chapter 4
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Chapter 4. Membrane Structure and Function. Plasma Membrane. Fluid Mosaic Model. Cholesterol Reduces the amount of stuff allowed to enter a cell Phospholipids This is the lipid bilayer Glycolipids A carbohydrate that is attached to a phospholipid Proteins - PowerPoint PPT PresentationTRANSCRIPT
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Chapter 4
Membrane Structure and Function
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Plasma Membrane
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Fluid Mosaic Model• Cholesterol– Reduces the amount of stuff allowed to enter a cell
• Phospholipids – This is the lipid bilayer
• Glycolipids – A carbohydrate that is attached to a phospholipid
• Proteins– Can help move things in and out of the cell
• Glycoproteins– A carbohydrate that is attached to a protein
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• The carbohydrates that come out of the plasma membrane allow cells to recognize each other
• If a cell is not recognized the body tries to kill that foreign cell
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Permeability of Plasma Membrane• Plasma membrane is selectively permeable
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Selective Permeability
• Selective permeability- Some things are let into the cell while some things remain outside of the cell
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Concentration Gradient• There is a greater concentration of small balls on one
side than the other. This means that it will try to reach an equilibrium.
• A gradient means that there is more on one side and gets less and less as you move to the other side
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Diffusion• Diffusion is the movement of molecules from
a higher concentration to a lower concentration
Time
Semi-Permeable
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• Diffusion– This occurs in our lungs.– High concentration of oxygen air enters lungs and
O2 diffuses into our blood, which has a lower concentration of oxygen
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Osmosis• Osmosis is the diffusion of water• Water moves from a high concentration to a low
concentration
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• Water moves to the right because there is a difference in concentration
• Osmotic pressure is the pressure that develops in a system because of osmosis
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Factors that will affect the rate of Diffusion
1. Temperature higher temp. the faster the rate of diffusion
2. Size of molecule the smaller the molecule then the faster the rate of diffusion
3. Charge of molecule charged molecules have difficulty moving through the cell
4. Concentration Gradient the larger the difference in concentration the faster the diffusion
5. Pressure Gradient If there is pressure on one side then the faster the diffusion
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What happens to a cell in a solution• Tonicity – concentration of the solution
compared to the concentration inside the cell• Isotonic – The concentration of the solution is equal to that of
inside the cell• Hypotonic – Solution has a lower concentration of solute (higher
concentration of water) than inside the cell• Hypertonic – Solution has higher concentration of solute than
inside the cell
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What happens to a cell in solution
• Isotonic solution– The cell remains the same. No changes
• Hypotonic solution– The cell swells and may undergo lysis
• Hypertonic solution– The cell loses water and shrivels. Or undergoes
crenation
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Which is which?
Hypertonic Isotonic Hypotonic
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Facilitated Transport
• This is for molecules that are too big to diffuse through the plasma membrane
• Proteins help them move• It stills move with the concentration gradient• It uses NO ENERGY
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Diffusion Facilitated Transport
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• Facilitated Transport• Diffusion• Osmosis
None of these use EnergySo therefore they are called “Passive Transport”
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Active Transport
• This uses energy– ATP ADP
• It moves molecules and ions against a concentration gradient
• An example of active transport is the sodium potassium pump– Sodium is moved to the outside and potassium is
moved to the inside of the cell
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Endocytosis and Exocytosis• These processes are used for materials that are too big to
pass through the plasma membrane by a protein transport
• Endocytosis– The cell engulfs material to bring it into the cell– Two types
• Phagocytosis• Pinocytosis
• Exocytosis– Moves material to the outside of the cell– This allows cell to secrete molecules
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Endocytosis• Phagocytosis– A type of endocytosis that engulfs large items. Like
cells or bacteria– The vesicle that forms afterwards combines with
lysosomes so digestion can occur
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Endocytosis
• Pinocytosis– This is when very small particles are engulfed by
the membrane– Receptor mediated endocytosis is a type of
pinocytosis that uses receptor proteins to help initiate pinocytosis
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