Photosynthesis Chapter 10 PDF

Summary

This chapter details photosynthesis, a crucial biological process in which plants convert light energy into chemical energy. It covers the process, including the structure of chloroplasts and the role of pigments in capturing light. The chapter explores the interconnectedness of photosynthesis and other organisms.

Full Transcript

Chapter 10
Photosynthesis

© 2017 Pearson Education, Inc.
 Each leaf of this tree is harvesting energy from sunlight and using
it to convert CO2 and H2O into chemical energy stored in sugar and
other organic molecules. The tree uses these sugars for energy and
to build its own trunk, branches, and leaves. Remarkably, enough
sugars are left over to feed other organisms (like moth larvae,
shown below) that cannot carry out this extraordinary
transformation
Figure 10.1a
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 Figure 10.1b
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CONCEPT 10.1 Photosynthesis feeds the
biosphere
Photosynthesis is the process that converts solar
energy into chemical energy within chloroplasts
Photosynthesis nourishes almost the entire living world
directly or indirectly

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The Process That Feeds the Biosphere
Autotrophs are “self-feeders” that sustain
themselves without eating anything derived from
other organisms
Autotrophs are the producers of the biosphere; they
produce organic molecules from CO2 and other
inorganic molecules

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 Almost all plants are photoautotrophs, that is, they
use the energy of sunlight to make organic
molecules
Photosynthesis also occurs in algae, certain other
protists, and some prokaryotes

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 Photoautotrophs

Figure 10.2
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 Heterotrophs obtain organic material from other
organisms; they are the consumers of the biosphere
Some consume other living things; others, called
decomposers, eat dead organic material or feces
Fossil fuels were formed from the remains of
organisms that died hundreds of millions of years
ago, representing ancient stores of the sun’s energy
Almost all heterotrophs depend on photoautotrophs,
either directly or indirectly, for food and O2

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CONCEPT 10.2: Photosynthesis converts light
energy to the chemical energy of food
Plants and other photosynthetic organisms contain
organelles called chloroplasts
Chloroplasts are structurally similar to and likely
evolved from photosynthetic bacteria
The structural organization of these organelles
allows for the chemical reactions of photosynthesis

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Chloroplasts: The Sites of Photosynthesis
in Plants
Most photosynthesis in plants occurs in the leaves
Chloroplasts are found mainly in cells of the
mesophyll, the interior tissue of the leaf
CO2 enters and O2 exits the leaf through
microscopic pores called stomata
Veins transport water from the roots and export
sugar to nonphotosynthetic parts of the plant

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 A chloroplast has an envelope of two membranes
surrounding a dense fluid called the stroma
Thylakoids are connected sacs in the chloroplast
that compose a third membrane system
Thylakoids may be stacked in columns called
grana
Chlorophyll, the pigment that gives leaves their
green color, resides in the thylakoid membranes

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 Zooming in on the location of photosynthesis in a plant

Figure 10.3
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Tracking Atoms Through Photosynthesis:
Scientific Inquiry
Photosynthesis is a complex series of reactions that
can be summarized as the following equation:
6 CO2 + 12 H2O + Light energy → C6H12O6 + 6 O2 + 6 H2O
The overall chemical change during photosynthesis
is the reverse of cellular respiration

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The Splitting of Water
Chloroplasts split H2O into hydrogen and oxygen,
incorporating the electrons of hydrogen into sugar
molecules and releasing O2 as a by-product

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Tracking atoms through photosynthesis

Figure 10.4
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 All photosynthetic organisms require a hydrogen
source, but the source varies among organisms
– For example, sulfur bacteria use H2S instead of
water, forming yellow globules of sulfur as a waste
product

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Photosynthesis as a Redox Process
Photosynthesis reverses the direction of electron
flow compared to respiration
Photosynthesis is a redox process in which H2O is
oxidized and CO2 is reduced
Photosynthesis is an endergonic process; the
energy boost is provided by light

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 Photosynthesis as a redox process

Figure 10.UN01
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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, providing electrons and protons (H+)
– Release O2 as a by-product
– Reduce the electron acceptor NADP+ to NADPH
– Generate ATP from ADP by photophosphorylation

