1. Cell Discovery and Theory
Section 7.1

2. Section 7.1 Summary – pages 171-174
The cell theory is made up of three main ideas:
All organisms are composed of one or more cells.
The cell is the basic unit of organization of organisms.
All cells come from preexisting cells.
Section 7.1 Summary – pages

3. Microscope Technology
Compound Light Microscope
What we use
Has a series of lenses and uses visible light to magnify an image
Electron Microscope- 1940’s
More detailed views
TEM: transmission electron microscope
SEM: scanning electron microscope
STM: scanning tunneling electron microscope
AFM: atomic force microscope

4. Cell Diversity Cells vary in shape, which relates to their function
Skin cells are flat to cover the body
Nerve cells are branched to transmit impulses
Cell size is limited by the surface area-to-volume ratio
If a cell’s volume gets too large, its exchange of substances would take too long and the cell could die

5. Section 7.1 Summary – pages 171-174
Two Basic Cell Types
Prokaryotic cells : cells that do not contain internal membrane-bound structures
Examples: Bacteria and some other single celled organisms
Blue Green Algae
Blue Green Algae
Bacteria
Section 7.1 Summary – pages

6. Prokaryotic cells
Basic structure

7. Section 7.1 Summary – pages 171-174
Two Basic Cell Types
Eukaryotic cells: contain membrane-bound structures .
Examples: all plant and animal cells – some single celled organisms
Section 7.1 Summary – pages

8. Eukaryotic cells

9. Eukaryotic v. Prokaryotic

10. Section 7.1 Summary – pages 171-174
Basic Parts of a Cell
Plasma membrane – Cell’s outer boundary
Organelles- membrane-bound structures within eukaryotic cells.
Each organelle has a specific function that contributes to cell survival.
Cytoplasm-The region within the cell
Nucleus-The central membrane-bound organelle that manages cellular functions in eukaryotes.
Cilia and Flagella- projections from a cell that aids in movement/feeding. (eukaryotic cells-external, prokaryotic-inside of plasma membrane)
Section 7.1 Summary – pages

11. The Plasma Membrane
Section 7.2

12. Purpose: To act as a barrier between a cell and its environment
To maintain homeostasis in a cell (a balance of conditions suitable for life)

13. How?
The plasma membrane is selectively permeable, so it allows certain substances (like oxygen and nutrients) in, while getting rid of others (like waste.)

14. Summary Section 2 – pages 175-178
Plasma Membrane
Oxygen
Amino acids
Water
Glucose
Wastes
Wastes
Carbon dioxide
SELECTIVE PERMEABILITY
Summary Section 2 – pages

15. It’s composed of a phospholipid bilayer
What does it look like?
It’s composed of a phospholipid bilayer
Polar heads (phosphate) on the outside
hydrophilic
Nonpolar tails (fatty acids) on the inside
hydrophobic
Two layers of phospholipids back-to-back

16. Polar heads: with phosphate group face outward and stay in contact with water inside and outside of cell
Nonpolar tails: fatty acid chains point inward toward one another.

17. The Model
The model of the p.m. is called the fluid mosaic model because the phospholipids move within the membrane and proteins in the membrane move among the phospholipids.
It’s flexible

18. What does that mean? “Fluid” means it can move “Mosaic” Animation

19. What are the other parts of the p.m.?
Cholesterol keeps the fatty acid tails from sticking together, keeps the membrane stable.
Carbohydrates stick out from the cell surface to help cells identify chemical signals.

20. Summary Section 2 – pages 175-178
Other components of the plasma membrane:
Transport proteins allow things to move through the plasma membrane.(2 types)
Channel protein – always open
Carrier protein – only open to certain substances
Summary Section 2 – pages

21. Cell Structures, Functions and Transport 7.3

22. Prokaryotic cells Eukaryotic Cells
cells that do not contain internal membrane-bound structures
Bacteria and some other single celled organisms
contain membrane-bound structures
all plant and animal cells

23. Cytoplasm
The environment inside the plasma membrane
Semifluid material
Thought to be where organelles float
Cytoskeleton
The supporting network of protein fibers that provide a framework for the cell (microfibers and microtublues)
Organelles are anchored

