1. Learning Objectives Students will be able to:
Identify three types of passive transport
Explain how an equilibrium is established as a result of diffusion.
Distinguish between diffusion and osmosis.

2. copyright cmassengale
The Plasma Membrane
9/10/2018
The Plasma Membrane -
Gateway to the Cell
copyright cmassengale
G. Podgorski, Biol. 1010

3. copyright cmassengale
The Plasma Membrane
9/10/2018
Cell Membrane
The cell membrane is flexible and allows a unicellular organism to move
copyright cmassengale
G. Podgorski, Biol. 1010

4. copyright cmassengale
The Plasma Membrane
9/10/2018
Homeostasis
Balanced internal condition of cells
Also called equilibrium
Maintained by plasma (cell) membrane controlling what enters & leaves the cell
copyright cmassengale
G. Podgorski, Biol. 1010

5. Functions of Plasma Membrane
The Plasma Membrane
9/10/2018
Functions of Plasma Membrane
Protective barrier
Regulates transport of materials in & out of cell (selectively permeable)
Provides anchoring sites for filaments of cytoskeleton
copyright cmassengale
G. Podgorski, Biol. 1010

6. Membrane Components Phospholipids Proteins Carbohydrates (glucose)
The Plasma Membrane
9/10/2018
Phospholipids
Proteins
Cholesterol
Carbohydrates (glucose)
G. Podgorski, Biol. 1010

7. Cell Membrane Polar heads are hydrophilic “water loving”
The Plasma Membrane
Cell Membrane
9/10/2018
Polar heads are hydrophilic “water loving”
Nonpolar tails are hydrophobic “water fearing”
Makes membrane “Selective” in what crosses
G. Podgorski, Biol. 1010

8. The Plasma Membrane
Cell Membrane
9/10/2018
The cell membrane is made of 2 layers of phospholipids called the lipid bilayer
Hydrophobic molecules pass easily; hydrophilic DO NOT
G. Podgorski, Biol. 1010

9. copyright cmassengale
The Plasma Membrane
9/10/2018
Solubility
Materials that are soluble in lipids can pass through the cell membrane easily
copyright cmassengale
G. Podgorski, Biol. 1010

10. Semipermeable Membrane
The Plasma Membrane
Semipermeable Membrane
9/10/2018
Small molecules and hydrophobic molecules move through easily.
e.g. O2, CO2, Steroid hormones
copyright cmassengale
G. Podgorski, Biol. 1010

11. Semipermeable Membrane
The Plasma Membrane
Semipermeable Membrane
9/10/2018
Ions, hydrophilic molecules larger than water, and large molecules such as proteins do not move through the membrane on their own.
G. Podgorski, Biol. 1010

12. Types of Transport Across Cell Membranes
The Plasma Membrane
9/10/2018
Types of Transport Across Cell Membranes
copyright cmassengale
G. Podgorski, Biol. 1010

13. copyright cmassengale
The Plasma Membrane
9/10/2018
Simple Diffusion
Requires NO energy
Molecules move from area of HIGH to LOW concentration
copyright cmassengale
G. Podgorski, Biol. 1010

14. copyright cmassengale
The Plasma Membrane
9/10/2018
DIFFUSION
Diffusion is a PASSIVE process which means no energy is used to make the molecules move. They have a natural KINETIC ENERGY
copyright cmassengale
G. Podgorski, Biol. 1010

15. Diffusion through a Membrane
The Plasma Membrane
9/10/2018
Diffusion through a Membrane
Cell membrane
Solute moves DOWN concentration gradient (HIGH to LOW)
G. Podgorski, Biol. 1010

16. Diffusion across a membrane Semipermeable membrane
The Plasma Membrane
9/10/2018
Osmosis
Diffusion of water across a membrane
Movement of water molecules (solute) from an area of LOW solute concentration to an area of HIGH solute concentration.
Diffusion across a membrane
Semipermeable membrane
G. Podgorski, Biol. 1010

