Notes Chapter 13 Photosynthesis in Higher Plants

Class 11 commerce students can refer to Chapter 13 Photosynthesis in Higher Plants notes given below which is an important chapter in the class 11 Biology book. These notes and important questions and answers have been prepared based on the latest CBSE and NCERT syllabus and books issued for the current academic year. Our team of Biology teachers has prepared these notes for class 11 Biology for the benefit of students so that you can read these revision notes and understand each topic carefully.

Photosynthesis in Higher Plants Notes Class 11 Biology

Refer to the notes and important questions given below for Photosynthesis in Higher Plants which is really useful and has been recommended by Class 11 Biology teachers. Understanding the concepts in detail and then solving questions by yourself will help you to learn all topics given in your NCERT Books.

Photosynthesis in Higher Plants

Photosynthesis is a physico-chemical process by which green plants use light energy to drive the synthesis of organic compounds. It is an enzyme regulated anabolic process.

Notes Chapter 13 Photosynthesis in Higher Plants
  • Photosynthesis is the basis of life on earth because it is the primary source of all food on earth and it is responsible for release of O2 in the atmosphere.
  • Chlorophyll, light and CO2 is required for photosynthesis. It occurs only in green part of leaves and in presence of light.

Early Experiments

  • Joseph Priestley in 1770, on the basis of his experiments showed the essential role of air in growth of green plants. A mouse kept in closed space could get suffocated and die but if a mint plant is kept in bell jar neither candle will extinguish nor will the mouse die. He concluded that foul air produced by animal is converted into pure air by plants. Priestley discovered Oxygen gas in 1774.
Notes Chapter 13 Photosynthesis in Higher Plants
  • Julius Von Sachs in 1854 shows that green part in plants produces glucose which is stored as starch. Starch is the first visible product of photosynthesis.
  • T.W.Engelmann (1843-1909) used prism to split light into its components and then illuminated Cladophora (an algae) placed in a suspension of aerobic bacteria. He found that bacteria accumulated in blue and red light of the split spectrum. He thus discovered the effect of different wavelength of light on photosynthesis (action spectrum).

Cornelius Van Neil (1897-1985) on the basis of studies with purple and green sulphur bacteria showed that photosynthesis is a light dependent reaction in which hydrogen from an oxidisable compound reduces CO2 to form sugar.

Notes Chapter 13 Photosynthesis in Higher Plants

In green sulphur bacteria, when H2S , instead of  H2o was used as hydrogen donor, no  Owas evolved. He inferred that O2 evolved by green plants comes from H2o but not from as CO2 thought earlier.

Where Does Photosynthesis Takes Place?

  • Chloroplasts are green plastids which function as the site of photosynthesis in eukaryotic photoautotrophs. Inside the leaves, chloroplast is generally present in mesophyll cells along their walls.
  • Within the chloroplast there is a membranous system consisting of grana, the stroma lamellae and the fluid stroma.
Notes Chapter 13 Photosynthesis in Higher Plants

The membrane system is responsible for synthesizing light energy for the synthesis of ATP and NADPH. In stroma enzymatic reactions incorporate COin plants leading to synthesis of sugar.

The reaction in which light energy is absorbed by grana to synthesis ATP and NADPH is called light reaction. The later part of photosynthesis in which CO2 is reduced to sugar, light is not necessary and is called dark reaction.

Pigments involved in Photosynthesis – Chromatographic separation of leaf pigments are as follows-

Notes Chapter 13 Photosynthesis in Higher Plants

Maximum absorption by chlorophyll a occurs in blue and red regions having higher rate of photosynthesis. So, chlorophyll a is the chief pigment.

  • Other thylakoid pigments like chlorophyll b, xanthophyll and carotenoids are called accessary pigments that absorb light and transfer energy to chlorophyll a and protect them from photo-oxidation.

Light reaction
Light reaction(photochemical phase) includes:
1. Light absorption
2. Water splitting
3. Oxygen release
4. Formation of high energy chemical intermediates (ATP and NADPH).

  • The pigments are organized into two discrete LHC( light harvesting complex) within photosystem I and photosystem II.
  • LHC are made up of hundreds of pigments molecules containing all pigments except single chlorophyll a molecules in each PS.
Notes Chapter 13 Photosynthesis in Higher Plants
  • The pigments in photosystem I and photosystem II absorbs the lights of different wavelength. Single chlorophyll a molecule makes the reaction centre. In PS I reaction centre has highest peak at 700nm, hence called P700. And PS II reaction centre has highest peak at 680 nm, so called P680.

The Electron Transport System

  • Reaction centre of photosystem II absorbs light of 680 nm in red region and causing electron to become excited. These electrons are picked by an electron acceptor which passes to electron transport system consisting of cytochromes.
Notes Chapter 13 Photosynthesis in Higher Plants
  • Electrons are passed down the electron transport chain and then to the pigment of PS I.
  • Electron in the PSI also get excited due to light of wavelength 700nm and are transferred to another accepter molecule having a greater redox potential.
  • When electron passes in downhill direction, energy is released. This is used to reduce the ADP to ATP and NADP+ to NADPH. The whole scheme of transfer of electron is called Z-scheme due to its shape.
  • Photolysis of water release electrons that provide electron to PS II. Oxygen is also released during this process.
Notes Chapter 13 Photosynthesis in Higher Plants

Difference between cyclic and non-cyclic photophosphorylation

Notes Chapter 13 Photosynthesis in Higher Plants
Notes Chapter 13 Photosynthesis in Higher Plants

Chemiosmotic Hypothesis of ATP FORMATION

This hypothesis was proposed by Mitchell in 1961. ATP synthesis is linked to development of proton gradient across the membrane of thylakoid and mitochondria.
The process that causes development of proton gradient across the membrane is-

Notes Chapter 13 Photosynthesis in Higher Plants

1. Splitting of water molecules occurs inside the thylakoid to produce hydrogen ion or proton.

2. As electron passes through the photosystems, protons are transported across the membrane because primary acceptor of electron is located towards the outer side the membrane.

