Muscle Organization and Function PDF

Summary

This document provides an overview of muscle organization and function, covering properties, anatomical organization, and different muscle types. It also discusses the sliding filament theory and the role of calcium in muscle contraction.

Full Transcript

Muscle Organization and Function
Overview
Muscles are essential for movement, stability, and heat production. Understanding their
organization and function is crucial for grasping how they work in the body.

Learning Objectives
1. Properties and Functions of Muscles
o Role in movement, stability, and heat production.
o Concept of muscle contraction.
2. Anatomical Organization
o Structure of skeletal, cardiac, and smooth muscle.
o Key components of a muscle fiber:
§ Sarcolemma
§ Sarcoplasm
§ Sarcoplasmic reticulum
o Sliding filament theory of muscle contraction.
o Structure and function of the sarcomere:
§ A band
§ I band
§ H zone
§ Z line
§ M line
o Role of calcium in muscle contraction.
3. Muscle Types
o Differences in structure, function, and location:
§ Skeletal muscle
§ Cardiac muscle (features: intercalated discs, autorhythmicity)
§ Smooth muscle (various types and functions).

Muscle Overview
Striated Unstriated

Skeletal Cardiac Smooth

Voluntary Involuntary
Skeletal Muscle Tissue

Properties:
o Contractility: Ability to shorten.
o Excitability: Capacity to respond to stimuli.
o Extensibility: Ability to stretch.
o Elasticity: Ability to return to original shape.
Functions:
o Production of movement.
o Maintaining posture.
o Stabilizing joints.
o Generating heat.

Skeletal Muscle Anatomy

Components:
o Epimysium: Connective tissue
surrounding the entire muscle.
o Fascicles: Muscle bundles.
o Perimysium: Connective tissue
surrounding fascicles.
o Muscle Fibre: Myofibril
bundles
o Endomysium: Connective
tissue surrounding individual
fibers.
o Myofibril bundles: Composed
of sarcomeres

Skeletal Muscle: Myofiber → Myofibril → Sarcomere → Myofilament.
Myofibril Proteins:
o Contractile: Generate force (e.g., Actin, Myosin).
o Regulatory: Initiate/terminate contraction (e.g., Troponin, Tropomyosin).
o Structural: Maintain alignment (e.g., Titin, Myomesin, Dystrophin).

Muscle Fiber Types

1. Slow Oxidative (Type I)
o Diameter: ↓
o Capillaries, Mitochondria, Myoglobin: ↑
o Glycogen & creatine kinase: ↓
o Color: Red
o ATP Generation: Aerobic
o Fatigue Resistance: ↑
 o Function: Postural, endurance.
2. Fast Oxidative-Glycolytic (Type II-A)
o Diameter: ↔
o Capillaries, Mitochondria, Myoglobin: ↑
o Glycogen & creatine kinase: ↔
o Color: Red-pink
o ATP Generation: Aerobic & glycolysis
o Fatigue Resistance: ↔
o Function: Sprinting, walking.
3. Fast Glycolytic (Type II-B)
o Diameter: ↑
o Capillaries, Mitochondria, Myoglobin: ↓
o Glycogen & creatine kinase: ↑
o Color: White
o ATP Generation: Glycolysis
o Fatigue Resistance: ↓
o Function: Short-term.

Fiber Types: I (Slow), II-A (Fast oxidative glycolytic), II-B (Fast glycolytic).

Sarcomere Structure

Functional Unit: Region between Z lines.
Components:
1. A band: Thick & thin myofilaments overlap.
§ H Zone: Only thick filaments.
§ M Line: Contains Myomesin (stabilizes thick filaments).
2. I band: Composed of thin filaments.
3. H zone: myosin only, no overlap
4. Z line: Anchors thin actin filaments.
§ Composed of actinin and nebulin
5. M line: Centre of sarcomere:
§ Composed of myomensin
6. Sarcoplasmic Reticulum: Contains terminal cisternae and T-tubules
§ Traid: two terminal cisternae and T-tubule

Sarcomere Structure
Myofilaments

Thick Filaments
o Composed mainly of the protein myosin.
o Myosin heads interact with actin during muscle contraction.
Thin Filaments
 o Composed primarily of actin, along with troponin and tropomyosin.
o Actin provides the site for myosin binding.