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 The Calvin cycle (in the stroma) makes sugar from
CO2, using the ATP and NADPH generated during
the light reactions
The Calvin cycle begins with carbon fixation,
incorporating CO2 into organic molecules
It then reduces fixed carbon to carbohydrate by
transferring electrons from NADPH

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 Chloroplasts use light energy to make sugar by
coordinating the two stages of photosynthesis
The light reactions occur in the thylakoids and
release NADPH and ATP to the stroma for use in
the Calvin cycle

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© 2021 Pearson Education, Inc.
Figure 10.5
CONCEPT 10.3: 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 electromagnetic energy, also called
electromagnetic radiation
Electromagnetic energy travels in rhythmic waves
Wavelength is a measure of the distance between
crests of electromagnetic waves
It can range from less than a nanometer (gamma
rays) to more than a kilometer (radio waves)

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 The electromagnetic spectrum is the entire range
of electromagnetic energy, or radiation
Visible light (wavelengths 380 nm to 740 nm)
drives photosynthesis and produces the colors
seen by the human eye

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 The electromagnetic spectrum

© 2021 Pearson Education, Inc. Figure 10.6
 Light also behaves as though it consists of discrete
particles, called photons
Each photon has a fixed quantity of energy which is
inversely related to the wavelength of light; shorter
wavelengths have more energy per photon of light

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Photosynthetic Pigments: The Light Receptors
Pigments are substances that absorb visible light
Different pigments absorb different wavelengths,
and the wavelengths that are absorbed disappear
Wavelengths that are not absorbed are reflected or
transmitted
– For example, most leaves appear green because
chlorophyll absorbs violet-blue and red light while
reflecting and transmitting green light

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 Why leaves are green: interaction of light with chloroplasts

© 2021 Pearson Education, Inc. Figure 10.7
 A spectrophotometer measures a pigment’s ability
to absorb various wavelengths
It sends light through pigments and measures the
fraction of light transmitted at each wavelength
An absorption spectrum is a graph plotting a
pigment’s light absorption versus wavelength

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 Determining an
absorption
spectrum

© 2021 Pearson Education, Inc. Figure 10.8
 Three types of pigments in chloroplasts include:
– Chlorophyll a, the key light-capturing pigment that
participates directly in light reactions
– Chlorophyll b, an accessory pigment
– Carotenoids, a separate group of accessory
pigments

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 The absorption spectrum of chlorophyll a indicates
that violet-blue and red light will work best for
photosynthesis, while green is the least effective
The action spectrum for photosynthesis, a profile
of the relative effectiveness of different
wavelengths, confirms the effectiveness of violet-
blue and red light

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 The action spectrum of photosynthesis was first
demonstrated in 1883 by Theodor W. Engelmann
He exposed different segments of a filamentous
alga to different wavelengths of light and used the
growth of aerobic bacteria as a measure of O2
production

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 Which
wavelengths of
light are most
effective in
driving
photosynthesis?

Figure 10.9
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 Which wavelengths of light are most effective
in driving photosynthesis?

Aerobic bacteria
Filament of alga

400 500 600 700
(c) Engelmann’s experiment
Data from T. W. Engelmann, Bacterium photometricum.
Ein Beitrag zur vergleichenden Physiologie des
Licht-und Farbensinnes, Archiv. für Physiologie
30:95–124 (1883).

Figure 10.9c
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 The action spectrum for photosynthesis is broader
than the absorption spectrum of chlorophyll
Accessory pigments, such as chlorophyll b,
broaden the spectrum used for photosynthesis
The difference in the absorption spectrum between
chlorophyll a and b is due to a slight structural
difference between the pigment molecules

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© 2021 Pearson Education, Inc. Figure 10.10
 CH3 in chlorophyll a
CHO in chlorophyll b

CH3

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 Figure 10.11
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 In the last decade, two other forms of chlorophyll
were discovered—chlorophyll d and chlorophyll f—
that absorb higher wavelengths of light
The cyanobacterium, Chroococcidiopsis thermalis,
uses chlorophyll f in place of chlorophyll a in
shaded conditions

