1. Cell Structure and Transport

2. 7-1 Objectives Describe the tenets of the cell theory
Compare the characteristics of prokaryotic and eukaryotic cells
Describe the parts of a light and electron microscope

3. All organisms are composed of one or more cells.
Chapter 7
Cellular Structure and Function
7.1 Cell Discovery and Theory
The Cell Theory
All organisms are composed of one or more cells.
The cell is the basic unit of structure and organization of organisms.
All cells come from preexisting cells.

4. All cells have a plasma membrane Prokaryotic Cell
Chapter 7
Cellular Structure and Function
7.1 Cell Discovery and Theory
Basic Cell Types
All cells have a plasma membrane
Prokaryotic Cell
Simple structure
Contains a plasma membrane
Does not contain membrane-bound organelles
No nucleus
11,000x

8. More complex structure
Chapter 7
Cellular Structure and Function
7.1 Cell Discovery and Theory
Eukaryotic Cell
More complex structure
Contains a plasma membrane
Membrane cell organelles

15. 7.2 The Plasma Membrane Objectives
Describe how a cell’s plasma membrane functions
Identify the roles of proteins, carbohydrates, and cholesterol in the plasma membrane

16. Thin, flexible boundary between the cell and its environment
Chapter 7
Cellular Structure and Function
7.2 The Plasma Membrane
Plasma Membrane
Thin, flexible boundary between the cell and its environment

17. Selective Permeability
Chapter 7
Cellular Structure and Function
7.2 The Plasma Membrane
Selective Permeability
The plasma membrane controls the movement of
substances into
and out of the cell.

18. The plasma membrane is composed of the phospholipid bilayer.
Chapter 7
Cellular Structure and Function
7.2 The Plasma Membrane
The plasma membrane is composed of the phospholipid bilayer.

19. “float” in the membrane.
Chapter 7
Cellular Structure and Function
7.2 The Plasma Membrane
Fluid Mosaic Model
“float” in the membrane.
Other Components
Proteins
Cholesterol
Carbohydrates

20. Transmit signals inside the cell support structure
Chapter 7
Cellular Structure and Function
7.2 The Plasma Membrane
Proteins
Transmit signals inside the cell
support structure
Provide pathways for substances to enter and leave

21. Prevents fatty acid tails from sticking together
Chapter 7
Cellular Structure and Function
7.2 The Plasma Membrane
Cholesterol
Prevents fatty acid tails from sticking together

22. Identify chemical signals
Chapter 7
Cellular Structure and Function
7.2 The Plasma Membrane
Carbohydrates
Identify chemical signals

23. Plasma membrane

24. 7.3 Structures and Organelles
Objectives 1. Identify the structure and function of the parts of a typical eukaryotic cell. 2. Compare and contrast structures of plant and animal cells.

25. Plant and Animal Cell Structures
Chapter 7
Cellular Structure and Function
7.3 Structures and Organelles
Plant and Animal Cell Structures
Plant Cell
Animal Cell

26. 7.3 Structures and Organelles
Chapter 7
Cellular Structure and Function
7.3 Structures and Organelles

27. 7.3 Structures and Organelles
Chapter 7
Cellular Structure and Function
7.3 Structures and Organelles

28. 7.3 Structures and Organelles
Chapter 7
Cellular Structure and Function
7.3 Structures and Organelles

29. 7.3 Structures and Organelles
Chapter 7
Cellular Structure and Function
7.3 Structures and Organelles

30. Short, numerous projections that look like hairs
Chapter 7
Cellular Structure and Function
7.3 Structures and Organelles
Cilia
Short, numerous projections that look like hairs
400x
Flagella
Longer and less numerous than cilia
Create movement with a whiplike motion
26,367x

31. Summary of cell parts

32. 7.4 Cellular Transport Objectives
Explain the processes of diffusion, facilitated diffusion, and active transport
Predict the effect of a hypotonic, hypertonic, or isotonic solution on a cell
Discuss how large particles enter and exit cells

33. Cell Membranes & Movement Across Them

34. Cell (plasma) membrane
Cells need an inside & an outside…
separate cell from its environment
cell membrane is the boundary IN
food
- sugars
- proteins
- fats
salts O2
H2O
OUT
waste
- ammonia
- salts
- CO2
- H2O
products
- proteins
cell needs materials in & products or waste out

35. Building a membrane
How do you build a barrier that keeps the watery contents of the cell separate from the watery environment?
 FATS 
 LIPIDS 
Remember: oil & water don’t mix!!
What substance do you know that doesn’t mix with water?