Muscle Contraction
Process Overview:
1. Arrival of a nerve impulse.
2. Release of calcium ions.
3. Interaction between actin and myosin.
4. Muscle shortening and contraction.

1. Resting State (No Contraction)

Troponin and Tropomyosin Block Actin Binding Sites:
o Tropomyosin covers the myosin-binding sites on actin filaments
Low Calcium Levels
o Cytosolic calcium concentration is low

2. Nerve Impulse & Calcium Release

Action Potential
o A nerve impulse (action potential) travels down a motor neuron to the
neuromuscular junction.
Acetylcholine Release:
o Acetylcholine is released into the synaptic cleft, binding to receptors on the
muscle fiber membrane (sarcolemma).
Depolarization:
o Depolarization of the muscle membrane, triggering an action potential in the
muscle fiber.
Calcium Release:
o Action potential spreads through the T-tubules à sarcoplasmic reticulum releases
calcium ions (Ca²⁺) into the cytoplasm of the muscle cell.

3. Calcium Binding to Troponin

Calcium Binds to Troponin:
Conformational Change in Troponin:
o Conformational change of troponin once Ca2+ binds.
o Tropomyosin moves away from the myosin-binding sites so that myosin heads
can bind.

4. Cross-Bridge Formation (Actin-Myosin Binding)

Myosin Head Binds to Actin:
 o Myosin head (bound ADP + Pi in the “cocked” position) connects to actin binding
sites, forming a cross-bridge.

5. Power Stroke

Release of ADP and Pi:
o Once the myosin head binds to actin, ADP and Pi are released from the myosin
head.
o Causes myosin head to pivot and pulls the actin filament towards the M line
(centre) à power stroke
§ Sarcomere shortens = muscle contraction

6. Detachment of Myosin from Actin

Binding of New ATP:
o ATP molecule binds to the myosin head, causing it to detach from the actin
filament.
§ No ATP = muscle cramps

7. Re-cocking of the Myosin Head

ATP Hydrolysis:
o ATP is then hydrolyzed into ADP and Pi by myosin ATPase activity,
o Results in “cocked position” of myosin head

8. Cycle Repeats (If Calcium is Present)

As long as calcium remains bound to troponin and ATP is available, the cycle of actin-
myosin binding, power stroke, and detachment will repeat = resulting in muscle
contraction.

9. Muscle Relaxation

Calcium Pumped Back into Sarcoplasmic Reticulum:
o Ca2+ is actively pumped back into the sarcoplasmic reticulum by calcium pumps
(using ATP)
o Calsequesterin binds Ca2+ in the SR.
Troponin and Tropomyosin Return to Resting Position:
o As Ca2+ is pumped back, calcium dissociates from troponin,
§ causing tropomyosin to move back over the actin binding sites, preventing
further myosin binding.
Relaxation: The muscle fiber returns to its relaxed state.

Muscle Physiology
Sarcotubular System
The sarcotubular system includes the sarcoplasmic reticulum and T-tubules.
Primary Function:
o Regulates calcium ion concentration, which is crucial for muscle contraction.

Comparison of Muscle Types
Skeletal Muscle

Structure: Striated, multi-nucleated, long fibers.
Function: Voluntary control, responsible for body movement.

