1. Photosynthesis
Chapter 4

2. Source of almost all energy utilized by living things is the sun
Source of almost all energy utilized by living things is the sun. Plants harvest solar energy and convert it into chemical energy (carbohydrates) in the process of photosynthesis. This stored energy is either utilized directly by the plant or passed on through the food chain to animals that feed upon those plants. How is the energy stored in food molecules recaptured and converted into the energy necessary to do work?

3. Goals for lecture Photosynthesis Respiration
Understand how plants use sunlight to convert carbon dioxide and water into sugar
Respiration
Understand how most creatures (plants, animals, fungi) convert sugar into carbon dioxide and water, thereby releasing energy for use by their cells

4. Photosynthesis What is it? Who does it? How does it work?
Why should we care?

5. Photosynthesis
6CO2 + 6H2O  C6H12O6 + 6O2

6. Photosynthesis What is it? 6CO2 + 6H2O  C6H12O6 + 6O2
Carbon dioxide + water + sunlight ---> sugar and oxygen

7. Photosynthesis
Who does it?
algae

9. Photosynthesis Who does it? algae mosses, ferns, higher plants
no fungi
rarely animals (corals, sea slugs)

10. Photosynthesis
Why should we care?

12. Photosynthesis How does it work? Light capture (energy storage)
Conversion of CO2 and H2O to sugar

13. Photosynthesis How does it work? Light capture (energy storage)
Light reactions
Conversion of CO2 and H2O to sugar
Calvin Cycle

14. The light reactions take place
in the thylakoids
The Calvin cycle take place in the stroma

15. The “energy currency” of the cell:
Sunlight is an energy source that is hard to spend in the cell.
It’s kind of like having a really big bill in your pocket: you’re
rich, but you can’t use it!

16. The “energy currency” of the cell:
By contrast, the molecules ATP and NADPH are easily spent,
like pocket change: chemical bond energy stored in these
molecules is easily released, making these molecules quick
sources of energy for cellular reactions.

17. Four things happen in the light reactions of photosynthesis:
1. Chlorophyll absorbs light energy
2. Some of this energy is transferred to chemical bond energy in the manufacture of ATP
3. Some of the energy is used to split water (H2O) into H and O. The O is released from the plant as molecular oxygen.
4. The H from the water combines with NADP+ to form NADPH.

20. atomic number = 6

21. Figure 10.10 Excitation of isolated chlorophyll by light
In fluorescent molecules, energy excites electrons in the molecules, boosting them to a higher energy state. As the electrons return to their normal, or ground, state, they give off some of that energy as light.
When light impinges on the chlorophyll molecule, electrons are similarly boosted to a higher state. However, the electron does not return directly to its ground state, but rather leaves the atom and is transferred to another molecule that accepts it, an electron acceptor molecule.

23. Figure 10.13 A mechanical analogy for the light reactions
Light energy impinges on photosystem I, exciting an electron and boosting it to a higher energy state. The electron is then passed to an electron acceptor molecule, which then passes it to another (like an electron bucket-brigade), until they are accepted by the compound NADP+. The NADP+. the electrons (e-), and protons present in the chloroplast, unite to form NADPH.

24. Figure How noncyclic electron flow during the light reactions generates ATP and NADPH (Layer 5)
In the chloroplast, chlorophyll and associated electron acceptor molecules are arranged into units called photosystems. There are two kinds, Photosystem One and Photosystem Two, each of which uses a slightly different form of chlorophyll. The photosystems are located in the
thylakoid membrane system inside the chloroplast.

25. Figure 10.13 A mechanical analogy for the light reactions
Photosystem II is similarly activated by light energy. Again, when this happens, an electron lost from the chlorophyll molecule is boosted up, and is accepted by an electron acceptor molecule. It is then passed from one electron acceptor molecule to another through an electron transport chain. A little bit of energy is lost at each step along the way, energy that is captured and used to make ATP.

26. Summary of the Light Reactions
Figure An overview of photosynthesis: cooperation of the light reactions and the Calvin cycle (Layer 2)
Summary of the Light Reactions
In summary, in the light reactions, energy from the sun is used to generate ATP and NADPH. In the process, water is consumed and oxygen is given off. The ATP and NADPH made during the light reactions are used to power the Calvin cycle.

27. The Calvin Cycle
In the Calvin Cycle, solar energy that was captured and stored (as ATP and NADPH) in the light reactions is used to convert carbon dioxide to sugar.
How does this happen?

28. How to make sugar (C6H12O6) from
carbon dioxide (CO2)?

29. The light reactions take place in the thylakoids
The carbon dioxide used in photosynthesis enters the leaf at the stomates.
Once inside the spongy mesophyll of the leaf, the CO2 diffuses across the cell membrane and into the stroma of the chloroplast.
The Calvin cycle take place in the stroma

30. = carbon atom + + CO2 CO2 RuBP RuBP PGA PGA Glucose
The CO2 is then transformed into sugars in a series of steps. Let’s keep track of the steps by thinking about the number of carbon atoms in the compounds being produced: you start with one, from the CO2. The CO2 entering the chloroplast is captured by an enzyme and attached to a sugar molecule with 5 carbon atoms. Now you have a 6-carbon sugar molecule.
In the next step, the 6-carbon sugar is broken into two 3-carbon sugar molecules called PGA.
The PGA is then, in a series of steps powered by chemical energy supplied by ATP and NADPH, converted into glucose and other 6-carbon sugars. Some, however, is converted into more of the 5-carbon sugar used in step one. Thus the process is a cycle, named the Calvin cycle for Milton Calvin, the physiologist who first elucidated the process.
PGAL P P P P P P
PGAL

31. Figure An overview of photosynthesis: cooperation of the light reactions and the Calvin cycle (Layer 3)

32. Figure Sunbeams

33. Respiration
Next we will focus on the process of cellular respiration, in which energy that enters the biosphere as solar energy and is captured as chemical (food) energy during photosynthesis is burned to release that energy for doing work.

34. All cells in the plant body carry out cellular respiration!

35. Respiration What is it? Who does it? How does it work?
Why should we care?
C6H12O6 + 6O2  6CO2 + 6H2O
Plants, animals, fungi, bacteria

36. Respiration How does it work? Why should we care?
C6H12O6 + 6O2  6CO2 + 6H2O
Produces chemical energy, which powers cells:
Without it, you’re dead!

37. Respiration How does it work? C6H12O6 + 6O2  6CO2 + 6H2O
Energy released by this reaction is used to make
ATP.
energy stored in sugar
energy stored in ATP

38. Respiration How does it work? Cytoplasm Glycolysis Mitochondria
Krebs cycle
Electron transport

39. CO2

40. The last electron acceptor molecule passes its electrons to oxygen to produce a molecule of water. It is because oxygen is required as the final electron acceptor in the electron transport chain that oxygen is required for aerobic respiration.