1. Chapter 3 How Cells Are Put Together

2. The Plasma Membrane “Sheet” of molecules that encases all living cells Fluid mosaic model –A model for the plasma membrane –The PM is composed of proteins, lipids and carbohydrates all of which are embedded in the phosholipid bilayer and may be exposed to the cell exterior/interior –The PM is fluid; lipids that make up the plasma membrane can move laterally

3. Phospholipid

4. Phospholipid Bilayer

5. Proteins Embedded in Lipid Bilayer

6. Fig. 4.7 Nonpolar regions of the lipid bilayer lock proteins into membranes

7. Eukaryotic Cell

8. Plant Cell

9. The Nucleus Spherical structure ensheathed in the nuclear envelope (a double-layered membrane) Fx = Command center of the cell!! –1. Directs protein synthesis –2. Directs cell reproduction –3. Stores genetic information (DNA) –4. Site where DNA is converted to RNA

10. Nuclear Envelope Membrane that surrounds the nucleus Contains “openings” through which RNA (once it’s converted from DNA) exits

11. The Nucleus Animal Plant

12. The Endomembrane System Route through which material is passed within the cell Main components include: –Nuclear envelope –Endoplasmic Reticulum –Golgi Complex –Vesicles –Cell membrane

13. Endoplasmic Reticulum An extensive system of internal membranes that form channels and interconnections; also vesicles ER surface: cell makes proteins to be exported here 2 types: Rough ER Smooth ER Heavily studded with ribosomes Fx = sites of protein synthesis RNA is converted to a polypeptide chain Surface ribosomes are scarce Rather, surface is embedded w/ enzymes that aid in manufacturing carbs and lipids

14. Endoplasmic Reticulum Animal Plant

15. Golgi Complex Sacs of flattened vesicles (“pancake-like”) Receives polypeptide chain from ER where it is modified (i.e. carb addition) and packaged into secretory vesicles Fx = packages protein for export from the cell

16. Golgi Complex Animal Plant

17. Lysosomes Spherical organelles that arise from Golgi Contain digestive enzymes that break down macromolecules “Recycling centers” of the cell: they digest intracellular matter

18. Fig. 4.15 The Endomembrane System

19. Additional Organelles Mitochondria Chloroplasts

20. Mitochondria Rod-shaped organelles that derived from a bacterium that invaded a host cell The powerhouse of the cell! Only organelle other than the nucleus to house DNA –Mitochondrial DNA (mtDNA) has unique genes in their DNA that are lacking in nuclear DNA Place where oxidative phosphorylation occurs –Energy (ATP) is extracted from food through a series of chemical reactions Two-membrane structure: –Outer –Inner: forms folds (cristae) which encompass the matrix

21. Mitochondria Animal Plant

22. Chloroplast Unique to plants Organelle in which photosynthesis occurs Plant cells can contain one to several hundred Two-membrane structure (outer and inner membranes) Larger size than mitochondria and more complex inner membrane organization –Thylakoids: fused inner membranes that form stacks in which photosynthesis occurs

23. Chloroplast Plant

24. The Cytoskeleton Dense fiber structure Fx: 1. Provide support to cellular structure 2. Anchors organelles to fixed locations Composed of dynamic protein fibers that are embedded to membrane proteins embedded in the PM –Microfilaments –Microtubules –Intermediate Filaments

25. Cytoskeletal Proteins

26. The Cytoskeleton, continued Microfilaments Fine, thread-like protein fibers Composed of the contractile protein actin, the most abundant cellular protein!!! Prevent excessive stretching of cells Form and dissolve readily ≡ major role in determining cell shape Roles in cellular movement include gliding and contraction (when in combination with myosin) http://www.biology.arizona.edu/cell_bio/tutorials/cytoskeleton/page1.html

27. The Cytoskeleton, continued Microtubules Composed of tubulin protein Assembled by centrioles –Located near the nuclear envelope in the cytoplasm at right angles to each other “Conveyor belts” of the cell They move vesicles and organelles (i.e. mitochondria) as well as chromosomes http://users.rcn.com/jkimball.ma.ultranet/BiologyPages/M/Microtubule.gif

28. Centrioles

29. The Cytoskeleton, continued Intermediate Filaments Filamentous fibers ‘Intermediate’ in size Ubiquitous throughout the body Bundles of IFs are found in characteristic ‘plaques’ that form in AD in brain Includes keratin http://www.cytoskeleton.com/aif.htm

30. Fig. 4.23 Central Vacuole Plant

31. Central Vacuole Storage center Contains large amounts of water, ions, sugars and pigments Increases surface-to-volume ratio outside the vacuole –Applies pressure to plasma membrane –Plasma membrane expands → ↑ surface area ↑ surface area → MORE EFFICIENCY!!

32. Is there anything outside the plasma membrane??

33. Cell Wall Plants

34. Cell Wall Present in plants and fungi – NOT ANIMAL CELLS Composed of cellulose (polysaccharide) Primary walls are laid while plant is growing Individual cells are held together by the middle lamella Secondary walls are present in some plants –Inside the Primary walls of fully expanded, grown cells Located OUTSIDE the plasma membrane Fx:maintain cell shape protection prevents excessive water uptake

35. Fig. 4.25 Extracellular Matrix Animal cell

36. Extracellular Matrix Present in ANIMAL cells Mixture of glycoproteins, collagen, elastin, proteoglycans Fx: serves as a protective layer for the cell helps coordinate cell behavior Attached to the plasma membrane by fibronectin –Glycoprotein –Bind to integrins in the plasma membrane

37. Everyday Science Forensic Science uses mitochondrial DNA testing mtDNA is maternally inherited Why use mtDNA vs. nuclear DNA? –mtDNA is more abundant – in every mitochondria in the cell –nuclear DNA may degrade more easily as there is only one copy What is the drawback of mtDNA testing? Relatives from the same mother can’t be excluded