17. copyright cmassengale
The Plasma Membrane
9/10/2018
Aquaporins
Water Channels
Protein pores used during OSMOSIS
WATER MOLECULES
copyright cmassengale
G. Podgorski, Biol. 1010

18. Cell in Isotonic Solution
The Plasma Membrane
9/10/2018
Cell in Isotonic Solution
10% NaCL 90% H2O
ENVIRONMENT
CELL
NO NET MOVEMENT
10% NaCL
90% H2O
What is the direction of water movement?
equilibrium
The cell is at _______________.
copyright cmassengale
G. Podgorski, Biol. 1010

19. Cell in Hypotonic Solution
The Plasma Membrane
9/10/2018
Cell in Hypotonic Solution
10% NaCL 90% H2O
CELL
20% NaCL
80% H2O
What is the direction of water movement?
copyright cmassengale
G. Podgorski, Biol. 1010

20. Cell in Hypertonic Solution
The Plasma Membrane
9/10/2018
Cell in Hypertonic Solution
15% NaCL 85% H2O
ENVIRONMENT
CELL
5% NaCL
95% H2O
What is the direction of water movement?
copyright cmassengale
G. Podgorski, Biol. 1010

21. copyright cmassengale
The Plasma Membrane
9/10/2018
Cells in Solutions
copyright cmassengale
G. Podgorski, Biol. 1010

22. NO NET MOVEMENT OF H2O (equal amounts entering & leaving)
The Plasma Membrane
9/10/2018
Hypotonic Solution
Hypertonic Solution
Isotonic Solution
NO NET MOVEMENT OF H2O (equal amounts entering & leaving)
PLASMOLYSIS
The contraction of a cell due to loss of water in plants and bacterial cells
CYTOLYSIS
When cells burst due to water moving into the cell until it bursts
G. Podgorski, Biol. 1010

23. copyright cmassengale
The Plasma Membrane
9/10/2018
copyright cmassengale
G. Podgorski, Biol. 1010

24. What Happens to Blood Cells?
copyright cmassengale

25. copyright cmassengale
The Plasma Membrane
9/10/2018
isotonic
hypotonic
hypertonic
hypertonic
isotonic
hypotonic
copyright cmassengale
G. Podgorski, Biol. 1010

26. Three Forms of Transport Across the Membrane
The Plasma Membrane
9/10/2018
G. Podgorski, Biol. 1010

27. copyright cmassengale
The Plasma Membrane
9/10/2018
Passive Transport
Simple Diffusion
Doesn’t require energy
Moves high to low concentration
Example: Oxygen or water diffusing into a cell and carbon dioxide diffusing out.
copyright cmassengale
G. Podgorski, Biol. 1010

28. Facilitated diffusion
The Plasma Membrane
9/10/2018
Passive Transport
Facilitated diffusion
Doesn’t require energy
Uses transport proteins to move high to low concentration
Examples: Glucose or amino acids moving from blood into a cell.
copyright cmassengale
G. Podgorski, Biol. 1010

29. Proteins Are Critical to Membrane Function
The Plasma Membrane
9/10/2018
Proteins Are Critical to Membrane Function
copyright cmassengale
G. Podgorski, Biol. 1010

30. Types of Transport Proteins
The Plasma Membrane
9/10/2018
Types of Transport Proteins
Channel proteins are embedded in the cell membrane & have a pore for materials to cross
Carrier proteins can change shape to move material from one side of the membrane to the other
copyright cmassengale
G. Podgorski, Biol. 1010

31. Facilitated Diffusion
The Plasma Membrane
9/10/2018
Facilitated Diffusion
Molecules will randomly move through the pores in Channel Proteins.
copyright cmassengale
G. Podgorski, Biol. 1010

32. Facilitated Diffusion
The Plasma Membrane
9/10/2018
Facilitated Diffusion
Some Carrier proteins do not extend through the membrane.
They bond and drag molecules through the lipid bilayer and release them on the opposite side.
copyright cmassengale
G. Podgorski, Biol. 1010

