Muscle Physiology PDF

Summary

This document provides information on muscle physiology, covering topics such as excitation-contraction coupling, molecular interactions, and calcium release. It details the processes involved in muscle contraction.

Full Transcript

Learning Objectives
By the end of this section, you should be able to:
– Understand the process of excitation-contraction coupling
– Describe the molecular interactions between the thick and thin
filaments during cross-bridge cycling
 Excitation-contraction coupling

Calcium initiates cross-bridge cycling after entering the cytoplasm.
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How? = Excitation-contraction coupling

Action potential along the plasma membrane of a myofibre => many steps => triggers cross-bridge cycling
Key pathway: Transverse tubule or T-tubule => directly links the plasma membrane and the lateral sacs.
They run perpendicularly from the surface of the muscle cell membrane into the central portion of the
muscle fibre.

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 Release of calcium from the sarcoplasmic reticulum
Remember that the cytosolic calcium concentration is very low in a resting (relaxed) muscle!
Action potential => Rapid increase in cytosolic calcium concentration. The source of increased calcium
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is the sarcoplasmic reticulum.

Very similar to the endoplasmic reticulum => Forms sleeve-like segments around each myofibril.
At the end of these segments = Lateral sacs => connected to each other via smaller tubular elements.

A single t-tubule and 2 lateral sacs on either side forms the triad – key for excitation-contraction coupling

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= voltage gated sensors

Triad

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 The transverse tubules bring action potentials into the interior of the skeletal muscle fibres so that the
wave of depolarization passes close to the sarcoplasmic reticulum

T-tubule membrane contains voltage-sensitive Dihydropyridine receptors (DHPR) – activate in
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response to action potential travelling down t-tubule.

DHPR are coupled to sarcoplasmic reticulum proteins, the ryanodine receptor (Ca2+ release channels) –
activation leads to the release of calcium into the muscle cell

The extensive meshwork of sarcoplasmic reticulum assures calcium can readily diffuse to all of the troponin
sites.

Activation
1. Action potential => T-tubule from the sarcoplasmic reticulum => Opening calcium channels.
2. Increase in cytosolic calcium concentration.
3. Calcium will bind to the subunit C (calcium) => Induces a change in the shape of the troponin.
4. Release of the inhibitory grip on tropomyosin.
5. Movement of tropomyosin making available myosin-binding sites.
6. Remove calcium from troponin => Reverses the process => Disconnects the cross bridge, relax
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 Passage of an action potential along
the transverse tubule opens nearby
voltage-gated calcium channels, the
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“ryanodine receptor,” located on the
sarcoplasmic reticulum, and calcium
ions released into the cytosol bind to
troponin.

The calcium-troponin complex “pulls”
tropomyosin off the myosin-binding site of
actin, thus allowing the binding of the
cross-bridge, followed by its flexing to
slide the actin filament.

Calcium re-uptake into SR occurs through
SERCA (SarcoEndoplasmic Reticulum
Calcium ATPase)

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 ATP-Powered cross-bridging cycling How does this start?
Resting myofibre = low calcium concentration.
No interaction between actin and myosin.
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Heads of myosin filament (M) are in an energized state
resulting from ATP hydrolysis. The hydrolysis products (ADP
and Pi) are both bound to the cross-bridge.
M + ATP => M-ADP-Pi

Calcium release => The myosin-binding site on actin
becomes available, so the energized myosin heads
bind and form a cross-bridge.
M + ATP => M-ADP-Pi => Able to interact with Actin (if tropomyosin removed)

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MODULE 4 – MUSCLE PHYSIOLOGY M + ATP => M-ADP-Pi

Binding A-M.ADP.Pi

Power stroke =
Movement of the cross-bridge
Release of ADP+Pi

The full hydrolysis and departure of
ADP + Pi causes the flexing of the
bound cross-bridge.

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 Hydrolysis of the bound ATP
energizes or “re-cocks” the bridge.
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Binding of a “new” ATP to the cross-
bridge uncouples the bridge.

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 ATP plays an important role for skeletal muscle contraction
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Rigor mortis

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Learning Objectives
By the end of this section, you should be able to:
– Describe the structure and function of a motor unit and their
classification
– Understand the generation and control of skeletal muscle force
– Explain the interactions between muscle structure and load on
contraction output
 Skeletal muscle contractile activity

An action potential lasts 1-2 msec in a myofiber
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and no mechanical activity is observable before it
ends.

Mechanical activity: About 100 ms.

The latent period between excitation and
development of tension in a skeletal muscle
includes the time needed to release Ca2+ from
sarcoplasmic reticulum, move tropomyosin, and
cycle the cross-bridges...

Notions of contraction time, relaxation time, muscle
twitch.

