Introduction
Muscle contraction is the process by which muscle fibers generate force
and shorten to produce movement. It is one of the most important physiological
processes in the human body and forms the basis of locomotion, posture
maintenance, respiration, circulation, and many other vital functions.
Muscle contraction occurs due to the sliding of thin actin filaments
over thick myosin filaments, known as the Sliding Filament Theory.
This theory was proposed independently by Andrew Huxley and Rolf Niedergerke
and by Hugh Huxley and Jean Hanson in 1954.
Muscle Tissue
Muscles are specialized tissues capable of:
- Excitability
- Contractility
- Extensibility
- Elasticity
There are three types of muscles:
|
Type |
Location |
Control |
|
Attached to bones |
Voluntary |
|
|
Smooth Muscle |
Walls of visceral organs |
Involuntary |
|
Cardiac Muscle |
Heart |
Involuntary |
Sliding filament theory is best explained in skeletal muscles.
Structure of a Skeletal Muscle
Hierarchical Organization
Muscle
↓
Muscle Fascicle
↓
Muscle Fiber (Muscle Cell)
↓
Myofibril
↓
↓
Actin & Myosin Filaments
Muscle Fiber
A skeletal muscle fiber is:
- Long
- Cylindrical
- Multinucleated
- Striated
Components
Sarcolemma
Cell membrane of muscle fiber.
Sarcoplasm
Cytoplasm of muscle fiber.
Sarcoplasmic Reticulum (SR)
Specialized endoplasmic reticulum storing calcium ions.
T-tubules
Invaginations of sarcolemma that transmit impulses deep into muscle
fiber.
Myofibrils
Contractile elements arranged parallel to each other.
Myofibril Structure
Myofibrils show alternate:
Dark Bands (A Bands)
- Anisotropic
- Contain thick myosin filaments
- Remain constant during
contraction
Light Bands (I Bands)
- Isotropic
- Contain only actin filaments
- Shorten during contraction
Sarcomere
Definition
Sarcomere is the structural and functional unit of muscle contraction.
Boundaries
Between two successive Z-lines.
Diagrammatic Representation
Z I
A H A
I Z
|-----|-----|------|------|------|-----|
Actin ←→ Myosin ←→ Actin
Parts of Sarcomere
Z-Line
- Boundary of sarcomere
- Anchors actin filaments
I-Band
Contains only actin filaments.
A-Band
Contains entire length of myosin filament.
H-Zone
Contains only myosin.
M-Line
Middle of H-zone.
Anchors myosin filaments.
Contractile Proteins
1. Actin (Thin Filament)
Major protein of thin filament.
Components
- F-actin
- G-actin
- Troponin
- Tropomyosin
G-actin
Globular protein molecule.
F-actin
Double helical polymer of G-actin.
Tropomyosin
- Fibrous protein
- Lies in groove of actin filament
- Covers myosin binding sites
during relaxation
Three subunits:
|
Subunit |
Function |
|
Troponin T |
Binds Tropomyosin |
|
Troponin I |
Inhibitory |
|
Troponin C |
Binds Calcium |
Calcium binds to Troponin-C.
2. Myosin (Thick Filament)
Major protein of thick filament.
Structure
Each myosin molecule consists of:
- Two heavy chains
- Four light chains
Parts
Head
- Cross-bridge formation
- ATPase activity
Neck
Connects head and tail.
Tail
Forms shaft of thick filament.
Types of Muscle Contraction
1. Isometric Contraction
- Muscle length unchanged
- Tension increases
Example: Pushing a wall.
2. Isotonic Contraction
Length changes.
Concentric- Muscle shortens.
Example: Lifting dumbbell.
Eccentric- Muscle lengthens under load.
Example: Lowering dumbbell.
Sliding Filament Theory
Principle
During contraction:
- Actin slides over myosin
- Filaments themselves do NOT
shorten
- Sarcomere shortens
- Muscle shortens
This is known as the Sliding Filament Theory.
Events of Muscle Contraction
Step 1: Nerve Impulse Arrives
Motor neuron carries impulse to neuromuscular junction.
Step 2: Release of Acetylcholine
Acetylcholine (ACh) is released into synaptic cleft. ACh binds receptors
on sarcolemma. This generates an action potential.
Step 3: Spread of Action Potential
Action potential spreads through:
- Sarcolemma
- T-tubules
Step 4: Calcium Release
Sarcoplasmic reticulum releases calcium ions into sarcoplasm. Calcium
concentration rises rapidly.
Step 5: Exposure of Active Sites
Calcium binds to Troponin-C.
Result:
- Troponin changes shape
- Tropomyosin shifts away
- Active sites on actin become
exposed
Cross-Bridge Cycle
This is the heart of muscle contraction.
Stage 1: Cross-Bridge Formation
Myosin head attaches to exposed actin site.
