Access the full text.
Sign up today, get DeepDyve free for 14 days.
(2003)
Participation of Membrane Lipids in Cladophora (Chlorophyta) Adaptation to the Live in the Shallow Lakes with Different Salinity
K. Künzler, W. Eichenberger, A. Radunz (1997)
Intracellular localization of two betaine lipids by cell fractionation and immunomicroscopy.Zeitschrift fur Naturforschung. C, Journal of biosciences, 52 7-8
(1988)
Water Relations, CRC Handbook of Lichenology
P. Campos, A.T. Pham Thi (1995)
Plant Lipid Metabolism
V. Vaskovsky, E. Kostetsky, I. Vasendin (1975)
A universal reagent for phospholipid analysis.Journal of chromatography, 114 1
P.A. Henckel (1978)
Problemy zasukhoustoichivosti rastenii
M. Koag, R. Fenton, S. Wilkens, T. Close (2003)
The binding of Maize DHN1 to Lipid Vesicles. Gain of Structure and Lipid Specificity1Plant Physiology, 131
D. Cowan, T. Green, A. Wilson (1979)
LICHEN METABOLISM. 1. THE USE OF TRITIUM LABELLED WATER IN STUDIES OF ANHYDROBIOTIC METABOLISM IN RAMALINA CELASTRI AND PELTIGERA POLYDACTYLANew Phytologist, 82
(1992)
The Effects of Water Deficit Stress on Plant Membrane Lipids, Prog
F. Navari-Izzo, M. Quartacci, C. Pinzino, N. Rascio, C. Vazzana, C. Sgherri (2000)
Protein dynamics in thylakoids of the desiccation-tolerant plant Boea hygroscopica during dehydration and rehydration.Plant physiology, 124 3
M. Quartacci, M. Forli, N. Rascio, F. Vecchia, A. Bochicchio, F. Navari-Izzo (1997)
Desiccation-tolerant Sporobolus stapfianus: lipid composition and cellular ultrastructure during dehydration and rehydrationJournal of Experimental Botany, 48
(1995)
Effects of Drought Stress on Enzymatic Breakdown of Galactolipids in Cowpea (Vigna unguiculata L
A. Sakamoto, N. Murata (2000)
Genetic engineering of glycinebetaine synthesis in plants: current status and implications for enhancement of stress tolerance.Journal of experimental botany, 51 342
J. Kabara, J. Chen (1976)
Microdetermination of lipid classes after thin-layer chromatography.Analytical chemistry, 48 6
(1998)
Environmental Effects on Plant Lipid Biochemistry, Plant Lipid Biosynthesis
J.L. Harwood (1998)
Plant Lipid Biosynthesis: Fundamentals and Agricultural Applications
E. Bligh, Dyer W.J.A. (1959)
A rapid method of total lipid extraction and purification.Canadian journal of biochemistry and physiology, 37 8
M. Kates (1972)
Techniques of Lipidology
E. Peveling, M. Galun (1976)
ELECTRON‐MICROSCOPICAL STUDIES ON THE PHYCOBIONT COCCOMYXA SCHMIDLENew Phytologist, 77
C. Ascaso, D. Brown, S. Rapsch (1986)
The Ultrastructure of the Phycobiont of Desiccated and Hydrated LichensThe Lichenologist, 18
M. Quartacci, O. Glisić, B. Stevanović, F. Navari-Izzo (2002)
Plasma membrane lipids in the resurrection plant Ramonda serbica following dehydration and rehydration.Journal of experimental botany, 53 378
(1997)
Lipid Composition and Cellular Ultrastructure during Dehydration and Rehydration
M. Maccarrone, G. Veldink, A. Agrò, J. Vliegenthart (1995)
Modulation of soybean lipoxygenase expression and membrane oxidation by water deficitFEBS Letters, 371
N. Smirnoff (1993)
The role of active oxygen in the response of plants to water deficit and desiccation.The New phytologist, 125 1
Patti Tarante, Thomas Keenan, Malcolm Potts (1993)
Rehydration induces rapid onset of lipid biosynthesis in desiccated Nostoc commune (Cyanobacteria).Biochimica et biophysica acta, 1168 2
(2000)
Antioxidative Systems of Lichens, Cand
N.F. Sinyutina, V.V. Polevoy (1995)
Auxin-Induced Changes in Phospholipid PhosphorylationFiziol. Rast., 42
J. Buitink, O. Leprince, F. Hoekstra (2000)