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 Other accessory pigments called carotenoids, are
yellow or orange because they absorb violet and
blue-green light
Carotenoids broaden the spectrum for
photosynthesis
Some are also photoprotective, that is, they absorb
excessive light that would otherwise damage
chlorophyll or react with oxygen

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Excitation of Chlorophyll by Light
When a pigment molecule absorbs light, one of its
electrons goes from a ground state to an excited
state, which is unstable
In isolation, excited electrons fall back to the ground
state, releasing excess energy as heat or light, an
afterglow called fluorescence

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 Excitation of isolated chlorophyll

© 2021 Pearson Education, Inc. Figure 10.11
A Photosystem: A Reaction-Center Complex
Associated with Light-Harvesting Complexes
A photosystem consists of a reaction-center
complex surrounded by light-harvesting complexes
The reaction-center complex is an association of
proteins holding a special pair of chlorophyll a
molecules and a primary electron acceptor

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 The light-harvesting complex consists of various
pigment molecules bound to proteins
Light-harvesting complexes transfer the energy of
photons to the chlorophyll a molecules in the
reaction-center complex
These chlorophyll a molecules are special because
they can transfer an excited electron to a different
molecule

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 A primary electron acceptor in the reaction center
accepts excited electrons and is reduced as a result
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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 The structure and function of a photosystem

Figure 10.12
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 There are two types of photosystems in the
thylakoid membrane, numbered in order of their
discovery
– Photosystem II (PS II) is called P680 because its
reaction-center chlorophyll a is best at absorbing
light with a wavelength of 680 nm
– Photosystem I (PS I) is called P700 because its
reaction-center chlorophyll a is best at absorbing
light with a wavelength of 700 nm

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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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 There are eight steps in linear electron flow:
1. A photon hits a pigment in a light-harvesting
complex of PS II, and its energy is passed among
pigment molecules until it excites P680
2. An excited electron from P680 is transferred to the
primary electron acceptor; we refer to the oxidized
form as P680+

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 3. An enzyme catalyzes the split of H2O into two
electrons, two hydrogen ions (H+) and an oxygen
atom
 The electrons are transferred to the P680+ pair,
reducing it back to P680
 The H+ are released into the thylakoid space
 The oxygen atom combines with another oxygen atom
generated by the splitting of a different H2O and forms
O2

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 4. Electrons are passed in a series of redox reactions
from the primary electron acceptor of PS II down an
electron transport chain to PS I
 The electron transport chain includes the electron
carrier plastoquinone (Pq), a cytochrome complex,
and a protein called plastocyanin (Pc)
 Energy released by electron transfer is used to pump
H+ into the thylakoid space, creating a proton gradient
across the thylakoid membrane

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 5. Potential energy stored in the proton gradient drives
production of ATP by chemiosmosis
6. In PS I (like PS II), transferred light energy excites
P700, which loses an electron to the primary
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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 7. Electrons are passed from the primary electron
acceptor of PS I down a second electron transport
chain to the protein ferredoxin (Fd)
 There is no proton gradient or ATP produced by this
electron transport chain

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 8. The enzyme NADP+ reductase catalyzes the
transfer of electrons from Fd to NADP+
 Two electrons are needed to reduce NADP+ to NADPH
 The electrons of NADPH are at a higher energy level
than they were in H2O, so are more readily available
for the reactions of the Calvin cycle
 The formation of NADPH also removes an H+ from the
stroma

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 Figure 10.UN02
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 How linear electron flow during the light reactions
generates ATP and NADPH

Figure 10.13
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 Light reactions use solar power to generate ATP
and NADPH, providing the chemical energy and
reducing power needed by the Calvin cycle to make
sugar
The energy changes of electrons during linear flow
through the light reactions can be shown in a
mechanical analogy

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 A mechanical analogy for linear electron
flow during the light reactions

Figure 10.14
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Cyclic Electron Flow
In cyclic electron flow, photoexcited electrons
cycle back from Fd to the cytochrome complex
instead of being transferred to NADP+
Electrons are passed to a P700 chlorophyll in the
PS I reaction center via the plastocyanin molecule
(Pc)
Cyclic electron flow uses only photosystem I
It produces ATP, but no NADPH or oxygen results
from this process

