MODULE - 2 Photosynthesis

Forms and Functions of

Plants and animals

11
Notes
PHOTOSYNTHESIS

Photosynthesis (Photo = light; synthesis = to join) is the single most important

process on earth on which depends the existence of human beings and almost all
other living organisms. It is a process by which green plants, algae and chlorophyll
containing bacteria utilize the energy of sunlight to synthesize their own food
(organic matter) from simple inorganic molecules. Innumerable number of organic
molecules which compose the living world are derived directly or indirectly from
the photosynthetic organic matter. The oxidation of organic compounds releases
stored energy to be utilized by the living organisms to carry out essential metabolic
processes. It is important to note that photosynthesis is the only natural process
which liberates oxygen to be used by all living forms for the process of aerobic
respiration.
You have studied in lesson 4, that chloroplasts are the organelles that carry out
photosynthesis or in other words they act as solar cells producing carbohydrates.
In this lesson you will learn how green plants carry out photosynthesis.

OBJECTIVES
After completing this lesson, you will be able to :
z define photosynthesis;
z name the different pigments found in chloroplasts;
z explain the main aspects of the process of photosynthesis;
z enumerate the steps involved in the light and dark reactions of photosynthesis;
z define the terms absorption spectrum, action spectrum, electron acceptor and
photophosphorylation;
z distinguish between, absorption spectrum and action spectrum; light and dark
reactions, cyclic and non-cyclic photo-phosphorylation, C 3 and C4
photosynthesis;
z list the environmental variables and internal factors affecting photosynthesis;
z describe the principle of limiting factor giving suitable graphs.

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11.1 PHOTOSYNTHESIS Plants and animals

11.1 Let us look into the significance of the process

Significance
1. Green plants possess the green pigment, chlorophyll which can capture,
transform, translocate and store energy which is readily available for all forms
of life on this planet.
Notes
2. Photosynthesis is a process in which light energy is converted into chemical
energy.
3. Except green plants, no other organism can directly utilise solar energy to
synthesize food, hence they are dependent on green plants for their survival.
4. Green plants which can prepare organic food from simple inorganic elements
are called autotrophic while all other organisms which cannot prepare their own
food are called heterotrophic.
5. During photosynthesis, oxygen liberated into the atmosphere makes the
environment livable for all aerobic organisms.
6. Simple carbohydrates produced in photosynthesis are transformed into lipids,
proteins, nucleic acids and other organic molecules.
7. Plants and plant products are the major food sources of almost all organisms
on the earth.
8. Fossil fuels like coal, gas, and oil represent the photosynthetic products of the
plants belonging to early geological periods.
11.1.1 What is photosynthesis?
Photosynthesis is the process by which green plants, in the presence of light combine
water and carbon dioxide to form carbohydrates. Oxygen is released as a by product
of photosynthesis. Current knowledge of photosynthesis has resulted from discoveries
made over 300 years of work. Some landmark experiments are given in the box
below.
z Joseph Priestley (1772) and later Jan Ingenhousz (1779) showed that plants
have the ability to take up CO2 from the atmosphere and release O2.
z Ingenhousz also discovered that release of O2 by plants was possible only
in presence of sunlight and by the green parts of the plant.
z Robert Hill (1939) demonstrated that isolated chloroplasts evolve O2 when
they are illuminated in the presence of electron acceptor which gets
reduced. This reaction called Hill reaction accounts for the use of water
as a source of electrons and protons for CO2 fixation and release of O2
as bye-product.
Photosynthesis is represented by the following overall chemical equation:

Chlorophyll
6CO2 + 12H2O ⎯ ⎯⎯⎯⎯→ C6H12O6 + 6H2O + 6O2
Sunlight
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Plants and animals In photosynthesis, CO2 is fixed (or reduced) to carbohydrates (glucose C6H12O6).
Water is split in the presence of light (called photolysis of water) to release O2. Note
that O2 released comes from the water molecule and not from CO2.

11.1.2 Where does photosynthesis occur?

Photosynthesis occurs in green parts of the plant, mostly the leaves, sometimes the
Notes green stems and floral buds. The leaves contain specialised cells called mesophyll
cells which contain the chloroplast– the pigment containing organelle. These are
the actual sites for photosynthesis.

Look at the figure 11.1 that shows leaf Cell Structure and Function.

Sunlight
Upper epidermis

Palisade cell
Cell wall
Cytoplasm Vessels carrying
Vacuole Water Water passes water
into cell Cells carrying
In the chloroplast from vessel food made in leaf
carbon dioxide and by osmosis
water combine to Carbon dioxide Carbon dioxide
make sugar diffuses through
air spaces to
reach cells
Carbon dioxide enters leaf
Nucleus through a stoma (pore)

Fig. 11.1 Diagram to show structure of leaf cells

11.2 PHOTOSYNTHETIC PIGMENTS

The thylakoids of the chloroplast contain the pigments which absorb light of different
wavelengths and carry out the photochemical reaction of photosynthesis.