Cardiac Muscle

Structure: Striated, branched, single nucleus, mitochondria, and lipid rich, intercalated
discs (gap junctions).
Function: Involuntary control, pumps blood throughout the body.
Unique Properties:
o Automaticity: Can generate its own electrical impulses.
o Rhythmic contractions.
o Functional syncytium – rapid synchronous contractions
o Slow calcium channels – extracellular Ca2+ brought in
§ Rapid contraction & slow heartbeats

Smooth Muscle

Structure: Non-striated, spindle-shaped (fusiform), single nucleus.
Function: Involuntary control, regulates internal organs, found in hollow organs
Unique Properties:
o Can sustain slow contractions for longer periods.
o Responds to various stimuli (hormonal, neural).
o No alignment/striations
o No T-tubules à poor SR development
§ Voltage gated Ca2+ channels (caveolae)
o Z-lines are referred to as dense bodies

Smooth Muscle Types
1. Single Unit Smooth Muscle
o Cells are connected by gap junctions.
o Contracts as a single unit (e.g., walls of hollow organs)
o Often hormone mediated
 o Autorhythmicity – rapid transmission of stimuli via gap junctins (similar to
cardiac)
2. Multi-Unit Smooth Muscle
o Cells are not connected by gap junctions.
o Contracts independently (e.g., eye muscles, large airways).
o More individual control

Muscle Physiology Overview
Structural Differences
1. Nuclei
o Skeletal: Multinucleated
o Cardiac: Uni/bi-nucleated
o Smooth: Uninucleated
2. Striations
o Skeletal: Yes
o Cardiac: Yes
o Smooth: No
3. T-tubules
o Skeletal: Yes
o Cardiac: Yes
o Smooth: No (caveolae instead)
4. Gap Junctions
o Skeletal: No
o Cardiac: Yes (intercalated discs)
o Smooth: Yes (only in single-unit)

Calcium Sources for Contraction
Skeletal Muscle: SR
Cardiac Muscle: SR and extracellular fluid
Smooth Muscle: Mostly extracellular fluid

Contraction Characteristics
Skeletal Muscle: Rapid onset, can tetanize
Cardiac Muscle: Slow onset, cannot tetanize
Smooth Muscle: Slow onset, may tetanize

Muscle Contraction
Key Definitions
Motor Unit: The smallest functional unit of muscle contraction, consisting of a single
motor neuron and all the muscle fibers it innervates.
Muscle Force Gradation: Nervous system control of muscle by:
o Recruitment: Increasing the number of active motor units for greater force.
o Frequency: Increasing the frequency of nerve impulses for greater force.
All-or-None Principle: All fibers in a motor unit contract simultaneously when
stimulated.

Types of Muscle Fibers
All fibres in a motor unit are the same fibre type

1. Slow Motor Units:
o Myosin uses ATP slowly.
o Many mitochondria for ATP production.
o Economical maintenance for isometric contractions and efficient about repetitive
slow isotonic contractions.
2. Fast Motor Units:
o Myosin uses ATP quickly.
o Higher power output.
o Type 2A fibers: Sustained power.
o Type 2B fibers: Fast, non-oxidative, and fatigue rapidly.

Isometric: Muscle length sustained
Isotonic: Muscle length changes

Sequence of Muscle Contraction
1. Neuromuscular Junction:
o Transmitter synthesized and stored in vesicles.
o Action potential reaches synaptic terminal.
o Depolarization opens voltage-gated Ca²⁺ channels.
o Influx of Ca²⁺ causes vesicles to fuse with the synaptic membrane.
o Transmitter (acetylcholine) is released into the synaptic cleft.
o Binds to receptors on the postsynaptic membrane, causing excitatory/inhibitory
potentials.
o Ach is broken down by acetylcholinesterase to end signal à relaxation

Acetylcholine

Curare:
 o Frogs
o Blocks nicotinic receptors, preventing muscle contractions.
Clostridium botulinum:
o Bacteria
o Produces a toxin that prevents acetylcholine release, leading to paralysis.

2. Excitation-Contraction Coupling: series of events that link an action potential to
muscle contraction
o Nerve impulse arrives à spreads to sarcolemma and T-tubules
o T-tubules depolarize activating voltage sensitive receptors (DHP receptors)
o Ca+ channels open SR
o Calcium ions play a crucial role in muscle contraction.
o They bind to troponin, causing tropomyosin to move and expose binding sites on
actin for myosin.
o Myosin heads carrying ADP and Pi bind to form cross bridges
o Release of Pi causes contraction
o Binding of ATP repositions head
3. Sliding Filament Theory:
o Myosin heads attach to actin, pulling the filaments past each other, generating
force.

