1. Chapter 2 The Cell

2. Limits of microscopes - Eukaryotic cells are measured in µm (100-10µm)
End light microscope viewing power
- Eukaryotic cells are measured in µm (100-10µm)
Micrometer is 10-6 of a meter.

3. 2 types of Electron Microscopes
Transmission EM (TEM)
Requires ultrathin
sections
See internal structures
2D image
Scanning EM (SEM)
Sweeps across surface
of specimen
See surface anatomy
3D image

4. Figure 2.1 Different Techniques, Different Perspectives
LM  400
TEM  2400
SEM  14,000
Cells as seen in light microscopy (respiratory tract)
Cells as seen in transmission electron microscopy (intestinal tract)
Cells as seen in scanning electron microscopy (respiratory tract)

5. Virus budding from cell
Which is TEM? SEM?

6. Plant cells: you can see 3 different cells and internal structures
M= mitochondria, G= golgi apparatus, Vac= vacuole PM= plasma membrane CW = cell wall ER= Endoplasmic reticulum

7. Head of an Antarctic mite magnified 1500x

8. Termite Head

10. Fly foot

12. Human Adipose tissue

13. lung

14. Spongy bone

15. skin

16. Connective Tissue

17. collagen

18. Human hair

19. Nerve fibers

20. Nerve fiber close up

21. Skeletal muscle fiber: pink are mitochondria

22. Nerve cell
White blood cell
liver cell
osteoblast

23. Generalized Eukaryotic Cell

24. Plasma Membrane (Plasmalemma)
Composition: lipids, proteins and carbohydrates.
phospholipid bilayer, cholesterol & glycolipids, glycoproteins, integral proteins, peripheral proteins
Label parts of the membrane

25. Different types of Endocytosis

26. Receptor mediated endocytosis
LDL tutorial

27. Exocytosis
Examples?

28. Microvilli: extensions of plasma membrane

29. Cytoplasm: interior of the cell
Cytosol jelly-like fluid inside the cell. Differs from outside in ion concentrations & molecular make-up (proteins, carbohydrates etc)
Organelles: nucleus ribosomes ER
golgi complex
mitochondria lysosomes peroxisomes cytoskeleton

30. Nucleus “little nut”

31. Figure 2.11 Ribosomes
Nucleus
Free ribosomes
Small ribosomal
subunit
Large ribosomal subunit
Endoplasmic reticulum with attached fixed ribosomes
An individual ribosome, consisting of small and large subunits
TEM  73,600
Both free and fixed ribosomes can be seen in the cytoplasm of this cell.

32. Endoplasmic Reticulum
• .

33. Functions of ER
Smooth ER: lipid metabolism (making & breaking down lipids)
Abundant in cells that make steroid hormones & in
liver that detoxifies fat soluble drugs/toxins.
Rough ER: makes proteins that are going to be secreted from the cell.

34. Figure 2.16b The Golgi Apparatus
EXTRACELLULAR FLUID
ode to Golgi Animated tutorial
CYTOSOL
Membrane renewal vesicles
Lysosome
Secretory vesicle
Cisternae
Maturing
(trans) face
This diagram shows the functional link between the ER and the Golgi apparatus. Golgi structure has been simplified to clarify the relationships between the membranes. Transport vesicles carry the secretory product from the endoplasmic reticulum to the Golgi apparatus, and transfer vesicles move membrane and materials between the Golgi cisternae. At the maturing face, three functional categories of vesicles develop. Secretory vesicles carry the secretion from the Golgi to the cell surface, where exocytosis releases the contents into the extracellular fluid.
Other vesicles add surface area and integral proteins to the plasmalemma. Lysosomes, which remain in the cytoplasm, are vesicles filled with enzymes.
Forming
(cis) face
Transport vesicle

36. Lysosomes
See animation of cell taking In particles, digesting them & gettign rid of waste.

37. liver & muscle cells have as many as 300 mitochondria
Figure Mitochondria
Inner membrane
Cytoplasm of cell
Cristae
Matrix
Organic molecules and O2
Outer
CO2 ATP
membrane
Matrix
Cristae
Enzymes
TEM  61,776
liver & muscle cells have as many as 300 mitochondria
© 2012 Pearson Education, Inc.

38. Peroxisomes

39. Cytoskeleton
Microvilli
Microfilaments
Plasmalemma
Terminal web
Mitochondrion
Intermediate filaments
Endoplasmic reticulum
The cytoskeleton provides strength and structural support for the cell and its organelles. Interactions between cytoskeletal elements are also important in moving organelles and in changing the shape of the cell.
Microtubule
Secretory vesicle

40. Amoeba move due to rearranging their cytoskeleton
Neutrophil motion

41. Centrioles & the Centrosome

42. Membrane proteins from adjacen t cells
Gap ju nctions create gaps that connect animal cells.
••••••••••••
Gap----c ju nctions
Membrane proteins from adjacen t cells
line up to form
a chan nel
Figure 8-13b part 2 Biological Science,2/e
© 2005 Pearson Prentice Hall,Inc.

43. A possible cause of Celiac disease

44. Three-dimensional view of tight junctions
Plasma membranes of adjacent cells
Figure 8-9b Biological Science, 2/e
© 2005 Pearson Prentice Hall, Inc..

45. Inner Life of the Cell

46. 1. Some integral membrane proteins form gated
channels that open or close to:
Regulate passage of materials in/out of cell
Permit water movement in/out of cell
Transport large proteins into cell
Communicate with neighboring cells
2. Which organelle would be in abundance in immune
cells that kill bacteria? a)
SER
c) lysosome b)
b) RER
d) centrosomes

47. 3. Products made in the ER would travel to
Nucleus
b) Golgi
peroxisome
mitochondria

48. Functions of the plasma membrane include which of the following?
regulation of exchange with the
environment
interaction with actin filaments to
produce contractions
production of proteins
production of ATP

49. 5. What are the benefits of having some
organelles enclosed by a membrane?