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Functional genomics of ozone stress in Arabidopsis

Research output: Contribution to conference - Without ISBN/ISSN Abstract

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Functional genomics of ozone stress in Arabidopsis. / Short, E.; McAinsh, Martin; Shirras, Alan et al.
2003. 55 Abstract from Plant Biology 2003, Honolulu, United States.

Research output: Contribution to conference - Without ISBN/ISSN Abstract

Harvard

Short, E, McAinsh, M, Shirras, A & Huckerby, T 2003, 'Functional genomics of ozone stress in Arabidopsis', Plant Biology 2003, Honolulu, United States, 25/07/03 - 30/07/03 pp. 55. <http://abstracts.aspb.org/pb2003/public/P30/0192.html>

APA

Vancouver

Short E, McAinsh M, Shirras A, Huckerby T. Functional genomics of ozone stress in Arabidopsis. 2003. Abstract from Plant Biology 2003, Honolulu, United States.

Author

Short, E. ; McAinsh, Martin ; Shirras, Alan et al. / Functional genomics of ozone stress in Arabidopsis. Abstract from Plant Biology 2003, Honolulu, United States.1 p.

Bibtex

@conference{59909ac8d5624a779f824bffda4ba086,
title = "Functional genomics of ozone stress in Arabidopsis",
abstract = "The gas ozone (O3) functions as a protector against ultra-violet radiation in the stratosphere. However, in the troposphere it is toxic to plants and causes significant reductions in crop yields. Ozone is a reactive oxygen species (ROS) and can cause oxidative damage directly by entering stomata and interacting with cell wall and membrane components. Ozone can also form other ROS such as hydrogen peroxide and hydroxyl radicals that can cross the plasma membrane and cause further damage, leading to reduced transpiration, accelerated senescence and decreased photosynthesis. A plant-derived oxidative burst also occurs after plants have been exposed to ozone. This closely resembles the hypersensitive response (HR) displayed when plants are challenged by a pathogen. Plants react to oxidative stress by increasing their antioxidant defences in an attempt to neutralise harmful ROS. The individual roles of several antioxidants have been extensively studied, however their regulation and interaction in planta have yet to be fully elucidated. The specificity of antioxidants and other stress-related molecules to each unique stress is also poorly understood. In this work a functional genomics approach has been used to identify novel genes in Arabidopsis thaliana, that are regulated by ozone. A DNA microarray has been utilised to determine gene regulation at the transcriptional level and NMR spectroscopy has been employed to investigate ozone-induced changes to the metabolite profile of Arabidopsis. Twenty genes, which are significantly up-regulated and one gene that is down-regulated by ozone treatment have been identified. The expression of these genes in response to a range of ozone concentrations and time points has been further investigated.",
author = "E. Short and Martin McAinsh and Alan Shirras and Thomas Huckerby",
year = "2003",
language = "English",
pages = "55",
note = "Plant Biology 2003 ; Conference date: 25-07-2003 Through 30-07-2003",

}

RIS

TY - CONF

T1 - Functional genomics of ozone stress in Arabidopsis

AU - Short, E.

AU - McAinsh, Martin

AU - Shirras, Alan

AU - Huckerby, Thomas

PY - 2003

Y1 - 2003

N2 - The gas ozone (O3) functions as a protector against ultra-violet radiation in the stratosphere. However, in the troposphere it is toxic to plants and causes significant reductions in crop yields. Ozone is a reactive oxygen species (ROS) and can cause oxidative damage directly by entering stomata and interacting with cell wall and membrane components. Ozone can also form other ROS such as hydrogen peroxide and hydroxyl radicals that can cross the plasma membrane and cause further damage, leading to reduced transpiration, accelerated senescence and decreased photosynthesis. A plant-derived oxidative burst also occurs after plants have been exposed to ozone. This closely resembles the hypersensitive response (HR) displayed when plants are challenged by a pathogen. Plants react to oxidative stress by increasing their antioxidant defences in an attempt to neutralise harmful ROS. The individual roles of several antioxidants have been extensively studied, however their regulation and interaction in planta have yet to be fully elucidated. The specificity of antioxidants and other stress-related molecules to each unique stress is also poorly understood. In this work a functional genomics approach has been used to identify novel genes in Arabidopsis thaliana, that are regulated by ozone. A DNA microarray has been utilised to determine gene regulation at the transcriptional level and NMR spectroscopy has been employed to investigate ozone-induced changes to the metabolite profile of Arabidopsis. Twenty genes, which are significantly up-regulated and one gene that is down-regulated by ozone treatment have been identified. The expression of these genes in response to a range of ozone concentrations and time points has been further investigated.

AB - The gas ozone (O3) functions as a protector against ultra-violet radiation in the stratosphere. However, in the troposphere it is toxic to plants and causes significant reductions in crop yields. Ozone is a reactive oxygen species (ROS) and can cause oxidative damage directly by entering stomata and interacting with cell wall and membrane components. Ozone can also form other ROS such as hydrogen peroxide and hydroxyl radicals that can cross the plasma membrane and cause further damage, leading to reduced transpiration, accelerated senescence and decreased photosynthesis. A plant-derived oxidative burst also occurs after plants have been exposed to ozone. This closely resembles the hypersensitive response (HR) displayed when plants are challenged by a pathogen. Plants react to oxidative stress by increasing their antioxidant defences in an attempt to neutralise harmful ROS. The individual roles of several antioxidants have been extensively studied, however their regulation and interaction in planta have yet to be fully elucidated. The specificity of antioxidants and other stress-related molecules to each unique stress is also poorly understood. In this work a functional genomics approach has been used to identify novel genes in Arabidopsis thaliana, that are regulated by ozone. A DNA microarray has been utilised to determine gene regulation at the transcriptional level and NMR spectroscopy has been employed to investigate ozone-induced changes to the metabolite profile of Arabidopsis. Twenty genes, which are significantly up-regulated and one gene that is down-regulated by ozone treatment have been identified. The expression of these genes in response to a range of ozone concentrations and time points has been further investigated.

M3 - Abstract

SP - 55

T2 - Plant Biology 2003

Y2 - 25 July 2003 through 30 July 2003

ER -