1. COURSE OVERVIEW
1) Understanding how plants work.
2) Understanding how plant biologists work.
Method
Technology

2. We will pick a problem in plant physiology and see where it takes us.
Plan C
We will pick a problem in plant physiology and see where it takes us.
Biofuels
Climate/CO2 change
Stress responses/stress avoidance
Plant products
Improving food production
Biotechnology
Phytoremediation
Plant movements
Plant signaling (including neurobiology)
Something else?

3. Plan C
Pick a problem
Pick some plants to study
Design some experiments
See where they lead us

4. Plan C
Grading?
Combination of papers and presentations
First presentation:10 points
Research presentation: 10 points
Final presentation: 15 points
Assignments: 5 points each
Poster: 10 points
Intermediate report 10 points
Final report: 30 points
Scavenger hunts?

5. Vegetative Plants
3 Parts
Leaf
Stem
Root

6. Vegetative Plants
3 tissue types
Dermal
Ground
Vascular

7. Plant Development
Cell division = growth

8. Plant Development
Cell division = growth
Determination = what cell can become

9. Plant Development
Cell division = growth
Determination = what cell can become
Differentiation = cells become specific types

10. Plant Development
Cell division = growth
Determination = what cell can become
Differentiation = cells become specific types
Pattern formation: developing specific structures in specific locations

11. Plant Development
Cell division = growth
Determination = what cell can become
Differentiation = cells become specific types
Pattern formation
Morphogenesis: organization into tissues & organs

12. Plant Development
umbrella term for many processes
embryogenesis

13. Plant Development
umbrella term for many processes
Embryogenesis
Seed dormancy and germination

14. Plant Development
umbrella term for many processes
Embryogenesis
Seed dormancy and germination
Seedling Morphogenesis

15. Plant Development
umbrella term for many processes
Embryogenesis
Seed dormancy and germination
Seedling Morphogenesis
Transition to flowering, fruit
and seed formation

16. Plant Development
umbrella term for many processes
Embryogenesis
Seed dormancy and germination
Seedling Morphogenesis
Transition to flowering, fruit
and seed formation
Many responses to environment

17. Plant Development
Umbrella term for many processes
Unique features of plant development
Cell walls: cells can’t move:
Must grow towards/away from signals

18. Plant Development
Umbrella term for many processes
Unique features of plant development
Cell walls: cells can’t move: must grow instead
Plasticity: plants develop in
response to environment

19. Unique features of plant development
Cell walls: cells can’t move
Plasticity: plants develop in response to environment
Totipotency: most plant cells can form an entire new plant given the correct signals

20. Unique features of plant development
Cell walls: cells can’t move
Plasticity: plants develop in response to environment
Totipotency: most plant cells can form an entire new plant given the correct signals
Meristems: plants have perpetually embryonic regions, and can form new ones

21. Unique features of plant development
Cell walls: cells can’t move
Plasticity: plants develop in response to environment
Totipotency: most plant cells can form an entire new plant given the correct signals
Meristems: plants have perpetually embryonic regions, and can form new ones
No germ line!

22. Unique features of plant development
Meristems: plants have perpetually embryonic regions, and can form new ones
No germ line! Cells at apical meristem become
flowers: allows Lamarckian evolution!

23. Unique features of plant development
Meristems: plants have perpetually embryonic regions, and can form new ones
No germ line! Cells at apical meristem become
flowers: allows Lamarckian evolution!
Different parts of the same 2000 year old tree have different DNA & form
different gametes

24. Why are cells so small?
1) many things move inside cells by diffusion
2) surface/volume ratio
surface area increases more slowly than volume
exchange occurs only at surface
eventually have insufficient exchange for survival

25. Plant Cells
Cell walls
Carbohydrate barrier
surrounding cell

26. Plant Cells
Cell walls
Carbohydrate barrier
surrounding cell
Protects & gives cell shape

27. Plant Cells
Cell walls
Carbohydrate barrier
surrounding cell
Protects & gives cell shape
1˚ wall made first
mainly cellulose

28. Plant Cells
Cell walls
Carbohydrate barrier
surrounding cell
Protects & gives cell shape
1˚ wall made first
mainly cellulose
Can stretch!

29. Plant Cells
Cell walls
Carbohydrate barrier
surrounding cell
Protects & gives cell shape
1˚ wall made first
mainly cellulose
Can stretch!
2˚ wall made after growth
stops

30. Plant Cells
Cell walls
Carbohydrate barrier
surrounding cell
Protects & gives cell shape
1˚ wall made first
mainly cellulose
Can stretch!
2˚ wall made after growth
stops
Lignins make it tough

31. Plant Cells
Cell walls
Carbohydrate barrier
surrounding cell
Protects & gives cell shape
1˚ wall made first
mainly cellulose
Can stretch!
2˚ wall made after growth
stops
Lignins make it tough
Problem for "cellulosic
Ethanol" from whole
plants

32. Plant Cells
Cell walls
1˚ wall made first
2˚ wall made after growth
stops
Lignins make it tough
Problem for "cellulosic
Ethanol" from whole
plants
Middle lamella = space
between 2 cells

33. Plant Cells
Cell walls
1˚ wall made first
2˚ wall made after growth
stops
Middle lamella = space
between 2 cells
Plasmodesmata = gaps in walls
that link cells

34. Plant Cells
Plasmodesmata = gaps in walls that link cells
Lined with plasma membrane

35. Plant Cells
Plasmodesmata = gaps in walls that link cells
Lined with plasma membrane
Desmotubule joins ER of both cells

36. Plant Cells
Plasmodesmata = gaps in walls that link cells
Lined with plasma membrane
Desmotubule joins ER of both cells
Exclude objects > 1000 Dalton, yet viruses move through them!

37. Types of Organelles
1) Endomembrane System
2) Putative endosymbionts

38. Endomembrane system
Common features
derived from ER

39. Endomembrane system
Common features
derived from ER
transport is in vesicles

40. Endomembrane system
Common features
derived from ER
transport is in vesicles
proteins & lipids are
glycosylated

41. Endomembrane system
Organelles derived from the ER
1) ER
2) Golgi
3) Vacuoles
4) Plasma
Membrane
5) Nuclear
Envelope
6) Endosome
7) Oleosomes

42. ER
Network of membranes t/out cell
2 types: SER & RER

43. SER
tubules that lack ribosomes
fns:
Lipid syn
Steroid syn
drug detox
storing Ca2+
Glycogen
catabolism

44. RER
Flattened membranes studded with ribosomes
1˚ fn = protein synthesis
-> ribosomes are making proteins

45. ER
SER & RER make new membrane!

46. GOLGI COMPLEX
Flattened stacks of membranes made from ER

47. GOLGI COMPLEX
Individual, flattened stacks of membranes made from ER
Fn: “post office”:
collect ER products,
process & deliver them
Altered in each stack

48. GOLGI COMPLEX
Individual, flattened stacks of membranes made from ER
Fn: “post office”:
collect ER products,
process & deliver them
Altered in each stack
Makes most cell wall
carbohydrates!

49. GOLGI COMPLEX
Individual, flattened stacks of membranes made from ER
Fn: “post office”:
collect ER products,
process & deliver them
Altered in each stack
Makes most cell wall
carbohydrates!
Protein’s address is
built in