1. Lecture and Animation Outline
Chapter 08
Lecture and Animation Outline
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2. Photosynthesis
Chapter 8 2

3. Heat Sunlight Photo- system II Photo- system I O2 Electron Transport
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Heat
Sunlight
Photo-
system II
Photo-
system I O2
Electron
Transport
System
ATP
H2O
ADP + Pi
ADP + Pi
ATP
NADP+
NADPH
NAD+
NADH
Calvin
Cycle
CO2
Krebs
Cycle
ATP
Glucose
Pyruvate
ADP + Pi
ATP

4. Photosynthesis Overview
Energy for all life on Earth ultimately comes from photosynthesis
6CO2 + 12H2O C6H12O6 + 6H2O + 6O2
Oxygenic photosynthesis is carried out by
Cyanobacteria
7 groups of algae
All land plants – chloroplasts

5. Chloroplast Thylakoid membrane – internal membrane
Contains chlorophyll and other photosynthetic pigments
Pigments clustered into photosystems
Grana – stacks of flattened sacs of thylakoid membrane
Stroma lamella – connect grana
Stroma – semiliquid surrounding thylakoid membranes

6. Courtesy Dr. Kenneth Miller, Brown University
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Cuticle
Epidermis
Mesophyll
Vascular bundle
Stoma
Vacuole
Cell wall
1.58 mm
Inner membrane
Chloroplast
Outer membrane
Courtesy Dr. Kenneth Miller, Brown University

7. Courtesy Dr. Kenneth Miller, Brown University
Cuticle
Epidermis
Mesophyll
Vascular bundle
Stoma
Vacuole
Cell wall
1.58 mm
Inner membrane
Chloroplast
Outer membrane
Courtesy Dr. Kenneth Miller, Brown University

8. Stages Light-dependent reactions
Require light
Capture energy from sunlight
Make ATP and reduce NADP+ to NADPH
Carbon fixation reactions or light-independent reactions
Does not require light
Use ATP and NADPH to synthesize organic molecules from CO2

9. Light-Dependent Reactions Calvin Cycle Organic molecules
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Sunlight
Photosystem
Photosystem
H2O O2 O2
Thylakoid
Light-Dependent
Reactions
ADP + Pi
ATP
NADP+
NADPH
Calvin
Cycle
Organic
molecules
CO2
Stroma

10. Discovery of Photosynthesis
Jan Baptista van Helmont (1580–1644)
Demonstrated that the substance of the plant was not produced only from the soil
Joseph Priestly (1733–1804)
Living vegetation adds something to the air
Jan Ingenhousz (1730–1799)
Proposed plants carry out a process that uses sunlight to split carbon dioxide into carbon and oxygen (O2 gas)

11. F.F. Blackman (1866–1947)
Came to the startling conclusion that photosynthesis is in fact a multistage process, only one portion of which uses light directly
Light versus dark reactions
Enzymes involved
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Maximum rate
Excess CO2; 35ºC
Temperature limited
Increased Rate of Photosynthesis
Excess CO2; 20ºC
Light limited
CO2 limited
Insufficient CO2 (0.01%); 20ºC
500
1000
1500
2000
2500
Light Intensity (foot-candles)

12. C. B. van Niel (1897–1985) Robin Hill (1899–1991)
Found purple sulfur bacteria do not release O2 but accumulate sulfur
Proposed general formula for photosynthesis
CO2 + 2 H2A + light energy → (CH2O) + H2O + 2 A
Later researchers found O2 produced comes from water
Robin Hill (1899–1991)
Demonstrated Niel was right that light energy could be harvested and used in a reduction reaction

13. Pigments Molecules that absorb light energy in the visible range
Light is a form of energy
Photon – particle of light
Acts as a discrete bundle of energy
Energy content of a photon is inversely proportional to the wavelength of the light
Photoelectric effect – removal of an electron from a molecule by light

14. Increasing wavelength
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Increasing energy
Increasing wavelength
0.001 nm
1 nm
10 nm
1000 nm
0.01 cm
1 cm
1 m
100 m UV
light
Gamma rays
X-rays
Infrared
Radio waves
Visible light
400 nm
430 nm
500 nm
560 nm
600 nm
650 nm
740 nm

