Your search keyword '"Murphy, Madeline"' showing total 6 results

1. Cell expansion coordinates leaf vein and stomatal density

Author

Carins-Murphy, Madeline

Abstract

The efficiency with which water is delivered through leaf tissue to sites of evaporation (the leaf hydraulic conductance) is an important determinant of photosynthetic capacity. This is because inadequate water supply forces stomata to close due to plant desiccation. The resulting reduction in stomatal conductance restricts carbon dioxide (CO2) uptake. An oversupply of water, on the other hand, results in unprofitable investment in vascular tissue. Accordingly, water supply is strongly correlated with the demand for water generated by stomata. Recent work suggests that this balance is achieved in a tropical angiosperm tree by a simple developmental mechanism in which changes to leaf size co-regulate vein and stomatal density (major determinants of water supply and demand, respectively). However, the generality of this mechanism is unknown. Thus, in this thesis I set out to establish whether there is a general developmental mechanism that allows plants to maintain a constant ratio between leaf vein and stomatal density. In doing so the following specific research questions were investigated: 1. Does acclimation to high and low VPD (vapour pressure difference) modify the relationships between vein density, stomatal density and leaf size? (Chapter 2) 2. Does leaf or epidermal cell expansion coordinate vein and stomatal density in herbs and woody angiosperms? (Chapter 3) 3. Does epidermal cell expansion coordinate vein and stomatal density in older plant lineages like ferns? (Chapter 4) 4. Is vein density directly regulated by epidermal cell expansion? (Chapter 5) The difference in vapour pressure between leaf tissue and the atmosphere determines how much water is transpired at any given stomatal conductance. Thus, I hypothesised in Chapter 2 that plants grown under high VPD would exhibit a modified relationship between vein and stomatal density resulting in maintenance of homeostasis in leaf water potential such that there is either a decrease in stomatal density and no change in vein density, or no change in stomatal density and an increase in vein density. This would also disrupt previously observed relationships with leaf size. However, contrary to my hypothesis, I found a small but coordinated increase in vein and stomatal density in plants grown under high VPD compared with those grown under low VPD. Furthermore, densities of veins and stomata were independent of large VPD-induced changes to leaf size and were instead limited by epidermal cell size (which was fairly insensitive to VPD). This suggests that significant modification of epidermal cell size is required to produce large changes in vein and stomatal density. Thus, to further investigate whether leaf expansion or epidermal cell expansion coordinates vein and stomatal density more generally among plants I examined relationships between vein density, stomatal density, leaf size and epidermal cell size across a diverse range of woody and herbaceous angiosperms grown under sun and shade conditions (Chapter 3). Contrary to the original premise that differential leaf expansion coordinates vein and stomatal density, I found that leaf size was independent of epidermal cell size in most cases and that relationships between vein density, stomatal density and epidermal cell size were well described by modelled relationships that assume veins and stomata are passively 'diluted' by epidermal cell expansion. These results demonstrate that coordination of vein and stomatal density in angiosperms is driven by their co-variation with epidermal cell size. While this 'passive dilution' mechanism seems to be common among angiosperms, it is not known when it appeared in the vascular plant phylogeny. Furthermore, older plant lineages like ferns may employ different mechanisms to coordinate vein and stomatal density because they differ from angiosperms in both current water relations physiology and evolutionary history. Contrary to this expectation, I found that relationships between vein density, stomatal density and epidermal cell size across four ferns species were very similar to those previously observed across angiosperm species (Chapter 4). However, there was little plasticity in these traits within fern species and changes to stomatal density across species were actively regulated by stomatal index, as well as epidermal cell size. Despite this, epidermal cell size was a strong determinant of vein and stomatal density in ferns (explaining 55.5 % of the variation in stomatal density versus the 44.5 % explained by stomatal index). Thus, ferns (like angiosperms) appear to use the co-variance of vein and stomatal density with epidermal cell expansion to maintain a constant ratio between the abundance of veins and stomata in the leaf. This suggests that the 'passive dilution' mechanism may be an ancient feature of vascular plants that co-regulates these tissues. In Chapters 3 and 4 it was proposed that coordination of vein and stomatal density is achieved through a 'passive dilution' mechanism in which densities of veins and stomata are co-regulated by epidermal cell size. However, unlike stomata, leaf veins are spatially isolated from the epidermis and it is not known whether they are directly regulated by epidermal cell expansion. To investigate this I tested whether relationships between vein density and epidermal cell size in a wild type genotype of Arabidopsis (Col-0) and seven other genotypes with modified forms of genes that affect both stomatal development and epidermal cell size were the same as modelled relationships that assume veins are passively 'diluted' by epidermal cell expansion (Chapter 5). Vein density in wild type plants was correlated with abaxial epidermal cell size in a way that was consistent with the 'passive dilution' mechanism (despite some deviation from modelled relationships). However, vein density was independent of variation in epidermal cell size among mutant and transgenic genotypes. This suggests that epidermal cell size in these genotypes was modified independently from the rest of the leaf in spite of prior evidence that cell sizes are correlated within leaves. Thus, vein density is not causally linked to epidermal cell expansion. Instead the relationship between vein density and epidermal cell size in wild type plants reflects developmental factors that affect both mesophyll and epidermal cells, suggesting that adaptation favours coordination of veins and stomata over independent development of these tissues. Thus, the overarching finding of this thesis is that the 'dilution' of veins and stomata by differential epidermal cell expansion (and perhaps mesophyll cell expansion) appears to be a general mechanism capable of maintaining a constant ratio between vein and stomatal density both within and across a diverse range of vascular plant species. Leaf cells expand more in the shade than the sun, and more in some species compared with others, which increases the space between veins and stomata concomitantly reducing their density. These relationships provide an insight into how plants construct leaves that can efficiently replace transpired water and maintain maximum carbon assimilation for the minimum investment in vein and stomatal infrastructure. Achieving this maximises the energetic return for investments made during leaf construction increasing the energy available for growth and reproduction.