The role of the pigments is to absorb light energy, thereby converting it to chemical
energy. These pigments are located on the thylakoid membranes and the chloroplasts
are usually so arranged within the cells that the membranes are at right angles to
the light source for maximum absorption. The photosynthetic pigments of higher
plants fall into two classes the chlorophyll and carotenoids.

The photosynthetic pigment chlorophyll is the principle pigment involved in

photosynthesis. It is a large molecule and absorbs light maximally in the violet blue
and in the red region of the visible spectrum and reflects green light and thus leaves
appear green in colour. Carotenoids (carotene and xanthophyll) absorb light in the
regions of the spectrum not absorbed by the chlorophylls and transfer that energy
to chlorophyll to be used in photosynthesis.

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Chlorophyll-a (a special type of chlorophyll) is the main pigment that traps solar Plants and animals
energy and converts it into chemical energy. Chlorophyll-a is present in all
autotrophic plants except photosynthetic bacteria. Thus Chl-a is called the essential
photosynthetic pigment responsible for representing the reaction centre.
All other pigments such as chlorophyll b and carotenoids are collectively called
accessory pigments since they pass on the absorbed light energy to chlorophyll a
(Chl-a) molecule to be utilized for photosynthesis. These pigments, that is the
Notes
reaction centres (Chl-a) and the accessory pigments (harvesting centre) are packed
into functional clusters called photosystems. Photosystems are of two types PSI
and PSII.
About 250-400 Chl-a molecules constitute a single photosystem. Two different
photosystems contain different forms of chlorophyll a in their reaction centres. In
photosystem I (PSI), chlorophyll– a with maximum absorption at 700 nm (P700)
and in photosystem II (PSII), chlorophyll– a with peak absorption at 680 nm (P680),
act as reaction centres. (P stands for pigment). The primary function of the two
photosystems, which interact with each other is to trap the solar energy and convert
it into the chemical energy also called assimilatory power (ATP and NADPH2).
The differences between them are given in the following Table 11.1.
Table 11.1 Differences between Photosystem I and Photosystem II
Photosystem I Photosystem II
z PS I has a reaction centre of z PS II has a reaction centre of
chlorophyll ‘a’ molecule with chlorophyll ‘a’ molecule with maximum
maximum light absorption at 700 nm light absorption at 680 nm. This
wavelength. This reaction centre is reaction centre is also referred to
referred to as P700. to as P680.

z Primary electron acceptor is an iron z Primary electron acceptor, pheophytin,

protein (Fe-S-protein) is a modified chlorophyll-a molecule with 2
hydrogen atoms in place of magnesium ion.
z A set of electron carriers are z A set of electron carriers are pheophytin
plastocyanin, ferredoxin and plastoquinone, cytochromes.
cytochrome

11.3 ROLE OF SUNLIGHT IN PHOTOSYNTHESIS

Light consists of small particles or packages of energy called “photons”. A single

photon is also called quantum. What does the chlorophyll do? It absorbs light
energy.
Chlorophyll molecules absorb light energy and get into an excited state and
lose an electron to the outer orbit. No substance can remain in an excited
state for long, so the energised and excited chlorophyll molecule comes
down to a low energy state known as ground state and releases the extra
amount of energy. This energy can be lost as heat, or as light (fluorescence)
or can do some work. In photosynthesis, it works by splitting water
moelcule to produce H+ and OH– ions.
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Carotene is orange-yellow pigment present along with chlorophylls in the
thylakoid membrane. A carotene molecule breaks down into the vitamin A
molecules. It is this pigment which gives carrot its colour.

Absorption and Action Spectra

For investigating a process such as photosynthesis that is activated by light, it is
Notes important to establish the action spectrum for the process and to use this to identify
the pigments involved. An action spectrum is a graph showing the effectiveness
of different wavelengths (VIBGYOR) of light in stimulating the process of
photosynthesis, where the response could be measured in terms of oxygen produced
at different wavelengths of light. An absorption spectrum is a graph representing
the relative absorbance of different wavelengths of light by a pigment. An action
spectrum for photosynthesis is shown in Fig. 11.2 together with an absorption
spectrum for the combined photosynthetic pigments. Note the close similarity, which
indicates that the pigments, chlorophyll-a in particular, are responsible for absorption
of light used in photosynthesis.
All wavelengths of light are not equally effective in photosynthesis i.e. the rate of
photosynthesis is more in some and less in others.
Rate of photosynthesis

Action spectrum

Absorption spectrum
Absorption

Chlorophyll b
Chlorophyll a

Fig. 11.2 Absorption Spectra of electromagnetic radiation B. Action Spectrum

Photosynthesis occurs maximum in blue and red region of spectra.
Photosynthesis is very little in green and yellow light, because these rays
are reflected back from the leaf.

