1. Movement Through the Cell Membrane

2. Cell Membrane
The thin flexible barrier around the cell that controls what enters/exits.
Selectively (semi) permeable- some substances can pass and others cannot

3. Cell membrane is made up of:
Lipid bi-layer- two layers of fat (Fence)
Protein channels- that move materials across. (Gates)
Carbohydrates- act as chemical identification cards so other cells to identify one another. (Security)
Watch

6. Cell Membrane Functions
The Plasma Membrane
12/31/2018
Cell Membrane Functions
1. Protective barrier
2. Regulate transport in & out of cell (selectively permeable)
3.Allow cell recognition
4. Provide anchoring sites for cytoskeleton
copyright cmassengale
G. Podgorski, Biol. 1010

7. Overview
Cell membrane separates living cell from nonliving surroundings
thin barrier = 8nm thick
Controls traffic in & out of the cell
selectively permeable
allows some substances to cross more easily than others
hydrophobic vs hydrophilic
Made of phospholipids, proteins & other macromolecules

8. Phospholipids Fatty acid tails Phosphate group head
hydrophobic
Phosphate group head
hydrophilic
Arranged as a bilayer
Fatty acid
Aaaah, one of those structure–function
examples

9. Phospholipid bilayer polar hydrophilic heads nonpolar hydrophobic
tails
polar
hydrophilic
heads

10. More than lipids… It’s like a fluid… It’s like a mosaic…
It’s the Fluid Mosaic Model!

11. Membrane fat composition varies
Fat composition affects flexibility
membrane must be fluid & flexible
about as fluid as thick salad oil
% unsaturated fatty acids in phospholipids
keep membrane less viscous
cold-adapted organisms, like winter wheat
increase % in autumn
cholesterol in membrane

12. Membrane is a collage of proteins & other molecules embedded in the fluid matrix of the lipid bilayer
Extracellular fluid
Glycoprotein
Carbohydrate
Glycolipid
Phospholipids
Transmembrane
proteins
The carbohydrates are not inserted into the membrane -- they are too hydrophilic for that. They are attached to embedded proteins -- glycoproteins.
Filaments of cytoskeleton
Cholesterol
Phospholipids
Peripheral
protein
Cytoplasm

13. Summarize the structure of the plasma membrane.
Write your answer in box #1

14. Membrane Proteins Proteins determine membrane’s specific functions
cell membrane & organelle membranes each have unique collections of proteins
Membrane proteins:
peripheral proteins
loosely bound to surface of membrane
cell surface identity marker (antigens)
integral proteins
penetrate lipid bilayer, usually across whole membrane
transport proteins
channels, permeases (pumps)

15. Many Functions of Membrane Proteins
Outside
Plasma
membrane
Inside
Transporter
Enzyme activity
Cell surface receptor
Signal transduction - transmitting a signal from outside the cell to the cell nucleus, like receiving a hormone which triggers a receptor on the inside of the cell that then signals to the nucleus that a protein must be made.
Cell surface identity marker
Cell adhesion
Attachment to the cytoskeleton

16. In box #2, write down the functions of membrane proteins, and why some go all the way through the membrane

17. 3 Types of Cell transport
1. Diffusion (includes osmosis)
2. Facilitated Diffusion
3. Active Transport
(VOCAB NOTE-concentration gradient is the difference in concentration of a substance across a membrane)

18. 1A.Diffusion
Movement of molecules(across concentration gradient) from an area of high concentration to an area of low concentration.
Require no energy (because molecules randomly move on their own)
Does this until equilibrium (equal concentration on both sides of the membrane)
Watch

19. Diffusion

20. Diffusion Animation

21. 1B. Osmosis
Osmosis animation
Diffusion of WATER across a semi-permeable membrane from an area of high concentration to an area of low concentration
Water moves freely through pores.
Solute (green) to large to move across.