Types of Muscle Contractions
1. Isometric: Muscle length remains the same while tension increases to peak.
2. Isotonic:
o Concentric: Muscle shortens while generating force, involved in resistance
o Eccentric: Muscle lengthens while generating force, control over rate of
elongation

Force of contraction increases after the latent phase (post stimulus), peaks at the end of
the contraction phase and beginning of relaxation phase
Treppe: gradual increase in contraction force and full relaxation between stimuli
o “stair like”
o Gradual Ca2+ increase as SR is unable to sequester all the Ca2+ between twitches
Summation: combination of multiple stimuli causing an increase in contraction strength
of stimuli overlap/converge
o 2nd stimulus occurs before full relaxation of the 1st
o Causes increasing tension overtime
o Multiple motor unit summation/recruitment: when more force is needed, more
and larger units are recruited
Incomplete tetanus: sustained contraction but some relaxation between stimuli occurs as
maximum tension is reached
Complete tetanus: sustained contraction at maximum tension with no relaxation between
stimuli
Muscle Fatigue
Physiological basis includes depletion of energy sources, accumulation of lactic acid, and
failure of neuromuscular transmission.

Force/Load/Length Relationship
Length-tension relationship: maximal tension is reached when there is the most
actin/myosin overlap
Force-Load relationship: increasing load deceases velocity of shortening

“Plastic” Nature of Muscles
Muscle can adapt to habitual demand
Regular exercise can enhance muscle strength and endurance.
Aging may result in muscle atrophy and decreased strength.
Endurance training:
o Cardiovascular, mitochondrial density, fuel storage
Strength training:
o muscle hypertrophy, neural changes, muscle fibre changes

Muscle Energy Metabolism
Creatine phosphate:
o Form of excess energy storage in muscles
o Concentration is 2-6x more than ATP
o Creatine kinase is the enzyme involved in rapid synthesis
o Longer/sustained energy source
Glycolis
o 2 ATP per glucose
o Type 2B fibres (fastest and anerobic)
o Glycogen utilized
o Short term energy source
Oxidative Phosphorylation:
o Most ATP produced (~36)
o Type 1 fibers
o Lipids involved in prolonged endurance training

Myogenesis and Nutrition
Embryonic Phase of Myogenesis
Key Events:
 Formation of myoblasts from mesodermal cells.
o
Myoblasts fuse to form myotubes.
o
Initial muscle fiber differentiation occurs.
o
Nutrition Impact:
o Adequate protein and energy are crucial for myoblast proliferation.
o Deficiencies can lead to impaired muscle development.

Phases of Myogenesis

Conception to Birth

o Mesoderm: The layer of cells that forms muscle develops into myotomal cells
and stem cells.
§ Myotomal Cells: Cells that develop into early muscle.
Primary Myotome: Early muscle formation.
§ Progenitor (Stem) Cells: Cells that can develop into various muscle
types.
Embryonic Myoblasts: Early muscle cells.
o Primary myotubules: early muscle fibres
§ Primary fibres: contain sarcomeres and other
structures (i.e., SR & T-tubules develop)
Type 1 fibers: (& type 2 in fast muscles)
Fetal Myoblasts: Later stage muscle cells.
o Secondary myotubules:
§ Secondary fibres: during later stages of
development
Type 2 fibres: (Type 1 and 2 in mixed
muscles)
Satellite cell: regenerate muscle and also play a role in secondary
myotubule formation

Mesoderm

Myotomal cell Progenitor/stem cell

Primary myotome Embryonic myoblast Foetal myoblast Satellite cell
(early muscle)

