Photosynthesis - Chapter 7 PDF

Summary

This document presents a lecture on photosynthesis, including details about chloroplasts, light reactions, and the Calvin cycle. It is part of the Eighth Edition of a Biology textbook, created by Neil Campbell and Jane Reece, updated by others.

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Chapter 7

Photosynthesis

PowerPoint® Lecture Presentations for

Biology
Eighth Edition
Neil Campbell and Jane Reece

Lectures by Chris Romero, updated by Erin Barley with contributions from Joan Sharp
Copyright © 2008 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
Overview: The Process That Feeds the Biosphere

Photosynthesis is the process that converts
solar energy into chemical energy
Directly or indirectly, photosynthesis nourishes
almost the entire living world

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 Autotrophs sustain themselves without eating
anything derived from other organisms
Autotrophs are the producers of the biosphere,
producing organic molecules from CO2 and
other inorganic molecules
Almost all plants are photoautotrophs, using
the energy of sunlight to make organic
molecules from H2O and CO2

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 Photosynthesis occurs in plants, algae, certain
other protists, and some prokaryotes
These organisms feed not only themselves but
also most of the living world

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Fig. 10-2

(a) Plants

(c) Unicellular protist
10 µm

(e) Purple sulfur
1.5 µm
bacteria

(b) Multicellular alga (d) Cyanobacteria
40 µm
 Heterotrophs obtain their organic material
from other organisms
Heterotrophs are the consumers of the
biosphere
Almost all heterotrophs, including humans,
depend on photoautotrophs for food and O2

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Photosynthesis converts light energy to the
chemical energy of food

Chloroplasts are structurally similar to and
likely evolved from photosynthetic bacteria
The structural organization of these cells allows
for the chemical reactions of photosynthesis

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Chloroplasts: The Sites of Photosynthesis in Plants

Leaves are the major locations of
photosynthesis
Their green color is from chlorophyll, the
green pigment within chloroplasts
Light energy absorbed by chlorophyll drives the
synthesis of organic molecules in the
chloroplast
CO2 enters and O2 exits the leaf through
microscopic pores called stomata
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 Chloroplasts are found mainly in cells of the
mesophyll, the interior tissue of the leaf
A typical mesophyll cell has 30–40 chloroplasts
The chlorophyll is in the membranes of
thylakoids (connected sacs in the chloroplast);
thylakoids may be stacked in columns called
grana
Chloroplasts also contain stroma, a dense fluid

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Fig. 10-3
Leaf cross section
Vein

Mesophyll

Stomata
CO2 O2

Chloroplast
Mesophyll cell

Outer
membrane
Thylakoid
Intermembrane 5 µm
Stroma Thylakoid space
Granum
space
Inner
membrane

1 µm
Fig. 10-3a
Leaf cross section
Vein

Mesophyll

Stomata
CO2 O2

Chloroplast
Mesophyll cell

5 µm
Fig. 10-3b
Chloroplast

Outer
membrane
Thylakoid
Intermembrane
Stroma Granum Thylakoid space
space
Inner
membrane

1 µm
Tracking Atoms Through Photosynthesis: Scientific
Inquiry

Photosynthesis can be summarized as the
following equation:

6 CO2 + 12 H2O + Light energy → C6H12O6 + 6 O2 + 6 H2O

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The Splitting of Water

Chloroplasts split H2O into hydrogen and
oxygen, incorporating the electrons of
hydrogen into sugar molecules

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Fig. 10-4

Reactants: 6 CO2 12 H2O

Products: C6H12O6 6 H2 O 6 O2
Photosynthesis as a Redox Process

Photosynthesis is a redox process in which
H2O is oxidized and CO2 is reduced

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The Two Stages of Photosynthesis: A Preview

Photosynthesis consists of the light reactions
(the photo part) and Calvin cycle (the synthesis
part)
The light reactions (in the thylakoids):
– Split H2O
– Release O2
– Reduce NADP+ to NADPH
– Generate ATP from ADP by
photophosphorylation
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 The Calvin cycle (in the stroma) forms sugar
from CO2, using ATP and NADPH
The Calvin cycle begins with carbon fixation,
incorporating CO2 into organic molecules

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Fig. 10-5-4

H2O CO2

Light

NADP+
ADP
+ P
i
Calvin
Light Cycle
Reactions

ATP

NADPH

Chloroplast

O2 [CH2O]
(sugar)
The light reactions convert solar energy to the
chemical energy of ATP and NADPH

Chloroplasts are solar-powered chemical
factories
Their thylakoids transform light energy into the
chemical energy of ATP and NADPH

