Day: January 15, 2025

Chapter 9: Physiology – Class 9th Biology Solved

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Delve into Chapter 9: Physiology from the Class 9th Biology New Syllabus, tailored for Lahore and Punjab Boards. This detailed post covers the human organ systems, their physiological functions, and related concepts, including the nervous system, circulatory system, and respiration. Includes solved MCQs, short questions, and exam tips to ensure success in your exams. A must-read for Class 9 students preparing for Punjab board exams.

1. Which of the following plant nutrients is required in large amounts?

Options:
a) Iron
b) Potassium
c) Phosphorus
d) Boron
Answer: b) Potassium
Explanation: Potassium is a macronutrient essential for plant growth. It regulates water uptake, photosynthesis, and enzyme activation.
Tip: Macronutrients like potassium, nitrogen, and phosphorus are needed in large amounts, while micronutrients like boron and iron are required in smaller amounts.

2. Which element is required by plants for the formation of chlorophyll?

Options:
a) Phosphorus
b) Calcium
c) Magnesium
d) Sulphur
Answer: c) Magnesium
Explanation: Magnesium is a core element in chlorophyll, enabling photosynthesis by capturing sunlight.
Tip: Link magnesium to chlorophyll by remembering that green leafy vegetables are rich in magnesium.

3. The primary function of root hairs is:

Options:
a) Transport of nutrients
b) Storage of food
c) Increase surface area for absorption
d) Synthesis of proteins
Answer: c) Increase surface area for absorption
Explanation: Root hairs increase the surface area, making water and nutrient uptake from the soil more efficient.
Tip: Think of root hairs as “extensions” that maximize absorption.

4. Root hairs absorb salts from soil by:

Options:
a) Diffusion
b) Active transport
c) Filtration
d) Osmosis
Answer: b) Active transport
Explanation: Active transport uses energy (ATP) to move salts and nutrients from lower to higher concentrations in the roots.
Tip: Remember, “active” means energy is required.

5. Water moves from the soil into root cells by:

Options:
a) Osmosis
b) Facilitated diffusion
c) Active transport
d) Bulk flow
Answer: a) Osmosis
Explanation: Osmosis is the movement of water from high to low water potential across a semi-permeable membrane.
Tip: Water = Osmosis; nutrients = Active transport.

6. The transpiration is regulated by:

Options:
a) Mesophyll
b) Guard cells
c) Xylem
d) Phloem
Answer: b) Guard cells
Explanation: Guard cells control the opening and closing of stomata, regulating water loss through transpiration.
Tip: Link “guard” cells with “guarding” the stomata.

7. Under which condition will there be high rate of transpiration?

Options:
a) High humidity
b) Low light intensity
c) Wind
d) Waterlogged soil
Answer: c) Wind
Explanation: Wind removes water vapor around leaves, increasing the rate of transpiration.
Tip: Think of wind as a “dryer” increasing water loss.

8. Which ion plays a role in the opening of stomata?

Options:
a) Sodium (Na⁺)
b) Potassium (K⁺)
c) Calcium (Ca²⁺)
d) Magnesium (Mg²⁺)
Answer: b) Potassium (K⁺)
Explanation: Potassium ions regulate the turgor pressure in guard cells, causing stomata to open or close.
Tip: Associate potassium (K⁺) with “Key” for stomata.

9. In most plants, the food is transported in the form of:

Options:
a) Glucose
b) Sucrose
c) Starch
d) Maltose
Answer: b) Sucrose
Explanation: Sucrose is water-soluble and easily transported through the phloem.
Tip: Glucose is stored, sucrose is transported.

10. What is TRUE according to the pressure flow mechanism of food transport?

Options:
a) Water enters the source, creating pressure.
b) Water is pulled from the sink.
c) Movement of food in phloem is due to gravity.
d) Solutes move from low to high concentration.
Answer: a) Water enters the source, creating pressure.
Explanation: In the source (e.g., leaves), sugar concentration draws water in, creating pressure that pushes food through the phloem to the sink (e.g., roots).
Tip: Think of the source as the “pump” for food transport.

MCQs:

11. Succulent organs are present in:
Options:
a) Xerophytes
b) Hydrophytes
c) Mesophytes
d) Halophytes
Answer: a) Xerophytes
Explanation: Xerophytes are plants adapted to dry environments, and their succulent organs store water to survive droughts.
Tip: “Xero” means dry, so remember xerophytes store water.

