1. Photosynthesis
Chapter 5

2. Overview of Photosynthesis
Converts solar energy (sunlight) into chemical energy which is used to build carbohydrate molecules
6CO2 + 6H2O + energy (sunlight)  C6H12O6 +6O2
Energy used to hold the carbohydrate molecules together is released by cellular respiration
C6H12O6 +6O2  6CO2 + 6H2O + energy (ATP)

3. Overview of Photosynthesis
Photosynthesizers
Autotrophs
Auto = self
Troph = feeder
Includes plants, algae from Kingdom Protista, cyanobacteria, and some archaebacteria
Major producers for most food webs
Algae
Kingdom Protista
Volvox
Cyanobacteria
Anabaena

4. Overview of Photosynthesis
Non photosynthesizers
Heterotrophs
Hetero = other
Troph = feeder
Rely on producers directly (herbivore) or indirectly (carnivore)
Includes fungi, animals, some Protists, and some bacteria
Kingdom Protista
Stentor and Amoeba

5. Main Structures of Photosynthesis
Photosynthesis occurs in chloroplasts contained in photosynthetic cells within the leaves (or other green parts of the plant)

6. Main Structures of Photosynthesis
Leaves
Leaves have multiple cell layers and tissues
Upper and lower epidermis (non-photosynthetic)
Palisade and spongy mesophyll (photosynthetic)
Bundle sheath cells surrounding veins
Xylem (transports water and dissolved nutrients)
Phloem (transports photosynthetic products)
Most photosynthesis occurs in mesophyll cells

7. Main Structures of Photosynthesis
Leaves
Leaves have stomata
Small, regulated openings through the leaf epidermis
Gas exchange occurs through stomata
CO2 enters
H2O and O2 exit

8. Main Structures of Photosynthesis
Chloroplasts
Structure
Surrounded by a double membrane (envelope)
The inner semi-fluid matrix is called the stroma
The thylakoid membrane is a third internal membrane
Extensively folded into thylakoid disks tightly stacked in grana
Function
Light is harvested and converted into chemical energy over the thylakoid membrane
Sugars are built in the stroma

10. Main Structures of Photosynthesis
Thylakoid membrane
Contains pigments and photosystems

11. Main Structures of Photosynthesis
Thylakoid membrane
Pigments absorb wavelengths of visible light
Part of the electromagnetic spectrum from the sun

12. Main Structures of Photosynthesis
Thylakoid membrane
Pigments absorb wavelengths of visible light
Can be described and measured as waves
Wavelength is inversely related to energy level
Long wavelength = low energy and short wavelength = high energy

13. Main Structures of Photosynthesis
Thylakoid membrane
Pigments absorb wavelengths of visible light
Organized as packets of energy called photons

14. Main Structures of Photosynthesis
Thylakoid membrane
Pigments absorb wavelengths of visible light
Chlorophyll a
Main photosynthetic pigment
Absorbs violet and red light
Reflects green light

15. Main Structures of Photosynthesis
Thylakoid membrane
Pigments absorb wavelengths of visible light
Accessory pigments
Chlorophyll b
Carotenoids (reflects yellow, orange, or red)
Lycopenes (reflects yellow, orange, or red)
Xanthophyls (reflects yellow or brown)
Phycobilins (reflects red)

16. Main Structures of Photosynthesis
Thylakoid membrane
Contains photosystems
Groups of pigments and other molecules
There are two photosystems
Photosystem II (absorbs light at 680nm)
Photosystem I (absorbs light at 700nm)

17. Questions What is a photoautotroph?
What organelle is used for photosynthesis?
Photosynthetic organelles are found in __________ cells
What happens in the stroma?
What is the chloroplast’s third membrane called?
Which pigment is the main photosynthetic pigment?
Chlorophyll a is green. What does this mean in terms of absorbed and reflected light?