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 Cyclic electron flow- compare/contrast to linear flow

Figure 10.15
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 Several groups of photosynthetic bacteria have only
a single photosystem related to either PS II or PS I
For these organisms, cyclic electron flow is the only
means of generating ATP during photosynthesis
Photosynthesis may have first evolved in the
ancestors of these bacteria in a form similar to
cyclic electron flow

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 Cyclic electron flow is probably, in part an
“evolutionary leftover” in organisms with both
photosystems
Cyclic electron flow may have some photoprotective
capability; plants that do not have it grow well in low
light, but cannot grow well in intense light

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A Comparison of Chemiosmosis in
Chloroplasts and Mitochondria
Chloroplasts and mitochondria both generate ATP
by chemiosmosis
– Electron transport chains pump protons (H +) across
a membrane as electrons are passed through
carriers with progressively higher electron affinity
– ATP synthase couples the diffusion of H + down their
gradient to the phosphorylation of ADP to ATP

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 Some of the electron carriers, including iron-
containing proteins called cytochromes, are very
similar in mitochondria and chloroplasts
The ATP synthase complexes are also very similar

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 Photophosphorylation differs from oxidative
phosphorylation in a few key ways
– In chloroplasts, high energy electrons drop down the
transport chain from water, while in mitochondria,
they are extracted from organic molecules
– Mitochondria transfer chemical energy from food to
ATP; chloroplasts transform light energy into the
chemical energy of ATP

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 Although the spatial organization of chemiosmosis
differs slightly, there are similarities
– 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 on the
stroma side of the membrane as they diffuse back
into the stroma

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 Comparison of chemiosmosis
in mitochondria and chloroplasts

Figure 10.16
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 Both ATP and NADPH are produced on the stroma
side of the thylakoid membrane, making them
available for sugar synthesis in the Calvin cycle

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© 2021 Pearson Education, Inc. Figure 10.UN03
 The light reactions: organization of the thylakoid
membrane

Figure 10.17
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CONCEPT 10.4: The Calvin cycle uses the
chemical energy of ATP and NADPH to reduce
CO2 to sugar
The Calvin cycle, like the citric acid cycle,
regenerates its starting material after molecules
enter and leave the cycle
The Calvin cycle is anabolic; it 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 one G3P, the cycle must take
place three times, fixing three molecules of CO2,
one for each turn of the cycle
The Calvin cycle has three phases: carbon fixation,
reduction, and regeneration of the CO2 acceptor

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 Phase 1: Carbon fixation
The binding of CO2 to a five-carbon sugar named
ribulose bisphosphate (RuBP) is catalyzed by RuBP
carboxylase-oxygenase, or rubisco
The six-carbon intermediate molecule is
immediately split into two molecules of 3-
phosphoglycerate (for each CO2 fixed)

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 Phase 2: Reduction
Each molecule of 3-phosphoglycerate is altered
through phosphorylation by six ATP and reduction
by six NADPH to ultimately produce a G3P sugar
For every three CO2 molecules that enter the cycle,
six molecules of G3P are formed
Only one of these can be counted as a net gain of
carbohydrate

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 Phase 3: Regeneration of the CO2 acceptor
(RuBP)
The remaining five molecules of G3P are
rearranged in a complex series of reactions yielding
three molecules of RuBP
Three additional molecules of ATP are used to
facilitate the regeneration of RuBP

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© 2021 Pearson Education, Inc. Figure 10.UN04
 The Calvin cycle

Figure 10.18
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 For the net synthesis of one G3P molecule, the
Calvin cycle consumes nine molecules of ATP and
six molecules of NADPH
The light reactions regenerate the ATP and NADPH
The G3P is the starting molecule for metabolic
pathways that synthesize other organic molecules,
including glucose, sucrose, and other
carbohydrates

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CONCEPT 10.5: Alternative mechanisms of
carbon fixation have evolved in hot, arid
climates
Dehydration is a major challenge of terrestrial life
for plants, particularly in arid climates
Plants have metabolic adaptations to help conserve
water; but these adaptations often involve trade-offs

