Fucoid algae live in the intertidal region where they experience daily fluctuations in
light and external osmotic environment. High light, especially in combination with
ultraviolet (UV) radiation and hyper-osmotic stress affected the cellular physiology of
Fucus embryos. Two photoinhibition responses were recognised. Firstly, a rapid decline
of the photosystem II (PSII) efficiency, linked with the operation of the xanthophyl
cycle, followed by a slower decline correlated with reactive oxygen species (ROS)
production. As a result of enhanced ROS production, a slower repair of the PSII
efficiency was observed, particularly with increased UV-B doses. Development of the
embryos was transiently affected by UV-B. The cellular signal transduction pathway
during hyper-osmotic stress was investigated. ROS production in response to hyperosmotic
stress comprised two distinct components. The first ROS component
coincided closely with the origin of a Ca2+ wave in the peripheral cytosol at the growing
cell apex, had an extracellular origin, and was necessary for the Ca2+ wave. Patch clamp
experiments showed that a non-selective cation channel was stimulated by H2O2, and
may underlie the initial cytosolic Ca2+ elevation. The spatio-temporal pattern of the
Ca2+ wave was thus determined by peripheral ROS production. The second, later ROS
component localised to the mitochondria and was a direct consequence of the Ca2+
wave. The first, but not the second component was required for short-term adaptation
to osmotic stress, probably through the activity of cell wall bromoperoxidases.
Mitogen-activated protein kinases may be involved in the hyper-osmotic stress
response downstream or independently of the mitochondrial ROS production.
Date of Award | 2002 |
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Original language | English |
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Awarding Institution | |
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ABIOTIC STRESS SIGNALLING IN THE FUCUS EMBRYO
COELHO, S. (Author). 2002
Student thesis: PhD