18. Questions
Name each indicated structure E F

19. Light Dependent Reactions
Light energy is converted into high-energy chemical carriers that will be used in the Calvin Cycle
ATP and NADPH
Occurs over the thylakoid membrane

20. Light Dependent Reactions
Photon energy is absorbed by pigments and passed along a pathway to other chlorophyll molecules
Energy is transferred to electrons enabling them to break free from the chlorophyll molecule
Chlorophyll is an electron donor (oxidized)
Electrons are accepted by the first molecule of the electron transfer chain (reduced)

21. Light Dependent Reactions
Replacement electrons are pulled from water molecules
Water is split into oxygen, electrons, and hydrogen ions (H+)
H2O  ½ O2 + 2e- + 2H+
This is referred to as photolysis
Hydrogen ions accumulate in the thylakoid space*
Oxygen diffuses out of the cell as O2

22. Light Dependent Reactions
High energy electrons enter the electron transport chain (ETC)
Each ETC molecule accepts the electrons (reduced) and then donates them (oxidized) to the next molecule

23. Light Dependent Reactions
Energy released by the electrons as they move through the chain is used to pump H+ from the stroma into the thylakoid space
Active transport
H+ concentration increases*
The electrons are ultimately accepted by a pigment molecule in photosystem I

24. Light Dependent Reactions
Photons are captured by photosystem I re-energizing the electrons

25. Light Dependent Reactions
High-energy electrons leave photosystem I where they are ultimately donated to NADP+ to form NADPH
NADP+ + 2 e- + H+  NADPH
NADPH is a high-energy molecule that will be used to make sugar molecules
The process results in a decrease of H+ in the stroma and thus an increase in the H+ concentration in the thylakoid space*

26. Light Dependent Reactions
The build-up of H+ in the thylakoid space creates an electrochemical gradient
Due to photolysis, ETC active transport of H+, and production of NADPH
Chemical because of the concentration difference of H+
Electrical because of the difference in the charge across the membrane

27. Light Dependent Reactions
The electrochemical gradient propels H+ across the thylakoid membrane through ATP synthase
Chemiosmosis
The flow of H+ has enough force to cause the synthase to attach a phosphate to ADP forming ATP
Phosphorylation
ATP is a high-energy molecule that will be used to make sugar molecules

28. Light Dependent Reactions
Summary
The light-dependent reactions capture and convert the sun’s radiant energy into ATP (chemical bond energy) and NADPH
ATP and NADPH will be used in the light-independent reactions (Calvin- Benson Cycle) to build sugar molecules
H2O is split to provide the electrons for the electron transport chain
Releases O2

29. Questions For each indicated location
Name any structures or molecules involved
Explain what is happening

31. Questions Where do the light-dependent reactions occur?
How are electrons replaced in photosystem II? (what is the process called?)
Energy from electrons is used for what process by the electron transport chain?
What molecule do the high-energy electrons finally end up in?
What processes result in the H+ electrochemical gradient?
What structure catalyzes phosphorylation of ADP to ATP?

32. Light Independent Reactions
During the light-independent reactions (Calvin-Benson Cycle) chemical energy from ATP and NADPH are used to build glucose from CO2
Fixes inorganic CO2 into organic molecules
Occurs in the stroma

33. Light Independent Reactions
Calvin-Benson Cycle
Major molecules involved
CO2 carbon dioxide
RuBP ribulose-1,5-bisphosphate
PGA 3-phosphoglyceric acid
PGAL/G3P glyceraldehyde-3-phosphate

34. Light Independent Reactions
Calvin-Benson Cycle
phases
Carbon Fixation
Reduction
Regeneration

35. Light Independent Reactions
Calvin-Benson Cycle
Carbon Fixation (RuBP  PGA)
CO2 is attached to RuBP (a 5-carbon molecule)
Catalyzed by the enzyme RuBisCO
A 6-carbon intermediate is formed which is converted immediately into two 3-carbon molecules called PGA
CO2 is “fixed” from its inorganic form into organic molecules

36. Light Independent Reactions
Calvin-Benson Cycle
Reduction (PGA  PGAL)
ATP provides energy
Releases ADP
NADPH donates high energy electrons and H+
Reduction
Releases NADP+
ADP and NADP+ return to the light- dependent reactions

37. Light Independent Reactions
Calvin-Benson Cycle
Reduction (PGA  PGAL)
PGAL/G3P is produced
Some is released to make glucose
2 PGAL  Glucose (C6H12O6)
The remainder is recycled in the next phase

38. Light Independent Reactions
Calvin-Benson Cycle
Regeneration (PGAL  RuBP)
ATP provides energy
Releases ADP
Multiple bond rearrangement steps regenerate RuBP
Thus the pathway is a “cycle”

