1. A Tour of the Cell, Part 2 Lecture 2, Part 2 Fall 2008

2. Cytoskeleton Network of fibers extending throughout the cytoplasm1
Network of fibers extending throughout the cytoplasm
Three types:
Microtubules
Microfilaments
Intermediate filaments
Fig. 6.20

3. Cytoskeleton Microtubules Hollow rods Protein: tubulin2
Microtubules
Hollow rods
Protein: tubulin
Largest diameter (25 nm)
Actively assembled & disassembled
Function
Maintain cell shape
Compression-resisting
Cell division (centrioles)
Tracks for organelle movement
Cell motility (cilia & flagella)
Fig. 6.21
Table 6.3

4. Cilia & Flagella Microtubular containing extensions from a cell3
Fig. 6.23
Microtubular containing extensions from a cell
Flagella
Typically one or two, long
Undulating motion
Cilia
Typically many, short
Back & forth motion
Functions:
Mobility of cell
Movement of fluid past a cell
Attachment (some cilia)
Signal-receiving (specialized cilia)

5. Cytoskeleton Microfilaments Solid rods Protein: actin4
Microfilaments
Solid rods
Protein: actin
Smallest diameter (7 nm)
Actively assembled & disassembled
Function
Maintain cell shape
Tension bearing
Change cell shape
Cell motility (pseudopodia)
Cell division (cleavage furrow)
Muscle contraction
Cytoplasmic streaming
Table 6.3

6. Cytoskeleton Intermediate filaments Supercoiled cables5
Intermediate filaments
Supercoiled cables
Proteins: keratin family
Intermediate & variable diameter (8-12 nm)
Permanent structures
Function:
Maintain cell shape (tension bearing)
Anchor nucleus, some organelles
Forms nuclear lamina
Table 6.3

7. Extracellular Matrix (ECM): Animal Cells6
Collagen
Glycoproteins (protein + carbohydrate)
Proteoglycan complex
Core protein with many carbohydrate chains
Fig. 6.30

8. Extracellular Matrix (ECM): Animal Cells7
Fibronectin
Attaches ECM to integrins
Integrins
Cell surface receptor proteins
Fig. 6.30

9. Intercellular Junctions: Animal Cells8
Tight junctions
Continuous seal around cell
Prevent fluid leakage
Desmosomes
Attach cells together
Gap Junctions
Cytoplasmic channels
Proteins
Fig. 6.32

10. Cell Walls in Plants Cell walls9
Cell walls
A protective layer external to the plasma membrane
Plants (also bacteria, archaea, fungi, some protists)
Functions:
Protection
Maintain shape
Prevent excessive water uptake
Fig. 6.28

11. Cell Walls in Plants 10
Matrix of cellulose, other polysaccharides & proteins
What is cellulose?

12. Carbohydrates Function Energy source11
Function
Energy source
used in cellular respiration to create ATP
What are some sources of carbohydrates?
Carbon skeleton “building block” for other organic molecules
Cell identity
Fibrous structural material
Cellulose, chitin, peptidoglycan
Sugars, starchs (pasta, bread, potatoes)
Ribose and other monosachharides could have been formed in the prebiotic chemical soup of early earth

13. Carbohydrates Monomer small molecule Polymer12
Monomer
small molecule
Polymer
large molecule made up of many smaller monomers
Macromolecules
“Big molecule”
Synthesis & Breakdown of Polymers
Dehydration reaction
Hydrolysis
Fig. 5.2

14. Carbohydrates Monosaccharides Simple sugar (CH2O) Disaccharides13
Monosaccharides
Simple sugar (CH2O)
E.g., glucose, fructose
Disaccharides
Double sugar (complex carbohydrate)
E.g., sucrose, maltose, lactose
Polysaccharides
Complex carbohydrates
Long chains of sugar
E.g., glycogen, starch, cellulose, chitin
Storage molecules
Sucrose = glucose + fructose, maltose = 2 glucose, lactose = glucose + galactose
Starch – glucose molecules strung together
Glycogen = glucose polymer – stored in liver & muscle cells “carb loading”
Cellulose – dietary fiber, roughage – need special anaerobic bacteria to break it down

15. Cellulose Structural polysaccharide Polymer of glucose14
Fig. 5.8
Structural polysaccharide
Polymer of glucose
Most abundant organic compound on earth
Not digestible by most organisms
Beta glucose
Unbranched & straight
Forms microfibrils
Fig. 5.7

16. Intercellular Junctions – Plant Cells15
Plasmodesmata
Channels between adjacent cells
Cytosol is continuous between connected cells
Fig. 6.31