Short Answers (3 lines each):

  1. Define mineral nutrition in plants.
    Mineral nutrition involves the uptake of essential nutrients like nitrogen, phosphorus, and potassium from the soil, which plants use for growth and development.
  2. Define macronutrients and micronutrients and give examples.
    Macronutrients are needed in large amounts (e.g., nitrogen, phosphorus), while micronutrients are needed in small amounts (e.g., iron, zinc).
  3. State the roles of nitrogen and magnesium in plants.
    Nitrogen helps in protein synthesis and plant growth. Magnesium is essential for chlorophyll production and photosynthesis.
  4. Define transpiration and its types.
    Transpiration is the loss of water vapor from plant surfaces, mainly through stomata. Types include stomatal, cuticular, and lenticular transpiration.
  5. How is the transpiration pull important in plants?
    Transpiration pull helps transport water and minerals from roots to leaves, supporting photosynthesis and maintaining plant structure.
  6. Transpiration is the loss of water from plants. Is it harmful?
    Transpiration can be harmful during droughts, but it also cools the plant, supports nutrient transport, and maintains water flow.
  7. Differentiate between Xylem and Phloem:
  • Xylem: Transports water and minerals.
  • Phloem: Transports food (sucrose).
  1. How do the plants of rubber and keekar excrete their wastes?
    Rubber trees excrete waste as latex, while keekar trees excrete waste through leaf shedding and bark.

Detailed Answers:

1. Describe the events involved in the opening and closing of stomata.
Stomata are tiny openings on the surface of leaves, controlled by guard cells. Their opening and closing depend on water movement and ion concentration:

  • Opening of stomata:
    • During the day, guard cells actively absorb potassium ions (K⁺) from surrounding cells.
    • This increases the solute concentration inside guard cells, causing water to enter by osmosis.
    • The guard cells swell and become turgid, bending outward to open the stomatal pore.
    • This allows gases like carbon dioxide to enter for photosynthesis and oxygen to exit.
  • Closing of stomata:
    • At night or in dry conditions, potassium ions leave the guard cells, reducing their solute concentration.
    • Water moves out of the guard cells, making them flaccid and closing the stomatal pore.
    • This prevents water loss through transpiration.

Importance:
The stomata help regulate water loss, maintain plant hydration, and allow essential gas exchange for photosynthesis and respiration.

2. Explain the internal structure of roots and describe the uptake of salt and water.
Roots are specially adapted for water and mineral uptake. The key parts are:

  • Root hairs: Tiny hair-like structures increase surface area for water and nutrient absorption.
  • Cortex: A layer of loosely packed cells that allows easy movement of water and nutrients.
  • Endodermis: A barrier that ensures selective absorption of minerals.
  • Xylem and phloem: Xylem transports water and minerals, while phloem transports food.

Water uptake:

  • Water enters the root hairs from the soil by osmosis (movement from high to low water potential).
  • It travels through the root cortex to the xylem, either through cell walls (apoplast pathway) or through the cytoplasm (symplast pathway).

Salt uptake:

  • Minerals are absorbed by active transport, a process that requires energy in the form of ATP. This allows plants to take up nutrients even when their concentration in the soil is low.

Importance:
This mechanism ensures the plant receives water and nutrients for growth, photosynthesis, and development.

3. Describe temperature, wind, and humidity as factors affecting transpiration.
Transpiration is the loss of water vapor from plant leaves, mainly through stomata. It is influenced by environmental factors:

  • Temperature:
    • High temperatures increase evaporation of water from leaf surfaces, raising the rate of transpiration.
    • At low temperatures, transpiration slows down because evaporation is reduced.
  • Wind:
    • Wind blows away water vapor around the leaves, creating a low-humidity environment.
    • This increases the water concentration gradient between the leaf and the surrounding air, speeding up transpiration.
  • Humidity:
    • High humidity (moist air) reduces the rate of transpiration because the air already has a high water content.
    • Low humidity (dry air) increases transpiration as water vapor diffuses more quickly.

Importance:
These factors affect a plant’s water balance, cooling, and nutrient transport.

4. Describe the mechanism of transport of water and salt in plants.
Plants transport water and salts from the roots to other parts through the xylem:

  • Root pressure:
    • Minerals actively absorbed by roots create a pressure that pushes water upward in the xylem.
  • Capillary action:
    • Water rises in the narrow xylem vessels due to adhesion (water sticking to the vessel walls) and cohesion (water molecules sticking to each other).
  • Transpiration pull:
    • As water evaporates from leaves during transpiration, it creates a negative pressure in the xylem that pulls water upward from the roots.

Salt transport:
Salts are absorbed by active transport and move with water through the xylem. This ensures the plant receives essential nutrients for growth.

5. Explain the mechanism of food translocation by Pressure Flow Mechanism.
Food (mainly sucrose) is transported through the phloem using the pressure flow mechanism:

  • At the source (e.g., leaves):
    • Sucrose is actively loaded into the phloem sieve tubes.
    • This increases solute concentration, causing water from the xylem to enter by osmosis.
    • The pressure builds up, pushing the sucrose solution (sap) toward the sink.
  • At the sink (e.g., roots or fruits):
    • Sucrose is actively unloaded and used for energy or storage.
    • Water exits the phloem, reducing pressure and maintaining flow from source to sink.

Importance:
This mechanism efficiently transports food to growing parts, storage organs, and roots.