15. Absorption spectrum
When a photon strikes a molecule, its energy is either
Lost as heat
Absorbed by the electrons of the molecule
Boosts electrons into higher energy level
Absorption spectrum – range and efficiency of photons molecule is capable of absorbing

16. high Absorbtion Light low 400 450 500 550 600 650 700 Wavelength (nm)
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high
carotenoids
chlorophyll a
chlorophyll b
Absorbtion
Light
low
400
450
500
550
600
650
700
Wavelength (nm)

17. Pigments in Photosynthesis
Organisms have evolved a variety of different pigments
Only two general types are used in green plant photosynthesis
Chlorophylls
Carotenoids
In some organisms, other molecules also absorb light energy

18. Chlorophylls Chlorophyll a Chlorophyll b
Main pigment in plants and cyanobacteria
Only pigment that can act directly to convert light energy to chemical energy
Absorbs violet-blue and red light
Chlorophyll b
Accessory pigment or secondary pigment absorbing light wavelengths that chlorophyll a does not absorb

19. Structure of chlorophyll porphyrin ring
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Structure of chlorophyll
porphyrin ring
Complex ring structure with alternating double and single bonds
Magnesium ion at the center of the ring
Photons excite electrons in the ring
Electrons are shuttled away from the ring
Chlorophyll a: R =
CH3
H2C CH H R
Chlorophyll b: R =
CHO
H3C
CH2CH3
Porphyrin
head N N H Mg H N N
H3C
CH3 H H H O
CH2
CO2CH3
CH2 O C O
CH2 CH
CCH3
CH2
CH2
CH2
CHCH3
Hydrocarbon
tail
CH2
CH2
CH2
CHCH3
CH2
CH2
CH2
CHCH3
CH3

20. Copyright © The McGraw-Hill Companies, Inc
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high
Oxygen-seeking bacteria
Absorbtion
Light
Filament of green algae
low
Action spectrum
Relative effectiveness of different wavelengths of light in promoting photosynthesis
Corresponds to the absorption spectrum for chlorophylls

21. © Eric Soder/pixsource.com
Carotenoids
Carbon rings linked to chains with alternating single and double bonds
Can absorb photons with a wide range of energies
Also scavenge free radicals – antioxidant
Protective role
Phycobiloproteins
Important in low-light ocean areas
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Oak leaf
in summer
Oak leaf
in autumn
© Eric Soder/pixsource.com

22. Photosystem Organization
Antenna complex
Hundreds of accessory pigment molecules
Gather photons and feed the captured light energy to the reaction center
Reaction center
1 or more chlorophyll a molecules
Passes excited electrons out of the photosystem

23. Antenna complex Also called light-harvesting complex
Captures photons from sunlight and channels them to the reaction center chlorophylls
In chloroplasts, light-harvesting complexes consist of a web of chlorophyll molecules linked together and held tightly in the thylakoid membrane by a matrix of proteins

24. Photosystem Electron acceptor Photon e– Electron donor e–
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Photosystem
Electron
acceptor
Photon e–
Electron
donor e–
Reaction center
chlorophyll
Chlorophyll
molecule
Thylakoid membrane
Thylakoid membrane

25. Reaction center Transmembrane protein–pigment complex
When a chlorophyll in the reaction center absorbs a photon of light, an electron is excited to a higher energy level
Light-energized electron can be transferred to the primary electron acceptor, reducing it
Oxidized chlorophyll then fills its electron “hole” by oxidizing a donor molecule

26. Excited chlorophyll molecule Chlorophyll reduced Chlorophyll oxidized
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Excited
chlorophyll
molecule
Light
Electron
donor
Electron
acceptor e– e– e– e–
Chlorophyll
reduced
Chlorophyll
oxidized
Donor
oxidized
Acceptor
reduced + – + – e– e– e– e–

27. Light-Dependent Reactions
Primary photoevent
Photon of light is captured by a pigment molecule
Charge separation
Energy is transferred to the reaction center; an excited electron is transferred to an acceptor molecule
Electron transport
Electrons move through carriers to reduce NADP+
Chemiosmosis
Produces ATP
Capture of light energy

28. Cyclic photophosphorylation
In sulfur bacteria, only one photosystem is used
Generates ATP via electron transport
Anoxygenic photosynthesis
Excited electron passed to electron transport chain
Generates a proton gradient for ATP synthesis