INTEXT QUESTIONS 11.1

1. (i) Define photosynthesis
..................................................................................................................
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(ii) Give the overall general chemical equation of photosynthesis. Plants and animals
..................................................................................................................
2. (i) List the two categories of photosynthetic pigments.
..................................................................................................................
(ii) Which pigments are known as accessory pigments?
..................................................................................................................
3. (i) What does chlorophyll do to the light falling on it?
Notes
..................................................................................................................
(ii) Which pigment system absorbs maximally the red wavelength of light?
..................................................................................................................
4. Answer the following
(i) In which colour of light, rate of photosynthesis is minimum and in which
colour of light it is maximum?
..................................................................................................................
(ii) Name the type of energy that is used in the process of photosynthesis.
In which form does this energy get stored in plant body?
..................................................................................................................
5. Which molecule is the source of evolution of oxygen in photosyntheisis— CO2
or H2O?
............................................................................................................................

11.4 PHOTOCHEMICAL AND BIOSYNTHETIC PHASE

z The entire process of photosynthesis takes place inside the chloroplast. The
structure of chloroplast is such that the light dependent (light reaction) and light
independent (Dark reaction) reactions take place at different sites in the same
organelle.
z The thylakoids have the pigments and other necessary components to absorb
light and transfer electrons to carry out the light reaction or Electron Transport
Chain (ETC). In ETC upon absorption of light, the electrons from PSII and PSI
are excited to a higher energy level i.e. the electrons acquire excitation energy.
As the electrons gain this energy, they are accepted by the electron acceptor
which in turn is reduced, leaving the reaction centres of PSII and PSI i.e. P680
and P700 molecules in an oxidised state. This represents the conversion of light
energy into chemical energy. The electrons then travel downhill in energy terms,
from one electron acceptor to another in a series of oxidation-reduction reaction.
This electron flow is ‘coupled’ to the formation of ATP. In addition, NADP is
reduced to NADPH2. The product of light reaction is called the reducing power
or assimilatory power (ATP and NADPH2) which move out of the thylakoid
into the stroma of the chloroplast.
z In the stroma, the second step called as dark reaction or biosynthetic pathway
occurs, where CO2 is reduced by the reducing power generated in the first step
and carbohydrates are produced.
Let us study these two steps in some more detail in the next part of the lesson.

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Plants and animals 11.4.1 Electron transport chain in photosynthesis
After receiving light PSII absorbs light energy and passes it on to its reaction centre,
P680. When P680 absorbs light, it is excited and its electrons are transferred to an
electron acceptor molecule (Primary electron acceptor i.e. pheophytin) and it itself
comes to the ground state. However by losing an electron P680 is oxidised and in
turn it splits water molecule to release O2. This light dependent spliting of water
is called photolysis. With the breakdown of water electrons are generated, which
Notes are then passed on to the electron deficient P (which had transferred its electrons
680
earlier). Thus the oxidised P680 regains its lost electrons from water molecules.
The reduced primary acceptor now donates electrons to the down stream components
of the electron transport chain. The electrons are finally passed onto the reaction
centre P700 or PSI. During this process, energy is released and stored in the form
of ATP.
Similarly, PSI also gets excited when it absorbs light and P700 (Reaction centre of
PSI) gets oxidised as it transfers its electrons to another primary acceptor molecule.
While the oxidised P700 draws its electrons from PSII, the reduced primary acceptors
molecule of PSI transfers its electrons via other electron carrier to NADP
(Nicotinamide Adenine Dinucleotide Phosphate) to produce NADPH2 a strong
reducing agent. Thus we see that there is a continuous flow of electrons from the
H2O molecules to PSII to PSI, and finally to the NADP molecule which is reduced
to NADPH2. NADPH2 is then utilised in reduction of CO2 to carbohydrates in the
biosynthetic pathway.

Primary
Primary acceptor
acceptor

Cytochrome
complex

= PS-I
Photons

= PS-II

Fig. 11.3 Non-cyclic (z-scheme) photophosphorylation PQ = Plastoquinine,

PC-Plastocyanin Fd = Ferredoxin
z Reduction of CO2 to carbohydrate also requires ATP, which too are generated
via electron transport chain. As the energy rich electrons pass down the electron
transport system, it releases energy which is sufficient to bind inorganic
phosphate (Pi) with ADP to form ATP. This process is called photo-
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phosphorylation. Since this takes place in presence of light it is called Photo- Plants and animals
phosphorylation. It occurs in chloroplast in two ways:
(a) Non-cyclic photophosphorylation where electrons flow from water molecule
to PSII and then to PSI and ultimately reduce NADP to NADPH2. Since
the electron flow is unidirectional and the electrons released from one
molecule do not return to the same molecule, it is called non-cyclic
photosphorylation (Fig. 11.3).
Notes
(b) Cyclic photophosphorylation occurs in photosynthetic bacteria which lack
PS-II, and it involves PSI only. During this process electrons from PSI
are not passed on to NADP. Instead the same electrons are returned to
the oxidised P700 molecule. During this downhill movement of electrons
ATP formation takes place. Thus this is termed as cyclic
photophosphorylation (Fig. 11.4).

