1. Light Dependent / Light Independent Reactions
Biology Module 1
Light Dependent / Light Independent
Reactions
Presentation by Dr. Han Ong and
Gayle Ross
Arkansas Science Specialist

2. Where do the reactions happen inside the chloroplast?
Biology Module 1
Where do the reactions happen inside the chloroplast?
H2O
CO2
Light Independent/
Calvin Cycle
Light dependent
The light dependent reaction supplies the energy for the light independent reaction
ATP
NADPH
Light dependent supplies energy for Calvin Cycle O2
Carbohydrates
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3. Biology Module 1
Light Dependent
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4. Capturing light through light absorbing pigments
Biology Module 1
Capturing light through light absorbing pigments
Photosynthetic organisms posses specialized pigments to harvest visible and infrared light
These pigments are called chromophores
Chromophores exist in many different forms, depending on what types of light are available to be harvested
Look at the size and complexity of these molecules. In living systems, complex molecules require lots of energy to produce, so they must be very important.
 - carotene
Phycoerythrin
Chlorophyll
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5. Absorption spectra of chromophores
Biology Module 1
Absorption spectra of chromophores
A peak is where the specific light quality is absorbed
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6. Biology Module 1
Why are plants green?
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7. Biology Module 1
Why are plants green?
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8. Biology Module 1
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9. Absorption spectra of chromophores
Biology Module 1
Absorption spectra of chromophores
A peak is where the light is absorbed
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10. How do chromophores harvest light energy?
Biology Module 1
How do
chromophores
harvest light energy?
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11. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
I. Resonance transfer
Excited state
An electron is at rest in a ground state
electron
Ground state
Molecule I
Molecule II 1
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12. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
I. Resonance transfer
Excited state
Radiation or photon energy (usually from light) irradiates the ground state electron
Energy
(light)
Ground state
Molecule I
Molecule II 2
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13. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
I. Resonance transfer
Excited state
The photon energy shifts the electron to an excited state
Ground state
Molecule I
Molecule II 3
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14. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
I. Resonance transfer
Excited state
Because an electron cannot remain at an excited state for long, it starts to lose its energy as it returns to the ground state
Ground state
Molecule I
Molecule II 4
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15. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
I. Resonance transfer
Excited state
The energy released from the first electron excites a neighboring electron from a ground state to an excited state.
This process is called resonance transfer.
Ground state
Molecule I
Molecule II 5
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16. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
I. Resonance transfer
Excited state
The process continues as the energy is relayed to excite other neighboring electrons.
Ground state
Molecule I
Molecule II 6
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17. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
II. Electron transfer
Excited state
The process of electron transfer begins the same way as resonance transfer
Energy
(light)
Ground state
Molecule I
Molecule II 7
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18. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
II. Electron transfer
Excited state
However, instead of returning to the ground state, the electron of Molecule I is transferred directly to Molecule II, where it loses a little bit of energy
Ground state
Molecule I
Molecule II 8
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19. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
II. Electron transfer
Excited state
However, instead of returning to the ground state, the electron of Molecule I is transferred directly to Molecule II, where it loses a little bit of energy
Ground state
Molecule I
Molecule II 9
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20. Photoexcitation: harvesting energy from excited molecules
Biology Module 1
Photoexcitation: harvesting energy from excited molecules
II. Electron transfer
Excited state
The lost of the electron makes Molecule I positively charged, and Molecule II negatively charged.
The electron continues to be transferred to other molecules, until all energy has been lost.
Ground state
Molecule I
Molecule II 10
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21. Resonance & electron transfer in chlorophyll
Biology Module 1
Resonance & electron transfer in chlorophyll
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22. Biology Module 1
Harvested electron is channeled to the thylakoid membrane to start the light dependent reaction
The electron is funneled by chlorophyll pigments to activate the first photosystem (Photosystem II or P680)
It is the second photosystem discovered, and absorbs light at 680nm
light
Photosystem II
(P680)
Cytochrome bf
Photosystem I
(P700)
Remember, photosystem I is named I because it was discovered first! A A
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23. Biology Module 1
Harvested electron is channeled to the thylakoid membrane to start the light dependent reaction
Energy transferred to PSII allows it to draw an electron from a water molecule
The electron is transferred to a series of electron acceptor molecules
Oxygen and ATP molecules are produced
light
Photosystem II
(P680)
Cytochrome bf
Photosystem I
(P700) A A
H2O O2
ATP
production
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24. Biology Module 1
Harvested electron is channeled to the thylakoid membrane to start the light dependent reaction
The electron is passed on to cytochrome bf, an intermediate acceptor molecule
More ATP is produced
The electron is passed on to more acceptor molecules
light
Photosystem II
(P680)
Cytochrome bf
Photosystem I
(P700) A A
H2O O2
ATP
ATP
production
production
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25. Biology Module 1
Harvested electron is channeled to the thylakoid membrane to start the light dependent reaction
The electron is passed on to Photosystem I (or P700), and it is excited again by harvested light energy
The electron is passed through more aceptor molecules
Energy transferred from this process is used to produce a NADPH molecule
light
light
NADPH
production A
Photosystem II
(P680)
Cytochrome bf
Photosystem I
(P700) A A
H2O O2
ATP
ATP
production
production
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26. A different view of the light dependent reaction
Biology Module 1
A different view of the light dependent reaction A A A A A A
light A
Energy potential A A A
light
Photosystem I
(P700)
Photosystem II
(P680)
Products:
ATP
ATP
H2O O2
NADPH
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27. Where do the reactions happen inside the chloroplast?