6. How do the plants excrete extra water and salts from their bodies?
Plants excrete waste through:

  • Transpiration: Excess water is lost as vapor through stomata.
  • Guttation: In some plants, water droplets are expelled from leaf edges (hydathodes) during the night or early morning.
  • Salt excretion: Halophytes excrete salts through special salt glands. Other plants store excess salts in leaves, which are later shed.

Importance:
These processes help plants maintain a balance of water and salts, preventing toxicity and dehydration.

7. Describe the process of gaseous exchange in plants.
Gaseous exchange in plants occurs through stomata and lenticels:

  • Daytime:
    • Carbon dioxide enters through stomata for photosynthesis.
    • Oxygen, a byproduct of photosynthesis, exits through stomata.
  • Nighttime:
    • Plants take in oxygen for respiration and release carbon dioxide as a waste product.

Importance:
This exchange is crucial for photosynthesis and cellular respiration, providing energy and maintaining life processes.

8. Describe the mechanisms/adaptations in plants for excretion of wastes.
Plants manage waste through:

  • Storage in vacuoles: Toxic substances are stored in vacuoles or in old tissues like bark and leaves.
  • Excretion through leaves: Some waste products are expelled when leaves shed.
  • Salt excretion: Halophytes (e.g., mangroves) excrete salts through specialized salt glands.

Importance:
These mechanisms help plants survive in challenging environments and prevent waste accumulation.

9. Explain osmotic adjustments in hydrophytes, xerophytes, and halophytes.

  • Hydrophytes:
    • Adapted to water-rich environments.
    • Excess water is stored or lost through transpiration.
  • Xerophytes:
    • Adapted to dry environments.
    • Store water in succulent tissues, have thick waxy cuticles, and small leaves to reduce water loss.
  • Halophytes:
    • Adapted to saline conditions.
    • Excrete excess salts through salt glands or store salts in vacuoles.

Importance:
These adjustments allow plants to survive and grow in their specific environments1. Describe the events involved in the opening and closing of stomata.
Stomata are tiny openings on the surface of leaves, controlled by guard cells. Their opening and closing depend on water movement and ion concentration:

  • Opening of stomata:
    • During the day, guard cells actively absorb potassium ions (K⁺) from surrounding cells.
    • This increases the solute concentration inside guard cells, causing water to enter by osmosis.
    • The guard cells swell and become turgid, bending outward to open the stomatal pore.
    • This allows gases like carbon dioxide to enter for photosynthesis and oxygen to exit.
  • Closing of stomata:
    • At night or in dry conditions, potassium ions leave the guard cells, reducing their solute concentration.
    • Water moves out of the guard cells, making them flaccid and closing the stomatal pore.
    • This prevents water loss through transpiration.

Importance:
The stomata help regulate water loss, maintain plant hydration, and allow essential gas exchange for photosynthesis and respiration.

2. Explain the internal structure of roots and describe the uptake of salt and water.
Roots are specially adapted for water and mineral uptake. The key parts are:

  • Root hairs: Tiny hair-like structures increase surface area for water and nutrient absorption.
  • Cortex: A layer of loosely packed cells that allows easy movement of water and nutrients.
  • Endodermis: A barrier that ensures selective absorption of minerals.
  • Xylem and phloem: Xylem transports water and minerals, while phloem transports food.

Water uptake:

  • Water enters the root hairs from the soil by osmosis (movement from high to low water potential).
  • It travels through the root cortex to the xylem, either through cell walls (apoplast pathway) or through the cytoplasm (symplast pathway).

Salt uptake:

  • Minerals are absorbed by active transport, a process that requires energy in the form of ATP. This allows plants to take up nutrients even when their concentration in the soil is low.

Importance:
This mechanism ensures the plant receives water and nutrients for growth, photosynthesis, and development.

3. Describe temperature, wind, and humidity as factors affecting transpiration.
Transpiration is the loss of water vapor from plant leaves, mainly through stomata. It is influenced by environmental factors:

  • Temperature:
    • High temperatures increase evaporation of water from leaf surfaces, raising the rate of transpiration.
    • At low temperatures, transpiration slows down because evaporation is reduced.
  • Wind:
    • Wind blows away water vapor around the leaves, creating a low-humidity environment.
    • This increases the water concentration gradient between the leaf and the surrounding air, speeding up transpiration.
  • Humidity:
    • High humidity (moist air) reduces the rate of transpiration because the air already has a high water content.
    • Low humidity (dry air) increases transpiration as water vapor diffuses more quickly.

Importance:
These factors affect a plant’s water balance, cooling, and nutrient transport.

4. Describe the mechanism of transport of water and salt in plants.
Plants transport water and salts from the roots to other parts through the xylem:

  • Root pressure:
    • Minerals actively absorbed by roots create a pressure that pushes water upward in the xylem.
  • Capillary action:
    • Water rises in the narrow xylem vessels due to adhesion (water sticking to the vessel walls) and cohesion (water molecules sticking to each other).
  • Transpiration pull:
    • As water evaporates from leaves during transpiration, it creates a negative pressure in the xylem that pulls water upward from the roots.

