1. Cells and Their Environment

2. Cell Membrane Phospholipids Phospholipids Lipid Bilayer Lipid Bilayer Fluid Mosaic Fluid Mosaic Integral Proteins Integral Proteins

3. Phospholipid

6. Transportation How do substances move into and out of cells? How do substances move into and out of cells? Passive Transport and Active Transport Passive Transport and Active Transport

7. Passive Transport Diffusion Diffusion Movement across the cell membrane that does not require energy Movement across the cell membrane that does not require energy

8. Some Important Terms Concentration gradient – a difference in the concentration of a substance across a space Concentration gradient – a difference in the concentration of a substance across a space Equilibrium – concentration of a substance is equal throughout space Equilibrium – concentration of a substance is equal throughout space

9. Diffusion Movement of substance from area of high concentration to low concentration (down its concentration gradient)–resulting in equilibrium Movement of substance from area of high concentration to low concentration (down its concentration gradient)–resulting in equilibrium

10. Example of Diffusion Small and nonpolar molecules diffusing across the cell membrane down their concentration gradient Small and nonpolar molecules diffusing across the cell membrane down their concentration gradient This is the simplest type of passive transport This is the simplest type of passive transport

11. Osmosis The diffusion The diffusion of water Movement of a substance down its concentration gradient

12. A simple rule to remember is: Salt is a solute, when it is concentrated inside or outside the cell, it will draw the water in its direction. This is also why you get thirsty after eating something salty.

13. 3 Possibilities for the direction of water movement in a cell 1. Water moves out 2. Water moves in 3. No net water movement

14. The word "HYPER" means more, in this case there are more solute (salt) molecules outside the cell, which causes the water to be sucked in that direction. In plant cells, the central vacuole loses water and the cells shrink, causing wilting. In animal cells, the cells also shrink. In both cases, the cell may die. Water Moves Out – Hypertonic Solution

15. The word "HYPO" means less, in this case there are less solute (salt) molecules outside the cell, since salt sucks, water will move into the cell. The cell will gain water and grow larger. In plant cells, the central vacuoles will fill and the plant becomes stiff and rigid, the cell wall keeps the plant from bursting In animal cells, the cell may be in danger of bursting, organelles called CONTRACTILE VACUOLES will pump water out of the cell to prevent this. Water Moves In – Hypotonic Solution

16. If the concentration of solute (salt) is equal on both sides, the water will move back in forth but it won't have any result on the overall amount of water on either side. "ISO" means the same Water moves in & out at the same rate!

17. Extra This is why it is dangerous to drink sea water - its a myth that drinking sea water will cause you to go insane, but people marooned at sea will speed up dehydration (and death) by drinking sea water. This is also why "salting fields" was a common tactic during war, it would kill the crops in the field, thus causing food shortages.

19. Transport Proteins Provide polar passageways through which ions and polar molecules can move across the cell membrane Provide polar passageways through which ions and polar molecules can move across the cell membrane Each channel is specific for a substance – selectivity – the cell has the Control! Each channel is specific for a substance – selectivity – the cell has the Control!

20. How can ions get into a cell?

21. Even though we have added a third party…. This is still a form of passive transport This is still a form of passive transport Why? Why? There is no use of energy by the cell required because the ions are moving down their concentration gradient There is no use of energy by the cell required because the ions are moving down their concentration gradient

22. Facilitated Diffusion Passive transport….why?

23. Active Transport How do substances enter a cell when they are working against their concentration gradient? How do substances enter a cell when they are working against their concentration gradient? Active transport - Requires the cell to use energy from ATP Active transport - Requires the cell to use energy from ATP

24. Carrier Proteins as “Pumps”

25. Why do we like the Na-K Pump? 1. Na ions continuously diffuse into the cell membrane through ion channels (why is this a problem) and the pump prevents these ions from accumulating 2. Maintains the concentration gradient of Na ions and K ions across the cell membrane

26. What about the large molecules (proteins and polysaccharides)? Endocytosis – the movement of a substance into a cell by a vesicle Endocytosis – the movement of a substance into a cell by a vesicle

27. How to move large substances out of the cell? Exocytosis – the movement of a substance by a vesicle to the outside of a cell (used to export proteins modified by the Golgi) Exocytosis – the movement of a substance by a vesicle to the outside of a cell (used to export proteins modified by the Golgi)

28. How cells communicate Release signal molecules that carry information to nearby cells and throughout the body Release signal molecules that carry information to nearby cells and throughout the body Ex. hormones Ex. hormones

29. What else is in the cell membrane? Receptor Proteins - proteins in the cell membrane that bind these signal molecules and then “read the message” Receptor Proteins - proteins in the cell membrane that bind these signal molecules and then “read the message” Marker Proteins – proteins that identify cell type. Marker Proteins – proteins that identify cell type.

30. Cells

31. Prokaryote vs. Eukaryote All have: All have: –Cell/Plasma Membrane –Cytosol/Cytoplasm –Chromosomes- What? –Ribosomes – Why?

32. Pro vs. Eu ProkaryoteEukaryote Chromosomes in NucleoidChromosomes in Nucleus No membrane-bound organellesHave membrane-bound organelles Very small (1-10 um)Bigger (10-100 um) Most have cell wallMay or may not have cell wall 3 common shapes (cocci, bacilli, spiral) Lots of shapes – Can have specialized cells

34. Prokaryote Shapes

35. Size of Cell Do organisms grow by adding cells or just the cells growing larger? Do organisms grow by adding cells or just the cells growing larger? Why can’t cells grow very big? Why can’t cells grow very big? –Something called the Surface Area to Volume Ratio –As a cell gets bigger, its volume increases more than its surface area –Comes down to transport – Organelle?

36. Example

37. Thiomargarita namibiensis

38. Xenophyophores