1. Chapter 8: Photosynthesis
Converting Light Into Food

2. Students Will Be Able To:
Describe how ATP/ADP and glucose are used to transfer energy.
Distinguish between autotrophs and heterotrophs.

3. Energy needs of life All life needs a constant input of energy
Heterotrophs (Animals)
get their energy from “eating others”
eat food = other organisms = organic molecules
extract energy through respiration
Autotrophs (Plants)
“produce” their own energy (from “self”)
convert energy of sunlight
build organic molecules (CHO) from CO2
capture energy & synthesize sugars through photosynthesis, then extract through it respiration
consumers
producers

4. ATP Living economy Fueling the body’s economy Need an energy currency
Eat & digest high energy organic molecules
food = carbohydrates, lipids, proteins, nucleic acids
capture released energy in a form the cell can use
Need an energy currency
a way to pass energy around
short term energy storage molecule
ATP

5. ATP Adenosine Triphosphate modified nucleotide
nucleotide = adenine + ribose + Pi  AMP
AMP + Pi  ADP
ADP + Pi  ATP
adding phosphates (phosphorylation) is endergonic
high energy bonds

6. How does ATP store energy?
ADP
AMP
ATP
Each negative Phosphate more difficult to add
a lot of stored energy in each bond
most energy stored in 3rd Pi
3rd Pi is hardest group to keep bonded to molecule
Bonding of negative Pi groups is unstable
spring-loaded
Pi groups “pop” off easily & release energy
Instability of its P bonds makes ATP an excellent energy donor

7. How does ATP transfer energy?+
ATP
ADP
ATP  ADP
releases energy
Fuel other reactions

8. A working muscle recycles over 10 million ATPs per second
ATP / ADP cycle
Can’t store ATP
good energy donor, not good energy storage
too reactive
transfers Pi too easily
only short term energy storage
carbohydrates & fats are highly stable, though
ATP
cellular respiration
7.3 kcal/mole
ADP Pi +
A working muscle recycles over 10 million ATPs per second

9. Discuss
If ATP is needed to power everything in the cell, but it doesn’t last long…
Whereas sugars and lipids store a ton of energy and are very stable, but can’t be used to directly power cell organelles…
…how can a cell survive? What must it do?

10. ATP and Glucose
Most cells have only a small amount of ATP, enough to last for only a few seconds of activity.
A single glucose molecule stores more than 90 times the chemical energy of an ATP.

11. Students Will Be Able To:
Describe the purpose, location, reactants, and products of the Light Reactions, Calvin Cycle, and photosynthesis overall.
Trace the pathway of energy through the photosynthetic reactions.
List the steps of the Light Reactions, and state the overall process of the Calvin Cycle.

12. How do plants make energy & food?
Plants use the energy from the sun
to “charge up” temporary ATP
to make sugars
glucose, sucrose, cellulose, starch, & more
sun
ATP
sugars

13. What do plants need to grow?
The “factory” for making energy & sugars
chloroplast
Fuels
sunlight
carbon dioxide
water
The Helpers
enzymes
Make ATP! Make sugar! I can do it all… And no one even notices!
sun
CO2
ATP
enzymes
sugars
H2O

14. Photosynthesis
Converts light energy into chemical energy in glucose through complex series of reactions.
Glucose = C6H12O6
What does a plant need in order to build glucose?
Where can it get those from?

15. Using light & air to grow plants
Photosynthesis
In chloroplasts
Capture sunlight
Carry out the many reactions of photosynthesis

16. Plant structure Chloroplasts Thylakoid membrane contains
ATP
thylakoid
Chloroplasts
double membrane
stroma
fluid-filled interior
thylakoid sacs
grana = stacks of
thylakoids
Thylakoid membrane contains
chlorophyll molecules
electron transport chain
ATP synthase
H+ (proton) gradient built up within thylakoid sac
outer membrane
inner membrane
granum
stroma
thylakoid

17. Light
Light from the sun appears white, but it is a combination of all the colors (ROY G BIV) or the visible spectrum
Light is measured in wavelengths.
Smaller wavelengths (violet) have more energy.
Larger wavelengths (red) have less energy.

18. Pigments Objects can reflect, transmit, or absorb light.
Pigments are molecules that absorb light. Most pigments absorb some colors more than others.
The color a pigment appears to the eye is actually the light being reflected
Ex. A red shirt appears red
because it absorbs all the
colors of light except red,
which bounces back to the eye.

19. Light: absorption spectra
Photosynthesis gets energy by absorbing wavelengths of light
chlorophyll a
absorbs best in red & blue wavelengths & least in green
accessory pigments with different structures absorb light of different wavelengths
chlorophyll b, carotenoids, xanthophylls
Why are plants green?