Salt transport:
Salts are absorbed by active transport and move with water through the xylem. This ensures the plant receives essential nutrients for growth.

5. Explain the mechanism of food translocation by Pressure Flow Mechanism.
Food (mainly sucrose) is transported through the phloem using the pressure flow mechanism:

  • At the source (e.g., leaves):
    • Sucrose is actively loaded into the phloem sieve tubes.
    • This increases solute concentration, causing water from the xylem to enter by osmosis.
    • The pressure builds up, pushing the sucrose solution (sap) toward the sink.
  • At the sink (e.g., roots or fruits):
    • Sucrose is actively unloaded and used for energy or storage.
    • Water exits the phloem, reducing pressure and maintaining flow from source to sink.

Importance:
This mechanism efficiently transports food to growing parts, storage organs, and roots.

6. How do the plants excrete extra water and salts from their bodies?
Plants excrete waste through:

  • Transpiration: Excess water is lost as vapor through stomata.
  • Guttation: In some plants, water droplets are expelled from leaf edges (hydathodes) during the night or early morning.
  • Salt excretion: Halophytes excrete salts through special salt glands. Other plants store excess salts in leaves, which are later shed.

Importance:
These processes help plants maintain a balance of water and salts, preventing toxicity and dehydration.

7. Describe the process of gaseous exchange in plants.
Gaseous exchange in plants occurs through stomata and lenticels:

  • Daytime:
    • Carbon dioxide enters through stomata for photosynthesis.
    • Oxygen, a byproduct of photosynthesis, exits through stomata.
  • Nighttime:
    • Plants take in oxygen for respiration and release carbon dioxide as a waste product.

Importance:
This exchange is crucial for photosynthesis and cellular respiration, providing energy and maintaining life processes.

8. Describe the mechanisms/adaptations in plants for excretion of wastes.
Plants manage waste through:

  • Storage in vacuoles: Toxic substances are stored in vacuoles or in old tissues like bark and leaves.
  • Excretion through leaves: Some waste products are expelled when leaves shed.
  • Salt excretion: Halophytes (e.g., mangroves) excrete salts through specialized salt glands.

Importance:
These mechanisms help plants survive in challenging environments and prevent waste accumulation.

9. Explain osmotic adjustments in hydrophytes, xerophytes, and halophytes.

  • Hydrophytes:
    • Adapted to water-rich environments.
    • Excess water is stored or lost through transpiration.
  • Xerophytes:
    • Adapted to dry environments.
    • Store water in succulent tissues, have thick waxy cuticles, and small leaves to reduce water loss.
  • Halophytes:
    • Adapted to saline conditions.
    • Excrete excess salts through salt glands or store salts in vacuoles.

Importance:
These adjustments allow plants to survive and grow in their specific environments

Chapter 8: Bioenergetics – Class 9th Biology

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Explore Chapter 8: Bioenergetics from the Class 9th Biology New Syllabus for Punjab Boards. This post provides detailed insights into photosynthesis, cellular respiration, ATP production, and factors affecting energy metabolism. It includes solved MCQs, short questions, and key points for exam preparation. Ideal for students studying under Punjab boards who want a comprehensive understanding of bioenergetics for better exam performance.

A. Select the correct answers for the following questions:

1. When we get energy from ATP, which bonds are broken?

  • Options:
    a) P-P bonds
    b) C-H bonds
    c) C-N bonds
    d) C=O bonds
  • Answer: a) P-P bonds
  • Explanation: Energy is released from ATP when the high-energy phosphate bonds (P-P bonds) are hydrolyzed. Typically, the terminal phosphate group is removed, converting ATP to ADP.
  • Tip: Remember “ATP = Adenosine Tri-Phosphate,” where the energy is stored in the phosphate bonds.

2. Light reactions of photosynthesis occur in:

  • Options:
    a) Plasma membrane of cell
    b) Cytoplasm of cell
    c) Stroma of chloroplasts
    d) Thylakoids of chloroplasts
  • Answer: d) Thylakoids of chloroplasts
  • Explanation: The light-dependent reactions of photosynthesis occur in the thylakoid membranes, where chlorophyll absorbs light and converts it into chemical energy (ATP and NADPH).
  • Tip: Think of “thylakoid” as the “power plant” of the chloroplast for light reactions.

3. Which type of chlorophyll is most common in plants?

  • Options:
    a) Chlorophyll a
    b) Chlorophyll b
    c) Chlorophyll c
    d) Chlorophyll d
  • Answer: a) Chlorophyll a
  • Explanation: Chlorophyll a is the primary pigment responsible for photosynthesis in plants. It absorbs light most efficiently in the blue-violet and red regions of the spectrum.
  • Tip: Chlorophyll a is “essential,” while others are “accessory pigments.”