3. The NADP reductase enzyme is located in the stroma side of membrane. Electrons come out from the acceptor of electron of PSI, protons are necessary for reduction of NADP+ to NADP + H+. These protons are also removed from the stroma. This creates proton gradient across the thylakoids membrane along with pH in the lumen.

4. Gradient is broken down due to movement of proton across the membrane to the stroma through trans-membrane channel of F0 of ATPase. One part of this enzyme is embedded
in membrane to form trans-membrane channel. The other portion is called F1that protrudes on the outer surface of thylakoid membrane which makes the energy packed ATP.

5. ATP and NADPH produced due to movement of electron is used immediately to fix CO2 to form sugar.
The product of light reaction used to drive the process leading to synthesis of sugar are called biosynthetic phase of photosynthesis.

Calvin Cycle/C3 cycle/Reductive Pentose Sugar Phosphate Pathway

Malvin Calvin, Benson and their colleagues used radioactive 14C and Chlorealla and Scenedesmus algae to discover that first fixation product is 3-carbon organic compound (3-phosphoglyceric acid) or PGA. Later on a new compound was discovered which contain 4-carbon called Oxaloacetic Acid (AAO). On the basis of number of carbon atoms in first stable product they are named C3 and C4 pathway.

Calvin cycle can be described under three stages: carboxylation, reduction and regeneration.

Carboxylation is the fixation of Co2 into 3-phosphoglyceric acid (3-PGA).
Carboxylation of RuBP occurs in presence of enzyme RuBP carboxylase (RuBisCO) which results in the formation of two molecules of 3-PGA.
Reduction is series of reaction that leads to formation of glucose. Two molecules of ATP and two molecules of NADPH are required for reduction of one molecules of Co2. Six turn of this cycle are required for removal of one molecule of Glucose molecules from pathway.
Regeneration is the generation of RuBP molecules for the continuation of cycle. This process require one molecules of ATP.

Notes Chapter 13 Photosynthesis in Higher Plants

Fig-Calvin Cycle/ C3 Cycle

For every molecules of CO2entering the Calvin Cycle, 3 molecules of ATP and 2 molecules of NADPH is required. To make one molecules of glucose 6 turns of cycle is completed so total energy molecule required is

Notes Chapter 13 Photosynthesis in Higher Plants

C4 pathway/Hatch Slack Pathway

This pathway was worked out by Hatch and Slack (1965, 1967), mainly operational in plants growing in dry tropical region like Maize, Sugarcane, Sorghum etc.

In this pathway first stable product is a 4-carbon compound Oxaloacetic acid (AAO) so called as Cpathway. Cplants have Kranz Anatomy (vascular bundles are surrounded by bundle sheath cells arranged in wreath like manner), characterized by large no of chloroplast, thick wall impervious to gases and absence of intercellular spaces.

The primary Co2 acceptor is a 3-carbon molecule Phosphoenol Pyruvate present in mesophyll cells and enzyme involved is PEP carboxylase.OAA formed in mesophyll cell forms 4-carbon compound like malic acid or aspartic acid which is transported to bundle sheath cells.

In bundle sheath cell, it is broken into Coand a 3-carbon molecule. The 3-carbon molecule is returned back to mesophyll cells to form PEP.

The Comolecules released in bundle sheath cells enters the Calvin cycle, where enzyme RuBisCO is present that forms sugar.

Notes Chapter 13 Photosynthesis in Higher Plants


  • It is a the light dependent process of oxygenation of RuBP and release of carbon dioxide by photosynthetic organs of plants.
  • Photorespiration decreases the rate of photosynthesis when oxygen concentration is increased from 2-3% to 21%.
  • Presence of light and higher concentration of Oxygen results in the binding of RuBisCO enzyme with O2 to form.

RuBisCO +O2 → PGA + phosphoglycolate
This pathway involves Chloroplast, Peroxisome and Mitochondria. Photorespiration do not occurs in C4 plants.

Notes Chapter 13 Photosynthesis in Higher Plants
Notes Chapter 13 Photosynthesis in Higher Plants

Factors affecting photosynthesis
1. Light- as light intensity increases, the rate of photosynthesis also increases until light saturation point.
2. Carbon dioxide concentration- with increase in concentration of rate of photosynthesis increase till the compensation point.
3. Temperature- it does not influence the rate of photosynthesis directly but at higher temperature enzyme activity is inhibited due to denaturation of enzymes which affect the dark reaction.
4. Water- due to increase in amount of water, rate of photosynthesis does not increase proportionally as after saturation no more water is required during photosynthesis.

Blackman’s Law of Limiting Factors states:
If a chemical process is affected by more than one factor, then its rate will be determined by the factor which is nearest to its minimal value: it is the factor which directly affects the process if its quantity is changed.

Notes Chapter 13 Photosynthesis in Higher Plants

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