren [0000-0002-7009-7202], Rodríguez-Domínguez, Celia M., Forner, Alicia, Martorell, Sebastià, Choat, B., López, Rosana, Peters, J.M.R., Pfautsch, S., Mayr, Stefan, Carins Murphy, Madeline R., McAdam, Scott, Richardson, Freya, Díaz-Espejo, Antonio, Hernández Santana, V., Menezes-Silva, Paulo E., Torres Ruiz, José Manuel, Batz, Timothy A, and Sack, Lawren

Abstract

eaf water potential (psi(leaf)), typically measured using the pressure chamber, is the most important metric of plant water status, providing high theoretical value and information content for multiple applications in quantifying critical physiological processes including drought responses. Pressure chamber measurements of psi(leaf) (psi(leafPC)) are most typical, yet, the practical complexity of the technique and of the underlying theory has led to ambiguous understanding of the conditions to optimize measurements. Consequently, specific techniques and precautions diversified across the global research community, raising questions of reliability and repeatability. Here, we surveyed specific methods of psi(leafPC) from multiple laboratories, and synthesized experiments testing common assumptions and practices in psi(leafPC) for diverse species: (i) the need for equilibration of previously transpiring leaves; (ii) leaf storage before measurement; (iii) the equilibration of psi(leaf) for leaves on bagged branches of a range of dehydration; (iv) the equilibration of psi(leaf) across the lamina for bagged leaves, and the accuracy of measuring leaves with artificially 'elongated petioles'; (v) the need in psi(leaf) measurements for bagging leaves and high humidity within the chamber; (vi) the need to avoid liquid water on leaf surfaces; (vii) the use of 'pulse' pressurization versus gradual pressurization; and (viii) variation among experimenters in psi(leafPC) determination. Based on our findings we provide a best practice protocol to maximise accuracy, and provide recommendations for ongoing species-specific tests of important assumptions in future studies.

Published

2022

3. Linking xylem network failure with leaf tissue death

Author

Australian Research Council, University of Tasmania, European Commission, Brodribb, Timothy J. [0000-0002-4964-6107], Brodersen, Craig [0000-0002-0924-2570], Carriquí, Marc [0000-0002-0153-2602], Tonet, Vanessa [0000-0002-8373-5779], Rodríguez Domínguez, Celia M. [0000-0003-2352-0829], McAdam, Scott [0000-0002-9625-6750], Brodribb, Timothy J., Brodersen, Craig, Carriquí, Marc, Tonet, Vanessa, Rodríguez-Domínguez, Celia M., McAdam, Scott, Australian Research Council, University of Tasmania, European Commission, Brodribb, Timothy J. [0000-0002-4964-6107], Brodersen, Craig [0000-0002-0924-2570], Carriquí, Marc [0000-0002-0153-2602], Tonet, Vanessa [0000-0002-8373-5779], Rodríguez Domínguez, Celia M. [0000-0003-2352-0829], McAdam, Scott [0000-0002-9625-6750], Brodribb, Timothy J., Brodersen, Craig, Carriquí, Marc, Tonet, Vanessa, Rodríguez-Domínguez, Celia M., and McAdam, Scott

Abstract

Global warming is expected to dramatically accelerate forest mortality as temperature and drought intensity increase. Predicting the magnitude of this impact urgently requires an understanding of the process connecting atmospheric drying to plant tissue damage. Recent episodes of forest mortality worldwide have been widely attributed to dry conditions causing acute damage to plant vascular systems. Under this scenario vascular embolisms produced by water stress are thought to cause plant death, yet this hypothetical trajectory has never been empirically demonstrated. Here we provide foundational evidence connecting failure in the vascular network of leaves with tissue damage caused during water stress. We observe a catastrophic sequence initiated by water column breakage under tension in leaf veins which severs local leaf tissue water supply, immediately causing acute cellular dehydration and irreversible damage. By highlighting the primacy of vascular network failure in the death of leaves exposed to drought or evaporative stress our results provide a strong mechanistic foundation upon which models of plant damage in response to dehydration can be confidently structured.

Published

2021

4. Linking xylem network failure with leaf tissue death

Author

Celia M. Rodríguez Domínguez, Vanessa Tonet, Craig R. Brodersen, Timothy J. Brodribb, Scott A. M. McAdam, Marc Carriquí, Australian Research Council, University of Tasmania, European Commission, Brodribb, Timothy J., Brodersen, Craig, Carriquí, Marc, Tonet, Vanessa, Rodríguez Domínguez, Celia M., McAdam, Scott, Brodribb, Timothy J. [0000-0002-4964-6107], Brodersen, Craig [0000-0002-0924-2570], Carriquí, Marc [0000-0002-0153-2602], Tonet, Vanessa [0000-0002-8373-5779], Rodríguez Domínguez, Celia M. [0000-0003-2352-0829], and McAdam, Scott [0000-0002-9625-6750]

Subjects

0106 biological sciences, Physiology, Plant Science, Biology, 01 natural sciences, Tissue death, 03 medical and health sciences, Xylem, Tissue damage, 030304 developmental biology, 0303 health sciences, Tissue water, Dehydration, fungi, Water stress, food and beverages, Plant Transpiration, 15. Life on land, Plant tissue, Droughts, Plant Leaves, Agronomy, Vascular network, 13. Climate action, 010606 plant biology & botany

Abstract

12 págs.- 5 figuras.- referencias, Global warming is expected to dramatically accelerate forest mortality as temperature and drought intensity increase. Predicting the magnitude of this impact urgently requires an understanding of the process connecting atmospheric drying to plant tissue damage. Recent episodes of forest mortality worldwide have been widely attributed to dry conditions causing acute damage to plant vascular systems. Under this scenario vascular embolisms produced by water stress are thought to cause plant death, yet this hypothetical trajectory has never been empirically demonstrated. Here we provide foundational evidence connecting failure in the vascular network of leaves with tissue damage caused during water stress. We observe a catastrophic sequence initiated by water column breakage under tension in leaf veins which severs local leaf tissue water supply, immediately causing acute cellular dehydration and irreversible damage. By highlighting the primacy of vascular network failure in the death of leaves exposed to drought or evaporative stress our results provide a strong mechanistic foundation upon which models of plant damage in response to dehydration can be confidently structured., This study was supported by funds from the Australian Research Council (DP190101552) to TB; a visiting research fellowship from University of Tasmania (UTAS) to CRB; Individual Fellowship from the European Union’sHorizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement no. 751918 -AgroPHYS to CRD.

Published

2021