1. Agenda 11/17/14- Photosynthesis
Cellular Respiration Quiz
Intro to Photosynthesis worksheet
New Information: Photosynthesis and Plant Cell Specialization
Photosynthesis Diagram worksheet
HW- finish packet

2. THE BASICS OF PHOTOSYNTHESIS
Most plants are photosynthetic autotrophs, as are some bacteria and protists
Autotrophs: generate their own organic matter through photosynthesis
Sunlight energy is transformed into energy stored in the form of chemical bonds
(c) Euglena
(b) Kelp
(d) Cyanobacteria
(a) Mosses, ferns, and
flowering plants 2

3. Light Energy Harvested by Photosynthetic Autotrophs
6 CO2 + 6 H2O + light energy → C6H12O6 + 6 O2 3

4. Food Chain 4

5. Transverse section of a Leaf
Waxy coating
Blade
Vein
Stem 5

6. The location and structure of chloroplasts
LEAF CROSS SECTION
MESOPHYLL CELL
LEAF
Mesophyll
CHLOROPLAST
Intermembrane space
Outer
membrane
Granum
Inner membrane
Grana
Stroma
Thylakoid compartment
Stroma
Thylakoid 6

7. Chloroplasts Intermembrane space Outer membrane Thylakoid
Inner membrane
Granum
Stroma

8. A Chloroplast Light Energy Grana Chemical Energy H2O CO2 Chloroplast
Sugars
CO2
Chloroplast
NADP+
ADP
Light-
Dependent
Reactions
Calvin
Cycle
Grana
ATP
NADPH
Chemical
Energy

9. 2 Pathways of Photosynthesis
Light-dependent reactions
Light energy absorbed
Occurs across thylakoid membranes
Produces ATP and NADPH (and waste O2)
Light-independent reactions or Calvin Cycle
Does not require light energy
Occurs in the stroma
Produces sugar using CO2

10. ATP
ATP - Adenosine Triphosphate
Adenine
Ribose
3 Phosphate groups

11. Formation of ATP ATP stores enough energy for many cellular functions.
ADP
ATP
Adenosine triphosphate (ATP)
Energy
Adenosine diphosphate (ADP) + Phosphate
Partially
charged
battery
Fully
charged
battery
ATP stores enough energy for many cellular functions.

12. A Chloroplast Light Energy Grana Chemical Energy H2O CO2 Chloroplast
Sugars
CO2
Chloroplast
NADP+
ADP
Light-
Dependent
Reactions
Calvin
Cycle
Grana
ATP
NADPH
Chemical
Energy

13. H2O CO2 C6H12O6 O2 Sunlight Energy NADP+ ADP ATP NADPH Stroma
Thylakoids
ATP
NADPH
C6H12O6 O2

14. Light Dependent Reactions
Pigments arranged into photosystems
Photosystem I (happens 2nd)
Photosystem II (happens 1st)
Inputs:
H2O
Light Energy
ADP, NADP+
Products (go on to fuel Calvin Cycle):
ATP, NADPH O2

15. Light Dependent Reactions
Electron transport chain
Pumps H+ ions across the thylakoid membrane- results in energy for ATP production
ATP Synthase (enzyme)
H+ ions pass through the thylakoid membrane via ATP synthase, making it spin (energy)
ATP synthase spins, binding ADP and a phosphate group into ATP

16. The Two Photosystems of the Light Reactions:
P-680 and P-700
Potential Energy
Off to the Calvin Cycle

17. H2O CO2 C6H12O6 O2 Sunlight Energy NADP+ ADP ATP NADPH Stroma
Thylakoids
ATP
NADPH
C6H12O6 O2

18. Light-Independent Reactions, aka Calvin Cycle
occurs in stroma
uses ATP and NADPH from the light-dependent reactions and CO2 to make the organic molecule glucose (C6H12O6)

