Cover image for Plant Membranes A biophysical approach to structure, development and senescence
Plant Membranes A biophysical approach to structure, development and senescence
Title:
Plant Membranes A biophysical approach to structure, development and senescence
ISBN:
9789401726832
Personal Author:
Edition:
1st ed. 1992.
Publication Information New:
Dordrecht : Springer Netherlands : Imprint: Springer, 1992.
Physical Description:
XIII, 266 p. 27 illus., 4 illus. in color. online resource.
Contents:
1. Introduction -- One The building blocks of the membrane -- 2. Membrane fatty acyl tailgroups -- 3. Membrane glycerolipid and sphingolipid headgroups -- 4. Sterols -- 5. Membrane proteins -- 6. Membrane water -- Two Biophysical aspects of membrane structure and function -- 7. Plant membrane biophysics in development and senescence -- Three The membrane in action -- 8. The role of calcium in the membrane -- 9. Membrane-associated phospholytic and lipolytic enzymes -- 10. Response of plant membranes to chilling and freezing -- 11. The plasma membrane and tonoplast of guard cells -- 12. Signal transduction, Ca2+-triggered membrane glycerolipid turnover and growth/senescence equilibria -- Epilogue -- Abbreviations.
Abstract:
The plasma membrane is at once the window through which the cell senses the environment and the portal through which the environment influences the structure and activities of the cell. Its importance in cellular physiology can thus hardly be overestimated, since constant flow of materials between cell and environment is essential to the well-being of any biological system. The nature of the materials mov­ ing into the cell is also critical, since some substances are required for maintenance and growth, while others, because of their toxicity, must either be rigorously excluded or permitted to enter only after chemical alteration. Such alteration frequently permits the compounds to be sequestered in special cellular compartments having different types of membranes. This type of homogeneity, plus the fact that the wear and tear of transmembrane molecular traffic compels the system to be constantly monitored and repaired, means that the membrane system of any organism must be both structurally complex and dy­ namic. Membranes have been traditionally difficult to study because of their fragility and small diameter. In the last several decades, however, remarkable advances have been made because of techniques permit­ ting the bulk isolation of membranes from homogenized cells. From such isolated membranes have come detailed physical and chemical analyses that have given us a detailed working model of membrane. We now can make intelligent guesses about the structural and func­ tional interactions of membrane lipids, phospholipids, proteins, sterols and water.
Added Corporate Author:
Language:
English