1. Chapter 10
Photosynthesis

2. Figure 10.1 Sunlight consists of a spectrum of colors, visible here in a rainbow

3. Figure 10.2 Photoautotrophs
These organisms use light energy to drive the
synthesis of organic molecules from carbon dioxide
and (in most cases) water. They feed not only
themselves, but the entire living world. (a) On
land, plants are the predominant producers of
food. In aquatic environments, photosynthetic
organisms include (b) multicellular algae, such
as this kelp; (c) some unicellular protists, such
as Euglena; (d) the prokaryotes called
cyanobacteria; and (e) other photosynthetic
prokaryotes, such as these purple sulfur
bacteria, which produce sulfur (spherical
globules) (c, d, e: LMs).
(a) Plants
(b) Multicellular algae
(c) Unicellular protist
10 m
40 m
(c) Cyanobacteria
1.5 m
(d) Pruple sulfur
bacteria

4. Figure 10.3 Focusing in on the location of photosynthesis in a plant
Mesophyll cell
Mesophyll
Vein
Stomata
CO2 O2
Chloroplast
5 µm
1 µm
Leaf cross section
Outer membrane
Granum
Storma
Thylakoid
Thylakoid Space
Intermembrane space
Inner membrane

5. Figure 10.4 Tracking atoms through photosynthesis
6 CO2
12 H2O
Reactants:
Products:
C6H12O6
6 H2O
6 O2

6. Figure 10.5 An overview of photosynthesis: cooperation of the light reactions and the Calvin cycle
Chloroplast

7. Figure 10.5 An overview of photosynthesis: cooperation of the light reactions and the Calvin cycle
ATP
NADPH
Chloroplast O2

8. Figure 10.5 An overview of photosynthesis: cooperation of the light reactions and the Calvin cycle
[CH2O]
(sugar)
NADP
ADP
+ P i
H2O
Light
LIGHT REACTIONS
ATP
NADPH
Chloroplast

9. Figure 10.6 The electromagnetic spectrum
Gamma
rays
X-rays UV
Infrared
Micro-
waves
Radio
10–5 nm
10–3 nm
1 nm
103 nm
106 nm
1 m
103 m
380
450
500
550
600
650
700
750 nm
Visible light
Shorter wavelength
Higher energy
Longer wavelength
Lower energy

10. Figure 10.7 Why leaves are green: interaction of light with chloroplasts
Reflected
Chloroplast
Absorbed
light
Granum
Transmitted

11. Figure 10.8 Research Method Determining an Absorption Spectrum
APPLICATION An absorption spectrum is a visual
representation of how well a particular pigment absorbs different
wavelengths of visible light. Absorption spectra of various chloroplast
pigments help scientists decipher each pigment’s role in a plant.
TECNIQUE A spectrophotometer measures the relative
amounts of light of different wavelengths absorbed and
transmitted by a pigment solution. 2
The transmitted light strikes a photoelectric tube, which
converts the light energy to electricity. 3 4
The electrical current is measured by a galvanometer. The meter
indicates the fraction of light transmitted through the sample,
from which we can determine the amount of light absorbed.
White light is separated into colors (wavelengths) by a prism. 1
One by one, the different colors of light are passed through the
sample (chlorophyll in this example). Green light and blue light
are shown here.

12. White
light
Refracting
prism
Chlorophyll
solution
Photoelectric
tube
Galvanometer
Slit moves to
pass light
of selected
wavelength
Green
The high transmittance
(low absorption)
reading indicates that
chlorophyll absorbs
very little green light.
The low transmittance
(high absorption) reading indicates that
chlorophyll absorbs most blue light.
Blue 1 2 3 4
100
See Figure 10.9a for absorption spectra of three types of chloroplast pigments.
Result

13. Wavelength of light (nm)
Figure 10.9 Inquiry Which wavelengths of light are most effective in driving photosynthesis?
Three different experiments helped reveal which wavelengths of light are photosynthetically important. The results are shown below.
EXPERIMENT
RESULTS
Chlorophyll a
Chlorophyll b
Absorption of light by
chloroplast pigments
Carotenoids
400
500
600
700
Wavelength of light (nm)
(a) Absorption spectra. The three curves show the wavelengths of light best absorbed by three types of chloroplast pigments.

