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    Home » NCERT Solutions Class 11 Biology Chapter 15 Plant Growth and Development
    Class 11 Biology

    NCERT Solutions Class 11 Biology Chapter 15 Plant Growth and Development

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    *According to the CBSE Syllabus 2023-24, this chapter has been renumbered as Chapter 13.

    List of subtopics covered in Chapter 15 – Plant Growth and Development

    Number Subtopic
    15.1 Growth
    15.2 Differentiation, Dedifferentiation and Redifferentiation
    15.3 Development
    15.4 Plant Growth Regulators
    15.5 Photoperiodism
    15.6 Vernalisation

    NCERT Solutions for Class 11 Biology Chapter 15 – Plant Growth and Development

    Class 11th Biology Chapter 15 Plant Growth and Development NCERT Solution is given below.
    Question 1: Define growth, differentiation, development, dedifferentiation, redifferentiation, determinate growth, meristem and growth rate.
    Answer
    (a) Growth
    It is an irreversible and permanent process, accomplished by an increase in the size of an organ or organ parts or even of an individual cell.
    (b) Differentiation
    It is a process in which the cells derived from the apical meristem (root and shoot apex) and the cambium undergo structural changes in the cell wall and the protoplasm, becoming mature to perform specific functions.
    (c) Development
    It refers to the various changes occurring in an organism during its life cycle – from the germination of seeds to senescence.
    (d) De-differentiation
    It is the process in which permanent plant cells regain the power to divide under certain conditions.
    (e) Re-differentiation
    It is the process in which de-differentiated cells become mature again and lose their capacity to divide.
    (f) Determinate growth
    It refers to limited growth. For example, animals and plant leaves stop growing after having reached maturity.
    (g) Meristem
    In plants, growth is restricted to specialised regions where active cell divisions take place. Such a region is called meristem. There are three types of meristems – apical meristem, lateral meristem, and intercalary meristem.
    (h) Growth rate
    It can be defined as the increased growth in plants per unit time.


    Question 2: Why is not any one parameter good enough to demonstrate growth throughout the life of a flowering plant?
    Answer
    In plants, growth is said to have taken place when the amount of protoplasm increases. Measuring the growth of protoplasm involves many parameters such as the weight of the fresh tissue sample, the weight of the dry tissue sample, the differences in length, area, volume, and cell number measured during the growth period. Measuring the growth of plants using only one parameter does not provide enough information and hence, is insufficient for demonstrating growth.


    Question 3: Describe briefly:
    (a) Arithmetic growth
    (b) Geometric growth
    (c) Sigmoid growth curve
    (d) Absolute and relative growth rates
    Answer
    (a) Arithmetic growth
    In arithmetic growth, one of the daughter cells continues to divide, while the other differentiates into maturity. The elongation of roots at a constant rate is an example of arithmetic growth.
    (b) Geometric growth
    Geometric growth is characterised by a slow growth in the initial stages and a rapid growth during the later stages. The daughter cells derived from mitosis retain the ability to divide, but slow down because of a limited nutrient supply.
    (c) Sigmoid growth curve
    The growth of living organisms in their natural environment is characterised by an S-shaped curve called sigmoid rowth curve. This curve is divided into three phases – lag phase, log phase or exponential phase of rapid growth, and stationary phase.
    Exponential growth can be expressed as:

    W1 =W0ert
    Where,
    W1 = Final size
    W0 = Initial size
    r = Growth rate
    t= Time of growth
    e = Base of natural logarithms
    (d) Absolute and relative growth rates
    Absolute growth rate refers to the measurement and comparison of total growth per unit time. Relative growth rate refers to the growth of a particular system per unit time, expressed on a common basis.


