Question

NCERT Solutions Class 11 Biology Chapter 13 Photosynthesis in Higher Plants has the solutions of one of the important chapters of biology. This NCERT solution deals with the concepts of plant and their process to make food.

NCERT Solutions Class 11 has solutions for all kinds of concepts. It is made by the mentors of the subject matter.

• Photosynthesis in Higher Plants – the fundamental process of photosynthesis is more or less the same as that of other plants. In this process, the plants use sunlight for the synthesis of an organic compound. Photosynthesis is a physicochemical process in which oxygen is released as waste material. Photosynthesis takes place in chloroplast which is found in mesophyll. There are 4 different types of pigment in photosynthesis:
  • Chlorophyll a
  • Chlorophyll b
  • Xanthophyll
  • Carotenoids
• Early Experiments on photosynthesis – in the process of photosynthesis the light energy is converted into chemical energy to produce oxygen. Many scientists conducted numerous experiments to prove the existence of photosynthesis.
  • Experiment to Prove Carbon dioxide is essential for Photosynthesis – in this experiment is found that carbon dioxide is needed for the process of photosynthesis.
  • Experiment by Joseph Priestley – in this experiment Joseph Priestley observed that plants purify the air by breathing in carbon dioxide and releasing oxygen.
  • There are many other experiments done by Jean Senebier, Jan Ingenhousz, Julius Robert Mayer, Julius Von Sachs, and many more.
• Where does Photosynthesis take place? – In plants, the process of photosynthesis takes place in the chloroplast which contains chlorophyll. Chloroplast is a double membrane cell organelle and it contains a third membrane as well which is called the thylakoid membrane.
• How many Pigments are involved in Photosynthesis? – There are four pigments involved in photosynthesis. The most important of all is chlorophyll and then there are others like chlorophyll b, xanthophylls, and carotenoids, and these pigments are called accessory pigments.

NCERT Solutions Class 11 Biology is the one study material one must refer to, for scoring well on their boards and competitive exams.

Answer 1

NCERT Solutions Class 11 Biology Chapter 13 Photosynthesis in Higher Plants

1. By looking at a plant externally can you tell whether a plant is C₃ or C₄? Why and how? 

Solution: 

One cannot distinguish whether a plant is C₃ or C₄ by observing its leaves and other morphological features externally. Unlike C₃ plants, the leaves of C₄ plants have a special anatomy called Kranz anatomy and this difference can only be observed at the cellular level. For example, although wheat and maize are grasses, wheat is a C₃ plant, while maize is a C₄ plant. 

2. By looking at which internal structure of a plant can you tell whether a plant is C₃ or C₄? Explain. 

Solution: 

The leaves of C₄ plants have a special anatomy called Kranz anatomy. This makes them different from C₃ plants. Special cells, known as bundle-sheath cells, surround the vascular bundles. These cells have a large number of chloroplasts. They are thick-walled and have no intercellular spaces. They are also impervious to gaseous exchange. All these anatomical features help prevent photorespiration in C₄ plants, thereby increasing their ability to photosynthesise. 

3. Even though a very few cells in a C₄ plant carry out the biosynthetic – Calvin pathway, yet they are highly productive. Can you discuss why? 

Solution: 

The productivity of a plant is measured by the rate at which it photosynthesises. The amount of carbon dioxide present in a plant is directly proportional to the rate of photosynthesis. C₄ plants have a mechanism for increasing the concentration of carbon dioxide. In C₄ plants, the Calvin cycle occurs in the bundle-sheath cells. The C₄ compound (malic acid) from the mesophyll cells is broken down in the bundlesheath cells. As a result, CO₂ is released. The increase in CO₂ ensures that the enzyme RuBisCo does not act as an oxygenase, but as a carboxylase. This prevents photorespiration and increases the rate of photosynthesis. Thus, C₄ plants are highly productive.

4. RuBisCo is an enzyme that acts both as a carboxylase and oxygenase. Why do you think RuBisCo carries out more carboxylation in C₄ plants? 

Solution: 

The enzyme RuBisCo is absent from the mesophyll cells of C₄ plants. It is present in the bundle-sheath cells surrounding the vascular bundles. In C₄ plants, the Calvin cycle occurs in the bundle-sheath cells. The primary CO₂ acceptor in the mesophyll cells is phosphoenol pyruvate – a three-carbon compound. It is converted into the four-carbon compound oxaloacetic acid (OAA). OAA is further converted into malic acid. Malic acid is transported to the bundle-sheath cells, where it undergoes decarboxylation and CO₂ fixation occurs by the Calvin cycle. This prevents the enzyme RuBisCo from acting as an oxygenase. 

5. Suppose there were plants that had a high concentration of Chlorophyll-b, but lacked chlorophyll-a, would it carry out photosynthesis? Then why do plants have chlorophyll-b and other accessory pigments? 