4. Where does the reaction of photosynthesis take place?

  • Options:
    a) Chloroplast
    b) Mitochondria
    c) Cytoplasm
    d) Ribosomes
  • Answer: a) Chloroplast
  • Explanation: Photosynthesis occurs in chloroplasts, with light reactions in the thylakoids and the Calvin cycle in the stroma.
  • Tip: Remember that chloroplasts are exclusive to plants and are the “photosynthesis factory.”

5. When yeast ferments glucose, the products are:

  • Options:
    a) Alcohol and CO₂
    b) Alcohol and water
    c) Lactic acid and H₂O
    d) Alcohol and H₂O
  • Answer: a) Alcohol and CO₂
  • Explanation: In anaerobic conditions, yeast ferments glucose to produce ethanol (alcohol) and carbon dioxide as by-products.
  • Tip: Associate “yeast” with “alcoholic fermentation.”

6. In which part of the chloroplast does the light-dependent reaction occur?

  • Options:
    a) Stroma
    b) Thylakoid membrane
    c) Outer membrane
    d) Matrix
  • Answer: b) Thylakoid membrane
  • Explanation: The light-dependent reactions take place in the thylakoid membrane, where light is absorbed to produce ATP and NADPH.
  • Tip: Light = “Thylakoid”; Calvin cycle = “Stroma.”

7. Which molecule donates electrons in the light-dependent reactions of photosynthesis?

  • Options:
    a) NADPH
    b) Water
    c) Oxygen
    d) Carbon dioxide
  • Answer: b) Water
  • Explanation: Water (H₂O) is split during photolysis in the light-dependent reactions, releasing electrons, protons, and oxygen as a by-product.
  • Tip: Remember that “water splitting” produces the electrons needed for photosynthesis.

8. Which process in aerobic respiration produces the most ATP?

  • Options:
    a) Glycolysis
    b) Electron transport chain
    c) Fermentation
    d) Krebs cycle
  • Answer: b) Electron transport chain
  • Explanation: The electron transport chain (ETC) produces the most ATP (approximately 34 molecules per glucose molecule) during aerobic respiration, using the energy from NADH and FADH₂.
  • Tip: The ETC is the “energy powerhouse” of respiration.

9. In yeast cells, anaerobic respiration leads to the production of:

  • Options:
    a) Lactic acid
    b) Ethanol
    c) Acetic acid
    d) Glucose
  • Answer: b) Ethanol
  • Explanation: Under anaerobic conditions, yeast converts glucose into ethanol and CO₂ via fermentation.
  • Tip: Recall the industrial use of yeast in brewing and alcohol production.

Answers to MCQs:

  1. How many ATP molecules are produced from one glucose molecule during anaerobic respiration?
    Answer: a) 2
  2. What is a common byproduct of anaerobic respiration in animal cells?
    Answer: c) Lactic acid

Short Answers:

  1. Importance of oxidation-reduction reactions:
    Oxidation-reduction reactions are essential in cellular respiration and photosynthesis. They help transfer energy by moving electrons between molecules.
  2. Meaning and roles of ATP and ADP:
  • ATP (Adenosine Triphosphate): The main energy carrier in cells. It stores and provides energy for cellular activities.
  • ADP (Adenosine Diphosphate): A lower-energy molecule that is converted back to ATP during cellular respiration.
  1. Word equation for photosynthesis:
    Carbon dioxide + Water → Glucose + Oxygen
    (In the presence of sunlight and chlorophyll)
  2. Why is chlorophyll important for photosynthesis?
    Chlorophyll absorbs light energy from the sun, which is needed to drive the process of photosynthesis.
  3. How is oxygen produced during photosynthesis?
    Oxygen is produced as a byproduct when water molecules are split during the light-dependent reactions of photosynthesis.
  4. Organisms that carry out photosynthesis and responsible organelle:
    Plants, algae, and some bacteria carry out photosynthesis. The chloroplast is the organelle responsible for absorbing light.
  5. Main purpose of cellular respiration:
    To produce energy in the form of ATP, which is used for various cellular activities.
  6. Equation for aerobic respiration:
    Glucose + Oxygen → Carbon dioxide + Water + Energy (ATP)
  7. Role of oxygen in aerobic respiration:
    Oxygen is essential for breaking down glucose completely to release energy efficiently.
  8. Definition of anaerobic and aerobic respiration:
  • Anaerobic respiration: Respiration that occurs without oxygen, producing less ATP.
  • Aerobic respiration: Respiration that requires oxygen, producing more ATP.
  1. End products of anaerobic respiration in animals and yeast:
  • Animals: Lactic acid and ATP.
  • Yeast: Ethanol, carbon dioxide, and ATP.
  1. How muscles respond to oxygen deficiency during exercise:
    Muscles switch to anaerobic respiration, producing lactic acid and causing fatigue.
  2. Ways respiratory energy is used in the body:
  • Muscle contraction
  • Cell division
  • Active transport of molecules
  • Maintaining body temperature

