1. Cell Structure and Function 1

2. Agre and cells in the news 2

3. Cells Smallest living unit Most are microscopic 3

4. Discovery of Cells Robert Hooke (mid-1600s) –Observed sliver of cork –Saw “row of empty boxes” –Coined the term cell 4

5. Cell theory (1839)Theodor Schwann & Matthias Schleiden “ all living things are made of cells” (50 yrs. later) Rudolf Virchow “all cells come from cells” 5

6. Principles of Cell Theory All living things are made of cells Smallest living unit of structure and function of all organisms is the cell All cells arise from preexisting cells (this principle discarded the idea of spontaneous generation) 6

7. Cell Size 7

8. Cells Have Large Surface Area-to-Volume Ratio 8

9. Characteristics of All Cells A surrounding membrane Protoplasm – cell contents in thick fluid Organelles – structures for cell function Control center with DNA 9

10. Cell Types Prokaryotic Eukaryotic 10

11. Prokaryotic Cells First cell type on earth Cell type of Bacteria and Archaea 11

12. Prokaryotic Cells No membrane bound nucleus Nucleoid = region of DNA concentration Organelles not bound by membranes 12

13. Eukaryotic Cells Nucleus bound by membrane Include fungi, protists, plant, and animal cells Possess many organelles Protozoan 13

14. Representative Animal Cell 14

15. Representative Plant Cell 15

16. Organelles Cellular machinery Two general kinds –Derived from membranes –Bacteria-like organelles 16

17. Bacteria-Like Organelles Derived from symbiotic bacteria Ancient association Endosymbiotic theory –Evolution of modern cells from cells & symbiotic bacteria 17

18. Plasma Membrane Contains cell contents Double layer of phospholipids & proteins 18

19. Phospholipids Polar –Hydrophylic head –Hydrophobic tail Interacts with water 19

20. Movement Across the Plasma Membrane A few molecules move freely –Water, Carbon dioxide, Ammonia, Oxygen Carrier proteins transport some molecules –Proteins embedded in lipid bilayer –Fluid mosaic model – describes fluid nature of a lipid bilayer with proteins 20

21. 21

22. Membrane Proteins 1. Channels or transporters –Move molecules in one direction 2. Receptors –Recognize certain chemicals 22

23. Membrane Proteins 3. Glycoproteins –Identify cell type 4. Enzymes –Catalyze production of substances 23

24. Cell Walls Found in plants, fungi, & many protists Surrounds plasma membrane 24

25. Cell Wall Differences Plants – mostly cellulose Fungi – contain chitin 25

26. Cytoplasm Viscous fluid containing organelles components of cytoplasm –Interconnected filaments & fibers –Fluid = cytosol –Organelles (not nucleus) – storage substances 26

27. Cytoskeleton Filaments & fibers Made of 3 fiber types –Microfilaments –Microtubules –Intermediate filaments 3 functions: – mechanical support – anchor organelles – help move substances 27

28. Actin Found inside of filaments Actin is a globular multi-functional protein that forms microfilaments. It is found in all eukaryotic cells. 28

29. A = actin, IF = intermediate filament, MT = microtubule 29

30. Cilia & Flagella Provide motility Cilia –Short –Used to move substances outside human cells Flagella –Whip-like extensions –Found on sperm cells Basal bodies like centrioles 30

31. Cilia & Flagella Structure Bundles of microtubules With plasma membrane 31

32. Centrioles Pairs of microtubular structures Play a role in cell division 32

33. Membranous Organelles Functional components within cytoplasm Bound by membranes 33

34. Nucleus Control center of cell Double membrane Contains –Chromosomes –Nucleolus 34

35. Nuclear Envelope Separates nucleus from rest of cell Double membrane Has pores 35

36. DNA Hereditary material Chromosomes –DNA –Protiens –Form for cell division Chromatin 36

37. Nucleolus Most cells have 2 or more Directs synthesis of RNA Forms ribosomes 37

38. Endoplasmic Reticulum Helps move substances within cells Network of interconnected membranes Two types –Rough endoplasmic reticulum –Smooth endoplasmic reticulum 38

39. Rough Endoplasmic Reticulum Ribosomes attached to surface –Has NON-FREE RIBOSOMES –Manufacture protiens –Not all ribosomes attached to rough ER May modify proteins from ribosomes 39

40. Smooth Endoplasmic Reticulum No attached ribosomes Has enzymes that help build molecules –Carbohydrates –Lipids 40

41. Golgi Apparatus Involved in synthesis of plant cell wall Packaging & shipping station of cell 41

42. Golgi Apparatus Function 1. Molecules come in vesicles 2. Vesicles fuse with Golgi membrane 3. Molecules may be modified by Golgi 42

43. Golgi Apparatus Function (Continued) 4. Molecules pinched-off in separate vesicle 5. Vesicle leaves Golgi apparatus 6. Vesicles may combine with plasma membrane to secrete contents 43