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 One important trade-off is the balance between
photosynthesis and water conservation
– On hot, dry days, plants close stomata, which
conserves H2O but also limits photosynthesis
– The closing of stomata reduces access to CO 2 and
causes O2 to build up
– These conditions favor an apparently wasteful
process called photorespiration

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Photorespiration: An Evolutionary Relic?
Most plants are C3 plants, in which the initial
fixation of CO2, via rubisco, forms a three-carbon
compound (3-phosphoglycerate)
In photorespiration, rubisco binds with O2 instead
of CO2, producing a two-carbon compound

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 Photorespiration is costly because it consumes O2
and organic fuel without producing any ATP or
sugar
It is thought to be an evolutionary relic because
rubisco first evolved at a time when the atmosphere
had far less O2 and more CO2
Photorespiration may provide some protection from
the damaging products of the light reactions that
build up when the Calvin cycle slows due to low
CO2

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 In many plants, photorespiration drains away as
much as 50% of the carbon fixed by the Calvin
cycle
In some plant species, alternate modes of carbon
fixation have evolved to minimize photorespiration
and optimize the Calvin cycle

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C4 Plants
C4 plants minimize the cost of photorespiration by
incorporating CO2 into a four-carbon compound as
the first product of the Calvin cycle
C4 has evolved several times and is used by several
thousand species in at least 19 different families
Important agricultural examples include sugarcane
and corn

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 In hot, dry weather, C4 plants partially close their
stomata, conserving water but reducing CO2
Photosynthesis begins in mesophyll cells, but is
completed in bundle-sheath cells, cells arranged
in tightly packed sheaths around the leaf veins

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 Sugar production in C4 plants occurs in a three-step
process
1. The production of the four-carbon precursors is
catalyzed by the enzyme PEP carboxylase in the
mesophyll cells
 PEP carboxylase has a higher affinity for CO2 than
rubisco does; it can fix CO2 even when CO2
concentrations are low

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 2. The four-carbon compounds are exported to
bundle-sheath cells through plasmodesmata
3. Within the bundle-sheath cells, CO2 is released
from the four-carbon compound and then used in
the Calvin cycle
 Pyruvate is transported to the mesophyll cells where
one ATP is used to convert it back to PEP
 This ATP is generated using cyclic electron flow

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 C4 leaf anatomy and the C4 pathway

Figure 10.19
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 CO2 levels have drastically increased since the
Industrial Revolution began in the 1800s, and
continue to rise today due to human activities
Increasing CO2 and temperature may affect C3 and
C4 plants differently, perhaps changing the relative
abundance of these species
The effects of such changes are unpredictable and
a cause for concern

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 Suitable agricultural land is decreasing due to the
effects of climate change, while the world
population and demand for food continue to
increase
C4 photosynthesis uses less water and resources
than C3 photosynthesis
Scientists have genetically modified rice, a C3 plant,
to carry out C4 photosynthesis for an estimated 30–
50% increase in yield for given water and resources

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CAM Plants
Some plants, including succulents, conserve water
by using crassulacean acid metabolism (CAM) to
fix carbon
CAM plants open their stomata at night, and
incorporate CO2 into organic acids that are stored in
the vacuoles
Stomata close during the day, and CO2 is released
from organic acids and used in the Calvin cycle

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 The CAM pathway is similar to the C4 pathway in
that they both incorporate CO2 into organic
intermediates before it enters the Calvin cycle
The C4 pathway structurally separates the initial
steps of carbon fixation from the Calvin cycle
In the CAM pathway, these steps occur in the same
cell, but are separated in time

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 C4 and CAM
photosynthesis
compared

Figure 10.20
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CONCEPT 10.6: Photosynthesis is essential for
life on Earth: 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 in the form of starch in
chloroplasts and other structures such as roots,
tubers, seeds, and fruits

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 A review of photosynthesis

Figure 10.21
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 Figure 10.22
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 Summary of Key Concepts:
Calvin Cycle

Figure 10.UN07
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