Cell Transport The movement of molecules into and out of a cell
How is a phospholipid constructed?
Interactions of phospholipid molecules with water The basis of phospholipid bi-layers
The phospholipid bilayer is the fundamental structure of the membrane The cell membrane contains both hydrophilic and hydrophobic regions
The Cell Membrane The cell membrane is composed of 2 layers of phospholipids Also called the phospholipid bilayer or plasma membrane The Polar heads face the outside of the membrane where water exists The Nonpolar tails face each other in the inside of the bilayer creating a hydrophobic region
Membranes are primarily composed of phospholipids and proteins Properties of Membrane Membranes have the important function of regulating the movement of substances into or out of cells or organelles
The Fluid-Mosaic Model of a membrane
Two types of proteins in membranes – peripheral proteins and integral proteins peripheral protein integral protein
The Passage of Molecules across the Plasma Membrane Hydrophobic molecules and non-polar molecules (such as O 2 ) cross the membrane with ease. Hydrophilic molecules cannot, however, slip through the extensive hydrophobic core of the membrane. The transport of hydrophilic compounds requires the help of the integral proteins of the membrane.
Diffusion -- a spontaneous process in which particles move from an area of high concentration to an area of low concentration across a concentration gradient
When two different solutes are diffusing at the same time, they will each follow their own concentration gradients from high to low.
The net diffusion occurs from a region of high concentration toward a region of low concentration. High concentrationLow concentration What happens if we remove the barrier?
Diffusion – fills the space – it is spontaneous, no work is done High concentrationLow concentration
Diffusion Summarized Some molecules can simply pass through Example: small molecules No energy required to pass: passive transport Move from high low concentration: diffusion Diffusion will occur until equilibrium is reached
Osmosis Osmosis – the diffusion of water across a selectively- permeable membrane higher solute concentration Solute is defined as polar or charged molecule or ion Water is attracted to solutes!
Osmosis Osmosis – the diffusion of water across a selectively- permeable membrane water level rises
Osmosis Summarized Water can simply pass through Special type of diffusion: osmosis No energy required: passive transport
Tonicity – the ability of a solution to cause a cell to loose or gain water Cell with higher solute concentration Water with low solute concentration hypotonic H2OH2O Hypotonic solution – contains fewer solutes than cell (Cell will enlarge when placed in this solution!)
Tonicity – the ability of a solution to cause a cell to loose or gain water Cell (with solutes) Water with high solute concentration hypertonic H2OH2O Hypertonic solution – contains more solutes than cell (Cell will shrink when placed in this solution!)
Tonicity – the ability of a solution to cause a cell to loose or gain water Cell (with solutes) Water with equal solute concentration isotonic H2OH2O Isotonic solution – contains equal solutes as cell (Cell will retain size when placed in this solution!)
Tonicity in animal cells
Tonicity in plant cells Turgid (normal) Flaccid (slight water stress) Plasmolyzed (severe water stress)
Facilitated Diffusion No ATP energy required Molecules follow their concentration gradients They are just “helped” across the hydrophobic core of the membrane by a transport protein
Facilitated Diffusion Net rate of diffusion from high concentration toward low concentration channel gate
Facilitated Diffusion Summarized Some molecules are too large to pass normally Example: monosaccharides Carrier proteins assist: facilitated diffusion No energy required: passive transport
Facilitated Diffusion Summarized Ions have a charge: cannot normally pass Examples: Na +, Ca +, Cl - Can pass through ion channel No energy required: passive transport
Active Transport Molecules go against their concentration gradients They are “helped” across the hydrophobic core of the membrane by a transport protein, but only when energy is expended. Work is done by the cell! Requires ATP (Energy)!!
Active Transport Summarized Molecules often move from low high concentration Such movement requires energy: active transport Carrier protein used as cell membrane “pump” Example: Na + and K + pump
Review the Differences
Bulk Transport EndocytosisEndocytosis – movement of large molecules into the cell –Phagocytosis – movement of foods (cell eating) –Pinocytosis – movement of fluids (cell drinking) ExocytosisExocytosis – movement of large molecules out of the cell