Actin + Myosin
↓
Cross Bridge
Stage 2: Power Stroke
ADP and Pi leave myosin head. Myosin bends. Actin filament is pulled
toward center. This is called the Power Stroke.
Stage 3: Detachment
New ATP binds myosin. Myosin detaches from actin.
Stage 4: Reactivation
ATP hydrolysis occurs:
ATP → ADP + Pi + Energy
Energy cocks myosin head. Head becomes ready for next cycle.
Role of ATP
ATP is essential for:
1. Detachment of Myosin from Actin
Without ATP, myosin remains attached.
2. Re-cocking of Myosin Head
ATP hydrolysis energizes myosin.
3. Calcium Pumping
ATP pumps calcium back into SR.
Changes In Sarcomere During Contraction
|
Structure |
Change |
|
Sarcomere Length |
Decreases |
|
Z-Lines |
Move closer |
|
I-Band |
Shortens |
|
H-Zone |
Shortens/disappears |
|
A-Band |
Unchanged |
Definition
Stiffening of muscles after death.
Cause
No ATP production after death. Myosin cannot detach from actin. Cross-bridges
remain locked.
Result: Muscle rigidity. Rigor mortis occurs due to ATP depletion.
Memory Table
|
Structure |
During Contraction |
|
Actin Length |
No change |
|
Myosin Length |
No change |
|
A-Band |
No change |
|
I-Band |
Decreases |
|
H-Zone |
Decreases |
|
Sarcomere |
Decreases |
Muscle Relaxation
Contraction stops when nerve impulse ceases.
Steps
1. Acetylcholine Breakdown
By acetylcholinesterase.
2. Calcium Reuptake
Calcium pumped back into SR.
3. Troponin Loses Calcium
Calcium dissociates.
4. Tropomyosin Covers Active Sites
Cross-bridge formation stops.
5. Muscle Returns to Resting Length
Muscle relaxes.
Excitation-Contraction Coupling
Definition
Process linking electrical excitation with mechanical contraction.
Sequence
Nerve Impulse
↓
Acetylcholine Release
↓
Action Potential
↓
Calcium Release
↓
Cross-Bridge Formation
↓
Muscle Contraction
Role Of Calcium
Calcium is the key regulator of contraction. Without calcium, contraction
cannot occur.
Functions:
- Binds Troponin-C
- Removes Tropomyosin blockade
- Initiates cross-bridge formation
- Maintains contraction
Energy Sources for Muscle Contraction
Immediate Source
ATP- Stored ATP lasts only 2–3 seconds.
Creatine Phosphate
Creatine-P + ADP
↓
Creatine + ATP
Provides energy for 10–15 seconds.
Anaerobic Glycolysis
Produces ATP quickly.
End product: Lactic acid
Aerobic Respiration
Major ATP source during prolonged exercise.
Definition
Temporary inability of muscle to contract effectively.
Causes
- ATP depletion
- Lactic acid accumulation
- Ionic imbalance
- Reduced calcium availability
Important Points
Most abundant protein in muscle: Myosin
Functional unit of contraction: Sarcomere
Calcium binds: Troponin-C
ATPase activity present in: Myosin head
Energy currency: ATP
H-zone during contraction: Decreases
I-band during contraction: Decreases
A-band during contraction: Remains unchanged
Theory explaining contraction: Sliding Filament Theory
Rigor mortis due to: ATP deficiency
Highlights
- Contraction occurs due to sliding
of actin over myosin.
- Cross-bridges are formed by
myosin heads.
- Calcium binds troponin.
- Tropomyosin masks active sites
during relaxation.
- ATP is required for muscle
contraction and relaxation.
- A-band remains unchanged during
contraction.
Flowchart For Quick Revision
Motor Neuron Stimulated
↓
Acetylcholine Released
↓
Action Potential
↓
T-Tubule Activation
↓
Ca²⁺ Released from SR
↓
Ca²⁺ + Troponin-C
↓
Tropomyosin Shifts
↓
Active Sites Exposed
↓
Actin-Myosin Cross Bridge
↓
Power Stroke
↓
Sarcomere Shortens
↓
Muscle Contraction
↓
Ca²⁺ Reuptake into SR
↓
Relaxation
High-Yield One-Liners
- Sarcomere is the contractile unit
of muscle.
- Actin forms thin filaments;
myosin forms thick filaments.
- Calcium binds Troponin-C.
- Myosin head possesses ATPase
activity.
- Cross-bridge formation is
essential for contraction.
- ATP is required for both
contraction and relaxation.
- A-band remains constant during
contraction.
- I-band and H-zone shorten during
contraction.
- Sliding filament theory was
proposed in 1954.
- Rigor mortis occurs due to lack
of ATP.
- Calcium is stored in the
sarcoplasmic reticulum.
- Excitation-contraction coupling
links electrical and mechanical events.