33. copyright cmassengale
The Plasma Membrane
9/10/2018
Carrier Proteins
Other carrier proteins change shape to move materials across the cell membrane
copyright cmassengale
G. Podgorski, Biol. 1010

34. copyright cmassengale
The Plasma Membrane
9/10/2018
Active Transport
Requires energy or ATP
Moves materials from LOW to HIGH concentration
AGAINST concentration gradient
copyright cmassengale
G. Podgorski, Biol. 1010

35. copyright cmassengale
The Plasma Membrane
9/10/2018
Active transport
Examples: Pumping Na+ (sodium ions) out and K+ (potassium ions) in against strong concentration gradients.
Called Na+ - K+ Pump
copyright cmassengale
G. Podgorski, Biol. 1010

36. Sodium-Potassium Pump
The Plasma Membrane
9/10/2018
Sodium-Potassium Pump
3 Na+ pumped in for every 2 K+ pumped out; creates a membrane potential
G. Podgorski, Biol. 1010

37. Moving the “Big Stuff” Exocytosis- moving things out.
The Plasma Membrane
Moving the “Big Stuff”
9/10/2018
Exocytosis- moving things out.
Molecules are moved out of the cell by vesicles that fuse with the plasma membrane.
This is how many hormones are secreted and how nerve cells communicate with one another.
copyright cmassengale
G. Podgorski, Biol. 1010

38. copyright cmassengale
The Plasma Membrane
Exocytosis
9/10/2018
Exocytic vesicle immediately after fusion with plasma membrane.
copyright cmassengale
G. Podgorski, Biol. 1010

39. copyright cmassengale
The Plasma Membrane
Moving the “Big Stuff”
9/10/2018
Large molecules move materials into the cell by one of three forms of endocytosis.
copyright cmassengale
G. Podgorski, Biol. 1010

40. Pinocytosis Most common form of endocytosis.
The Plasma Membrane
Pinocytosis
9/10/2018
Most common form of endocytosis.
Takes in dissolved molecules as a vesicle.
G. Podgorski, Biol. 1010

41. copyright cmassengale
The Plasma Membrane
9/10/2018
Pinocytosis
Cell forms an invagination
Materials dissolve in water to be brought into cell
Called “Cell Drinking”
copyright cmassengale
G. Podgorski, Biol. 1010

42. Example of Pinocytosis
The Plasma Membrane
Example of Pinocytosis
9/10/2018
mature transport vesicle
pinocytic vesicles forming
Transport across a capillary cell (blue).
G. Podgorski, Biol. 1010

43. Receptor-Mediated Endocytosis
The Plasma Membrane
9/10/2018
Receptor-Mediated Endocytosis
Some integral proteins have receptors on their surface to recognize & take in hormones, cholesterol, etc.
G. Podgorski, Biol. 1010

44. copyright cmassengale
The Plasma Membrane
Receptor-Mediated Endocytosis
9/10/2018
copyright cmassengale
G. Podgorski, Biol. 1010

45. copyright cmassengale

46. Endocytosis – Phagocytosis
The Plasma Membrane
9/10/2018
Endocytosis – Phagocytosis
Used to engulf large particles such as food, bacteria, etc. into vesicles
Called “Cell Eating”
G. Podgorski, Biol. 1010

47. copyright cmassengale

48. copyright cmassengale
The Plasma Membrane
Phagocytosis About to Occur
9/10/2018
copyright cmassengale
G. Podgorski, Biol. 1010

49. copyright cmassengale
The Plasma Membrane
9/10/2018
Phagocytosis - Capture of a Yeast Cell (yellow) by Membrane Extensions of an Immune System Cell (blue)
copyright cmassengale
G. Podgorski, Biol. 1010

50. The Plasma Membrane
9/10/2018
Exocytosis The opposite of endocytosis is exocytosis. Large molecules that are manufactured in the cell are released through the cell membrane.
Inside Cell
Cell environment
G. Podgorski, Biol. 1010