Published

2023

2. Do levels of emotional contagion and interpersonal emotion regulation influence reported interpersonal pleasure?

Author

Murphy, Madeline

Subjects

FOS: Psychology, Social Psychology, Psychology, Social and Behavioral Sciences

Abstract

A quantitative correlational study looking at the relationship between three factors: emotion contagion, interpersonal emotion regulation and interpersonal pleasure.

Published

2022

3. REPLICATION-21: Does the colour of the mug influence the taste of the coffee?

Author

Punton, Georgia, McCarty, Kris, Fenwick, Sam, Murphy, Madeline, Abir, Tunajjina, Murray, Rhiannon, Iranpour, Arman, Shepherd, Josh, Davison, Grace, Bates, Emily, Barber, Sarah, Anguera, Alejandro, Penfold, Phoebe, Oliver, Emily, Wilson, Callum, and Murphy, Olivia

Subjects

FOS: Psychology, Cognition and Perception, Psychology, Social and Behavioral Sciences

Abstract

Northumbria University: MRes Psychology 2021 | Replication project for Practical Research Skills and Techniques AsPredicted Pre-Registration: https://aspredicted.org/23qz5.pdf

Published

2022

4. Supplementary_material – Supplemental material for Frequency, impact and a preclinical study of novel ERBB gene family mutations in HER2-positive breast cancer

Author

Elster, Naomi, Sinead Toomey, Fan, Yue, Cremona, Mattia, Morgan, Clare, Gorzel, Karolina Weiner, Bhreathnach, Una, Malgorzata Milewska, Murphy, Madeline, Madden, Stephen, Jarushka Naidoo, Fay, Joanna, Kay, Elaine, Carr, Aoife, Kennedy, Sean, Furney, Simon, Mezynski, Janusz, Breathhnach, Oscar, Morris, Patrick, Grogan, Liam, Hill, Arnold, Kennedy, Susan, Crown, John, Gallagher, William, Hennessy, Bryan, and Eustace, Alex

Subjects

110203 Respiratory Diseases, FOS: Clinical medicine, 111702 Aged Health Care, FOS: Health sciences, 111599 Pharmacology and Pharmaceutical Sciences not elsewhere classified, 111299 Oncology and Carcinogenesis not elsewhere classified

Abstract

Supplemental material, Supplementary_material for Frequency, impact and a preclinical study of novel ERBB gene family mutations in HER2-positive breast cancer by Naomi Elster, Sinead Toomey, Yue Fan, Mattia Cremona, Clare Morgan, Karolina Weiner Gorzel, Una Bhreathnach, Malgorzata Milewska, Madeline Murphy, Stephen Madden, Jarushka Naidoo, Joanna Fay, Elaine Kay, Aoife Carr, Sean Kennedy, Simon Furney, Janusz Mezynski, Oscar Breathhnach, Patrick Morris, Liam Grogan, Arnold Hill, Susan Kennedy, John Crown, William Gallagher, Bryan Hennessy and Alex Eustace in Therapeutic Advances in Medical Oncology

Published

2018

5. Non-invasive imaging of hydraulic function in leaves, stems and roots

Author

Choat, B., Peters, J.M.R., Gauthey, A., Carins Murphy, Madeline R., Rodríguez Domínguez, Celia M., and Brodribb, Timothy J.