44. 44

45. Lysosomes Contain digestive enzymes Functions –Aid in cell renewal –Break down old cell parts –Digests invaders 45

46. Vacuoles Membrane bound storage sacs More common in plants than animals Contents –Water –Food –wastes 46

47. Bacteria-Like Organelles Release & store energy Types –Mitochondria (release energy) –Chloroplasts (store energy) 47

48. Mitochondria Have their own DNA Bound by double membrane 48

49. Mitochondria Break down fuel molecules ( cellular respiration) –Glucose –Fatty acids Release energy –ATP 49

50. Chloroplasts Derived form photosynthetic bacteria Solar energy capturing organelle 50

51. Photosynthesis Takes place in the chloroplast Makes cellular food – glucose 51

52. Review of Eukaryotic Cells 52

53. Review of Eukaryotic Cells 53

54. 54

55. Molecule Movement & Cells Passive Transport Active Transport Endocytosis ( phagocytosis & pinocytosis) Exocytosis 55

56. Passive Transport No energy required Move due to gradient –differences in concentration, pressure, charge Move to equalize gradient –High moves toward low 56

57. Types of Passive Transport 1. Diffusion 2. Osmosis 3. Facilitated diffusion 57

58. Diffusion Molecules move to equalize concentration 58

59. Osmosis Special form of diffusion Fluid flows from lower solute concentration Often involves movement of water –Into cell –Out of cell 59

60. Solution Differences & Cells solvent + solute = solution Hypotonic –Solutes in cell more than outside –Outside solvent will flow into cell Isotonic –Solutes equal inside & out of cell Hypertonic –Solutes greater outside cell –Fluid will flow out of cell 60

61. 61

62. Facilitated Diffusion Differentially permeable membrane Channels (are specific) help molecule or ions enter or leave the cell Channels usually are transport proteins (aquaporins facilitate the movement of water) No energy is used 62

63. Process of Facilitated Transport Protein binds with molecule Shape of protein changes Molecule moves across membrane 63

64. Active Transport Molecular movement Requires energy (against gradient) Example is sodium-potassium pump 64

65. Cell Permeability Passive transport is carrier mediated –Facilitated diffusion –Solute molecule combines with a “carrier” or transporter –Electrochemical gradients determines the direction –Integral membrane proteins form channels 65

66. Crossing the Membrane Simple or passive diffusion Passive transport –Channels or pores Facilitated transport –Assisted by membrane-floating proteins Active transport pumps and carriers –ATP is required –Enzymes and reactions may be required 66

67. Modes of Transport 67

68. Carrier-Mediated Transport Integral protein binds to the solute and undergo a conformational change to transport the solute across the membrane T 68

69. Channel Mediated Transport Proteins form aqueous pores allowing specific solutes to pass across the membrane Allow much faster transport than carrier proteins 69

70. Coupled Transport Some solutes “go along for the ride” with a carrier protien or an ionophore Can also be a Channel coupled transport 70

71. Three main mechanisms: –coupled carriers: a solute is driven uphill compensated by a different solute being transported downhill (secondary) –ATP-driven pump: uphill transport is powered by ATP hydrolysis (primary) –Light-driven pump: uphill transport is powered by energy from photons (bacteriorhodopsin) Active Transport 71

72. Active Transport Energy is required 72

73. Endocytosis Movement of large material –Particles –Organisms –Large molecules Movement is into cells Types of endocytosis – bulk-phase (nonspecific) – receptor-mediated (specific) 73

74. Process of Endocytosis Plasma membrane surrounds material Edges of membrane meet Membranes fuse to form vesicle 74

75. Forms of Endocytosis Phagocytosis – cell eating Pinocytosis – cell drinking 75

76. Exocytosis Reverse of endocytosis Cell discharges material 76

77. Exocytosis Vesicle moves to cell surface Membrane of vesicle fuses Materials expelled 77

78. Endocytosis and Exocytosis Exocytosis - membrane vesicle fuses with cell membrane, releases enclosed material to extracellular space. Endocytosis - cell membrane invaginates, pinches in, creates vesicle enclosing contents 78

79. End Chapter 5 79

80. Types of Proteins 1) Enzymes – catalyzes covalent bond breakage or formation 2) Structural – collagen, elastin, keratin, etc. 3) Motility – actin, myosin, tubulin, etc. 4) Regulatory – bind to DNA to switch genes on or off 5) Storage – ovalbumin, casein, etc. 6) Hormonal – insulin, nerve growth factor (NGF), etc. 7) Receptors – hormone and neurotransmitter receptors 8) Transport – carries small molecules or irons 9) Special purpose proteins – green fluorescent protein, etc. 80

81. Peroxisome 1 a small organelle that is present in the cytoplasm of many cells and that contains the reducing enzyme catalase and usually some oxidases. 81

82. Peroxisome 2 A major function of the peroxisome is the breakdown of very long chain fatty acids through beta-oxidation. In animal cells, the very long fatty acids are converted to medium chain fatty acids, which are subsequently shuttled to mitochondria where they are eventually broken down to carbon dioxide and water. In yeast and plant cells, this process is exclusive for the peroxisomes. 82

83. THE END 83