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Membrane Structure & Function Overview: Fluid Mosaic Model

Explore membrane models and the structure of a fluid mosaic membrane consisting of lipids, proteins, and carbohydrates. Learn about membrane traffic and the importance of selective permeability in cell survival. Understand passive and active transport mechanisms, including diffusion, osmosis, facilitated diffusion, and active transport. Discover the roles of specific membrane proteins in aiding solute transport and maintaining electrochemical gradients. Delve into processes like exocytosis and endocytosis for large molecule transportation in cells.

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Membrane Structure & Function Overview: Fluid Mosaic Model

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  1. CHAPTER 8 MEMBRANE STRUCTURE AND FUNCTIONOVERVIEW

  2. A. MEMBRANE MODELS HAVE EVOLVED TO FIT NEW DATA: SCIENCE AS A PROCESS CURRENT MEMBRANE MODEL: FLUID MOSAIC MODEL Figure 8.2 Two generations of membrane models I. MEMBRANE STRUCTURE

  3. B. A MEMBRANE IS A FLUID MOSAIC OF LIPIDS, PROTEINS, AND CARBOHYDRATES • INTEGRAL PROTEINS ARE EMBEDDED IN THE LIPID BILAYER • PERIPHERAL PROTEINS ARE ATTACHED TO THE SURFACE • THE INSIDE AND OUTSIDE MEMBRANE FACES DIFFER IN COMPOSITION • CARBOHYDRATES LINKED TO PROTEINS AND LIPIDS IN THE PLASMA MEMBRANE ARE IMPORTANT FOR CEL-CELL RECOGNITION

  4. Figure 8.5 The detailed structure of an animal cell’s plasma membrane

  5. II. TRAFFIC ACROSS MEMBRANES • A. A MEMBRANE’S MOLECULAR ORGANIZATION RESULTS IN SELECTIVE PERMEABILITY • A CELL MUST EXCHANGE SMALL MOLECULES AND IONS WITH ITS SURROUNDINGS, A PROCESS CONTROLLED BY THE PLASMA MEMBRANE • HYDROPHOBIC SUBSTANCES ARE SOLUBLE IN LIPID AND PASS THROUGH MEMBRANES RAPIDLY • SMALL POLAR MOLECULES SUCH AS H2O ALSO PASS THROUGH THE MEMBRANE • LARGER POLAR MOLECULES AND IONS REQUIRE SPECIFIC TRANSPORT PROTEINS TO HELP THEM ACROSS

  6. DIFFUSION: THE SPONTANEOUS MOVEMENT OF A SUBSTANCE DOWN ITS CONCENTRATION GRADIENT Figure 8.9 Diffusion B. PASSIVE TRANSPORT IS DIFFUSION ACROSS A MEMBRANE

  7. C. OSMOSIS IS THE PASSIVE TRANSPORT OF WATER • WATER FLOWS ACROSS A MEMBRANE FROM THE SIDE WHERE SOLUTE IS LESS CONCENTRATED (HYPOTONIC) TO THE SIDE WHERE SOLUTE IS MORE CONCENTRATED (HYPERTONIC) • IF THE CONCENTRATIONS ARE EQUAL (ISOTONIC), NO NET OSMOSIS OCCURS

  8. Figure 8.10 Osmosis

  9. CELLS LACKING CELL WALLS (AS IN ANIMALS) ARE ISOTONIC WITH THEIR ENVIRONMENTS OR HAVE ADAPTATIONS FOR OSMOREULATION 8.11 Water Balance of Living Cells D. CELL SURVIVAL DEPENDS ON BALANCING WATER UPTAKE AND LOSS

  10. IN FACILITATED DIFFUSION, A TRANSPORT PROTEIN SPEEDS MOVEMENT OF A SOLUTE ACROSS A MEMBRANE DOWN ITS CONCENTRATION GRADIENT 8.13 Facilitated Diffusion E. SPECIFIC PROTEINS FACILITATE THE PASSIVE TRANSPORT OF SELECTED SOLUTES

  11. SPECIFIC MEMBRANE PROTEINS USE ENERGY, USUALLY IN THE FORM OF ATP, TO DO THIS WORK 8.15 Passive and Active Transport Compared E. ACTIVE TRANSPORT IS THE PUMPING OF SOLUTES AGAINST THEIR GRADIENTS

  12. G.     SOME ION PUMPS GENERATE VOLTAGE ACROSS MEMBRANES • IONS CAN HAVE BOTH A CONCENTRATION (CHEMICAL) GRADIENT AND AN ELECTRIC GRADIENT (VOLTAGE) • THESE FORCES COMBINE IN THE ELECTROCHEMICAL GRADIENT, WHICH DETERMINES THE NET DIRECTION OF IONIC DIFFUSION • ELECTROGENIC PUMPS, SUCH AS SODIUM-POTASSIUM PUMPS AND PROTON PUMPS, ARE TRANSPORT PROTEINS THAT CONTRIBUTE TO ELECTROCHEMICAL GRADIENTS

  13. 8.14 The Sodium - Potassium Pump

  14. ONE SOLUTE’S “DOWNHILL” DIFFUSION DRIVES THE OTHER’S “UPHILL” TRANSPORT 8.17 CONTRANSPORT H.     IN COTRANSPORT, A MEMBRANE PROTEIN COUPLES THE TRANSPORT OF ONE SOLUTE TO ANOTHER

  15. I. EXOCYTOSIS AND ENDOCYTOSIS TRANSPORT LARGE MOLECULES • EXOCYTOSIS: TRANSPORT VESICLES MIGRATE TO THE PLASMA MEMBRANE, FUSE WITH IT, AND RELEASE THEIR CONTENTS • ENDOCYTOSIS: LARGE MOLECULES ENTER CELLS WITHIN VESICLES PINCHED INWARD FROM THE PLASMA MEMBRANE • PHAGOCYTOSIS • PINOCYTOSIS • RECEPTOR-MEDIATED ENDOCYTOSIS

  16. 8.18 THREE TYPES OF ENDOCYTOSIS IN ANIMALS

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