24. Animal Cell Figure 7-5 Plant and Animal Cells Cytoplasm Nucleolus
Section 7-2
Animal Cell
Cytoplasm
Nucleolus
Nucleus
Cell Membrane
Lysosomes
Go to Section:

25. Eukaryotic Cell Organelles and Function
Nucleus
Nickname: “The Control Center”
Function: holds the DNA
Parts:
Nucleolus: dark spot in the middle of the nucleus that helps make ribosomes

26. Animal Cell Figure 7-5 Plant and Animal Cells Cytoplasm Nucleolus
Section 7-2
Animal Cell
Cytoplasm
Nucleolus
Ribosomes
Nucleus
Cell Membrane
Lysosomes
Go to Section:

27. Eukaryotic Cell Organelles and Function
Ribosomes
Function: makes proteins
Found in all cells, prokaryotic and eukaryotic

28. Eukaryotic Cell Organelles and Function
Endoplasmic Reticulum (ER)
Nickname: “Roads”
Function: The internal delivery system of the cell

29. Animal Cell Figure 7-5 Plant and Animal Cells Cytoplasm Nucleolus
Section 7-2
Animal Cell
Cytoplasm
Nucleolus
Ribosomes
Nucleus
Cell Membrane
Smooth Endoplasmic Reticulum
Rough Endoplasmic Reticulum
Lysosomes
Go to Section:

30. Endoplasmic Reticulum
2 Types:
Rough ER:
Rough appearance because it has ribosomes
Function: helps make proteins, that’s why it has ribosomes
Smooth ER:
NO ribosomes
Function: makes fats or lipids

31. Animal Cell Figure 7-5 Plant and Animal Cells Cytoplasm Ribosomes
Section 7-2
Cytoplasm
Ribosomes
Nucleolus
Nucleus
Cell Membrane
Smooth Endoplasmic Reticulum
Rough Endoplasmic Reticulum
Golgi Complex
Lysosomes
Go to Section:

32. Eukaryotic Cell Organelles and Function
Golgi Complex
Nickname: The shippers
Function: packages, modifies, and transports materials to different location inside/outside of the cell
Appearance: stack of pancakes

33. Animal Cell Figure 7-5 Plant and Animal Cells Lysosomes Cytoplasm
Section 7-2
Cytoplasm
Nucleolus
Ribosomes
Nucleus
Cell Membrane
Smooth Endoplasmic Reticulum
Rough Endoplasmic Reticulum
Golgi Bodies
Lysosomes
Go to Section:

34. Eukaryotic Cell Organelles and Function
Lysosomes: circular, but bigger than ribosomes)
Nickname: “Clean-up Crews”
Function: to break down food into particles the rest of the cell can use and to destroy old cells

35. Animal Cell Figure 7-5 Plant and Animal Cells Cytoplasm Nucleolus
Section 7-2
Cytoplasm
Nucleolus
Ribosomes
Nucleus
Cell Membrane
Mitochondria
Rough Endoplasmic Reticulum
Smooth Endoplasmic Reticulum
Golgi Bodies
Lysosomes

36. Eukaryotic Cell Organelles and Function
Mitochondria
Nickname: “The Powerhouse”
Function: Energy formation
Breaks down food to make ATP
ATP: is the major fuel for all cell activities that require energy

38. Animal Cell Cytoplasm Nucleolus Ribosomes Nucleus Cell Membrane
Mitochondria
Rough Endoplasmic Reticulum
Smooth Endoplasmic Reticulum
Golgi Bodies
Lysosomes

39. Now let’s talk about structures only found in PLANT Cells!!

40. Plant Cell Figure 7-5 Plant and Animal Cells Vacuole Cell Membrane
Section 7-2
Vacuole
Cell Membrane
Go to Section:

41. Eukaryotic Cell Organelles and Function
Vacuoles (animals may have a much smaller vacuole)
Function: stores water
This is what makes lettuce crisp
When there is no water, the plant wilts