Primary myotubules Secondary myotubules

Primary fibres Secondary fibres

Type 1 fibres Type 2 fibres
 Myogenesis
o Primary Myogenesis: Formation of primary muscle fibers (type 1), a bit of type
2.
o Secondary Myogenesis: Formation of mainly secondary muscle fibers.
o Muscle Fiber Types:
§ Type I Fibers: Slow-twitch fibers.
§ Type II Fibers: Fast-twitch fibers.
o Total number of fibres fixed by ~6 months gestation
§ Muscle hypertrophy occurs after this mark

Fetal Phase of Myogenesis
Key Events:
o Continued growth and maturation of muscle fibers.
o Development of satellite cells, which aid in muscle repair and growth.
o Muscle fibers increase in size and number.
Nutrition Impact:
o Nutritional support influences muscle mass and fiber type distribution.
o Essential amino acids and minerals are vital for optimal growth.
o Decreased nutrient intake:
§ during (halfway through) primary and secondary myogenesis = decreases
myogenesis (# of fibres)
§ harder to recover from
§ during hypertrophy = decreased hypertrophy and birth weight
§ theoretically possible to recover from postnatally

Skeletal Muscle Growth
Hypertrophy: number of sarcomeres increase
o Sarcomeres in parallel
o ↑ # of sarcomeres = stronger the muscle
Hyperplasia: parallel alignment of muscle fibres (early in development)
o New myocytes
o ↑ force produced
o Can occur as an adult à tears/lacerations repaired via satellite cells
Lengthening (growth): addition of sarcomeres to both sides of the length
o ↑ velocity
o ↑shortening capacity

Summary of Myogenesis

Embryonic Stage:
o Paraxial mesodermal cells form myotome and progenitor cells (that further
differentiate)
Fetal Stage:
 o Primary and secondary myogenesis à leading to muscle fiber formation (primary
and secondary).
Postnatal Stage:
o Muscle fibers undergo hypertrophy primarily through satellite cell activity.
Nutrition:
o Critical during prenatal development for fiber number and mass
o Affects mass postnatally.

Muscle Disorders
Types of Muscle Disorders

Muscle Cramps/Spasms
o Involuntary contractions, often painful.
o Cramps last longer (up to 15 minutes) à “Charley horse”.
o Causes include:
§ Injury
§ Overuse
§ Central Nervous System issues
Muscle Strain
o Tearing of muscle fibers, often at the musculotendinous junction.
o Caused by overexertion or excessive stretching.
o Common in large muscles (e.g., hamstrings, quadriceps)
§ Less common in postural muscles (slow twitch muscle, less force)
Muscle Hypertrophy
o Increase in muscle size due to increased sarcomeres.
o Case: Double Muscling
§ Myostatin: plays an important role in growth regulation àinhibit muscle
cell hypertrophy & hyperplasia
expression limited to skeletal muscle
§ Mutation in myostatin = ↑ muscle mass
§ Causes problems in calving with affected calves
Muscle Atrophy
o Decrease in muscle size due to disuse or malnutrition.
o Neurogenic:
§ Denervation: lysosomal protein degeneration = 50%↓ muscle mass +
EMG abnormalities
Common: pinched nerve à can be easily resolved (even if slow)
§ Myogenic: malnutrition, cachexia (secondary to other conditions),
corticosteroid excess
Slow progression, normal EMG,
Only type 2 fibres
Muscle Necrosis & Regeneration
o Death of muscle fibers followed by regeneration.
Muscle Necrosis/Rhabdomyolysis
 o May affect whole fiber or subgroup of sarcomeres within a fibre
o Symptoms:
§ Muscle pain. Contracture, increased RR, sweating
§ ↑ Creatine Kinase & Aspartate transaminase in serum
§ Myoglobinuria (oxygen storage within the muscle) is released into the
bloodstream when muscle breaks down and is then filtered by kidneys into
urine
o Causes:
§ Nutrition: Vitamin E and Selenium deficiency
“white muscle disease” à degeneration of cardiac and skeletal
muscles
Hypokalemia (low K+) toxins
§ Infectious
§ Immune related
§ Metabolic
Muscular Dystrophy
o Progressive degeneration of skeletal muscles (small mammals) & Inherited
o In dogs:
§ Puppies: stunted growth, elbow abduction, bunny hop gait,
§ Adult: plantigrade stance
o Due to deficiency of dystrophin (protein, anchors sarcolemma to actin of
cytoskeleton) à fibre damage
Altered Electrical conduction:
o Altered motor neuron firing:
§ Hypocalcemia (cows): ↓ Ach release = ↓ neuronal firing = paresis
o Altered motor end plate depolarization
§ Myasthenia gravis (dogs):
Congenital – deficiency in the number of Ach receptors
Acquired – Autoantibodies to Ach receptors
§ Botulism: clostridium botulism toxin à ↓Ach release = ↓ neuronal firing
= paresis
o Altered sarcolemma excitability:
§ Myotonia (dogs, horses, goats): muscle hypertrophy, stiffness, rigidity,
prolonged muscle contraction
Goats: autosomal dominant mutation in Cl- channel = ↓ Cl-
conductance = ↑ K+ in T-tubules = ↑ contraction

