1. Cellular Structure and Function Chapter 7

2. 7.1: Cell Discovery and Theory MAIN IDEA: The invention of the microscope led to the discovery of cells.

3. Types of Microscopes  Light Microscopes Light waves pass through small organisms, or thin slices of larger ones Simple – one set of lenses (magnifying glass) Complex – more than one set of lenses Magnify up to 1500 times Dyes often used – kill/distort cells

4. Types of Microscopes cont’d  Phase contrast microscope Type of light microscope Increases contrast – difference btwn light/dark Cell structures more visible Can study living cells and processes

5. Electron Microscopes  Use electron beams instead of light beams  High magnification  View image on screen: micrograph  2 Types: Transmission electron microscope (TEM) – electron beam passed through thin slice of specimen; up to 1 million X magnification Scanning electron microscope (SEM) – views surface of specimen

6. 1.Light 2.Phase contrast 3.TEM 4.SEM 1 2 3 4

7. Compound Light Microscope

8. Early Scientists…  1665 – Robert Hooke Also made microscopes Examined cork – discovered cells  1600s – Anton von Leeuwenhoek (Dutch lens maker) – made simple microscopes Observed tiny organisms (bacteria, insect structure, etc.)  Scientists focused only on cell itself

9. Cell Theory Discovered!  1700s – 1800s - 2 German biologists: Matthias Schleiden and Theodor Schwann discovered cell theory  Schwann emphasized contents of cells, found similarities between plant and animal cells  1864 – Louis Pasteur disproved spontaneous generation  By 1880s – scientists could show how cells divide

10. Cell Theory 1.All living things are made of one or more cells. 2.Cells are the units of structure and function in all organisms. 3.All cells come from pre- existing cells.

11. Cells – Units of Life  Cell – basic unit of life; in ALL organisms: Unicellular (one-celled) Multicellular (many cells, some with special functions)  Complex organisms: cells  tissues  organs  body systems  organism

12. 2 Main Cell Types Prokaryotes  “Pro-” = early  Simple cells  No nucleus  No membrane- bound organelles Eukaryotes  “you”  More complex cells  Have a nucleus  May have other organelles (other membrane-bound cell structures w/specific jobs)

13. Prokaryotes  Microscopic:.1 – 10 micrometers – billions in a spoonful of soil, or in your mouth!  Can live in extreme environments  Bacteria  Has DNA, ribosomes, plasma membrane  Some have cell walls, flagella  Divide rapidly  Will not form tissues

14. Prokaryote

15. Eukaryotes  Larger – about 2-100 micrometers, some even larger (neurons, frog eggs)  Contain membran-bound organelles: structures for organization Allow for different reactions to occur in cell at once b/c separate from each other All have different functions Cells can form tissues

16. Eukaryote

17. 7.2: The Plasma Membrane MAIN IDEA: A cell’s plasma membrane helps maintain homeostasis.

18. Plasma Membrane  Thin, flexible boundary between the cell and its environment  Allows nutrients into the cell  Allows waste to leave the cell

19. Selective Permeability  Ability of plasma membrane to control which substances, and how much of them, enter and leave a cell

20. Composition of Membrane  Made of phospholipids which form a double layer (phospholipid bilayer)

21. One Phospholipid

22. Phospholipid Bilayer

23. Fluid Mosaic Model  The phospholipid bilayer allows other molecules to “float” in the membrane. Proteins, cholesterol, carbohydrates

24. Proteins  Transmit signals inside the cell  Act as support structures  Provide pathways for substances to enter and leave the cell

25. Cholesterol  Prevent fatty acid tails from sticking together

26. Carbohydrates  Identify chemical signals

27. 7.3: Cell Structures and Organelles MAIN IDEA: The eukaryotic cell contains organelles.

28. 2 Main Eukaryotic Cell Types  Animal and Plant cells  Many of the same organelles, but some different from each other

31. Main Differences Animal Cells  Contain centrioles  Contain lysosomes  NO cell wall  NO central vacuole (only small ones)  NO chloroplasts Plant Cells  NO centrioles  NO lysosomes  Contain cell wall  Contain central vacuole  Contain chloroplasts

32. 7.4 – Cellular Transport MAIN IDEA: Cellular transport moves substances within a cell, and moves substances into and out of cells.

33. Passive Transport  Movement of particles across cell membrane without using energy  3 Types: Diffusion Facilitated Diffusion Osmosis

34. Diffusion  Movement of particles from an area of high concentration to an area of low concentration

35. Concentration Gradient

36. Diffusion Controlled By…  Temperature  Concentration  Pressure  ALL of the above, when increased, increase the amount of collisions particles have with each other, so diffusion occurs more rapidly.

37. Diffusion and Cells  Diffusion allows for… Some substances to pass into and out of cells Substances to spread out within cells  Dynamic Equilibrium Diffusion into cell = diffusion out of cell Concentration on either side of membrane is equal, although movement of particles continues

38. Diffusion in a Cell

39. Facilitated Diffusion  Movement of particles across a plasma membrane using proteins  Proteins are specific to certain particles Channel Proteins – span membrane so particles do not come into contact with nonpolar tails; effective for ion transport Carrier Proteins – physically bind particles on one side of membrane, and release them on other, changing shape; used for ions, sugars, amino acids

40. Cellular Structure and Function Carrier Proteins Channel Proteins Facilitated Diffusion

41. Osmosis  Diffusion of WATER across selectively permeable membrane, from high concentration to low concentration

42. Osmosis

43. 3 Types of Solutions  Isotonic  Hypotonic  Hypertonic

44. Isotonic Solution  Water and dissolved substances diffuse into and out of the cell at the same rate.; concentrations equal; cell size, pressure stays the same Plant Cell Blood Cell

45. Hypotonic Solution  Solute concentration is higher inside the cell than in the solution  Water diffuses into the cell; cell swells  Plant cells don’t burst (b/c of cell wall) Plant Cell Blood Cell

46. Hypertonic Solution  Solute concentration is higher outside the cell than in the solution  Water diffuses out of the cell (shrinks) Plant Cell Blood Cell

47. Active Transport  Movement of substances AGAINST the concentration gradient (____ to _____ concentration)  Requires energy  Helps cell maintain homeostasis  Uses carrier proteins called pumps  Some move substances only one way, some move them both ways

48. Active Transport and Proteins

49. Transport of Large Particles  Endocytosis – cell surrounds substance outside of cells, encloses it in a sac/vesicle, and takes it into the cell  Exocytosis – vesicle with a substance is released from the cell

50. Endocytosis

51. Exocytosis