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The Nature of Sunlight

Light is a form of electromagnetic energy, also
called electromagnetic radiation
Like other electromagnetic energy, light travels
in rhythmic waves
Wavelength is the distance between crests of
waves
Wavelength determines the type of
electromagnetic energy

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Photosynthetic Pigments: The Light Receptors

Pigments are substances that absorb visible
light
Different pigments absorb different
wavelengths
Wavelengths that are not absorbed are
reflected or transmitted
Leaves appear green because chlorophyll
reflects and transmits green light

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Fig. 10-7

Light
Reflected
light

Chloroplast

Absorbed Granum
light

Transmitted
light
 Chlorophyll a is the main photosynthetic
pigment
Accessory pigments, such as chlorophyll b,
broaden the spectrum used for photosynthesis
Accessory pigments called carotenoids
absorb excessive light that would damage
chlorophyll

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Excitation of Chlorophyll by Light

When a pigment absorbs light, it goes from a
ground state to an excited state, which is
unstable
When excited electrons fall back to the ground
state, photons are given off, an afterglow called
fluorescence
If illuminated, an isolated solution of chlorophyll
will fluoresce, giving off light and heat

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Fig. 10-11

Excited
e– state
Energy of electron

Heat

Photon
(fluorescence)
Photon
Ground
Chlorophyll state
molecule

(a) Excitation of isolated chlorophyll molecule (b) Fluorescence
A Photosystem: A Reaction-Center Complex
Associated with Light-Harvesting Complexes
A photosystem consists of a reaction-center
complex (a type of protein complex)
surrounded by light-harvesting complexes
The light-harvesting complexes (pigment
molecules bound to proteins) funnel the energy
of photons to the reaction center

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 A primary electron acceptor in the reaction
center accepts an excited electron from
chlorophyll a
Solar-powered transfer of an electron from a
chlorophyll a molecule to the primary electron
acceptor is the first step of the light reactions

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Fig. 10-12

Photosystem STROMA
Photon
Light-harvesting Reaction-center Primary
complexes complex electron
acceptor
Thylakoid membrane

e–

Transfer Special pair of Pigment
of energy chlorophyll a molecules
molecules
THYLAKOID SPACE
(INTERIOR OF THYLAKOID)
 There are two types of photosystems in the
thylakoid membrane
Photosystem II (PS II) functions first (the
numbers reflect order of discovery) and is best at
absorbing a wavelength of 680 nm
The reaction-center chlorophyll a of PS II is
called P680

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 Photosystem I (PS I) is best at absorbing a
wavelength of 700 nm
The reaction-center chlorophyll a of PS I is
called P700

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Linear Electron Flow

During the light reactions, there are two
possible routes for electron flow: cyclic and
linear
Linear electron flow, the primary pathway,
involves both photosystems and produces ATP
and NADPH using light energy

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 A photon hits a pigment and its energy is
passed among pigment molecules until it
excites P680
An excited electron from P680 is transferred to
the primary electron acceptor

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Fig. 10-13-1

Primary
acceptor
2
e–

P680

1 Light

Pigment
molecules

Photosystem II
(PS II)
 P680+ (P680 that is missing an electron) is a
very strong oxidizing agent
H2O is split by enzymes, and the electrons are
transferred from the hydrogen atoms to P680+,
thus reducing it to P680
O2 is released as a by-product of this reaction

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Fig. 10-13-2

Primary
acceptor
2
H2O e–
2 H+
+
1/ O 3
2 2
e–
e–
P680

1 Light

Pigment
molecules

Photosystem II
(PS II)
 Each electron “falls” down an electron transport
chain from the primary electron acceptor of PS
II to PS I
Energy released by the fall drives the creation
of a proton gradient across the thylakoid
membrane
Diffusion of H+ (protons) across the membrane
drives ATP synthesis

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Fig. 10-13-3

Primary 4
acceptor
Pq
2
H2O e– Cytochrome
2 H+
complex
+
1/ O2 3
2
Pc
e–
e–
P680 5

1 Light

ATP

Pigment
molecules

Photosystem II
(PS II)
 In PS I (like PS II), transferred light energy
excites P700, which loses an electron to an
electron acceptor
P700+ (P700 that is missing an electron)
accepts an electron passed down from PS II
via the electron transport chain

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Fig. 10-13-4

Primary
Primary 4 acceptor
acceptor
Pq e–
2
H2O e– Cytochrome
2 H+
complex
+
1/ O2 3
2
Pc
e–
e– P700
P680 5 Light

