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Transcript
DIFFUSION, OSMOSIS AND CELLULAR TRANSPORT • Explain what you see in the following pictures: Directional Movement of Water Across Membranes • Osmosis – Diffusion of water due to a water concentration gradient between two regions that are separated by a selectively permeable membrane • Osmotic movement – Dependent on concentration of solutes in the water – Side with more solutes has a lower concentration of water Osmosis NET WATER MOVEMENT Effect of solute concentration on water movement Effects of Tonicity • The solute concentrations of two fluids – Hypotonic: fewer solutes • Water diffuses in • Cell swells – Hypertonic: more solutes • Water diffuses out • Cell shrinks – Isotonic • No net change 2M sucrose solution 1 liter of distilled water 10M sucrose solution 2M sucrose solution Fig. 5.14, p. 88 HYPOTONIC CONDITIONS HYPERTONIC CONDITIONS ISOTONIC CONDITIONS compartment 1 compartment 2 membrane permeable to water but not to solutes fluid volume increases In compartment 2 Fig. 5.15, p. 89 when salt water is added to plant cells, water moves out of the cell due to the increase of solutes outside of the cell (hypertonic) Fig. 5.16, p. 89 Effects of Fluid Pressure • Volume of fluid exerts hydrostatic pressure – Force against a wall or membrane Diffusion Through the Plasma Membrane Extracellular fluid Lipidsoluble solutes Lipid-insoluble solutes Small lipidinsoluble solutes Water molecules Lipid bilayer Cytoplasm (a) Simple diffusion directly through the phospholipid bilayer (b) Carrier-mediated facilitated diffusion via protein carrier specific for one chemical; binding of substrate causes shape change in transport protein (c) Channel-mediated facilitated diffusion through a channel protein; mostly ions selected on basis of size and charge (d) Osmosis, diffusion through a specific channel protein (aquaporin) or through the lipid bilayer Figure 3.7 Active Transport • ATP required • Movement is against the concentration gradient – Sodium-potassium pump – Calcium pump Exocytosis and Endocytosis • Exocytosis – Vesicle moves to cell surface and fuses with plasma membrane • Endocytosis – Substances move in when plasma membrane balloons inward concentration gradient high P energy input low DIFFUSION ACROSS LIPID BILAYERS lipid-soluble substances as well as water diffuse across PASSIVE TRANSPORT Water-soluble substances, and water, diffuse through interior of transport proteins. No energy boost required. Also called facilitated diffusion ACTIVE TRANSPORT Specific solutes are pumped through interior of transport proteins. Requires energy boost Fig. 5.9a, p. 85 Passive Membrane Transport: Diffusion • Simple diffusion – nonpolar and lipidsoluble substances – Diffuse directly through the lipid bilayer – Diffuse through channel proteins Passive Membrane Transport: Diffusion • Facilitated diffusion – Transport of glucose, amino acids, and ions – Transported substances bind carrier proteins or pass through protein channels Carrier Proteins • Are integral transmembrane proteins • Show specificity for certain polar molecules including sugars and amino acids Passive Transport • Solute transport through transport protein • Movement – From higher to lower concentration • No ATP required Passive Membrane Transport – Review Process Energy Source Example Simple diffusion Kinetic energy Movement of O2 through membrane Facilitated diffusion Kinetic energy Movement of glucose into cells Osmosis Kinetic energy Movement of H2O in & out of cells Filtration Hydrostatic pressure Formation of kidney filtrate Active Membrane Transport – Review Process Energy Source Example Active transport of solutes ATP Movement of ions across membranes Exocytosis ATP Neurotransmitter secretion Endocytosis ATP White blood cell phagocytosis Fluid-phase endocytosis ATP Absorption by intestinal cells Receptor-mediated endocytosis ATP Hormone and cholesterol uptake Endocytosis via caveoli ATP Cholesterol regulation Endocytosis via coatomer vesicles ATP Intracellular trafficking of molecules Membrane Potential • Voltage across a membrane • Resting membrane potential – the point where K+ potential is balanced by the membrane potential – Ranges from –20 to –200 mV – Results from Na+ and K+ concentration gradients across the membrane – Differential permeability of the plasma membrane to Na+ and K+ • Steady state – potential maintained by active transport of ions Generation and Maintenance of Membrane Potential PLAY InterActive Physiology ®: Nervous System I: The Membrane Potential Figure 3.15