Dehydration-induced redistribution of amphiphilic molecules between cytoplasm and lipids is associated with desiccation tolerance in seeds.Plant physiology, 124 3
(1995)
Auxin-Induced Changes in Phospholipid Phosphorylation, Fiziol
(1959)
A Rapid Method of Total Lipids Extraction and Purification, Can
(1978)
Cryptobiosis (Anabiosis) in Poikiloxerophytes and Seeds and Their Resistance to Dehydration, Problemy zasukhoustoichivosti rastenii (Problems of Drought Resistance), Prokof’ev
K. Grünewald, J. Hirschberg, C. Hagen (2001)
Ketocarotenoid Biosynthesis Outside of Plastids in the Unicellular Green Alga Haematococcus pluvialis *The Journal of Biological Chemistry, 276
C. Liljenberg (1992)
The effects of water deficit stress on plant membrane lipids.Progress in lipid research, 31 3
V. Vaskovsky, T. Terekhova (1979)
HPTLC of phospholipid mixtures containing phosphatidylglycerolHrc-journal of High Resolution Chromatography, 2
P.W. Rundel (1988)
CRC Handbook of Lichenology
T. Munnik, H. Meijer, B. Riet, J. HimbergenvanJ.A., H. Hirt, W. Frank, D. Bartels, A. Musgrave (2000)
Hyperosmotic stress stimulates phospholipase D activity and elevates the levels of phosphatidic acid and diacylglycerol pyrophosphate.The Plant journal : for cell and molecular biology, 22 2
N. Radin, F. Lavin, J. Brown (1955)
Determination of cerebrosides.The Journal of biological chemistry, 217 2
A lichen Peltigera aphthosa (L.) Willd. was subjected to a short-term (7 days) or a long-term (180 and 540 days) dehydration followed by rehydration. Then the composition and content of lipids, as well as the rate of their metabolism (the rate of sodium 2-14C-acetate incorporation) were investigated. The long-term dehydration resulted in a dramatic decrease in the content (per dry wt) of major extrachloroplastic phospholipids, mainly phosphatidylcholines and phosphatidylethanolamines. The rehydration of lichen thalli after a short-term and long-term dehydration also resulted in an enhanced breakdown of these lipid molecules; however, it was accompanied by their rather intense in vivo synthesis, which was decreased after long-term dehydration. In contrast to phospholipids, the betaine lipids, diacylglyceroltrimethylhomoserines (DGTSs), were involved in metabolic processes to a far lesser extent. In the course of rehydration, their content was virtually unchanged and decreased only after 540 days of dehydration. The rate of incorporation of sodium 2-14C-acetate into the DGTS molecules was moderate and did not change even after long-term dehydration. Glycolipids were characterized by a fair tolerance to hydrolytic processes and by an increase in the rate of their synthesis after 540 days of the lichen dehydration. Responses of neutral lipids to dehydration turned out to be different. The long-term dehydration (for 540 days) was accompanied by a decrease in the contents of free sterols and sterol esters, whereas the contents of di- and triacylglycerols remained unchanged. Rehydration resulted in a decrease in diacylglycerol and sterol ester contents. All neutral lipids were characterized by a dramatic decrease in the rate of de novo synthesis after long-term dehydration. It was suggested that the tolerance of lichen to long-term dehydration was appreciably determined by the tolerance of its phycobiont, in this case, a green alga Coccomyxa sp.; the bulk of its lipids was characterized by a minimum rate of breakdown and, at the same time, by a stable synthesis.
Russian Journal of Plant Physiology – Springer Journals
Published: Feb 19, 2005
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.