19. The Calvin Cycle Inputs: ATP NADPH CO2 Products: C6H12O6 ADP NADP+
CO2 Enters the Cycle
Energy Input
Inputs:
ATP
NADPH
CO2
Products:
C6H12O6
ADP
NADP+
5-Carbon
Molecules
Regenerated
Sugars and other compounds
6-Carbon Sugar
Produced

20. H2O CO2 C6H12O6 O2 Sunlight Energy NADP+ ADP ATP NADPH Stroma
Thylakoids
ATP
NADPH
C6H12O6 O2 20

21. Agenda 11/18/14- Photosynthesis and Plant Pigments
Bellwork
New Information- Plant Pigments and Properties of Light
Lab- Plant Pigments and Chromatography
HW- finish lab, formal lab report due Thurs.

22. Properties of Light be reflected be absorbed be transmitted
particle nature
Photon
wave nature
photons move in waves; wavelength
when a photon strikes a substance, it may
be reflected
be absorbed
be transmitted

23. Why Are Plants Green? Electromagnetic Spectrum and Visible Light
Gamma rays
Infrared & Microwaves
X-rays UV
Radio waves
Visible light
Wavelength (nm)

24. WHY ARE PLANTS GREEN?
Different wavelengths of visible light are seen by the human eye as different colors.
Gamma rays
Micro- waves
Radio
waves
X-rays UV
Infrared
Visible light
Wavelength (nm)

25. Why are plants green?
Reflected light

26. The color of light seen is the color REFLECTED, NOT ABSORBED
Chloroplasts absorb light energy and convert it to chemical energy
What colors of light does chlorophyll absorb? Reflect?
Reflected
light
Light
Absorbed
light
Transmitted
light
Chloroplast

27. Chloroplast Pigments
Thylakoids in chloroplasts contain several pigments
Chlorophyll a (bright green)
Chlorophyll b (yellow-green)
Carotenoids (yellow/orange)
Xanthophylls (yellow)
Anthocyanins (red)
Figure 7.7

28. Why do plants have pigments other than chlorophyll?
Chlorophyll a (bright green)
Chlorophyll b (yellow-green)
Carotenoids (yellow/orange)
Xanthophylls (yellow)
Anthocyanins (red)
Figure 7.7

29. Different pigments absorb light differently
Green to Greenish-yellow
Yellow/Orange/Red

30. Absorbed Photons
energy from photon is transferred to the substance that absorbs it
electron jumps to a higher energy level
This fuels the production of ATP, NADPH
pigments absorb light energy

31. Photosynthesis Activity Site
Chlorophyll
Photosynthesis Activity Site

32. Endosymbiotic Theory (Lynn Margulis, 1981)
Mitochondria and chloroplasts may have originated as free-living prokaryotes that lived symbiotically within cells, leading to eukaryotes.
Evidence:
Circular DNA
Two or more cell membranes, with the innermost one similar to prokaryotic cell membranes
Ribosomes

33. Agenda 11/19- Photosynthesis and Cellular Respiration
Bellwork
Finish Lab- calculate Rf values, answer lab questions, discuss lab report
Review for test

34. Spinach Leaf Pigments
Distance travelled by solvent: 65 mm

35. Concept Map Photosynthesis Light- dependent reactions Calvin cycle
Section 8-3
Photosynthesis
includes
Light-
dependent
reactions
Calvin cycle
takes place in
uses
use
take place in
Energy from
sunlight
Thylakoid
membranes
Stroma
ATP
NADPH
to produce of
to produce
High-energy
sugars
ATP
NADPH O2
Chloroplasts
Go to Section:

36. Compare/Contrast Photosynthesis Cellular Respiration
Energy Storing or Releasing
Energy storing
Energy releasing
Products
Glucose, oxygen gas
Carbon dioxide, water, energy (ATP)
Reactants
Carbon dioxide, water, light energy
Location
Chloroplast
Mitochondrion

37. Typical Leaf Cross Section Model
Chapter 23, page 596
Cuticle
Veins
Epidermis
Palisade mesophyll
Xylem
Vein
Phloem
Spongy mesophyll
Epidermis
Stoma
Guard cells