Detailed Answers:

  1. Explain ATP as the chief energy currency of all cells:
    ATP is the primary molecule that stores and transfers energy in cells. It powers cellular processes like muscle contraction, nerve impulses, and biosynthesis. ATP releases energy when its phosphate bonds are broken, turning into ADP.
  2. Outline the processes involved in photosynthesis:
    Photosynthesis occurs in two stages:
  • Light-dependent reactions: Light energy splits water into oxygen, hydrogen ions, and electrons.
  • Light-independent reactions (Calvin cycle): Carbon dioxide combines with hydrogen ions to form glucose using energy from ATP and NADPH.
  1. Write a note on the intake of carbon dioxide and water by plants:
    Plants absorb carbon dioxide through tiny pores called stomata in their leaves. Water is absorbed by roots from the soil and transported to leaves via xylem vessels.
  2. Explain the types and importance of anaerobic respiration:
  • Types:
    • Lactic acid fermentation in animals.
    • Alcoholic fermentation in yeast.
  • Importance:
    • Provides energy in low-oxygen conditions.
    • Used in industries like brewing and baking.
  1. Outline the mechanism of aerobic respiration:
    Aerobic respiration occurs in three stages:
  • Glycolysis: Glucose is broken down into pyruvate, producing 2 ATP.
  • Krebs cycle: Pyruvate is broken down further, releasing carbon dioxide and energy-rich molecules.
  • Electron transport chain: Oxygen accepts electrons, forming water and generating a large amount of ATP (about 36 molecules).
  1. Compare the processes of respiration and photosynthesis:
  • Photosynthesis:
    • Occurs in chloroplasts.
    • Converts light energy into chemical energy.
    • Reactants: Carbon dioxide and water.
    • Products: Glucose and oxygen.
  • Respiration:
    • Occurs in mitochondria.
    • Converts chemical energy (glucose) into usable energy (ATP).
    • Reactants: Glucose and oxygen.
    • Products: Carbon dioxide and water.

Chapter 7: Enzymes – Class 9th Biology New Syllabus

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Explore Chapter 7: Enzymes from the Class 9th Biology New Syllabus of the Lahore Board. This detailed post includes a thorough explanation of enzyme characteristics, the lock-and-key model vs. the induced-fit model, factors affecting enzyme activity, pH, temperature effects, competitive and non-competitive inhibition, and much more. Get exam-prepared with solved MCQs, short answers, and detailed explanations. Ideal for students looking to master this chapter for top performance in exams.”

1. Primarily, all enzymes are:

  • Options:
    a) Nucleic acids
    b) Proteins
    c) Carbohydrates
    d) Lipids
  • Answer: b) Proteins
  • Explanation: Enzymes are biological catalysts made up of proteins. They accelerate chemical reactions in the body.
  • Tip: Remember, most enzymes end in “-ase,” and they are protein-based.

2. Which best defines an enzyme?

  • Options:
    a) A chemical that breaks down food.
    b) A hormone that regulates metabolism.
    c) A protein that speeds up reactions.
    d) A molecule that stores energy.
  • Answer: c) A protein that speeds up reactions.
  • Explanation: Enzymes lower the activation energy required for a chemical reaction, thereby speeding it up without being consumed in the process.
  • Tip: Focus on the key term “speed up reactions” in the question.

3. What can happen if an enzyme is exposed to a temperature that is higher than its optimal temperature?

  • Options:
    a) Enzyme activity rate will increase.
    b) Enzyme’s shape will change, potentially reducing its activity.
    c) Enzyme will speed up the reaction and remain stable.
    d) Enzyme will become a substrate itself.
  • Answer: b) Enzyme’s shape will change, potentially reducing its activity.
  • Explanation: High temperatures can denature enzymes, causing them to lose their shape and function.
  • Tip: Recall that enzymes have an optimal temperature range for activity.

4. Enzymes are specific in their action because:

  • Options:
    a) Their active sites fit specific substrates.
    b) They are always proteins.
    c) They are consumed in reactions.
    d) They work only at high temperatures.
  • Answer: a) Their active sites fit specific substrates.
  • Explanation: Enzyme specificity arises from the “lock-and-key” model, where the active site of an enzyme binds only to specific substrates.
  • Tip: Visualize the lock-and-key analogy for enzyme specificity.

5. Prosthetic groups are:

  • Options:
    a) Required by all enzymes.
    b) Proteins in nature.
    c) Loosely attached with enzymes.
    d) Tightly bound to enzymes.
  • Answer: d) Tightly bound to enzymes.
  • Explanation: Prosthetic groups are non-protein molecules that are permanently attached to enzymes and assist in their catalytic activity.
  • Tip: Remember, “tightly bound” differentiates prosthetic groups from coenzymes.