29. b-c1 complex Reaction center (P870)
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High
Excited reaction center e–
Electron
acceptor
Energy of electrons
b-c1
complex e–
ATP
Reaction
center (P870)
Low
Photon
Electron
acceptor e–
Photosystem

30. Chloroplasts have two connected photosystems
Oxygenic photosynthesis
Photosystem I (P700)
Functions like sulfur bacteria
Photosystem II (P680)
Can generate an oxidation potential high enough to oxidize water
Working together, the two photosystems carry out a noncyclic transfer of electrons that is used to generate both ATP and NADPH

31. Photosystem I transfers electrons ultimately to NADP+, producing NADPH
Electrons lost from photosystem I are replaced by electrons from photosystem II
Photosystem II oxidizes water to replace the electrons transferred to photosystem I
2 photosystems connected by cytochrome/ b6-f complex

32. Noncyclic photophosphorylation
Plants use photosystems II and I in series to produce both ATP and NADPH
Path of electrons not a circle
Photosystems replenished with electrons obtained by splitting water
Z diagram

33. Proton gradient formed
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Excited reaction center
2. The electrons pass through the b6-f
complex, which uses the energy
released to pump protons across
the thylakoid membrane. The proton
gradient is used to produce ATP by
chemiosmosis.
Ferredoxin 2 e– Fd
Excited reaction center
NADP
reductase 2
Plastoquinone e– e–
NADP+ + H+
NADPH PQ 2
b6-f
complex
Plastocyanin
Reaction
center
Energy of electrons 2 e– PC
Photon H+
Proton gradient formed
for ATP synthesis
Reaction
center
3. A pair of chlorophylls in the reaction
center absorb two photons. This excites two electrons that are passed to
NADP+, reducing it to NADPH. Electron
transport from photosystem II replaces
these electrons.
Photon 2
H2O e–
2H+ + 1/2O2
Photosystem I
Photosystem II
1. A pair of chlorophylls in the reaction center absorb two photons of light. This excites two electrons that
are transferred to plastoquinone (PQ). Loss of electrons from the reaction center produces an oxidation potential capable of oxidizing water.

34. Two photosystems high Rate of Photosynthesis low Far-red light on Off
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high
Rate of Photosynthesis
low
Far-red light on
Off
Red light on
Off
Both lights on
Off
Time

35. Photosystem II Resembles the reaction center of purple bacteria
Core of 10 transmembrane protein subunits with electron transfer components and two P680 chlorophyll molecules
Reaction center differs from purple bacteria in that it also contains four manganese atoms
Essential for the oxidation of water
b6-f complex
Proton pump embedded in thylakoid membrane

36. Photosystem I
Reaction center consists of a core transmembrane complex consisting of 12 to 14 protein subunits with two bound P700 chlorophyll molecules
Photosystem I accepts an electron from plastocyanin into the “hole” created by the exit of a light-energized electron
Passes electrons to NADP+ to form NADPH

37. Antenna complex Thylakoid membrane NADP reductase ATP synthase
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Photon
Light-Dependent
Reactions
Photon H+
ATP
ADP + Pi
ATP
NADP
NADPH
ADP
NADPH
Antenna
complex
Calvin H+ +
NADP+
Cycle
Thylakoid
membrane Fd 2 2 e– PQ e– 2 2 e–
Stroma 2 2 e– 2 2 PC
H2O H+
Proton H+
Plastoquinone
Plastocyanin
Ferredoxin
gradient H+
Water-splitting
enzyme H+
Thylakoid
space
1/2O2
2H+
NADP
reductase
ATP
synthase
Photosystem II
b6-f complex
Photosystem I
1. Photosystem II
absorbs photons,
exciting electrons
that are passed to
plastoquinone (PQ).
Electrons lost from
photosystem II are
replaced by the
oxidation of water,
producing O2
2. The b6-f complex
receives electrons
from PQ and passes
them to plastocyanin
(PC). This provides
energy for the b6-f
complex to pump
protons into the
thylakoid.
3. Photosystem I absorbs
photons, exciting
electrons that are
passed through a
carrier to reduce
NADP+ to NADPH.
These electrons are
replaced by electron
transport from
photosystem II.
4. ATP synthase uses
the proton gradient
to synthesize ATP
from ADP and Pi
enzyme acts as a
channel for protons
to diffuse back into
the stroma using this
energy to drive the
synthesis of ATP.