42. Plant Cell Figure 7-5 Plant and Animal Cells Vacuole Chloroplasts
Section 7-2
Plant Cell
Vacuole
Chloroplasts
Cell Membrane
Go to Section:

43. Eukaryotic Cell Organelles and Function
Chloroplasts
Function: traps energy from the sun to produce food for the plant cell
Green in color because of chlorophyll, which is a green pigment

44. Chloroplasts

45. Plant Cell Figure 7-5 Plant and Animal Cells Vacuole Chloroplasts
Section 7-2
Vacuole
Chloroplasts
Cell Membrane
Cell Wall
Go to Section:

46. Eukaryotic Cell Organelles and Function
Cell Wall
Function: provides support and protection to the cell membrane
Found outside the cell membrane in plant cells

47. Plant Cell Cytoplasm Vacuole Smooth ER Ribosomes Chloroplasts
Cell Membrane
Cell Wall
Nucleolus
Golgi Bodies
Nucleus
Mitochondria
Rough ER

48. Comparing Plant and Animal Cells

50. Comparing Plant, Animal and Prokaryotic Cells
Prokaryotes

51. Plant Cell Animal Cell Prokaryotic Cell Cell Wall Chloroplasts
Cytoskeleton and cytoplasm
Nucleus
Endoplasmic Reticulum
Golgi Apparatus
Vacuole
Mitochondria
Genetic Material
Plasma Membrane
Ribosomes
1) Lysosomes 2) Centrioles 3) Cytoskeleton and cytoplasm 4) Nucleus 5) Endoplasmic Reticulum 6) Golgi Apparatus 7) Vacuole 8) Mitochondria 9) Genetic Material 10) Plasma Membrane 11) Ribosomes
Prokaryotic Cell
Cytoskeleton and cytoplasm 6) Capsule
Ribosomes 7) Flagella
Plasma Membrane 8) Cillia
Cell Wall
DNA

52. Cellular Transport
Section 7.4

53. Cellular Transport Passive Transport
Movement of particles across the cell membrane without using energy
Three Modes of Passive Transport
Diffusion
Facilitated Diffusion
Osmosis

54. Passive Transport Diffusion
Movement of particles from an area of high concentration to an area of lower concentration

55. Passive Transport Diffusion is controlled by Temperature Pressure
Concentration
Dynamic Equilibrium
Reached when diffusion of material into the cell equals diffusion of material out of the cell
Molecules continue to move, but the overall concentration remains the same.

56. Passive Transport
Diffusion in a Cell

57. Passive Transport Facilitated Diffusion
Movement of materials across the plasma membrane using proteins

58. Passive Transport- Facilitated Diffusion
Channel Proteins
always open to allow certain substances to pass down their concentration gradient
Carrier Proteins
change shape as diffusion continues to help move the particle through the membrane

59. Passive Transport -Video Clip
Diffusion: Channel and Carrier Proteins

60. Passive Transport Osmosis
Diffusion of water across a selectively permeable membrane
Three Types of Solutions
Isotonic
Hypotonic
Hypertonic
Isotonic, Hypotonic, Hypertonic Solutions -Video Clip

61. Passive Transport Isotonic Solution
Water and dissolved substances diffuse into and out of the cell at the same rate.
Plant Cell

62. Passive Transport Hypotonic Solution
Solute concentration is higher inside the cell.
Water diffuses into the cell.
Plant Cell

63. Passive Transport Hypertonic Solution
Solute concentration is higher outside the cell.
Water diffuses out of the cell.
Plant Cell

64. Cellular Transport
Active Transport

65. Active Transport Using Carrier Proteins
Cellular Transport
Active Transport
Movement of particles across the cell membrane using energy; going from low to high concentration
Active Transport Using Carrier Proteins
Against the concentration gradient

66. Active Transport Types of Active Transport Pumps Na+/K+ ATPase pump
Moves three Na+ ions out of the cell and two K+ ions into the cell
Sodium-Potassium Pump-Video Clip

67. Active Transport Endocytosis
Process by which the cell surrounds and takes particles into the cell
Exocytosis
Secretion of material out of the plasma membrane
VIDEO