Primary
Acceptor

Cytochrome
Complex

2 Photons

Fig. 11.4 Cyclic photophosphorylation

Table 11.2 Differences between cyclic and non-cyclic
photophosphorylation

Cyclic photophosphorylation Non-cyclic photophosphorylation

1. Only PSI is functional. 1. Both PSI and PSII are functional.

2. Electron comes from the chlorophyll P700 2. Water is the primary source of the electorns
molecule and returns to the same and H+. It gets photolysed through the
chlorophyll P700 process called Photolysis; NADP is the final
acceptor of the electrons and H+ ions.
4. Oxygen is not evolved because there is 4. Oxygen is evolved as a bye product.
no photolysis of water
5. This process is found mainly in 5. This mainly takes place in all green plants,
photosynthetic eubacteria e.g. purple and cyanobacteria except photosynthetic
sulphur bacteria. eubacteria.

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Plants and animals In higher photosynthetic plants, extra ATP can be made via cyclic photophosphorylation
if cyclic and non-cyclic photophosphorylaiton occur side by side. The efficiency of
energy conversion in the light reactions of photosynthesis is high and estimated at
about 39%.
11.5 BIOSYNTHETIC PATHWAY (DARK REACTION)
z Both NADPH2 and ATP produced during light reaction are essential requirements
Notes for synthesis of carbohydrates.
z These series of reactions which catalyse the reduction of CO2 to carbohydrates
(also called fixation of CO2) take place in the stroma of the chloroplast.
z These reactions are independent of light i.e. light is not necessary but can
continue in light as well if products of the light reaciton are available. Thus it
is also called dark reaction.
z The carbon fixation reactions produce sugar in the leaves of the plant from where
it is exported to other tissues of the plant as source of both organic molecule
and energy for growth and metabolism.
z There are two major pathways by which CO2 fixation (Dark reaction) takes
place.
11.5.1 C3 cycle (also called Calvin cycle after the name of its discoverer, Melvin
Calvin)
In this cycle, initially the atmospheric CO2 is accepted by a 5-carbon sugar ribulose
bisphosphate (RuBP) resulting in the generation of two molecules of 3-carbon
compound, 3-phosphoglyceric acid (PGA). This 3-carbon molecule is the first stable
product of this pathway and hence the name C3 cycle is given. Formation of PGA
is called carboxylation. This reaction is catalysed by an enzyme called ribulose
bisphosphate carboxylase/oxygenase or Rubisco. This enzyme is probably the
most abundant protein on earth.

Ribulose–1 CO2 + H2 O
5-bisphosphate

1 Carboxylation
ADP

Regeneration
3 3-phospoglycerate

ATP
+
ATP
2 NADPH
Reduction

Triose
phosphate
ADP
+
Pi NADP+
Sucrose, starch

Fig. 11.5 The Calvin cycle

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z In the next step, PGA is reduced to 3-carbon carbohydrate called triose Plants and animals
phosphate using NADPH2 and ATP (from light reaction). Much of these
molecules are then diverted from the C3 cycle and used for synthesis of other
carbohydrates such as glucose and sucrose.
z To complete the cycle, the initial 5-carbon acceptor molecule, RuBP is
regenerated from the triose phosphates using ATP molecule thus the C3 cycle
continues to regenerate the CO2-acceptor (RuBP).
Notes
11.5.2 C4 Cycle (or Hatch Slack Cycle)
z The C4 cycle seems to be an adaptation for plants growing under dry hot
environment. Such plants can photosynthesise even in the conditions of very low
CO2 concentration and under partial closure of stomata.
z Such plants can thus grow at low water content, high temperature and high light
intensity. Sugarcane, and maize are some examples.
z Photorespiration (oxidation of RuBP in presence of O2) is absent in these
plants. So the photosynthetic rate is high. (For detail of photorespiration refer
to lesson-12 Plant Respiration Section No. 12.5)
z The leaves of C4 plants show presence of dimorphic chloroplasts, called Kranz anatomy.
(a) In these plants, the vascular bundles have a sheath of large parenchyma cells around
them in the form of a wreath, thus the name Kranz anatomy (Kranz : wreath)
(b) Leaves possess two types of chloroplasts (dimorphic chloroplasts)
(c) Chloroplasts in the mesophyll cells are smaller and have well developed
grana (granal chloroplasts) but do not accumulate starch.
(d) Chloroplasts in the bundle sheath cells are larger and lack grana (agranal
chloroplasts) but contain numerous starch grains. (See Fig. 11.6).

