Respiration in Plants | Class 11 Biology Notes

Introduction

Respiration is a vital metabolic process in plants through which stored food (glucose) is oxidized to release energy. This energy is used for growth, repair, transport, and other life processes.

Unlike animals, plants do not have specialized respiratory organs. Gas exchange occurs through stomata, lenticels, and root surfaces.

What is Respiration?

Respiration is the biochemical process of breaking down organic substances (like glucose) to release energy in the form of ATP.

General Equation of Respiration

$C_6H_{12}O_6 + 6O_2 \rightarrow 6CO_2 + 6H_2O + Energy\ (ATP)$ C6H12O6+6O2→6CO2+6H2O+Energy (ATP)

Types of Respiration

1. Aerobic Respiration

Occurs in the presence of oxygen
Complete oxidation of glucose
Produces large amount of energy (~36–38 ATP)

Equation:
Glucose + Oxygen → CO₂ + H₂O + Energy

2. Anaerobic Respiration

Occurs in absence of oxygen
Incomplete breakdown of glucose
Produces less energy (~2 ATP)

Examples:

In yeast: Ethanol + CO₂
In muscles (rare in plants): Lactic acid

Amphibolic Pathway

Respiration is called an amphibolic pathway because it involves both:

Catabolism: Breakdown of glucose
Anabolism: Synthesis of biomolecules

Respiratory Quotient (RQ)

RQ = CO₂ released / O₂ consumed

Values of RQ

Carbohydrates: 1
Fats: < 1
Organic acids: > 1

Steps of Respiration

Respiration in plants occurs in multiple steps:

1. Glycolysis (EMP Pathway)

Occurs in cytoplasm
Does not require oxygen
Glucose (6C) → 2 Pyruvate (3C)

Key Features

Produces 2 ATP (net gain)
Produces 2 NADH
Common to both aerobic and anaerobic respiration

2. Oxidative Decarboxylation (Link Reaction)

Occurs in mitochondria
Pyruvate → Acetyl CoA

Products:

CO₂ released
NADH formed

3. Krebs Cycle (Citric Acid Cycle)

Occurs in mitochondrial matrix
Acetyl CoA enters cycle

Key Outputs (per glucose):

2 ATP
6 NADH
2 FADH₂
4 CO₂

4. Electron Transport System (ETS)

Occurs in inner mitochondrial membrane
Electrons transferred through carriers

Final Step:

Oxygen acts as final electron acceptor
Water is formed

ATP Production:

Maximum ATP generated here

Total ATP Yield

Stage	ATP Produced
Glycolysis	2
Krebs Cycle	2
ETS	~32–34
Total	36–38 ATP

Fermentation

Fermentation is a type of anaerobic respiration.

Types:

1. Alcoholic Fermentation

Pyruvate → Ethanol + CO₂
Occurs in yeast

2. Lactic Acid Fermentation

Pyruvate → Lactic acid
Rare in plants

Energy Relations

ATP is the energy currency of the cell
Stored energy released in a stepwise manner
Prevents loss of energy as heat

Factors Affecting Respiration

1. Temperature

Higher temperature → faster respiration
Extreme heat → enzyme denaturation

2. Oxygen Availability

Required for aerobic respiration
Low oxygen → anaerobic respiration

3. Water

Necessary for enzyme activity

4. Substrate Availability

More glucose → increased respiration

Differences Between Aerobic and Anaerobic Respiration

Feature	Aerobic	Anaerobic
Oxygen	Required	Not required
Breakdown	Complete	Incomplete
ATP yield	High	Low
End products	CO₂ + H₂O	Ethanol/Lactic acid

Differences Between Respiration and Photosynthesis

Feature	Respiration	Photosynthesis
Type	Catabolic	Anabolic
Energy	Released	Stored
Occurs in	All cells	Chloroplast
Oxygen	Consumed	Released

Significance of Respiration in Plants

Provides energy (ATP)
Supports growth and development
Helps in biosynthesis
Maintains metabolic activities

Important NEET & CBSE Points

Glycolysis occurs in cytoplasm
Krebs cycle occurs in mitochondria
Final electron acceptor = Oxygen
ATP = Energy currency
RQ of carbohydrate = 1
Amphibolic pathway = Respiration

Quick Revision Notes

Respiration = energy release
Glycolysis → Krebs → ETS
Aerobic = high energy
Anaerobic = low energy
ATP is produced mainly in ETS

Frequently Asked Questions (FAQs)

Q1. What is respiration in plants?

It is the process of breaking down glucose to release energy.

Q2. Where does glycolysis occur?

In the cytoplasm.

Q3. What is the final electron acceptor?

Oxygen.

Q4. Why is respiration called amphibolic?

Because it involves both breakdown and synthesis pathways.

Conclusion

Respiration in plants is a complex yet essential process that ensures continuous energy supply for all life activities. Understanding its pathways, mechanisms, and significance is crucial for excelling in CBSE board exams and NEET.