1. A Closer Look At Cell Membranes Ch.5 OCC BIO-161

2. Intro Video
The Cell Membrane
Active and Passive Transport

3. 5.1 The Structure of Membranes
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
(Fig 5.1)

4. Phospholipids (Fig 5.1) Fatty acid tails Phosphate group head
hydrophobic
Phosphate group head
hydrophilic
Arranged as a bilayer
Fatty acid

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

6. More than lipids…
In 1972, S.J. Singer & G. Nicolson proposed that membrane proteins are inserted into the phospholipid bilayer = Fluid Mosaic Model

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

8. 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

9. Membrane Proteins (Table 5.1)
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
transmembrane protein
transport proteins
channels, permeases (pumps)

10. Why are proteins the perfect molecule to build structures in the cell membrane?

11. nonpolar & hydrophobic
Classes of amino acids
What do these amino acids have in common?
nonpolar & hydrophobic

12. Classes of amino acids What do these amino acids have in common?
polar & hydrophilic

13. Proteins domains anchor molecule (Fig 5.5)
Within membrane
nonpolar amino acids
hydrophobic
anchors protein into membrane
On outer surfaces of membrane
polar amino acids
hydrophilic
extend into extracellular fluid & into cytosol
Polar areas
of protein
Nonpolar areas of protein

14. Examples water channel in bacteria
NH2 H+
COOH
Cytoplasm
Retinal
chromophore
Nonpolar
(hydrophobic)
a-helices in the
cell membrane
Examples
water channel in bacteria
Porin monomer
b-pleated sheets
Bacterial
outer
membrane
proton pump channel in photosynthetic bacteria
function through conformational change = shape change

15. Many Functions of Membrane Proteins (Fig 5.5)
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. Membrane carbohydrates
Play a key role in cell-cell recognition
ability of a cell to distinguish one cell from another
antigens
important in organ & tissue development
basis for rejection of foreign cells by immune system
The four human blood groups (A, B, AB, and O) differ in the external carbohydrates on red blood cells.

18. 5.4-5.5 Movement across the Cell Membrane

19. Diffusion 2nd Law of Thermodynamics governs biological systems
universe tends towards disorder (entropy)
Movement from high concentration of that substance to low concentration of that substance.
Diffusion
movement from high  low concentration

20. Diffusion (Fig 5.11) Move from HIGH to LOW concentration
“passive transport”
no energy needed
movement of water
diffusion
osmosis

21. 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

22. 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

23. Channels through cell membrane
Membrane becomes semi-permeable with protein channels
specific channels allow specific material across cell membrane
inside cell
H2O aa
sugar
salt
outside cell
NH3

24. Facilitated Diffusion (Fig 5.10)
Diffusion through protein channels
channels move specific molecules across cell membrane
no energy needed
facilitated = with help
open channel = fast transport
high
low
Donuts!
Each transport protein is specific as to the substances that it will translocate (move).
For example, the glucose transport protein in the liver will carry glucose from the blood to the cytoplasm, but not fructose, its structural isomer.
Some transport proteins have a hydrophilic channel that certain molecules or ions can use as a tunnel through the membrane -- simply provide corridors allowing a specific molecule or ion to cross the membrane.
These channel proteins allow fast transport.
For example, water channel proteins, aquaporins, facilitate massive amounts of diffusion.
“The Bouncer”

25. conformational change
Active Transport
Cells may need to move molecules against concentration gradient
shape change transports solute from one side of membrane to other
protein “pump”
“costs” energy = ATP
conformational change
low
high
Some transport proteins do not provide channels but appear to actually translocate the solute-binding site and solute across the membrane as the protein changes shape. These shape changes could be triggered by the binding and release of the transported molecule. This is model for active transport.
ATP
“The Doorman”

26. Active transport Many models & mechanisms ATP ATP antiport symport
Plants: nitrate & phosphate pumps in roots.
Why?
Nitrate for amino acids
Phosphate for DNA & membranes
Not coincidentally these are the main constituents of fertilizer
Supplying these nutrients to plants
Replenishing the soil since plants are depleting it
antiport
symport

27. Getting through cell membrane
Passive Transport
Simple diffusion
diffusion of nonpolar, hydrophobic molecules
lipids
high  low concentration gradient
Facilitated transport
diffusion of polar, hydrophilic molecules
through a protein channel
Active transport
diffusion against concentration gradient
low  high
uses a protein pump
requires ATP
ATP

28. Transport summary simple diffusion facilitated diffusion
ATP
active transport

29. 5.6 How about large molecules? (Fig 5.13)
Moving large molecules into & out of cell
through vesicles & vacuoles
endocytosis
phagocytosis = “cellular eating”
pinocytosis = “cellular drinking”
exocytosis
exocytosis

30. Endocytosis (Fig 5.15 & 5.16) fuse with lysosome for digestion
phagocytosis
non-specific process
pinocytosis
triggered by molecular signal
receptor-mediated endocytosis

31. Which Way Will Water Move? Movement of water across the cell membrane

32. Osmosis is diffusion of water (Fig 5.9)
Water is very important to life, so we talk about water separately
Diffusion of water from high concentration of water to low concentration of water
across a semi-permeable membrane

33. Concentration of water (Fig 5.12)
Direction of osmosis is determined by comparing total solute concentrations
Hypertonic - more solute, less water
Hypotonic - less solute, more water
Isotonic - equal solute, equal water
hypotonic
hypertonic
water
net movement of water

34. Managing water balance
Cell survival depends on balancing water uptake & loss
freshwater
balanced
saltwater

35. Managing water balance
Isotonic
animal cell immersed in mild salt solution
example: blood cells in blood plasma
problem: none
no net movement of water
flows across membrane equally, in both directions
volume of cell is stable
balanced

36. Managing water balance
Hypotonic
a cell in fresh water
example: Paramecium
problem: gains water, swells & can burst
water continually enters Paramecium cell
solution: contractile vacuole
pumps water out of cell
ATP
plant cells
turgid
ATP
freshwater

37. Water regulation
Contractile vacuole in Paramecium
ATP

38. Managing water balance
Hypertonic
a cell in salt water
example: shellfish
problem: lose water & die
solution: take up water or pump out salt
plant cells
plasmolysis = wilt
Red Blood Cells in Hypertonic Solution
Red Blood Cells in Hypotonic Solution
saltwater

39. Osmosis…
.05 M
.03 M
Cell (compared to beaker)  hypertonic or hypotonic
Beaker (compared to cell)  hypertonic or hypotonic
Which way does the water flow?  in or out of cell