6. How does increasing temperature affect enzyme activity?

  • Options:
    a) Increases activity to a point.
    b) Always decreases activity.
    c) Makes enzymes non-functional.
    d) No effect on enzyme.
  • Answer: a) Increases activity to a point.
  • Explanation: Enzymes work optimally within a temperature range. Beyond this range, the activity decreases due to denaturation.
  • Tip: Recall the bell-shaped curve of enzyme activity vs. temperature.

7. How does a competitive inhibitor affect enzyme action?

  • Options:
    a) Attaches with the substrate.
    b) Changes enzyme shape.
    c) Attaches and blocks the active site.
    d) Blocks the cofactors.
  • Answer: c) Attaches and blocks the active site.
  • Explanation: Competitive inhibitors compete with the substrate by binding to the enzyme’s active site, preventing substrate interaction.
  • Tip: Remember, “competitive” means direct competition for the active site.

8. An enzyme works best at a pH of 7.4. It is placed in an acidic solution with a pH of 4.0. How will this affect the enzyme?

  • Options:
    a) The active site will be modified, reducing substrate binding.
    b) Enzyme activity will increase.
    c) Enzyme will become a substrate.
    d) No change will occur.
  • Answer: a) The active site will be modified, reducing substrate binding.
  • Explanation: A pH far from the enzyme’s optimal range can alter its shape, affecting its functionality.
  • Tip: Recall that extreme pH values can denature enzymes.

9. What is TRUE according to the induced-fit model of enzyme action?

  • Options:
    a) Enzyme’s active site changes shape to bind the substrate.
    b) Substrate must fit the enzyme perfectly before binding.
    c) No shape changes occur during binding.
    d) Enzyme is inactivated during the process.
  • Answer: a) Enzyme’s active site changes shape to bind the substrate.
  • Explanation: The induced-fit model suggests that the enzyme undergoes a conformational change to better accommodate the substrate.
  • Tip: Contrast this with the rigid “lock-and-key” model.

10. What is true about the optimum pH values of the following enzymes of the digestive system?

  • Options:
    a) Pepsin works at low pH while trypsin works at high pH.
    b) Both work at high pH.
    c) Both work at low pH.
    d) Pepsin works at high pH while trypsin works at low pH.
  • Answer: a) Pepsin works at low pH while trypsin works at high pH.
  • Explanation: Pepsin operates in the acidic environment of the stomach (low pH), while trypsin functions in the alkaline environment of the small intestine (high pH).
  • Tip: Recall the specific environments where these enzymes are active.

B. Short Answer Questions

  1. Define metabolism. Differentiate between catabolism and anabolism.
    • Answer: Metabolism refers to all the chemical processes in the body that maintain life.
      • Catabolism: Breakdown of molecules to release energy (e.g., digestion).
      • Anabolism: Synthesis of molecules, requiring energy (e.g., protein synthesis).
  1. Which type of metabolism demands input of energy? Give an example.
    • Answer: Anabolism requires energy input. Example: DNA synthesis.
  1. Define an enzyme. What is its role in metabolism?
    • Answer: An enzyme is a protein catalyst that speeds up chemical reactions in the body.
      • Role in metabolism: Enzymes lower the activation energy required for metabolic reactions, making them efficient.
  1. What is the active site of an enzyme? State its importance in enzyme specificity.
    • Answer: The active site is the region of an enzyme where the substrate binds and the reaction occurs.
      • Importance: It ensures that only specific substrates fit, maintaining reaction specificity.
  1. Provide an example of a specific enzyme-substrate pair.
    • Answer: Enzyme: Amylase, Substrate: Starch.
  1. How does pH affect enzyme activity?
    • Answer: Deviations from the optimal pH can denature the enzyme, altering its structure and reducing activity.
  1. Provide two examples of enzymes that operate optimally at specific pH.
    • Answer:
      • Pepsin (pH 1.5–2)
      • Trypsin (pH 8)
  1. What do you mean by optimum temperature and pH?
    • Answer: Optimum temperature and pH are the conditions where an enzyme exhibits maximum activity.
  1. Which type of enzyme inhibitors inhibit the enzymes without attaching to the active site?
    • Answer: Non-competitive inhibitors.
  1. Differentiate between competitive and non-competitive inhibition.
    • Answer:
      • Competitive inhibition: Inhibitor binds to the active site, blocking substrate binding.
      • Non-competitive inhibition: Inhibitor binds elsewhere, altering the enzyme’s shape and reducing activity.