36. Lipids of cell membrane
Membrane is made of special kind of lipid
phospholipids
“split personality”
Membrane is a double layer
phospholipid bilayer
“attracted to water”
phosphate
inside cell
outside cell
lipid
“repelled by water”

37. Semi-permeable membrane
Cell membrane controls what gets in or out
Need to allow some materials — but not all — to pass through the membrane
semi-permeable
only some material can get in or out
So what needs to get across the membrane?
sugar
lipids aa O2
H2O
salt
waste

38. Crossing the cell membrane
What molecules can get through the cell membrane directly?
fats and oils can pass directly through
lipid
inside cell
outside cell
salt
waste
but…
what about other stuff?
sugar aa
H2O

39. Cell membrane channels
Need to make “doors” through membrane
protein channels allow substances in & out
specific channels allow specific material in & out
H2O channel, salt channel, sugar channel, etc.
inside cell
H2O aa
sugar
salt
outside cell
waste

40. How do you build a semi-permeable cell membrane?
Channels are made of proteins
proteins both “like” water & “like” lipids
bi-lipid
membrane
protein channels in bi-lipid membrane

41. Protein channels Proteins act as doors in the membrane
channels to move specific molecules through cell membrane
HIGH
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, aquaprorins, facilitate massive amounts of diffusion.
LOW

42. Movement through the channel
Why do molecules move through membrane if you give them a channel?
HIGH ?
LOW ?

43. Molecules move from high to low
Diffusion
move from HIGH to LOW concentration
Movement from high concentration of that substance to low concentration of that substance.

44. Diffusion Move from HIGH to LOW concentration diffusion of water
passive transport
no energy needed
diffusion of water
diffusion
osmosis

45. Simple Diffusion Move from HIGH to LOW LOW HIGH
fat
fat
fat
Which way will fat move?
inside cell
fat
fat
fat
LOW
HIGH
fat
outside cell
fat
fat
fat
fat
fat
fat
fat

46. Facilitated Diffusion
Move from HIGH to LOW through a channel
sugar
sugar
sugar
sugar
inside cell
sugar
sugar
LOW
Which way will sugar move?
HIGH
outside cell
sugar
sugar
sugar
sugar
sugar
sugar
sugar

47. Diffusion Move from HIGH to LOW concentration
directly through membrane
simple diffusion
no energy needed
help through a protein channel
facilitated diffusion (with help)
HIGH
LOW

48. Simple vs. facilitated diffusion
simple diffusion
facilitated diffusion
lipid
inside cell
outside cell
inside cell
outside cell
H2O
protein channel
H2O

49. Active transport
Cells may need molecules to move against concentration “hill”
need to pump “uphill”
from LOW to HIGH using energy
protein pump
requires energy
ATP
Plants have nitrate & phosphate pumps in their roots.
Why?
Nitrate for amino acids
Phosphate for DNA & membranes
Not coincidentally these are the main constituents of fertilizer.
ATP

50. Transport summary simple diffusion facilitated diffusion
ATP
active transport

51. Osmosis Movement of Water Across Cell Membrane

52. Osmosis Water is very important, so we talk about water separately
diffusion of water from HIGH concentration of water to LOW concentration of water
across a semi-permeable membrane

53. Keeping water balance
Cell survival depends on balancing water uptake & water loss
freshwater
balanced
saltwater

54. Keeping right amount of water in cell1
Keeping right amount of water in cell
Freshwater
a cell in fresh water
high concentration of water around cell
cell gains water
example: Paramecium
problem: cells gain water, swell & can burst
water continually enters Paramecium cell
solution: contractile vacuole
pumps water out of cell
KABOOM!
freshwater
No problem, here

55. Controlling water
Contractile vacuole in Paramecium

56. Keeping right amount of water in cell2
Keeping right amount of water in cell
Saltwater
a cell in salt water
low concentration of water around cell
cell loses water
example: shellfish
problem: cell loses water
in plants: plasmolysis
in animals: shrinking cell
solution: take up water
I’m shrinking, I’m shrinking!
saltwater
I will survive!

57. Keeping right amount of water in cell3
Keeping right amount of water in cell
Balanced conditions
no difference in concentration of water between cell & environment
cell in equilibrium
example: blood
problem: none
water flows across membrane equally, in both directions
volume of cell doesn’t change
That’s better!
balanced
I could be better…

58. Ice Fishing in Barrow