14. (measured by O2 release)
Rate of photosynthesis
Action spectrum. This graph plots the rate of photosynthesis versus wavelength. The resulting action spectrum resembles the absorption spectrum for chlorophyll a but does not match exactly (see part a). This is partly due to the absorption of light by accessory pigments such as chlorophyll b and carotenoids.
(b)

15. Aerobic bacteria 400 500 600 700 Filament of alga
Engelmann‘s experiment. In 1883, Theodor W. Engelmann illuminated a filamentous alga with light that had been passed through a prism, exposing different segments of the alga to different wavelengths. He used aerobic bacteria, which concentrate near an oxygen source, to determine which segments of the alga were releasing the most O2 and thus photosynthesizing most.
Bacteria congregated in greatest numbers around the parts of the alga illuminated with violet-blue or red light. Notice the close match of the bacterial distribution to the action spectrum in part b.
(c)
Light in the violet-blue and red portions of the spectrum are most effective in driving photosynthesis.
CONCLUSION

16. Figure 10.10 Structure of chlorophyll molecules in chloroplasts of plants
H3C Mg H
CH3 O
CHO
in chlorophyll a
in chlorophyll b
Porphyrin ring:
Light-absorbing
“head” of molecule;
note magnesium
atom at center
Hydrocarbon tail:
interacts with hydrophobic
regions of proteins inside
thylakoid membranes of
chloroplasts: H atoms not
shown

17. Figure 10.11 Excitation of isolated chlorophyll by light
Excited
state
Energy of election e–
Heat
Photon
(fluorescence)
Chlorophyll
molecule
Ground
(a) Excitation of isolated chlorophyll molecule
(b) Fluorescence

18. Figure 10.21 A review of photosynthesis
Light reactions:
• Are carried out by molecules in the
thylakoid membranes
• Convert light energy to the chemical
energy of ATP and NADPH
• Split H2O and release O2 to the
atmosphere
Calvin cycle reactions:
• Take place in the stroma
• Use ATP and NADPH to convert
CO2 to the sugar G3P
• Return ADP, inorganic phosphate, and NADP+ to the light reactions O2
CO2
H2O
Light
Light reactions
Calvin cycle
NADP+
ADP
ATP
NADPH
+ P 1
RuBP
3-Phosphoglycerate
Amino acids
Fatty acids
Starch
(storage)
Sucrose (export)
G3P
Photosystem II
Electron transport chain
Photosystem I
Chloroplast

19. Figure 10.12 How a photosystem harvests light
Primary election
acceptor
Photon
Thylakoid
Light-harvesting
complexes
Reaction
center
Photosystem
STROMA
Thylakoid membrane
Transfer
of energy
Special
chlorophyll a
molecules
Pigment
THYLAKOID SPACE
(INTERIOR OF THYLAKOID)

20. Figure 10.13 How noncyclic electron flow during the light reactions generates ATP and NADPH
CO2
Light
NADP+
ADP
CALVIN CYCLE
LIGHT REACTIONS
ATP
NADPH O2
[CH2O] (sugar)
Primary acceptor 2 e
Energy of electrons
Light
P680 1
Photosystem II (PS II)

21. Figure 10.13 How noncyclic electron flow during the light reactions generates ATP and NADPH
CO2
Light
LIGHT REACTIONS
CALVIN CYCLE O2
NADP+
NADPH
[CH2O] (sugar)
Photosystem II (PS II) e
Primary acceptor
ADP
ATP
2 H+ +
1⁄2 1 3 2
Energy of electrons
P680

22. Electron transport chain
Figure How noncyclic electron flow during the light reactions generates ATP and NADPH O2 +
H2O
CO2
Light
LIGHT REACTIONS
CALVIN CYCLE
NADP+
NADPH
[CH2O] (sugar)
Photosystem II (PS II) e
Primary acceptor
ATP
2 H+
1⁄2 2
Energy of electrons
ADP Pq
Cytochrome
complex Pc
Electron transport chain 4 3 e 5 e
P680 1

23. Electron transport chain
Figure How noncyclic electron flow during the light reactions generates ATP and NADPH O2
H2O
CO2
Light
LIGHT REACTIONS
CALVIN CYCLE
NADPH
[CH2O] (sugar)
Photosystem II (PS II) e
Primary acceptor
2 H+
1⁄2 2
Energy of electrons
ADP Pq
Cytochrome
complex Pc
ATP
Electron transport chain 5
NADP+
Photosystem I (PS I) 6 1 3 4 + e e
P700
P680

24. Electron transport chain
Figure How noncyclic electron flow during the light reactions generates ATP and NADPH
P700 +
CO2
Photosystem II (PS II)
H2O
Light
LIGHT REACTIONS
CALVIN CYCLE O2
NADPH
[CH2O] (sugar) e
Primary acceptor
2 H+
1⁄2 1
Energy of electrons Pq
Cytochrome
complex Pc
ATP
Electron transport chain
NADP+
Photosystem I (PS I) 6 2
ADP 5 Fd
Electron
Transport
chain 7
reductase
+ 2 H+ 8
+ H+ 3 4
P680

25. Figure 10.14 A mechanical analogy for the light reactions
Mill
makes
ATP e–
Photon
Photosystem II
Photosystem I
NADPH

26. Figure 10.15 Cyclic electron flow
Primary
acceptor Pq Fd
Cytochrome
complex Pc
NADP+
reductase
NADPH
ATP
NADP+
Photosystem II
(PS II)
Photosystem I
(PS I)