38. Chemiosmosis Electrochemical gradient can be used to synthesize ATP
Chloroplast has ATP synthase enzymes in the thylakoid membrane
Allows protons back into stroma
Stroma also contains enzymes that catalyze the reactions of carbon fixation – the Calvin cycle reactions

39. Production of additional ATP
Noncyclic photophosphorylation generates
NADPH
ATP
Building organic molecules takes more energy than that alone
Cyclic photophosphorylation used to produce additional ATP
Short-circuit photosystem I to make a larger proton gradient to make more ATP

40. Carbon Fixation – Calvin Cycle
To build carbohydrates cells use
Energy
ATP from light-dependent reactions
Cyclic and noncyclic photophosphorylation
Drives endergonic reaction
Reduction potential
NADPH from photosystem I
Source of protons and energetic electrons

41. Calvin cycle Named after Melvin Calvin (1911–1997)
Also called C3 photosynthesis
Key step is attachment of CO2 to RuBP to form PGA
Uses enzyme ribulose bisphosphate carboxylase/oxygenase or rubisco

42. 3 phases Carbon fixation Reduction Regeneration of RuBP
RuBP + CO2 → PGA
Reduction
PGA is reduced to G3P
Regeneration of RuBP
PGA is used to regenerate RuBP
3 turns incorporate enough carbon to produce a new G3P
6 turns incorporate enough carbon for 1 glucose

43. 3-phosphoglycerate (3C) (PGA) Ribulose 1,5-bisphosphate (5C) (RuBP)
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Stroma of chloroplast
Light-Dependent
Reactions
6 molecules of
Carbon
dioxide (CO2)
ADP + Pi
ATP
NADP+
NADPH
Calvin
Cycle
Rubisco
12 molecules of
6 molecules of
3-phosphoglycerate (3C) (PGA)
Ribulose 1,5-bisphosphate (5C) (RuBP)
12 ATP
PHASE 1
12 ADP
6 ADP
Regeneration of RuBP
12 molecules of
PHASE 3
Calvin Cycle
1,3-bisphosphoglycerate (3C)
6 ATP
12 NADPH
PHASE 2 4 Pi
Reduction
12 NADP+
10 molecules of 12 Pi
Glyceraldehyde 3-phosphate (3C)
12 molecules of
Glyceraldehyde 3-phosphate (3C) (G3P)
2 molecules of
Glyceraldehyde 3-phosphate (3C) (G3P)
Glucose and
other sugars

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45. Output of Calvin cycle
Glucose is not a direct product of the Calvin cycle
G3P is a 3 carbon sugar
Used to form sucrose
Major transport sugar in plants
Disaccharide made of fructose and glucose
Used to make starch
Insoluble glucose polymer
Stored for later use

46. Energy cycle
Photosynthesis uses the products of respiration as starting substrates
Respiration uses the products of photosynthesis as starting substrates
Production of glucose from G3P even uses part of the ancient glycolytic pathway, run in reverse
Principal proteins involved in electron transport and ATP production in plants are evolutionarily related to those in mitochondria

47. Heat Sunlight Photo- system II Photo- system I O2 Electron Transport
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Heat
Sunlight
Photo-
system II
Photo-
system I O2
Electron
Transport
System
ATP
H2O
ADP + Pi
ADP + Pi
ATP
NADP+
NADPH
NAD+
NADH
Calvin
Cycle
CO2
Krebs
Cycle
ATP
Glucose
Pyruvate
ADP + Pi
ATP

48. Photorespiration Rubisco has 2 enzymatic activities
Carboxylation
Addition of CO2 to RuBP
Favored under normal conditions
Photorespiration
Oxidation of RuBP by the addition of O2
Favored when stoma are closed in hot conditions
Creates low-CO2 and high-O2
CO2 and O2 compete for the active site on RuBP

49. Under hot, arid conditions, leaves lose water by
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Leaf
epidermis
Heat
H2O
H2O O2 O2
CO2
CO2
Stomata
Under hot, arid conditions, leaves lose water by
evaporation through openings in the leaves
called stomata.
The stomata close to conserve water but as a
result, O2 builds up inside the leaves, and CO2
cannot enter the leaves.