1 Light 6

ATP

Pigment
molecules
Photosystem I
(PS I)
Photosystem II
(PS II)
 Each electron “falls” down an electron transport
chain from the primary electron acceptor of PS
I to the protein ferredoxin (Fd)
The electrons are then transferred to NADP+
and reduce it to NADPH
The electrons of NADPH are available for the
reactions of the Calvin cycle

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Fig. 10-13-5

Primary
Primary 4 acceptor 7
acceptor Fd
Pq e–
2 e– 8
H2O e– e– NADP+
Cytochrome
2 H+ NADP+ + H+
complex
+ reductase
1/ O 3 NADPH
2 2
Pc
e–
e– P700
P680 5 Light

1 Light 6

ATP

Pigment
molecules
Photosystem I
(PS I)
Photosystem II
(PS II)
Fig. 10-14

e–
ATP

e– e–

NADPH
e–
e–
e–

Mill
makes
ATP

e–

Photosystem II Photosystem I
Cyclic Electron Flow

Cyclic electron flow uses only photosystem I
and produces ATP, but not NADPH
Cyclic electron flow generates surplus ATP,
satisfying the higher demand in the Calvin
cycle

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Fig. 10-15

Primary
Primary acceptor
Fd
acceptor Fd
NADP+
Pq
NADP+ + H+
reductase
Cytochrome NADPH
complex

Pc

Photosystem I
Photosystem II ATP
 Some organisms such as purple sulfur bacteria
have PS I but not PS II
Cyclic electron flow is thought to have evolved
before linear electron flow
Cyclic electron flow may protect cells from
light-induced damage

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A Comparison of Chemiosmosis in Chloroplasts
and Mitochondria

Chloroplasts and mitochondria generate ATP
by chemiosmosis, but use different sources of
energy
Mitochondria transfer chemical energy from
food to ATP; chloroplasts transform light energy
into the chemical energy of ATP
Spatial organization of chemiosmosis differs
between chloroplasts and mitochondria but
also shows similarities

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 In mitochondria, protons are pumped to the
intermembrane space and drive ATP synthesis
as they diffuse back into the mitochondrial
matrix
In chloroplasts, protons are pumped into the
thylakoid space and drive ATP synthesis as
they diffuse back into the stroma

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Fig. 10-16
Mitochondrion Chloroplast

MITOCHONDRION CHLOROPLAST
STRUCTURE STRUCTURE
H+ Diffusion
Intermembrane Thylakoid
space space
Electron
Inner Thylakoid
transport
membrane chain membrane

ATP
synthase
Matrix Stroma
Key
ADP + P i
ATP
Higher [H+] H+
Lower [H+]
 ATP and NADPH are produced on the side
facing the stroma, where the Calvin cycle takes
place
In summary, light reactions generate ATP and
increase the potential energy of electrons by
moving them from H2O to NADPH

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Fig. 10-17

STROMA
(low H+ concentration) Cytochrome
Photosystem II Photosystem I
complex
4 H+ Light NADP+
Light reductase
Fd 3
NADP+ + H+

Pq NADPH

e– Pc
e– 2
H2O
THYLAKOID SPACE 1 1/
2 O2
(high H+ concentration) +2 H+ 4 H+

To
Calvin
Cycle

Thylakoid
membrane ATP
synthase
STROMA
ADP
(low H+ concentration)
+ ATP
Pi
H+
The Calvin cycle uses ATP and NADPH to convert
CO2 to sugar

The Calvin cycle, like the citric acid cycle,
regenerates its starting material after
molecules enter and leave the cycle
The cycle builds sugar from smaller molecules
by using ATP and the reducing power of
electrons carried by NADPH

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 Carbon enters the cycle as CO2 and leaves as
a sugar named glyceraldehyde-3-phospate
(G3P)
For net synthesis of 1 G3P, the cycle must take
place three times, fixing 3 molecules of CO2
The Calvin cycle has three phases:
– Carbon fixation (catalyzed by rubisco)
– Reduction
– Regeneration of the CO2 acceptor (RuBP)
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Fig. 10-18-1
Input 3 (Entering one
at a time)
CO2

Phase 1: Carbon fixation

Rubisco

3 P P
Short-lived
intermediate
3P P 6 P
Ribulose bisphosphate 3-Phosphoglycerate
(RuBP)
Fig. 10-18-2
Input 3 (Entering one
at a time)
CO2

