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Transcript
Membrane Transport Cell or Plasma Membrane • Composed of double layer of phospholipids • • • and proteins (phospholipid bilayer) Surrounds outside of ALL cells Controls what enters or leaves the cell Living layer Outside of cell Proteins Carbohydrate chains Cell membrane Inside of cell (cytoplasm) Protein channelcopyright cmassengale Lipid bilayer 2 Phospholipids • Heads contain glycerol & • • • phosphate and are hydrophilic (attract water) Tails are made of fatty acids and are hydrophobic (repel water) Make up a bilayer where tails point inward toward each other Can move laterally to allow small molecules (O2, CO2, & H2O to enter) copyright cmassengale 3 Cell Membrane Proteins • Proteins help move • • large molecules or aid in cell recognition Peripheral proteins are attached on the surface (inner or outer) Integral proteins are embedded completely through the membrane copyright cmassengale 4 The Cell Membrane is also referred to as the Fluid Mosaic Model Molecules in cell membranes are constantly moving and changing copyright cmassengale 6 Structures Of The Plasma Membrane • Phosphate Head: Made of a phosphate group (polar and • • • • attracts water) Carbohydrate: Used for cell recognition Membrane Protein: Transports large particles across the cell membrane Cholesteral: Helps stabilize the phospholipids Lipid Tails: Made of fatty acids (non-polar and does not attract water) Diffusion • Movement of particles – From high – To Low Diffusion • Concentration: the mass of solute (what's being • dissolved) in a given volume of solvent (what’s doing the dissolving) Equilibrium: the concentration throughout a solution is the same Diffusion • ● Concentration gradient: the difference in • concentration across a barrier/membrane ● Because diffusion depends upon random particle movements, substances diffuse across membranes without requiring the cell to use energy Osmosis • Movement of water • From high to low • Across a selectively permeable membrane -selects what moves in and out Osmosis Dynamic Equilibrium • Equal concentrations are reached – Not the same volumes • Continued • movement across the membrane Not gain or loss Osmosis • ● Osmosis is the diffusion of water through a selectively permeable barrier. Water will tend to move across the membrane until equilibrium is reached, when this occurs the two solutions will be isotonic, the same. • ● When a solution is more concentrated with solute it is said to be hypertonic, whereas a dilute (less concentrated) solution is said to be hypotonic. Osmosis Isotonic Solutions • Iso- equal • No change in concentrations – Water still moves – Same amount of water moves in as moves out • Both sides of membrane are the same Hypertonic Solution • Hyper- Over • Out side of cell – More dissolved substance – Less water • Water moves out of cell Hypotonic Solution • Hypo- under • Out side of cell – Less dissolved substance – More water • Water moves into cell Passive Transport • Cell uses no energy • From high to low Plasma membrane Concentration gradient Facilitated Diffusion • Type of passive • transport Use transport proteins – Channel proteins – Carrier proteins • Changes shape • From high to low Facilitated Diffusion • ● During facilitated diffusion molecules that would not normally be able to cross through the membrane, such as glucose, diffuse across the membrane through selected protein channels. • It is dependent upon the concentration gradient because it does not require the cell to expend any energy. Active Transport • Cell uses energy • Against concentration gradient – From low to high • Carrier Proteins – Molecule binds with carrier protein – Energy then used to change shape – Molecule released on other side – Carrier protein returns to original shape Active Transport • ●The movement of material across a membrane and • against a concentration gradient is called active transport. Like facilitated diffusion this is carried out by protein channels in the membrane called transport proteins, however in this form of diffusion energy is expended in the process of “pumping” the material “uphill” against the gradient. Active Transport Molecule to be carried Energy Molecule being carried Large Particle Transport • ● Endocytosis is the process of taking material • into the cell by means of enfolding's, or pockets, of the cell membrane. The pocket or enfold, once it has surrounded the molecule, then closes and breaks off from the membrane forming a vacuole. Two examples of endocytosis are phagocytosis (cell eating) and pinocytosis (cell drinking). ● Exocytosis works the opposite of endocytosis. It is a vacuole with material designated to leave the cell which joins with the cell membrane then releases its material outside of the cell. Large Particle Transport (Exocytosis and Endocytosis) Large Particle Transport • Not through • • membrane Requires energy Exocytosis- out Large Particle Transport • Endocytosis- in Types of Endocytosis Pinocytosis: liquid (into) Phagocytosis: Solid (into)