50. Types of photosynthesisC3
Plants that fix carbon using only C3 photosynthesis (the Calvin cycle)
C4 and CAM
Add CO2 to PEP to form 4 carbon molecule
Use PEP carboxylase
Greater affinity for CO2, no oxidase activity
C4 – spatial solution
CAM – temporal solution

51. a. C4 pathway b. C4 pathway Mesophyll cell Bundle-sheath cell CO2
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Mesophyll cell
Bundle-sheath cell
CO2
Mesophyll
cell
RuBP
Calvin
Cycle
3PG
(C3)
G3P
Stoma
Vein
a. C4 pathway
Mesophyll cell
Bundle-
sheath cell
CO2
Mesophyll
cell C4
Bundle-
sheath
cell
CO2
Calvin
Cycle
G3P
Stoma
Vein
b. C4 pathway
a: © John Shaw/Photo Researchers, Inc. b: © Joseph Nettis/National Audubon Society Collection/Photo Researchers, Inc.

52. C4 plants Corn, sugarcane, sorghum, and a number of other grasses
Initially fix carbon using PEP carboxylase in mesophyll cells
Produces oxaloacetate, converted to malate, transported to bundle-sheath cells
Within the bundle-sheath cells, malate is decarboxylated to produce pyruvate and CO2
Carbon fixation then by rubisco and the Calvin cycle

53. CO2 Mesophyll cell Phosphoenolpyruvate (PEP) Oxaloacetate AMP + PPi
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CO2
Mesophyll
cell
Phosphoenolpyruvate
(PEP)
Oxaloacetate
AMP +
PPi
ATP
+ Pi
Pyruvate
Malate
Pyruvate
Malate
Bundle-sheath
cell
CO2
Calvin
Cycle
Glucose

54. C4 pathway, although it overcomes the problems of photorespiration, does have a cost
To produce a single glucose requires 12 additional ATP compared with the Calvin cycle alone
C4 photosynthesis is advantageous in hot dry climates where photorespiration would remove more than half of the carbon fixed by the usual C3 pathway alone

55. CAM plants
Many succulent (water-storing) plants, such as cacti, pineapples, and some members of about two dozen other plant groups
Stomata open during the night and close during the day
Reverse of that in most plants
Fix CO2 using PEP carboxylase during the night and store in vacuole

56. When stomata closed during the day, organic acids are decarboxylated to yield high levels of CO2
High levels of CO2 drive the Calvin cycle and minimize photorespiration

57. (inset): © 2011 Jessica Solomatenko/Getty Images RF
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
night
CO2 C4
day
CO2
Calvin
Cycle
G3P
(inset): © 2011 Jessica Solomatenko/Getty Images RF

58. Compare C4 and CAM Both use both C3 and C4 pathways
C4 – two pathways occur in different cells
CAM – C4 pathway at night and the C3 pathway during the day

60. Antenna complex Thylakoid membrane NADP reductase ATP synthase
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Photon
Light-Dependent
Reactions
Photon H+
ATP
ADP + Pi
ATP
NADP
NADPH
ADP
NADPH
Antenna
complex
Calvin H+ +
NADP+
Cycle
Thylakoid
membrane Fd 2 2 e– PQ e– 2 2 e–
Stroma 2 2 e– 2 2 PC
H2O H+
Proton H+
Plastoquinone
Plastocyanin
Ferredoxin
gradient H+
Water-splitting
enzyme H+
Thylakoid
space
1/2O2
2H+
NADP
reductase
ATP
synthase
Photosystem II
b6-f complex
Photosystem I
1. Photosystem II
absorbs photons,
exciting electrons
that are passed to
plastoquinone (PQ).
Electrons lost from
photosystem II are
replaced by the
oxidation of water,
producing O2
2. The b6-f complex
receives electrons
from PQ and passes
them to plastocyanin
(PC). This provides
energy for the b6-f
complex to pump
protons into the
thylakoid.
3. Photosystem I absorbs
photons, exciting
electrons that are
passed through a
carrier to reduce
NADP+ to NADPH.
These electrons are
replaced by electron
transport from
photosystem II.
4. ATP synthase uses
the proton gradient
to synthesize ATP
from ADP and Pi
enzyme acts as a
channel for protons
to diffuse back into
the stroma using this
energy to drive the
synthesis of ATP.