1. TRANSPORT PROTEINS
Make lipid bilayer permeable to hydrophilic substances: ions and polar molecules
SPAN entire membrane – “transmembrane”
TWO general classes
Channel proteins
Carrier proteins

2. Channel Proteins A hydrophilic “tunnel” Example: aquaporins
3 billion water molecules per second per aquaporin
Water molecules move single file/channel holds 10
Tremendous increase in rate!

3. Carrier Proteins
Hold on to molecules/ions; change conformation; shuttle across
Specific for substance translocated
Ex. glucose transporter; sodium potassium pump

4. This is a receptor protein
The signal DOES NOT come in
There is NO channel
There is a binding site for the signal.
The message is transmitted to the inside of the cell but THE MESSENGER DOES NOT COME IN

5. Selective Permeability
What determines direction of transport?
What determines whether a substance will enter or leave the cell?
To answer these questions we need to understand 2 modes of transport:
Passive transport
Active transport

6. PASSIVE TRANSPORT
ACTIVE TRANSPORT
Solutes move DOWN the concentration gradient
Solutes move AGAINST the concentration gradient
Does not require cell energy – uses the potential energy of the chemical gradient
Requires cell energy – ATP directly or indirectly (cotransport)
Solutes move between phospholipids or through transport protein (channels or carriers)
Solutes bind carriers and carrier changes conformation and translocates solute across the membrane

7. Passive Transport
Passive transport - diffusion of a substance across a biological membrane.
Diffusion - net movement of molecules from high concentration to low concentration (down the concentration gradient)
Results from kinetic energy of molecules. Does not require energy input.
Diffusion continues until a dynamic equilibrium is reached (no net directional movement)

8. Diffusion – movement of molecules of a substance so that they spread out evenly into the available space
Why do molecules move?
Is the movement here random or directional (net movement)? Explain.
Describe the movement of the molecules at equilibrium.
Is the movement in the pictures “down the concentration gradient” or “against the concentration gradient”?
What is the free energy change for this process?

9. What is different in this picture?
Where is the concentration gradient highest initially?
Does the diffusion to the purple dye influence the diffusion of the yellow dye?
Would you describe the membrane between the two compartments as permeable to the dye or selectively permeable to the dye?

10. Osmosis
Osmosis - passive transport (diffusion!) of water across a selectively permeable membrane.
What is the role of water in cells?
Biological fluids are usually dilute solutions.
Some water within the cell is not “free” to move down it’s concentration gradient. Why?
Cell membranes are not barriers to diffusion of water.
Aquaporins

11. Osmosis Relative concentration terms:
a) Hypertonic - solution with greater solute concentration than inside the cell.
b) Hypotonic - solution with lower solute concentration than inside the cell.
c) Isotonic - solution with equal solute concentration compared to that inside a cell.
The prefixes refer to solute concentration. What would the water concentration be in each example above?
What are some units that could be used to express the amount of solute in an aqueous solution?
HYPO = LESS HYPER = MORE ISO = EQUAL

12. TIP! WATER FOLLOWS SOLUTES
WHAT ARE THESE THINGS ANYWAY?

13. Movement of Water
If two solutions are separated by a selectively permeable membrane that is permeable to water but not to solute, water will diffuse from the hypoosmotic solution to the hyperoosmotic solution.
“Water moves to DILUTE!”
Direction of osmosis is determined by the difference in total solute concentration, regardless of the types of solutes in the solutions.
At equilibrium, water molecules move in both directions at the same rate. (True for isotonic solutions also)

14. Cell Survival
Balance of water between the cell and its environment are crucial to organisms.
Osmoregulation - control of water balance.
Animal cells (no cell walls) have adaptations for osmoregulation. Ex) Paramecium have contractile vacuoles
Plants can take in water and become turgid (firm), while in isotonic solutions cells become flaccid (limp). In hypertonic solutions, the plant cell shrivels and plasmolysis occurs.

15. cytolysis
plasmolysis

16. Facilitated Diffusion
Diffusion of polar molecules and ions across a membrane with the aid of transport proteins.
Proteins have a specialized binding site for the solute they transport.
Some proteins have gated channels that open or close in response to a stimulus.

17. Facilitated Diffusion

18. Active Transport
Pumping of solutes against the concentration gradient, requiring energy from the cell.
Sodium-potassium pump allows cells to exchange Na+ and K+ across animal cell membranes.

21. Ion Pumps
Because anions and cations are unequally distributed across plasma membranes, all cells have voltages across their plasma membrane (membrane potential).
Forces that drive passive transport of ions across membranes include: concentration gradient of the ion (chemical force), and effect of membrane potential (electrical force) on the ion.
The combination of these forces is called the electrochemical gradient.
VOLTAGE OCCURS WHEN ELECTICAL CHARGES ARE SEPARATED.

22. Electrogenic Pumps
Transport proteins that generate voltage across a membrane.
Na+/K+ ATPase is the major electrogenic pump in animal cells
A proton pump (H+) is the major electrogenic pump in plants, bacteria, and fungi.
Mitochondria and chloroplasts use a proton pump to drive ATP synthesis.
Voltages created by electrogenic pumps are sources of potential energy available to do cellular work.

24. Cotransport
Process where a single ATP-powered pump actively transports one solute and indirectly drives the transport of other solutes against their concentration gradients.
Example: Plants use the mechanism of sucrose/H+ cotransport to load sucrose produced by photosynthesis into specialized cells in the veins of leaves. Transport proteins can move sucrose into the cell against the concentration gradient only if it travels with the H+ ion.

26. Movement of Large Molecules or Cells
Large molecules such as proteins or polysaccharides and cells cross membranes by the processes of endocytosis and exocytosis.
Material to be transported is placed in membrane-bound sacs
Formation and transport of these vesicles requires energy

27. Exocytosis
Process of exporting macromolecules from a cell by fusion of vesicles with the plasma membrane.
Vesicle usually budded from the ER or Golgi and migrates to plasma membrane
Used by secretory cells to export products, such as insulin in the pancreas or neurotransmitters from neurons.

28. Endocytosis
Process of importing macromolecules into a cell forming vesicles derived from the plasma membrane.
Vesicle forms from a localized region of plasma membrane that sinks inward, pinches off into the cytoplasm.
Used by cells to incorporate extracellular substances.

29. Types of Endocytosis: Phagocytosis
Endocytosis of solid particles.
Cell engulfs particle with pseudopodia, and pinches off a food vacuole.
Vacuole fuses with a lysosome containing hydrolytic (digestive) enzymes that break down the particle.
Ex. unicellular protists like amoeba and some immune system cells

30. Phagocytosis of a
bacterial cell by an
amoeba

31. Types of Endocytosis: Pinocytosis
Endocytosis of fluid droplets
Extracellular fluid is engulfed in small vesicles
Nonspecific in the substances it transports. Cell takes in all solutes dissolved in the droplet.

32. Pinocytosis of
fluid into cell
lining a blood
vessel

33. Types of Endocytosis: Receptor-mediated Endocytosis
Very specific – molecule to be transported (ligand) must bind to receptor of cell surface
After ingested material is released from the vesicle for metabolism, the receptors are recycled to the plasma membrane.
Ex. uptake of cholesterol

34. Receptor-mediated endocytosis