Fig. 11.6 Transverse section of maize leaf showing Kranz’ anatomy

z In C4 plants, the initial acceptor of CO2 is phosphoenol pyruvic acid or PEP,
a 3-carbon compound. It combines with CO2 in presence of an enzyme
Phosphoenol pyruvate carboxylase (PEP carboxylase) and forms a C4 acid,
oxaloacetic acid (OAA). This fixation of CO2 occurs in the cytosol of the
mesophyll cells of the leaf. OAA is the first stable product of this cycle which
is 4 carbon compound and hence the name C4 pathway is given.
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Plants and animals z OAA then travels from mesophyll cells to the chloroplasts of bundle sheath cell
where it releases the fixed CO2. C3 cycle operates within these cells and this
CO2 immediately combines with RuBP in C3 cycle producing sugars. (See Fig.
11.7).
Atmospheric CO 2
Mesophyll
Plasma membrane
cell
Notes Cell wall
HCO 2–
Phosphoenol
pyruvate

Fixation Regeneration

Plasmodesmate C 4 acid C 3 acid

Bundle
sheath
cell Transport Transport
Fixation by
C 4 acid Calvin cycle

CO 2
C acid
Decarboxylation 3

Fig. 11.7 The C4 photosynthetic carbon cycle

z Thus in C4 pathway of dark reaction, there are two carboxylase enzymes that
take part. PEP carboxylase (PEPCo) in the mesophyll cells and RUBP
carboxylase (Rubisco) in the bundle sheath cells.
z The differences between C3 and C4 plants are tabulated below.
Table 11.3 Difference between C3 and C4 Plants

C3 Plants C4 Plants

Carbon dioxide Occurs once Occurs twice, first in mesophyll

fixation cells, then in bundle sheath cells.
Carbon dioxide Only one acceptor, RuBP which In Mesophyll cells, PEP (Phosphoenol
acceptor occurs in all green cells of the Pyruvic acid), 3-C, compound is CO2
plant acceptor, but in the bundle sheath cells-
RuBP, 5C, compound, is the CO2– acceptor
Carbon dioxide RuBP carboxylase, which is not PEP caboxylase which is very
fixing enzymes efficient when CO2 conc is low efficient, even if CO2 conc. is low
RuBP carboxylase, works efficiently
because carbon dioxide
concentration is high.
First product of The first stable product is 3-C The first product is 4-C compound
photosynthesis compound phosphoglyceric acid oxaloacetic acid

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Concentration of Higher CO2 conc. promotes Photosynthetic efficiency is high even Plants and animals
CO2 photosynth]esis if CO2 conc. is low
Leaf anatomy Only one type of chloroplast Two types of chloroplasts (dimorphic)
Kranz’ anatomy is absent or Kranz’ anatomy, i.e., two types
of cells. each with its own type of
chloroplasts are present.
Photorespiration Occurs; excess of oxygen is an Photorespiration is absent. The photo
inhibitor of photosynthesis synthetic efficiency is further increased Notes
Efficiency Less efficient More efficient photosynthesis
plotosynthesis than as compared to that of the C3 plants.
C4 plants. Yields Yields usually much higher.
usually much lower.

INTEXT QUESTIONS 11.2

1. What is the role of NADP?
............................................................................................................................
2. Why is dark reaction called so?
............................................................................................................................
3. What is the role of the enzymes (i) rubisco and (ii) PEPCo and where are they
present?
............................................................................................................................
4. Explain Kranz anatomy.
............................................................................................................................
5. Differentiate between the chloroplasts present in the mesophyll cells and in the
bundle sheath cells of the leaf of a C4 plant.
............................................................................................................................
6. Why are C4 plants more efficient than C3 plants?
............................................................................................................................
7. Name the two sets of reactions in photosynthesis in which light energy is
required.
............................................................................................................................

11.6 FACTORS AFFECTING RATE OF PHOTOSYNTHESIS

11.6.1 Factors affecting Photosynthesis
Factors affecting photosynthesis can be divided into two broad categories, the
internal and external (environmental) factors.

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Plants and animals (i) Internal Factors
1. Chlorophyll : The amount of chlorophyll present has a direct relationship with
the rate of photosynthesis because this pigment is directly involved in trapping
light energy responsible for the light reactions.
2. Leaf age and anatomy : Newly expanding leaves show gradual increase in rate
of photosynthesis and the maximum is reached when the leaves achieve full size.
Notes Chloroplast functions decline as the leaves age. Rate of photosynthesis is
influenced by variation in (i) number, structure and distribution of stomata, (ii)
size and distribution of intercellular spaces (iii) relative proportion of palisade
and spongy tissues and (iv) thickness of cuticle.
3. Demand for photosynthate : Rapidly growing plants show increased rate of
photosynthesis in comparison to mature plants. When demand for photosynthesis
is lowered due to poor meristematic activity, the photosynthetic rate declines.