Detailed Answer

1. Describe the characteristics of enzymes.

  • Biological Catalysts: Enzymes are proteins that catalyze biochemical reactions, increasing their speed without being consumed or permanently altered.
  • Specificity: Each enzyme is highly specific to its substrate due to the unique shape of its active site, often described using the “lock-and-key” or “induced-fit” model.
  • Reusable: Enzymes are not consumed during reactions and can be used repeatedly for the same type of reaction.
  • Temperature Sensitivity: Enzymes work best within a narrow temperature range. High temperatures can denature them, while low temperatures slow down molecular motion, reducing activity.
  • pH Sensitivity: Each enzyme has an optimal pH at which it functions most effectively. Extreme pH values can alter the enzyme’s structure and reduce its activity.
  • Regulation: Enzymes can be regulated by activators (which increase activity) or inhibitors (which decrease activity).
  • Cofactors and Coenzymes: Some enzymes require non-protein molecules (like metal ions or organic molecules) to function. These are called cofactors and coenzymes, respectively.

2. Describe how temperature extremes can inhibit enzyme activity and lead to enzyme denaturation.

  • At High Temperatures:
    • Enzymes are proteins, and high temperatures disrupt their hydrogen bonds, ionic bonds, and other interactions maintaining their structure.
    • This denaturation leads to the unfolding of the enzyme, rendering it non-functional because the active site loses its specific shape.
    • Example: Denaturation of human enzymes typically occurs above 40°C.
  • At Low Temperatures:
    • Molecular motion decreases significantly at lower temperatures, resulting in fewer collisions between enzymes and substrates.
    • The enzyme-substrate complex formation slows down, leading to reduced reaction rates.
  • Effects of Prolonged Temperature Extremes:
    • High temperatures can cause permanent denaturation, while low temperatures often cause reversible inactivation.
    • Optimal enzyme activity is observed within a specific temperature range, typically between 35°C and 40°C for most human enzymes.
  • Practical Implications:
    • Heat-sensitive enzymes are used in industries where precise temperature control is required, such as in brewing or pharmaceuticals.

3. How does pH affect enzyme activity?

  • Optimal pH:
    • Each enzyme functions best at a specific pH, called its “optimal pH.” For example, pepsin in the stomach works best at a pH of 1.5–2, while trypsin in the intestine works best at pH 8.
    • This pH aligns with the enzyme’s natural environment.
  • Effect on Ionization:
    • pH changes affect the ionization of amino acids at the enzyme’s active site and the substrate.
    • If the active site loses its correct charge distribution, it may fail to bind the substrate.
  • Denaturation at Extreme pH:
    • Both highly acidic and highly alkaline environments can disrupt the enzyme’s tertiary and quaternary structures by breaking hydrogen bonds and ionic interactions.
    • This structural alteration prevents the enzyme from functioning effectively.
  • Reversible vs. Irreversible Effects:
    • Minor pH deviations may cause reversible changes in activity, but extreme pH shifts can permanently denature the enzyme.
  • Example: Salivary amylase operates around neutral pH (7), but becomes inactive in the acidic environment of the stomach.

4. Briefly describe the factors that affect enzyme activity.

  • Temperature:
    • Enzyme activity increases with temperature until it reaches the optimum point, beyond which activity decreases due to denaturation.
    • Example: Human enzymes have an optimal temperature around 37°C.
  • pH:
    • Each enzyme has a specific pH range for optimal activity. Deviations from this range reduce enzyme efficiency or lead to denaturation.
    • Example: Digestive enzymes like pepsin (acidic) and trypsin (alkaline) have different pH optima.
  • Substrate Concentration:
    • Enzyme activity increases with substrate concentration until all active sites are saturated. Beyond this point, increasing substrate concentration has no further effect.
  • Enzyme Concentration:
    • Increasing enzyme concentration increases the rate of reaction, provided the substrate is in excess.
  • Inhibitors:
    • Competitive inhibitors: Bind to the active site, blocking substrate access.
    • Non-competitive inhibitors: Bind elsewhere on the enzyme, altering its shape and reducing functionality.
  • Cofactors and Coenzymes:
    • These molecules are essential for the activity of some enzymes.
    • Example: Metal ions like Mg²⁺ are cofactors, while vitamins like B6 act as coenzymes.
  • Environmental Conditions:
    • Factors like ionic strength, salinity, and pressure can also influence enzyme activity.

5. Compare the Lock-and-Key model and Induced-Fit model of enzyme action.

  • Lock-and-Key Model:
    • Proposed by Emil Fischer, it suggests that the enzyme’s active site is rigid and fits only specific substrates, like a key fits into a lock.
    • Strength: Explains enzyme specificity well.
    • Limitation: Fails to explain flexibility and conformational changes in enzymes.
  • Induced-Fit Model:
    • Proposed by Daniel Koshland, this model suggests that the enzyme’s active site is flexible and molds itself to fit the substrate.
    • Strength: Explains the dynamic nature of enzyme-substrate interactions and the formation of the enzyme-substrate complex.
    • Limitation: Slightly more complex to conceptualize compared to the lock-and-key model.
  • Comparison:
    • The lock-and-key model emphasizes rigidity and specificity, while the induced-fit model accounts for enzyme flexibility and adaptability.
    • Induced-fit is considered more accurate and widely accepted today due to evidence from structural biology.

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