20. Building plants from sunlight & air
Photosynthesis
2 separate processes
ENERGY obtaining reactions
collect sun energy
use it to make ATP
SUGAR building reactions
take the ATP energy
collect CO2 from air & H2O from ground
use all to build sugars
ATP
H2O +
CO2
sugars
carbon dioxide
CO2
water
H2O
sugars
C6H12O6 +

21. Photosynthesis ATP ADP ENERGY building reactions
sun
Photosynthesis
ENERGY building reactions
ADP
ATP
SUGAR building reactions
used immediately to synthesize sugars
H2O
sugar
CO2

22. It’s not the Dark Reactions!
Photosynthesis
Light reactions
“light-dependent reactions”
energy conversion reactions
convert solar energy to chemical energy
Make electron acceptor “chemical batteries” ATP & NADPH
Calvin cycle
“light-independent reactions”
sugar building reactions
uses chemical energy from light rxns to reduce CO2 & synthesize glucose
It’s not the Dark Reactions!

23. Photosystems of photosynthesis
2 photosystems in thylakoid membrane
collections of chlorophyll molecules
act as light-gathering molecules
Photosystem II
chlorophyll a
P680 = absorbs 680nm wavelength red light
Photosystem I
chlorophyll b
P700 = absorbs 700nm wavelength red light
reaction center
antenna pigments

24. ETC of Photosynthesis Photosystem II Photosystem I chlorophyll a
chlorophyll b
Photosystem I

25. Light Dependant Reactions

26. ETC of Photosynthesis
Chloroplasts transform light energy into chemical energy of ATP
use electron carrier NADPH
generates O2

27. ETC of Photosynthesis
Electron transport chain (ETC) uses light energy to produce
ATP & NADPH
go to Calvin cycle
Photosystems absorb light photon, which excites an electron in that molecule
excited electron passes from chlorophyll to “primary electron acceptor,” which passes it down ETC
Eventually, used to synthesize NADPH
NADP+ + H+ + e- -> NADPH
Now need to replace electron in chlorophyll, so…
enzyme extracts electrons from H2O & supplies them to chlorophyll
This splits H2O
O combines with another O to form O2
O2 released to atmosphere
H+ used to power ATP synthase proton pump
Enzyme which synthesizes ATP

28.   build stuff !! photosynthesis
Light reactions
Result: converted solar energy to chemical energy
ATP
NADPH
What can we do now?
ATP
 energy
 reducing power
  build stuff !!
photosynthesis

29. CO2 C6H12O6 How is that helpful? Want to make C6H12O6 synthesis
How? From what? What raw materials are available?
CO2
NADPH
reduces CO2
carbon fixation
NADP
NADP
C6H12O6

30. From CO2  C6H12O6 CO2 has very little chemical energy
C6H12O6 contains a lot of chemical energy
Synthesis = endergonic or exergonic?
Reduction of CO2  C6H12O6 proceeds in many small uphill steps
each catalyzed by a specific enzyme
using energy stored in ATP & NADPH

31. From Light reactions to Calvin cycle
Occurs in the stroma
Requires energy from ATP and NADPH (from Light Rxns), and CO2
Stores that energy in food molecules—glucose
stroma
ATP
thylakoid

32. From Light reactions to Calvin cycle
Regenerates ADP and NADP+ which go back to the light-dependent reactions
Does not require light
stroma
ATP
thylakoid

33. The Calvin Cycle
“Carbon fixation”: incorporation of inorganic carbon (from CO2 in this case) into organic compounds

34. Photosynthesis summary
Light reactions
produced ATP
produced NADPH
consumed H2O
produced O2 as byproduct
Calvin cycle
consumed CO2
produced sugar
regenerated ADP
regenerated NADP
ADP
NADP

35. Light Reactions  produces ATP produces NADPH
H2O
ATP O2
light
energy  +
NADPH
H2O
sunlight
produces ATP
produces NADPH
releases O2 as a waste product
Energy Building
Reactions
NADPH
ATP O2

36. Calvin Cycle  builds sugars uses ATP & NADPH recycles ADP & NADP CO2
C6H12O6  +
NADP
ATP
NADPH
ADP
CO2
builds sugars
uses ATP & NADPH
recycles ADP & NADP
back to make more ATP & NADPH
ADP
NADP
Sugar Building
Reactions
NADPH
ATP
sugars

37. Putting it all together
CO2
H2O
C6H12O6 O2
light
energy  +
H2O
CO2
sunlight
ADP
NADP
Energy Building
Reactions
Sugar Building
Reactions
NADPH
ATP O2
sugars

38. Photosynthesis Overview

39. Factors Affecting Photosynthesis
Temperature
Why might temperature affect photosynthesis?
Light
Availability of Water & Carbon Dioxide
As light, water, and carbon dioxide concentration increases, the rate of photosynthesis increases and then reaches a plateau. Why do you think it plateaus?

40. How do we figure out something this complicated?!
Thousands of scientists in many incremental steps, for instance:
Van Helmont’s Experiment
Measured water intake and weight increase, concluded that trees gain most of their mass from water. (Later experiments refuted this)

41. Investigating Photosynthesis
Priestley’s Experiment
Finds that the plant releases a substance that keeps the candle burning (oxygen).

42. Investigating Photosynthesis
Ingenhousz’ Experiment
Found that aquatic plants produce oxygen bubbles in the light but not in the dark. Concludes that plants need sunlight to produce oxygen.