Biology Module 1
Where do the reactions happen inside the chloroplast?
H2O
CO2
NADP+
ADP
Light dependent
Light Independent/
Calvin Cycle
ATP
NADPH
Light independent uses energy supplied by light reaction to reduce atmospheric CO2 into carbohydrates O2
Carbohydrates
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28. Light Independent/ Calvin Cycle Biology Module 1
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29. Light Independent is a cyclic process
Biology Module 1
Light Independent is a cyclic process
Several acceptor molecules are used in the
process to produce a carbohydrate
molecule
These acceptor molecules must then be
re-cycled to produce more carbohydrates
This cycle is called the Calvin cycle
Light Independent = Calvin Cycle
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30. Biology Module 1
Melvin Calvin ( )
University of California, Berkeley
Tracked radioactive-labeled carbon (in CO2) as it travels through the plant during photosynthesis
Found that the radioactive-labeled carbon is incorporated into carbohydrates formed by the plant
The process was named the Calvin-Benson-Bassham cycle
Nobel Prize in Chemistry, 1961
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31. The Calvin Cycle- Light Independent CO2 Rubisco
Biology Module 1
The Calvin Cycle-
Light Independent
CO2
Three carbon dioxide molecules are fixed in the stroma of chloroplasts by an enzyme known as ribulose-1,5-biphosphate carboxylase….or simply called Rubisco
Rubisco
There are 3 parts of the calvin cycle Blue-fix Carbon from the air, Green-carbon is reduced or assembled into carbohydrates, Yellow regenerates the molecules involved
Rubisco is the most abundant enzyme on Earth: about 40 million tons, or about 20 pounds per every living person but it is only found in photosynthetic organisms
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32. The Calvin Cycle- Light Independent CO2 Carbohydrates ATP ADP NADPH
Biology Module 1
The Calvin Cycle-
Light Independent
CO2
Fixation
One ATP and one NADPH molecule (supplied by the light reaction) is used to further reduce the fixed carbons
Reduction
ATP
ADP
NADPH
NADP+
Carbohydrates
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33. The Calvin Cycle Light Independent CO2 Carbohydrates ADP ATP
Biology Module 1
ATP
ADP
Another ATP molecule is used to recycle the acceptor molecule in order to receive more fixed carbon dioxide, and the cycle continues
The Calvin Cycle
Light Independent
CO2
Fixation
Reduction
Carbohydrates
Regeneration
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34. The Calvin Cycle- Light Independent (a more complex view)
Biology Module 1
The Calvin Cycle-
Light Independent
(a more complex view)
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35. How efficient is the photosynthetic process?
Biology Module 1
How efficient is the photosynthetic process?
The efficiency to fix and store one molecule of CO2 = ~28%
Only certain wavelength of light can be absorbed ( nm), which equals ~43% of total solar radiation
Canopy limits light absorption to 80%
Respiration and other processes use 33% of energy stored in leaves, leaving 67% of energy
Overall efficiency = 0.28 X 0.43 X 0.8 X 0.67 = 0.065
Therefore, as a biochemical process, photosynthesis has a 6.5% efficiency!
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36. Frameworks Strand: Molecules and Cells
Biology Module 1
Frameworks
Strand: Molecules and Cells
Standard 3: Students shall demonstrate an understanding of how cells obtain and use
energy (energetics).
MC.3.B.1
Compare and contrast the structure and function of mitochondria and chloroplasts
MC.3.B.2
Describe and model the conversion of stored energy in organic molecules into usable cellular energy (ATP):
glycolysis
citric acid cycle
electron transport chain
MC.3.B.3
Compare and contrast aerobic and anaerobic respiration:
lactic acid fermentation
alcoholic fermentation
MC.3.B.4
Describe and model the conversion of light energy to chemical energy by photosynthetic organisms:
light dependent reactions
light independent reactions
MC.3.B.5
Compare and contrast cellular respiration and photosynthesis as energy conversion pathways
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