27. Figure 10.16 Comparison of chemiosmosis in mitochondria and chloroplasts
Key
Higher [H+]
Lower [H+]
Mitochondrion
Chloroplast
MITOCHONDRION
STRUCTURE
Intermembrance
space
Membrance
Matrix
Electron
transport
chain H+
Diffusion
Thylakoid
Stroma
ATP P
ADP+
Synthase
CHLOROPLAST

28. Figure 10.17 The light reactions and chemiosmosis: the organization of the thylakoid membrane
REACTOR
NADP+
ADP
ATP
NADPH
CALVIN
CYCLE
[CH2O] (sugar)
STROMA
(Low H+ concentration)
Photosystem II
H2O
CO2
Cytochrome
complex O2 1
1⁄2 2
Photosystem I
Light
THYLAKOID SPACE
(High H+ concentration)
Thylakoid
membrane
synthase Pq Pc Fd
reductase
+ H+
NADP+ + 2H+ To
Calvin
cycle P 3 H+
2 H+
+2 H+

29. Figure 10.18 The Calvin cycle
Light
H2O
CO2
LIGHT REACTIONS
ATP
NADPH
NADP+
[CH2O] (sugar)
CALVIN CYCLE
ADP
(Entering one
at a time)
CO2 3
Phase 1: Carbon fixation
Rubisco
Short-lived intermediate
3 P P
Ribulose bisphosphate (RuBP)
3-Phosphoglycerate
6 ATP
6 ADP
Input O2 6
CALVIN
CYCLE

30. Figure 10.18 The Calvin cycle
(Entering one
at a time)
CO2 3
Phase 1: Carbon fixation
Rubisco
Short-lived intermediate
3 P P
Ribulose bisphosphate (RuBP)
3-Phosphoglycerate
6 P
1,3-Bisphosphoglycerate
6 NADPH
6 NADP+
6 P i 6
Glyceraldehyde-3-phosphate
(G3P)
Phase 2: Reduction
6 ATP
CALVIN
CYCLE 1
G3P (a sugar) Output
Glucose and
other organic
compounds
6 ADP
Input
Light
H2O
LIGHT REACTIONS
ATP
NADP+
[CH2O] (sugar)
CALVIN CYCLE
NADPH
ADP O2 6

31. Figure 10.18 The Calvin cycle
(Entering one
at a time)
CO2 3
Phase 1: Carbon fixation
Rubisco
Short-lived intermediate
3 P P
Ribulose bisphosphate (RuBP)
3-Phosphoglycerate
6 P
1,3-Bisphosphoglycerate
6 NADPH
6 NADP+
6 P i 6
Glyceraldehyde-3-phosphate
(G3P)
Phase 2: Reduction
6 ATP
3 ATP
3 ADP
CALVIN
CYCLE 5
Phase 3: Regeneration of the CO2 acceptor (RuBP) 1
G3P (a sugar) Output
Glucose and
other organic
compounds
G3P
6 ADP
Light
H2O
LIGHT REACTIONS
NADPH
NADP+
[CH2O] (sugar)
CALVIN CYCLE
Input
ATP
ADP O2 6

32. Figure 10.19 C4 leaf anatomy and the C4 pathway
CO2
Mesophyll cell
Bundle-
sheath
cell
Vein
(vascular tissue)
Photosynthetic
cells of C4 plant
leaf
Stoma
Mesophyll
C4 leaf anatomy
PEP carboxylase
Oxaloacetate (4 C)
PEP (3 C)
Malate (4 C)
ADP
ATP
Sheath
Pyruate (3 C)
CALVIN
CYCLE
Sugar
Vascular
tissue

33. Figure 10.20 C4 and CAM photosynthesis compared
Spatial separation of steps. In C4 plants, carbon fixation and the Calvin cycle occur in different
types of cells.
(a)
Temporal separation of steps. In CAM plants, carbon fixation and the Calvin cycle occur in the same cells at different times.
(b)
Pineapple
Sugarcane
Bundle-
sheath cell
Mesophyll Cell
Organic acid
CALVIN CYCLE
Sugar
CO2 C4
CAM
CO2 incorporated
into four-carbon
organic acids
(carbon fixation)
Night
Day 1 2
CO2
Organic acids
release CO2 to
Calvin cycle
Organic acids
release CO2 to
Calvin cycle

34. Figure 10.21 A review of photosynthesis
Light reactions:
• Are carried out by molecules in the
thylakoid membranes
• Convert light energy to the chemical
energy of ATP and NADPH
• Split H2O and release O2 to the
atmosphere
Calvin cycle reactions:
• Take place in the stroma
• Use ATP and NADPH to convert
CO2 to the sugar G3P
• Return ADP, inorganic phosphate, and NADP+ to the light reactions O2
CO2
H2O
Light
Light reactions
Calvin cycle
NADP+
ADP
ATP
NADPH
+ P 1
RuBP
3-Phosphoglycerate
Amino acids
Fatty acids
Starch
(storage)
Sucrose (export)
G3P
Photosystem II
Electron transport chain
Photosystem I
Chloroplast