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 Skeletal muscle mechanics: Contraction of the whole muscle

A single action potential in a muscle fibre => brief and weak contraction = Twitch.
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A twitch is too weak and too short to have a real effect at the level of the entire muscle and the body.
=> Muscle fibres cooperate to produce muscle contractions for variable strength...that’s why you can vary
the force developed by your muscles.

How?
1) By changing the number of fibres contracting (recruited) within the muscle.
2) By affecting the tension developed by each contracting fibre (i.e., activation rate).

Motor unit = one motorneuron + all the myofibres it innervates (different size depending on muscle types).

Upon reaching a muscle, the axon makes several divisions/branches, and each branch will form one
connection with one fibre = Neuromuscular junction.

Motor unit recruitment – all muscle fibres within a motor unit are activated when a motor unit is recruited

=> The greater the number of motor units recruited to contract, the greater the total muscle tension!
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 Different muscles can have different numbers and sizes of motor units to vary the power and
dexterity of movement
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Fingers: less fibres per motor unit = greater
control of fine movements

Back muscles: more fibres per motor unit = less
control of fine movements

Notion of asynchronous recruitment of motor units
and fatigue prevention.
Muscles are often composed of different fibre
types
=> More (Type I) or less (Type II) resistant
to fatigue.

Weak or moderate exercise
=> Recruitment of motor units more
resistant to fatigue first (Type I).
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 How do we determine which motor units to recruit?

Henneman’s size principle – describes the relationship between the
size of a motor unit and its sequence of recruitment (i.e., when it first
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begins to discharge action potentials)

In other words, motor units are recruited according to the magnitude of
their force output, from smallest to largest

Benefits of orderly recruitment of motor units:

Minimizes fatigue by first activating fatigue-resistant (i.e., type I) muscle fibres.
- larger, more powerful units are recruited when more force is needed

Allows the finer control of muscle forces
- weaker units allows smaller gradation of force during low-level contractions

Simplifies the control of force
- central nervous system is not burden by determining which motor units to activate (occurs automatically
according to size of motor neuron)

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 Frequency of activation
Whole muscle tension => Number of fibres contracting (i.e., motor unit recruitment) and tension
developed by each contracting fibre (i.e., frequency of motor unit activation).
Other factors influence the extent to which tension can be developed:
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- Frequency of stimulation
- Length of the fibre at the onset of contraction
- Extent of fatigue
- Thickness of the fibre (number of myofibrils/sarcomeres)

One action potential => twitch

What happens with the repetition
of the stimulation?

Similar in principle to the
temporal summation of
EPSP at the postsynaptic
neuron (but building
tension in this case)
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 Twitch summation is possible because the duration of the action potential (1-2 msec) is shorter than
the twitch duration (100 msec).

Recall the refractory period: the fibre can be excited only once the absolute refractory period of the
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action potential is complete.

The fibre can be re-stimulated while still in contraction.
If repeated stimulations occur without allowing time for relaxation => Tetanus.

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 Take home points!
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Central nervous system can control muscle force through two key mechanisms

1) Motor unit recruitment (through Henneman’s size principle)

2) Motor unit activation rate (fusion of muscle twitches)

BUT!

What about the characteristics of the muscle?
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 Importance of initial muscle length on force development

At optimal muscle length, maximum tension can
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be developed
=> Thin filaments optimally overlap regions of
thick filament

At greater than optimal length, tension production
decreases linearly
=> Thin filaments are pulled out from between the
thick filaments
=> Causes a decrease in available sites for
crossbridge formation

At less than optimal length, tension production
decreases
=> Thin filaments overlap, limiting the number of
active sites available for crossbridge formation

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 Isotonic and Isometric contractions

Different types of muscle contractions…
The force exerted by a muscle contraction on an object is known as muscle tension.
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The force exerted on a muscle by an object is known as muscle load.
Muscle length changes will depend on the balance between tension and load.
If tension > load = Shortening. If tension < load = lengthening

When a muscle contracts without any shortening => Isometric contraction (= constant length).

Contraction that involves constant load/tension = Isotonic contraction. This can be either an increase in
muscle length (lengthening or eccentric contraction) or a decrease in muscle length (shortening or
concentric contraction).
iso = same tonic = tension metric = length

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 Consequence of the muscle load on muscle shortening

Isometric contraction
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Ideal combination of force and velocity which
produces maximal power (force x velocity) output

Unloaded shortening velocity (Vmax)

The greater the load, the lower the velocity of shortening
Curve-linear relationship, known commonly as the force-velocity relationship
Maximal force can be produced when velocity is zero (i.e., an isometric contraction)
Maximal power is produced when optimal load and velocity relationship is determined

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 Skeletal muscle fibre types

Three fibre types in human skeletal muscle
Type I
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Type IIA
Type IIX

Different structural, functional, and metabolic characteristics across fibre types
 Skeletal muscle fibre types
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