22. Osmosis

23. Diffusion across cell membrane
Cell membrane is the boundary between inside & outside…
separates cell from its environment
Can it be an impenetrable boundary?
NO!
OUT
waste
ammonia
salts
CO2
H2O
products IN
food
carbohydrates
sugars, proteins
amino acids
lipids
salts, O2, H2O
OUT IN
cell needs materials in & products or waste out

24. Diffusion through phospholipid bilayer
What molecules can get through directly?
fats & other lipids
What molecules can NOT get through directly?
polar molecules
H2O
ions
salts, ammonia
large molecules
starches, proteins
lipid
inside cell
outside cell
salt
NH3
sugar aa
H2O

25. Summarize what can and cannot cross through the membrane in box #4.

26. What’s wrong with this poster? (tell your face partner)

27. Facilitated diffusion (Channel Protein) Diffusion (Lipid Bilayer)
2. Facilitated diffusion: diffusion of specific particles through transport proteins found in the membrane
Transport Proteins are specific – they “select” only certain molecules to cross the membrane
Transports larger or charged molecules
Facilitated diffusion (Channel Protein)
Diffusion (Lipid Bilayer)
Carrier Protein

28. 2. Facilitated Diffusion(continued)
Glucose
molecules
Cellular Transport From a-
High
High Concentration
Channel Proteins animations
Cell Membrane
Low Concentration
Protein
channel
Low
Transport Protein
Through a 
Go to Section:

29. 2. Facilitated Diffusion
The Plasma Membrane
12/31/2018
2. Facilitated Diffusion
Molecules will randomly move through the pores in Channel Proteins.
copyright cmassengale
G. Podgorski, Biol. 1010

30. Facilitated Diffusion Animation

31. 2. Facilitated Diffusion
The Plasma Membrane
2. Facilitated Diffusion
12/31/2018
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. Protein changes shape to move molecules: this requires energy!
Active Transport
Sodium Potassium Pumps (Active Transport using proteins)
1. Protein Pumps -transport proteins that require energy to do work
Protein changes shape to move molecules: this requires energy!

34. Types of Active Transport
2. Endocytosis: taking bulky material into a cell
Moves AGAINST concentration gradient
Uses energy
Cell membrane in-folds around food particle
forms food vacuole & digests food

35. Active Transports

36. copyright cmassengale
The Plasma Membrane
Moving the “Big Stuff”
12/31/2018
Large molecules move materials into the cell by one of three forms of endocytosis.
copyright cmassengale
G. Podgorski, Biol. 1010

37. Types of Active Transport
3. Exocytosis: Forces material out of cell in bulk
membrane surrounding the material fuses with cell membrane
Cell changes shape – requires energy
EX: Hormones or wastes released from cell in vesicles
Endocytosis & Exocytosis animations

38. Moving the “Big Stuff” Exocytosis- moving things out.
The Plasma Membrane
Moving the “Big Stuff”
12/31/2018
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

39. copyright cmassengale
The Plasma Membrane
Exocytosis
12/31/2018
Exocytic vesicle immediately after fusion with plasma membrane.
copyright cmassengale
G. Podgorski, Biol. 1010

40. Osmosis Animations for isotonic, hypertonic, and hypotonic solutions
Hypotonic: The solution has a lower concentration of solutes and a higher concentration of water than inside the cell. (Low solute; High water)
Result: Water moves from the solution to inside the cell. Cell Swells and bursts open (cytolysis)!

41. Osmosis Animations for isotonic, hypertonic, and hypotonic solutions
Hypertonic Solution
Hypertonic: The solution has a higher concentration of solutes and a lower concentration of water than inside the cell. (High solute; Low water)
shrinks
Result: Water moves out of cell the cell into the solution: Cell shrinks (Plasmolysis)!

42. Plasmolysis Video https://www.youtube.com/watch?v=4JyT__Dea8Q

43. Osmosis Animations for isotonic, hypertonic, and hypotonic solutions
Isotonic Solution
Isotonic: The concentration of solutes in the solution is equal to the concentration of solutes inside the cell.
Result: Water moves equally in both directions and the cell remains same size! (Dynamic Equilibrium)