Solution: 

Chlorophyll-a molecules act as antenna molecules. They get excited by absorbing light and emit electrons during cyclic and non-cyclic photophosphorylations. They form the reaction centres for both photosystems I and II. Chlorophyll-b and other photosynthetic pigments such as carotenoids and xanthophylls act as accessory pigments. Their role is to absorb energy and transfer it to chlorophyll-a. Carotenoids and xanthophylls also protect the chlorophyll molecule from photo-oxidation. 

Therefore, chlorophyll-a is essential for photosynthesis. 

If any plant were to lack chlorophyll-a and contain a high concentration of chlorophyll-b, then this plant would not undergo photosynthesis.

6. Why is the colour of a leaf kept in the dark frequently yellow, or pale green? Which pigment do you think is more stable? 

Solution: 

Since leaves require light to perform photosynthesis, the colour of a leaf kept in the dark changes from a darker to a lighter shade of green. Sometimes, it also turns yellow. The production of the chlorophyll pigment essential for photosynthesis is directly proportional to the amount of light available. In the absence of light, the production of chlorophyll-a molecules stops and they get broken slowly. This changes the colour of the leaf gradually to light green. During this process, the xanthophyll and carotenoid pigments become predominant, causing the leaf to become yellow. These pigments are more stable as light is not essential for their production. They are always present in plants. 

7. Look at leaves of the same plant on the shady side and compare it with the leaves on the sunny side. Or, compare the potted plants kept in the sunlight with those in the shade. Which of them has leaves that are darker green? Why? 

Solution: 

Light is a limiting factor for photosynthesis. Leaves get lesser light for photosynthesis when they are in shade. Therefore, the leaves or plants in shade perform lesser photosynthesis as compared to the leaves or plants kept in sunlight. 

In order to increase the rate of photosynthesis, the leaves present in shade have more chlorophyll pigments. This increase in chlorophyll content increases the amount of light absorbed by the leaves, which in turn increases the rate of photosynthesis. Therefore, the leaves or plants in shade are greener than the leaves or plants kept in the sun. 

Answer 2

8. Figure shows the effect of light on the rate of photosynthesis. Based on the graph, answer the following questions: 

(a) At which point/s (A, B or C) in the curve is light a limiting factor? 

(b) What could be the limiting factor/s in region A? 

(c) What do C and D represent on the curve?

Solution:

(a) Generally, light is not a limiting factor. It becomes a limiting factor for plants growing in shade or under tree canopies. In the given graph, light is a limiting factor at the point where photosynthesis is the minimum. The least value for photosynthesis is in region A. Hence, light is a limiting factor in this region. 

(b) Light is a limiting factor in region A. Water, temperature, and the concentration of carbon dioxide could also be limiting factors in this region. 

(c) Point D represents the optimum point and gives the light intensity at which the maximum photosynthesis is recorded. The rate of photosynthesis remains constant after this point, even though the intensity of light

9. Give comparison between the following: 

(a) C₃ and C₄ pathways 

(b) Cyclic and non-cyclic photophosphorylation 

(c) Anatomy of leaf in C₃ and C₄ plants 

Solution: 

(a) C₃ and C₄ pathways.

C3 pathways		C4 pathways
1.	The primary acceptor of CO2 is RUBP – a six-carbon compound.	1.	The primary acceptor of CO2 is phosphoenol pyruvate – a threecarbon compound.
2.	The first stable product is 3 phosphoglycerate.	2.	The first stable product is oxaloacetic acid.
3.	It occurs only in the mesophyll cells of the leaves.	3.	It occurs in the mesophyll and bundle-sheath cells of the leaves.
4.	It is a slower process of carbon fixation and photo-respiratory losses are high.	4.	It is a faster process of carbon fixation and photo-respiratory losses are low.

(b) Cyclic and non-cyclic photophosphorylations

Cyclic photophosphorylation		Non-cyclic photophosphorylation
1.	It occurs only in photosystem I. 1.	1.	It occurs in photosystems I and II.
2.	It involves only the synthesis of ATP.	2.	It involves the synthesis of ATP and NADPH2.
3.	In this process, photolysis of water does not occur. Therefore, oxygen is not produced.	3.	In this process, photolysis of water takes place and oxygen is liberated.
4.	In this process, electrons move in a closed circle.	4.	In this process, electrons do not move in a closed circle.

(c) Anatomy of the leaves in C₃ and C₄ plants

C3 leaves		C4 plants
1.	Bundle-sheath cells are absent	1.	Bundle-sheath cells are present
2.	RuBisCo is present in the mesophyll cells.	2.	RuBisCo is present in the bundlesheath cells.
3.	The first stable compound produced is 3-phosphoglycerate –a three-carbon compound.	3.	The first stable compound produced is oxaloacetic acid – a four-carbon compound.
4.	Photorespiration occurs	4.	Photorespiration does not occur