1. Chapter 4 part C

2. Figure 4.22a The Eukaryotic Cell

3. Flagella and Cilia 4-13Differentiate prokaryotic and eukaryotic flagella. Learning Objective

4. Figure 4.23a-b Flagella and Cilia

5. Microtubules Tubulin 9 pairs + 2 array Figure 4.23c Flagella and Cilia

6. The Cell Wall and Glycocalyx 4-14Compare and contrast prokaryotic and eukaryotic cell walls and glycocalyxes. Learning Objective

7. The Cell Wall and Glycocalyx Cell wall – Plants, algae, fungi – Carbohydrates Cellulose, chitin, glucan, mannan Glycocalyx – Carbohydrates extending from animal plasma membrane – Bonded to proteins and lipids in membrane

8. Q&A Penicillin was called a “miracle drug” because it doesn’t harm human cells. Why doesn’t it?

9. The Plasma Membrane 4-15Compare and contrast prokaryotic and eukaryotic plasma membranes. Learning Objective

10. The Plasma Membrane Phospholipid bilayer Peripheral proteins Integral proteins Transmembrane proteins Sterols Glycocalyx carbohydrates

11. The Plasma Membrane Selective permeability allows passage of some molecules Simple diffusion Facilitative diffusion Osmosis Active transport Endocytosis – Phagocytosis: Pseudopods extend and engulf particles – Pinocytosis: Membrane folds inward, bringing in fluid and dissolved substances

12. Cytoplasm 4-16Compare and contrast prokaryotic and eukaryotic cytoplasms. Learning Objective

13. Table 4.2 Cytoplasm

14. Cytoplasm membrane: Substance inside plasma and outside nucleus Cytosol: Fluid portion of cytoplasm Cytoskeleton: Microfilaments, intermediate filaments, microtubules Cytoplasmic streaming: Movement of cytoplasm throughout cells

15. Ribosomes 4-17Compare the structure and function of eukaryotic and prokaryotic ribosomes. Learning Objective

16. Ribosomes Protein synthesis 80S – Membrane-bound: Attached to ER – Free: In cytoplasm 70S – In chloroplasts and mitochondria

17. Check Your Understanding Identify at least one significant difference between eukaryotic and prokaryotic flagella and cilia, cell walls, plasma membranes, and cytoplasm. 4-13–4-16 The antibiotic erythromycin binds with the 50S portion of a ribosome. What effect does this have on a prokaryotic cell? On a eukaryotic cell? 4-17

18. Organelles 4-18Define organelle. 4-19 Describe the functions of the nucleus, endoplasmic reticulum, Golgi complex, lysosomes, vacuoles, mitochondria, chloroplasts, peroxisomes, and centrosomes.

19. Organelles Nucleus: Contains chromosomes ER: Transport network Golgi complex: Membrane formation and secretion Lysosome: Digestive enzymes Vacuole: Brings food into cells and provides support

20. Organelles Mitochondrion: Cellular respiration Chloroplast: Photosynthesis Peroxisome: Oxidation of fatty acids; destroys H 2 O 2 Centrosome: Consists of protein fibers and centrioles

21. Figure 4.24 The Eukaryotic Nucleus

22. Figure 4.24a–b The Eukaryotic Nucleus

23. Figure 4.25 Rough Endoplasmic Reticulum

24. Figure 4.25a Detailed Drawing of Endoplasmic Reticulum

25. Figure 4.25b Micrograph of Endoplasmic Reticulum

26. Figure 4.26 Golgi Complex

27. Figure 4.22b Lysosomes and Vacuoles

28. Figure 4.27 Mitochondria

29. Figure 4.28 Chloroplasts

30. Figure 4.28a Chloroplasts

31. Figure 4.28b Chloroplasts

32. Figure 4.22b Peroxisome and Centrosome

33. Check Your Understanding Compare the structure of the nucleus of a eukaryote and the nucleoid of a prokaryote. 4- 18 How do rough and smooth ER compare structurally and functionally? 4-19

34. The Evolution of Eukaryotes 4-20Discuss evidence that supports the endosymbiotic theory of eukaryotic evolution. Learning Objective

35. Figure 10.2 Endosymbiotic Theory

36. What are the fine extensions on this protozoan?

37. Endosymbiotic Theory

38. Check Your Understanding Which three organelles are not associated with the Golgi complex? What does this suggest about their origin? 4-20