(ii) External Factors

The major external factors which affect the rate of photosynthesis are temperature,
light, carbondioxide, water, and mineral elements.
Concept of limiting factors : When a process is affected by various factors, the rate
of the process depends upon the pace of the slowest factor. Let us consider three
factors like light, carbon dioxide and temperature. It is seen that when all three factors
are optimum, the rate of photosynthesis is maximum. However, of the three factors
even if one of the factors becomes suboptimal and the other factors remain optimal,
the rate of the photosynthetic process declines substantially. This is known as law of
limiting factors shown by Blackman in 1905. It is defined as when a process is
conditioned as to its rapidity by a number of separate factors, the rate of the process
is limited by the pace of the slowest factor which is known as the limiting factor.
Light : The rate of photosynthesis increases with increase of intensity of light within
physiological limits or rate of photosynthesis is directly proportional to light
intensity. Except on a cloudy day and at nights, light is never a limiting factor in
photosynthesis in nature.
At a certain light intensity the amount of CO2 used in photosynthesis and the amount
of CO2 produced in respiration are the same. This point of light intensity is known
as compensation point.
Wavelength of light absorbed by photosynthetic pigments affects rate of photosynthesis.
Red light and to some extent blue light has an enhancing influence on photosynthesis
(See action spectrum).
The proportion of the total incident sunlight on earth, absorbed by green plants is
generally a limiting factor. As per the estimates of the total incident light reaching
the green plants, only about 1-2% is actually absorbed, because 70% is transmitted,
and 28-29% is reflected back into the atmosphere.
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Temperature : Very high and very low temperature affect the rate of photosynthesis Plants and animals
adversely. Rate of photosynthesis will rise with temperature from 5°-37°C beyond
which there is a rapid fall, as the enzymes involved in the process of the dark reaction
are denatured at high temperature. Between 5°-35°C, with every 10°C rise in
temperature rate of photosynthesis doubles or Q10 is 2 (Q = quotient), or slightly
less than two.

Carbon dioxide : Since carbon dioxide being one of the raw materials for Notes
photosynthesis, its concentration affects the rate of photosynthesis markedly.
Because of its very low concentration (0.03%) in the atmosphere, it acts as limiting
factor in natural photosynthesis. At optimum temperature and light intensity, if
carbon dioxide supply is increased the rate of photosynthesis increases markedly
until CO2 conc. is as high as 3.0%. Thus, CO2 conc. in the atmosphere is always
a limiting factor for photosynthesis.

Water : Water has an indirect effect on the rate of photosynthesis. Loss of water
in the soil is immediately felt by the leaves, which get wilted and their stomata close
down thus hampering the absorption of CO2 from the atmosphere. This causes
decline in photosynthesis.

Oxygen : Concentration of oxygen as an external factor, is never a limiting factor

for photosynthesis because it is a by-product of photosynthesis, and it easily diffuses
into the atmosphere from the photosynthesizng organ, the leaf. However, excesss
of O2 surrounding a green plant, reduces photosynthetic rate by promoting the rate
of aerobic respiraiton.

Mineral elements : Some mineral elements like magnesium, copper, manganese and
chloride ions, which are components of photosynthetic enzymes, and magnesium
as a component of chlorophylls are important, and their deficiency would affect the
rate of photosynthesis indirectly by affecting the synthesis of photosynthetic enzymes
and chlorophyll, respectively.

11.7 CHEMOSYNTHESIS
Chemosynthesis
When plants utilise light energy to reduce carbon dioxide to carbohydrates, they
are called photosynthetic autotrophs. There are some bacteria which can utilise
chemical energy released during biological oxidation of certain inorganic substances
to reduce carbon dioxide to carbohydrate. These bacteria are called chemosynthetic
autotrophs.
This is found in many colourless bacteria and because they use chemical energy to
reduce carbon dioxide, this process of carbohydrate synthesis is known as
chemosynthesis.