Muscle Disorders 2.0 (simplified)
4. Double Muscling
 Defect: Myostatin gene mutation.
Consequence: Increased muscle mass due to reduced inhibition of muscle growth.

5. Muscular Atrophy

Defect: Loss of muscle fibers or decrease in size.
Consequence: Weakness and reduced mobility due to inactivity or malnutrition.

6. Muscular Dystrophy & Malignant Hyperthermia

Defect: Genetic mutations affecting muscle proteins.
Consequence: Progressive muscle weakness and potential life-threatening reactions to
anesthesia.

7. Botulism

Defect: Toxin from Clostridium botulinum.
Consequence: Muscle paralysis due to disrupted neurotransmission.

8. Hypocalcaemia & Myotonia

Defect: Low calcium levels affecting muscle function.
Consequence: Muscle stiffness and spasms due to impaired excitability.

Muscle Disorders Study Notes
Muscle Hypertrophy
Definition: Increase in muscle size.
Double Muscling:
o Caused by mutations in myostatin, a protein that inhibits muscle growth.
o Common in breeds like Belgian Blue and Piedmontese cattle.
o Results in increased muscle mass and calving difficulties due to higher calf birth
weight.

Muscle Atrophy
Definition: Decrease in muscle size.
Types:
1. Neurogenic:
§ Caused by nerve damage (e.g., "Sweeney" in horses).
§ Results in significant muscle mass loss and EMG abnormalities.
2. Myogenic:
§ Caused by malnutrition, cachexia, or corticosteroid excess.
 § Slow progression with normal EMG; affects mainly type 2 muscle fibers.

Muscle Necrosis or Rhabdomyolysis
Common Names: Tying up, Monday morning sickness, Azoturia.
Symptoms:
o Muscle pain, contracture, increased respiratory rate, sweating.
o Elevated creatine kinase and aspartate transaminase in serum; myoglobinuria.
Causes:
o Nutritional deficiencies (e.g., Vitamin E, Selenium).
o Infectious agents (e.g., Clostridial, Viral).
o Immune-mediated conditions (e.g., Masticatory muscle myositis in dogs).
o Metabolic disorders (e.g., Glycogenoses).

Muscular Dystrophy
Definition: Inherited progressive degeneration of skeletal muscle.
Example: Duchenne’s muscular dystrophy in humans and similar conditions in dogs
(e.g., German Shorthaired Pointers, Golden Retrievers).
Symptoms:
o Stunted growth, abnormal gait, plantigrade stance in adults.
Cause: Deficiency of dystrophin, leading to muscle fiber damage.

Altered Electrical Conduction
Conditions:
1. Hypocalcemia (Milk Fever):
§ Decreased acetylcholine (Ach) release leads to paresis.
2. Myasthenia Gravis:
§ Congenital or acquired deficiency of Ach receptors.
3. Botulism:
§ Caused by Clostridium botulinum toxin, leading to decreased Ach release.
4. Myotonia:
§ Prolonged muscle contraction and stiffness due to altered ion channel
function.