    Question 4: List five main groups of natural plant growth regulators. Write a note on discovery, physiological functions and agricultural/horticultural applications of any one of them.
    Answer:
    Plant growth regulators are the chemical molecules secreted by plants affecting the physiological attributes of a plant. There are five main plant growth regulators. These are:
    (i) Auxins
    (ii) Gibberellic acid
    (iii) Cytokinins
    (iv) Ethylene
    (v) Abscisic acid
    (i) Auxins
    Discovery:
    The first observations regarding the effects of auxins were made by Charles Darwin and Francis Darwin wherein they saw the coleoptiles of canary gross bending toward a unilateral source of light.
    It was concluded after a series of experiments that some substance produced at the tip of coleoptiles was responsible for the bending. Finally, this substance was extracted as auxins from the tips of coleoptiles in oat seedlings.
    Physiological functions:
    1. They control plant cell-growth.
    2. They cause the phenomenon of apical dominance.
    3. They control division in the vascular cambium and xylem differentiation.
    4. They induce parthenocarpy and prevent abscission of leaves and fruits.
    Horticultural applications:
    1. They are used as the rooting hormones in stem cuttings.
    2. 2-4 D is used weedicide to kill broadleaf, dicotyledonous weeds.
    3. They induce parthenocarpy in tomatoes.
    4. They promote flowering in pineapple and litchi.

    (ii) Gibberellic acid
    Discovery:
    Bakane or the “foolish rice seedling” disease was first observed by Japanese farmers. In this disease, rice seedlings appear to grow taller than natural plants, and become slender and pale green. Later, after several experiments, it was found that this condition was caused by the infection from a certain fungus Gibberella fujikuroi. The active substance was isolated and identified as gibberellic acid.
    Physiological functions:
    1. It causes elongation of internodes.
    2. It promotes bolting in rosette plants.
    3. It helps in inducing seed germination by breaking seed dormancy and initiating the synthesis of hydrolases enzymes for digesting reserve food.
    Horticultural applications:
    1. It helps in increasing the sugar content in sugarcane by increasing the length of the internodes.
    2. It increases the length of grape stalks.
    3. It improves the shape of apple.
    4. It delays senescence.
    5. It hastens maturity and induces seed-production in juvenile conifers.

    (iii) Cytokinins
    Discovery:
    Through their experimental observations, F. Skoog and his co-workers found that the tobacco callus differentiated when extracts of vascular tissues, yeast extract, coconut milk, or DNA were added to the culture medium. This led to the discovery of cytokinins.
    Physiological functions:
    1. They promote the growth of lateral branches by inhibiting apical dominance.
    2. They help in the production of new leaves, chloroplasts, and adventitious shoots. 3. They help in delaying senescence by promoting nutrient mobilisation.
    Horticultural applications:
    1. They are used for preventing apical dominance.
    2. They are used for delaying senescence in leaves.

    (iv) Ethylene
    Discovery:
    It was observed that unripe bananas ripened faster when stored with ripe bananas. Later, the substance promoting the ripening was found to be ethylene.
    Physiological functions:
    1. It helps in breaking seed and bud dormancy.
    2. It promotes rapid internode-elongation in deep-water rice plants.
    3. It promotes root-growth and formation of root hairs.
    4. It promotes senescence and abscission of leaves and flowers.
    5. It hastens the respiration rate in fruits and enhances fruit ripening.
    Horticultural applications:
    1. It is used to initiate flowering and synchronising the fruit set in pineapples.
    2. It induces flowering in mango.
    3. Ethephon is used to ripen the fruits in tomatoes and apples, and accelerate the abscission of flowers and leaves in cotton, cherry, and walnut.
    4. It promotes the number of female flowers in cucumbers.

    (v) Abscisic acid
    Discovery:
    During the mid 1960s, inhibitor-B, abscission II, and dormin were discovered by three independent researchers. These were later on found to be chemically similar and were thereafter called ABA (Abscisic acid).
    Physiological functions:
    1. It acts as an inhibitor to plant metabolism.
    2. It stimulates stomatal closure during water stress.
    3. It induces seed dormancy.
    4. It induces abscission of leaves, fruits, and flowers.
    Horticultural application:
    It induces seed dormancy in stored seeds.