Subjects

fungi, food and beverages

Abstract

Plants have evolved a water transport system that relies on water sustaining a tensile force. Counter intuitively, this means water moves through the plant as a liquid under negative absolute pressures. This mechanism is made possible by the intricate plumbing system that constitutes the xylem tissue of plants. However, water under tension is prone to cavitation, which results in the formation of a gas bubble (embolism). Embolism reduces the capacity of the xylem tissue to deliver water to the canopy, eventually causing dieback and whole plant mortality. Xylem embolism is exacerbated by environmental stresses and is now considered one of the leading causes of plant mortality resulting from drought stress.Non-invasive imaging techniques offer the potential to make direct observations on intact plants at high resolution and in real time. In this presentation, I discuss recent exciting developments in the application of non-invasive imaging technologies such as X-ray Micro Computed Tomography (microCT) and optical imaging to studies of plant vascular function. This includes visualisation of xylem networks during drought stress and recovery in leaves, stems and roots. MicroCT imaging of stems and roots indicated that significant embolism formation occurs at similar time points and levels of water stress in dehydrating plants. This result was observed in herbaceous and woody species, and is surprising given previous hydraulic measurements indicating that, within a plant, roots were more vulnerable to drought-induced embolism than stems. A newly developed optical technique indicates that leaf vasculature is also similar in vulnerability to stems and roots. The overlap in vulnerability suggests that induction of embolism occurs at the same time in different organs or is propagated rapidly through the plant. In examining recovery from drought stress, we saw little evidence of embolism refilling in the xylem of woody plants, except in cases where substantial root pressure is produced. These results suggest that embolism refilling is less widespread than previously thought.

Published

2018

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

Author

Celia M. Rodriguez‐Dominguez, Alicia Forner, Sebastia Martorell, Brendan Choat, Rosana Lopez, Jennifer M. R. Peters, Sebastian Pfautsch, Stefan Mayr, Madeline R. Carins‐Murphy, Scott A. M. McAdam, Freya Richardson, Antonio Diaz‐Espejo, Virginia Hernandez‐Santana, Paulo E. Menezes‐Silva, Jose M. Torres‐Ruiz, Timothy A. Batz, Lawren Sack, Instituto de Recursos Naturales y Agrobiología de Sevilla (IRNAS), Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Museo Nacional de Ciencias Naturales, Departamento de Biogeografía y Cambio Global, Laboratorio Internacional de Cambio Global (LINC-Global), Spanish National Research Council (CSIC), Université des îles Baléares (UIB), Western Sydney University, Departamento de Sistemas y Recursos Naturales, Escuela Técnica Superior de Ingeniería de Montes, Forestal y del Medio Natural, Universidad Politécnica de Madrid, Madrid, Hawkesbury Institute for the Environment [Richmond] (HIE), Institute of Botany [Innsbruck], Leopold Franzens Universität Innsbruck - University of Innsbruck, School of Biological Sciences [Hobart], University of Tasmania [Hobart, Australia] (UTAS), Purdue University [West Lafayette], Laboratoire de Physique et Physiologie Intégratives de l’Arbre en environnement Fluctuant (PIAF), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Clermont Auvergne (UCA), Perdue University, Department of Ecology and Evolutionary Biology (Faculty of Biology), University of Science-Vietnam National Universities, SKA South Africa751918-AgroPHYSAustrian Science Fund (FWF)P32203National Science Foundation (NSF)1457279, European Project: 624473,EC:FP7:PEOPLE,FP7-PEOPLE-2013-IOF,HYDROPIT(2015), European Commission, Austrian Research Promotion Agency, National Science Foundation (US), Rodríguez Domínguez, Celia M., Forner, Alicia, Choat, B., López, Rosana, Peters, J.M.R., Pfautsch, S., Carins Murphy, Madeline R., McAdam S.A.M., Richardson, Freya, Díaz-Espejo, Antonio, Hernández Santana, V., Menezes-Silva, Paulo E., Torres Ruiz, José Manuel, Sack, Lawren, 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 S.A.M. [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], and Sack, Lawren [0000-0002-7009-7202]

Subjects

Physiology, Water stress, Reproducibility of Results, Water, plant water relations, Plant water relations, pressure bomb, Plant Science, Leaf water potential, leaf water potential, Droughts, Plant Leaves, water stress, Pressure bombpressure chamber, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, plant water status, Plant water status, pressure chamber

Abstract

25 páginas.- 8 figuras.- 2 tablas.- 66 referencias.- Additional supporting information can be found online in the Supporting Information section at the end of this article., 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., European Union's Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement No. 751918-AgroPHYS; Marie Curie Fellowship (FP7-PEOPLE-2013-IOF-624473); Austrian research agency (FWF) project P32203; National Science Foundation (Grant IOS-#1457279)

Published

2022