Phase 1: Carbon fixation

Rubisco

3 P P
Short-lived
intermediate
3P P 6 P
Ribulose bisphosphate 3-Phosphoglycerate
(RuBP) 6 ATP

6 ADP

Calvin
Cycle
6 P P
1,3-Bisphosphoglycerate
6 NADPH

6 NADP+
6 Pi

6 P
Glyceraldehyde-3-phosphate Phase 2:
(G3P) Reduction

1 P Glucose and
Output G3P other organic
(a sugar) compounds
Fig. 10-18-3
Input 3 (Entering one
at a time)
CO2

Phase 1: Carbon fixation

Rubisco

3 P P
Short-lived
intermediate
3P P 6 P
Ribulose bisphosphate 3-Phosphoglycerate
(RuBP) 6 ATP

6 ADP

3 ADP Calvin
Cycle
6 P P
3 ATP
1,3-Bisphosphoglycerate
6 NADPH
Phase 3:
Regeneration of 6 NADP+
the CO2 acceptor 6 Pi
(RuBP)
5 P
G3P
6 P
Glyceraldehyde-3-phosphate Phase 2:
(G3P) Reduction

1 P Glucose and
Output G3P other organic
(a sugar) compounds
Alternative mechanisms of carbon fixation have
evolved in hot, arid climates

Dehydration is a problem for plants, sometimes
requiring trade-offs with other metabolic
processes, especially photosynthesis
On hot, dry days, plants close stomata, which
conserves H2O but also limits photosynthesis
The closing of stomata reduces access to CO2
and causes O2 to build up
These conditions favor a seemingly wasteful
process called photorespiration
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Photorespiration: An Evolutionary Relic?

In most plants (C3 plants), initial fixation of
CO2, via rubisco, forms a three-carbon
compound
In photorespiration, rubisco adds O2 instead
of CO2 in the Calvin cycle
Photorespiration consumes O2 and organic fuel
and releases CO2 without producing ATP or
sugar

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 Photorespiration may be an evolutionary relic
because rubisco first evolved at a time when
the atmosphere had far less O2 and more CO2
Photorespiration limits damaging products of
light reactions that build up in the absence of
the Calvin cycle
In many plants, photorespiration is a problem
because on a hot, dry day it can drain as much
as 50% of the carbon fixed by the Calvin cycle

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C4 Plants

C4 plants minimize the cost of photorespiration by
incorporating CO2 into four-carbon compounds in
mesophyll cells
This step requires the enzyme PEP carboxylase
PEP carboxylase has a higher affinity for CO2 than
rubisco does; it can fix CO2 even when CO2
concentrations are low
These four-carbon compounds are exported to
bundle-sheath cells, where they release CO2 that
is then used in the Calvin cycle
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Fig. 10-19

C4 leaf anatomy The C4 pathway

Mesophyll
Mesophyll cell cell CO2
Photosynthetic PEP carboxylase
cells of C4 Bundle-
plant leaf sheath
cell
Oxaloacetate (4C) PEP (3C)
Vein ADP
(vascular tissue)
Malate (4C) ATP

Pyruvate (3C)
Bundle-
Stoma sheath CO2
cell

Calvin
Cycle

Sugar

Vascular
tissue
CAM Plants

Some plants, including succulents, use
crassulacean acid metabolism (CAM) to fix
carbon
CAM plants open their stomata at night,
incorporating CO2 into organic acids
Stomata close during the day, and CO2 is
released from organic acids and used in the
Calvin cycle

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Fig. 10-20

Sugarcane Pineapple
C4 CAM
CO2 CO2
Mesophyll 1 CO2 incorporated Night
cell Organic acid into four-carbon Organic acid
organic acids
(carbon fixation)

Bundle- CO2 CO2 Day
sheath
cell
2 Organic acids
Calvin release CO2 to Calvin
Cycle Calvin cycle Cycle

Sugar Sugar

(a) Spatial separation of steps (b) Temporal separation of steps
The Importance of Photosynthesis: A Review

The energy entering chloroplasts as sunlight gets
stored as chemical energy in organic compounds
Sugar made in the chloroplasts supplies chemical
energy and carbon skeletons to synthesize the
organic molecules of cells
Plants store excess sugar as starch in structures
such as roots, tubers, seeds, and fruits
In addition to food production, photosynthesis
produces the O2 in our atmosphere
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Fig. 10-21
H2O CO2

Light
NADP+
ADP
+ P
i
Light RuBP
Reactions: 3-Phosphoglycerate
Photosystem II Calvin
Electron transport chain Cycle
Photosystem I
Electron transport chain
ATP G3P
Starch
NADPH (storage)

Chloroplast

O2 Sucrose (export)