    Question 5: What do you understand by photoperiodism and vernalisation? Describe their significance.
    Answer
    Photoperiodism refers to the response of plants with respect to the duration of light (i.e., period of day and night). On the basis of its response to the duration of light, a plant is classified as a short-day plant, a long-day plant, or a day-neutral plant. Short-day plants flower when they are exposed to light for a period less than the critical day-length (for example: Chrysanthemum). Long-day plants flower when they are exposed to light for a period more than the critical day-length (for example: radish). When no marked correlation is observed between the duration of exposure to light and the flowering response, plants are termed as day-neutral plants (for example: tomato).

    It is hypothesised that the hormonal substance responsible for flowering is formed in the leaves, subsequently migrating to the shoot apices and modifying them into flowering apices. Photoperiodism helps in studying the response of flowering in various crop plants with respect to the duration of exposure to light.

    Vernalisation is the cold-induced flowering in plants. In some plants (such as the winter varieties of wheat and rye and biennials such as carrot and cabbage), exposure to low temperature is necessary for flowering to be induced. The winter varieties of rye and wheat are planted in autumn. They remain in the seedling stage during winters and flower during summers. However, when these varieties are sown in spring, they fail to flower. Similar response is seen in cabbage and radish.


    Question 6: Why is Abscisic acid also known as stress hormone?
    Answer: 
    Abscisic acid is called stress hormones as it induces various responses in plants against stress conditions. It increases the tolerance of plants toward various stresses. It induces the closure of the stomata during water stress. It promotes seed dormancy and ensures seed germination during favourable conditions. It helps seeds withstand desiccation. It also helps in inducing dormancy in plants at the end of the growing season and promotes abscission of leaves, fruits, and flowers.


    Question 7: ‘Both growth and differentiation in higher plants are open’. Comment.
    Answer
    Growth and development in higher plants is referred to as being open. This is because various meristems, having the capacity for continuously dividing and producing new cells, are present at different locations in these plant bodies.


    Question 8: ‘Both a short day plant and a long day plant can flower simultaneously in a given place’. Explain.
    Answer
    The flowering response in short-day plants and long-day plants is dependent on the durations for which these plants are exposed to light. The short-day plant and longday plant can flower at the same place, provided they have been given an adequate photoperiod.


    Question 9: Which one of the plant growth regulators would you use if you are asked to:
    (a) Induce rooting in a twig
    (b) Quickly ripen a fruit
    (c) Delay leaf senescence
    (d) Induce growth in axillary buds
    (e) ‘Bolt’ a rosette plant
    (f) Induce immediate stomatal closure in leaves.
    Answer
    (a) Induce rooting in a twig – Auxins
    (b) Quickly ripen a fruit – Ethylene
    (c) Delay leaf senescence – Cytokinins
    (d) Induce growth in axillary buds – Cytokinins
    (e) ‘Bolt’ a rosette plant – Gibberellic acid
    (f) Induce immediate stomatal closure in leaves – Abscisic acid


    Question 10: Would a defoliated plant respond to photoperiodic cycle? Why?
    Answer
    A defoliated plant will not respond to the photoperiodic cycle. It is hypothesised that the hormonal substance responsible for flowering is formed in the leaves, subsequently migrating to the shoot apices and modifying them into flowering apices. Therefore, in the absence of leaves, light perception would not occur, i.e., the plant would not respond to light.


    Question 11: What would be expected to happen if:
    (a) GA3 is applied to rice seedlings
    (b) Dividing cells stop differentiating
    (c) A rotten fruit gets mixed with unripe fruits
    (d) You forget to add cytokinin to the culture medium.
    Answer
    (a) If GA3 is applied to rice seedlings, then the rice seedlings will exhibit internodeelongation and increase in height.
    (b) If dividing cells stop differentiating, then the plant organs such as leaves and stem will not be formed. The mass of undifferentiated cell is called callus.
    (c) If a rotten fruit gets mixed with unripe fruits, then the ethylene produced from the rotten fruits will hasten the ripening of the unripe fruits.
    (d) If you forget to add cytokinin to the culture medium, then cell division, growth, and differentiation will not be observed.

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