39. Light Independent Reactions
Calvin-Benson Cycle
The cycle continues to repeat
It takes 6 CO2 molecules to produce 1 molecule of glucose

40. Photosynthesis Overview
Process:
Photo:
Light-dependent reactions split H2O and produce ATP, NADPH, and O2
Synthesis:
Light-independent reactions use ATP, NADPH, and CO2 to produce glucose
LIGHT ENERGY
C6H12O6 + 6O2
glucose
6H2O + 6CO2

41. Questions Light-independent reactions use ATP and NADPH to build what?
What is the name of the metabolic pathway used for the light-independent reactions?
What is the reaction called when CO2 binds to RuBP?
What enzyme is responsible for the above reaction?
Two of which intermediate are used to make glucose?
How many CO2 molecules are required to make one glucose molecule?

42. Questions Identify the molecules 6 A C ATP 3ADP Calvin-Benson
cycle
6ADP + 6Pi 3
ATP 6 D
2Pi
6NADP+
5PGAL E
1 Pi F

43. Alternate Carbon-fixing Pathways
C3 Plants
Most plants harvest and convert light energy while fixing CO2 into organic sugars at the same time in mesophyll cells
They are referred to as C3 plants because the first stable intermediate (PGA) is a 3- carbon molecule
Typically found in temperate climates
Inefficient on hot, dry days and suffer lower productivity due to photorespiration

44. Alternate Carbon-fixing Pathways
C3 plants have a problem in hot climates
To reduce H2O loss, they close their stomata which are used for gas exchange
CO2, O2 and H2O
Closed stomata means that
H2O and O2 can’t exit
CO2 can’t enter
Reduced CO2 and increased O2 concentrations results in photorespiration
Thus C3 plants are faced with two bad choices on hot days
Wilt due to water loss or
Have reduced productivity due to photorespiration
Stomata surrounded by guard cells
H2O O2
CO2

45. Alternate Carbon-fixing Pathways
Photorespiration
Without CO2 no PGAL/G3P will be synthesized
Rubisco binds O2 instead of CO2 forming a useless molecule
Wastes CO2 and energy
The result:
No glucose is synthesized
Reduced or no productivity (growth)
The adaptation
Use alternate carbon-fixing pathways

46. Alternate Carbon-fixing Pathways
Alternate Pathways
Some plants that live in hot climates have adaptations to circumvent photorespiration
When they can take in CO2 they create a chemical which stores the CO2 to be used later or in a different cell type in the Calvin- Benson Cycle

47. Alternate Carbon-fixing Pathways
Alternate Pathways: C4 plants
When the stomata are open CO2 is fixed into a 4 carbon intermediate in mesophyll cells (thus called C4 plants)
The enzyme used ignores O2, so no photorespiration occurs
Provides a “storage” of CO2 for the plant

48. Alternate Carbon-fixing Pathways
Alternate Pathways: C4 plants
The 4 carbon molecule moves into the bundle-sheath cells
CO2 is released from the C4 molecule and used in the Calvin-Benson pathway to produce sugar

49. Alternate Carbon-fixing Pathways
Alternate Pathways: C4 plants
Divides photosynthesis between different cells
Typically found in tropical climates

50. Alternate Carbon-fixing Pathways
Alternate Pathways: CAM plants
The stomata are only open at night when it is cooler
CO2 is fixed into a 4 carbon molecule at night
Crassulacean acid metabolism (CAM)
The cell “stores” CO2 in the central vacuole as part of a C4 intermediate
During the day CO2 is shuttled back into the chloroplast for the Calvin/Benson cycle

51. Alternate Carbon-fixing Pathways
Alternate Pathways: CAM plants
Divides photosynthesis between night and day
Typically found in desert climates

52. Questions Stomata A. Fixes CO2 at night
Photorespiration B. Openings on leaves
Rubisco C. Temperate plants
C3 plant D. Uses bundle sheath cells
C4 plant E. Enzyme used to fix CO2
CAM plant F. Location of Calvin Cycle in C4 plants
Bundle sheath cells G. Result of too much O2 and not enough CO2

53. Summary Photosynthesis structures Light dependent reactions
Chloroplasts
Pigments
Light dependent reactions
Light independent reactions
Calvin-Benson Cycle
Alternate pathways