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The Cell Membrane

Learn about the fluid mosaic model of cell membranes and the different components and functions of the membrane. Explore various modes of membrane transport, including passive transport (diffusion and osmosis) and active transport (protein pumps and endocytosis/exocytosis).

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The Cell Membrane

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  1. The Cell Membrane Mader Biology, Chapter 5

  2. Membrane Structure: Fluid Mosaic Model

  3. The Membrane is Selectively Permeable • The ability to allow some substances to cross more easily than others • Allows the cell to maintain an internal environment different from the external one

  4. Membrane Components • Phospholipids Proteins • Cholesterol Carbohydrates (glucose)

  5. Phospholipids

  6. Cholesterol • Steroid (lipid) found within the phospholipid bilayer • Keeps membrane solid when under heat

  7. Membrane Proteins • Transport Proteins carry materials across the membrane

  8. Glycocalyx Polysaccharides (chains of glucose) attached to glycoproteins Functions:

  9. Membrane Transport

  10. Modes of Membrane Transport • Passive Transport • Diffusion • Osmosis • Facilitated Diffusion • Active Transport • Protein Pumps • Endocytosis • Exocytosis

  11. Passive Transport Goes “with” the concentration gradient; no ATP energy required

  12. Simple Diffusion • The tendency for molecules of any substance to spread out into the available space • Molecules move from a region of high concentration to low concentration • moving down the concentration gradient

  13. Osmosis • Osmosis is the diffusion of water across a semi-permeable membrane • Water travels • through protein • pores called • aquaporins

  14. Effects of Tonicity on Cell Membranes • Hypotonic solution • higher concentration of water outside of cell results in hemolysis • Hypertonic solution • lower concentration of water outside of cell causes crenation • Isotonic solution • water concentration the same inside & outside of cell results in no net movement of water across cell membrane

  15. Osmosis • Water always moves from a hypotonic solution to a hypertonic solution • What happens to cells when placed in: • Hypotonic solutions? • Hypertonic solutions? • Isotonic solutions?

  16. Cells in Solutions Isotonic Solution Hypotonic Solution Hypertonic Solution No net movement of H2O (equal amounts entering & leaving) CYTOLYSIS PLASMOLYSIS

  17. Facilitated Diffusion • Diffusion with the assistance of integral transport proteins. (Still Passive transport) Note: Carrier proteins allow both passive and active transport

  18. Facilitated Diffusion • Transport proteins • Provide corridors allowing a specific molecule or ion to cross membrane • Undergo a shape change that translocates the molecule across the membrane • Still Passive Transport • Process requires no energy • Particles are moving from an area of high concentration to low concentration

  19. Channel Proteins • Channel Proteins – allow certain materials to flow in and out (down their concentration gradient.) • Aquaporin – channel protein that only lets water in. • Ion Channels – also called gated channels, open and close in response to a chemical or electrical stimulus

  20. Carrier Proteins • Carrier Proteins – change shape to escort certain material in and out of the cell. (Passive- down their concentration gradients; Active- against). Passive is shown below. How do you know?

  21. Active Transport Goes “against” the concentration gradient (“low to high”); requires ATP energy

  22. Active Transport • Movement of solutes AGAINST the concentration gradient. Goes from low to high concentration. • Requires energy input by the cell • ATP supplies this energy

  23. Active Transport • Carrier proteins are needed to transport molecules across the membrane against the concentration gradient and require an expenditure of energy • Often referred to as “pumps”. • Ex: Na+ and K+ for nerve (neuron) impulses

  24. Active Transport • Active transport - requires energy • Proteins act as pumps to move material from low to high concentration. Ex. Proton Pumps (Hydrogen Pumps) going against the gradient

  25. Moving Large Objects • Endocytosis – Cells take in materials by forming vesicles from the plasma membrane • Exocytosis – Cell secretes macromolecules by the fusion of vesicles with plasma membrane

  26. 2 Types of Endocytosis • 1. Phagocytosis: engulfing solid particles • 2. Pinocytosis: engulfing liquid substances (extracellular fluid)

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