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Plants and animals Chemosynthesis may be defined as “the method of carbon assimilation when the
reduction of CO2 is carried out in darkness, utilising the energy obtained from
oxidation of inorganic substances, such as H2S and NH3.
The common chemosynthetic forms are :
(i) Nitrifying bacteria. Nitrosomonas and Nitrobactor oxidise NH3 to NO2
Notes (ii) Sulphur bacteria
(iii) Iron bacteria
(iv) Hydrogen and methane producing bacteria

Differences between photosynthesis and chemosynthesis

Chemosynthesis Photosynthesis
1. It occurs only in colourless anaerobic 1. This process occurs in all green plants
bacteria including green bacteria.
2. During this process CO2 is reduced 2. CO2 and H2O are converted into
to carbohydrates without light carbohydrates in the presence of
and chlorophyll. light and chlorophyll.
3. Here chemical energy released 3. Light energy is converted into chemical
during oxidation of inorganic energy and stored in the form of
substances is used up to synthesise carbohydrates.
carbohydrates.
4. No pigment molecule is involved and 4. Several pigments are involved and
oxygen is not evolved. oxygen is evolved as a by-product.
5. No photophosphorylation takes place. 5. Photophosphorytion takes place i.e. ATP
is produced.

11.8 CHEMIOSMOTIC SYNTHESIS

This is a process in which energy stored as a hydrogen ion gradient across a
membrane is used to synthesise ATP from ADP and Pi. The enzyme which uses the
energy is ATP synthase and the energy or power source is the difference in the
concentration of H+ ions on opposite sides of the membrane. The membrane is the
inner membrane of the mitochondrion or the chloroplast. The word ‘osmosis’ in
Greek means ‘push’ and here the flow of H+ ions across the membrane provides
the energy or push to ATP synthase enzyme which then catalyses the synthesis of
ATP.
Chloroplasts use chemiosmosis to generate ATP during photosynthesis. The
prokaryotes lack the organelles mitochondria and chloroplast to generate H+
gradients across plasma membranes and cannot use it for ATP synthesis. Peter
Mitchell won the Nobel prize in 1978 for proposing the chemiosmotic model for
syntheis of ATP.
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Plants and animals

INTEXT QUESTIONS 11.3

1. List the internal factors that influence the rate of photosynthesis?
............................................................................................................................
2. State the principle of limiting factor.
Notes
............................................................................................................................
3. Give an example of chemosynthetic bacteria.
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4. Why are prokaryotes not able to produce ATP by chemiosmosis?
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WHAT YOU HAVE LEARNT

z Green plants are capable of synthesizing carbohydrates from CO2 and H2O in
the presence of light, by the process of photosynthesis.
z During photosynthesis ‘light energy’, which is captured by the photosynthetic
pigments (chlorophyll, carotenoids and xanthophylls) present in the chloroplasts,
is converted into chemical energy.
z Photosynthesis in general is expressed by the following equation:
Chlorophyll
6CO2 + 12H2O ⎯⎯⎯⎯⎯
Light
→ C6H12O6 + 6H2O + 6O2

z Photosynthesis comprises two sets of reactions:

z Light reactions: which take place in grana or thylakoids of chloroplasts only in
the presence of light.
z Dark reactions: Which occur in the stroma of chloroplast and are independent
of light, if products of light reaction are provided.
z Light energy is used for splitting of water, and production of ATP and NADPH2
and actual reduction of CO2 takes place in the dark reaction.
z Light reaction occurs with the help of two functional units, photosystem-I and
photosystem-II.
z During light reaction phosphorylation of ADP to ATP may occur in two ways,
cyclic and non-cyclic.
z During dark reactions CO2 is accepted by Ribulose biphosphate (RuBP) and the
first stable product. 3-PGA (3 phosphoglyceric acid) is formed, which by further
cyclic reactions (Calvin Cycle) leads to the formation of carbohydrates as well
as in regeneration of RuBP.
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Plants and animals z In C4 plants like maize, jawar, bajra, the primary acceptor of CO2 is in mesophyll
cells and the first detectable product of dark reaction is oxaloacetic acid (OAA),
whereas in the bundle sheath cells CO 2 fixation occurs through.
Calvin cycle.
z Occurrence of dimorphic chloroplasts in C4 plants is known as “Kranz anatomy”
and is characterized by the presence of a sheath of parenchyma cells around a
vascular bundle (bundle sheath). Cells of this sheath have larger chloroplasts
Notes
which lack grana and are filled with starch grains. In contrast mesophyll cells
contain chloroplasts which are smaller but have well developed grana.
z Rate of photosynthesis is influenced by (i) environmental factors such as light,
temperature, carbon dioxide concentration and water, and (ii) internal factors
which include age of leaf, chlorophyll content and leaf anatomy.

A SUMMARY OF PHOTOSYNTHESIS

Photosynthesis

Light dependent stage Light-independet stage

in in
H2O CO2
grana NADPH2 Stroma
1 O
(CH2O)
out 2 2 Water split CO2 reduced
carbohydrate

Light-dependent stage Light independent stage

z occurs in the thylakoid membranes z occurs in the stroma

of the grana

z largely a photochemical change, z a series of biochemical changes, each

requiring light energy reaction catalysed by an enzyme

z light energy is converted to chemical z carbon dioxide is converted to compounds

energy in the form of ATP and NADPH2; such as carbohydrates (with the help of chemical
water is split into hydrogen and oxygen; energy of ATP and NADPH2); the reactions
hydrogen is combined in NADPH2; of the light-independent stage are known
oxygen gas is released as a byproduct as the Calvin cycle and C4-pathway

z chlorophylls are grouped together in z carbon dioxide is combined with ribulose

units of about 300 molecules (known as bisphosphate (the acceptor substance) and
photosystems); two types exist, the product splits instantly into two
photosystems I and II molecules of glycerate 3-phosphate (GP,
the first product of photosynthesis) in C3-plants

z light energy absorbed by the photo- z CO2 is reduced with the help of RuBP and
systems causes electrons from chlorophyll Rubisco to a three-carbon sugar, triose phosphate;
to be raised to a high energy level and then, in a series of reactions, the acceptor
to pass to NADPH2; ATP is generated; molecule is regenerated and sugars, starch and
water is split and provides the electrons other substances are formed from

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to the photosystem and the hydrogen triose phosphate: Plants and animals
for NADPH2 production:

Light
3ATP 3ADP + 3Pi
2H2O + 2NADP O2 + 2NADPH2
Chlorophyll
Light
CO2 (CH2O) + H2O
ADP + Pi ATP (considerable, but
Chlorophyll
variable amount) 2NADPH2 2NADP

Notes
Light

Grana Stroma
Photosystem I + II ADP Starch
Water + Pi Sucrose
ATP Glucose
Water NADP
+ ATP ADP Organic
ADP +Pi acid
+ Triose amino acid
Hydrogen Pi phosphate lipids
ATP ADP
ions +Pi
Calvin
Acceptor
Oxygen cycle
molecule
Energy currency +CO2
(ATP) and reducing Glycerate
power (NADPH)2 3-phosphate
(GP) Carbon dioxide

TERMINAL EXERCISES
1. Describe briefly the process of photosynthesis.
2. Write short notes on (i) Ultrastructure of chloroplast and (ii) Pigments involved
in photosynthesis.
3. What are accessory pigments? Why they are called so?
4. Mention path of electrons in the light reaction of photosynthesis.
5. What do you understand by photophosphorylation.
6. Discuss photolysis of water and its significance.
7. Describe the reactions occurring during dark reaction of photosynthesis.
8. Differentiate between C3 and C4 plants.
9. Differentiate between PSI and PSII.
10. What are the products of light reactions. What is the fate of these products?

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 MODULE - 2 Photosynthesis
Forms and Functions of
Plants and animals 11. Why is cyclic photophosphorylation called so?
12. What is Kranz anatomy?
13. Name the two carboxylase enzymes in C4 cycle.
14. What are chemosynthetic autotrophs?

Notes 15. How does CO2 concentration affect the rate of photosynthesis?
16. What is the effect of excess of oxyygen on the rate of photosynthesis?
17. Whether light absorbed by green plants, on global basis is limiting factor for
photosynthesis or not! Explain

ANSWERS TO INTEXT QUESTIONS

11.1 1. (i) It is the process by which green plants produce food (carbohydrates)
from simple substances like CO2 and water in presence of sun light
and chlorophyll.

Chlorophyll
(ii) 6CO2 + 12H2O ⎯⎯⎯⎯⎯
Sunlight
→ C6H12O6 + 6H2O + 6O2

2. (i) Chlorophylls and carotenoids.

(ii) Carotenoids and chlorophyll b
3. (i) Absorb it and then convert it into chemical energy.
(ii) Chlorophyll a and b
4. (i) Minimum in green and yellow light and maximum in blue and red
light.
(ii) light energy; chemical energy
5. From photolysis of water in PSII
11.2 1. NADP acts as an electron acceptor and H+ acceptor and finally, it gets
reduced to NADPH2.
2. It is called dark reaction because it can occur independent of light i.e.
can occur both in light and in dark.
3. (i) Rubisco is a part of C3 cycle and combines with CO2 to produce
a C3 compound called PGA.
(ii) PEPCo is a part of C4 path way and combines with CO2 to form
a C4 compound called OAA.

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Rubisco is present in the mesophyll cells of C3 plants and in the Plants and animals
bundle sheath cells of C4 plants.
PEPCo is found only in mesophyll cells of C4 plants.
4. See text
5. See text
6. C4 plants have no photorespiration and thus there is no loss of additional Notes
carbon dioxide, due to breakdown of RuBP to Glycolate and CO2.
7. (i) Photolysis of water
11.3 1. leaf age, chlorophyll content, leaf anatomy (size, internal structure,
stomatal distribution)
2. See text
3. Nitrosomonass and Nitrobacter.
4. Because they are not able to maintain H+ gradient across a membrane
in the absence of membrane bound organelles in their cytoplasm.

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