Chapter 9 Part 2: The Physiology of Muscle Contraction PDF

Summary

This document is a chapter on the physiology of muscle contraction, including how muscles work and the events at the neuromuscular junction. It covers topics such as action potentials, excitation-contraction coupling and the cross-bridge cycle.

Full Transcript

Chapter 9 Part 2
The Physiology of Muscle
Contraction

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Muscle Fiber Contraction – Background and Overview

You decide to pick up a book.
The decision-making activates
the upper motor neurons in the
brain to plan, initiate, and
coordinate this movement.
These neurons then synapse
with the spinal cord, and an
efferent signal is transmitted to
motor neurons that activate
skeletal muscle fibers at the
neuromuscular junction.

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 Excitable cells such as neurons and muscle cells can change their
resting membrane potentials in response to stimuli.
Electrical signals generated due to large changes in RMP are
called action potentials (APs). APs spread across the muscle cell.
In order to travel from cell to cell, these electrical signals are
converted to chemical signals.
Neurons use the neurotransmitter acetylcholine (ACh), to activate
muscle cells to contract.
Neurotransmitters open up specific ion channels on the muscle cells

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Ion Channels play a major role in changing
of membrane potentials. Two classes of ion
channels are:

Chemically gated ion channels –
opened by chemical messengers such
as neurotransmitters (ACh binding to
ACh receptors on muscle cells). Create
local changes in membrane potential
(small depolarization).

Voltage-gated ion channels – open or
close in response to local changes in
membrane potential created by the
chemically gated channels. APs are
created by these channels.

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 Anatomy of Motor Neurons and the Neuromuscular Junction (NMJ)
– Skeletal muscles are stimulated by somatic motor neurons
– A part of the peripheral nervous system, the somatic nervous system
consists of nerves that go to the skin and muscles, and is involved in
conscious activities.

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 Anatomy of Motor Neurons and the Neuromuscular Junction (NMJ)
– Axons (long, threadlike extensions of motor neurons) travel from
central nervous system to skeletal muscle
– Each axon divides into many branches as it enters muscle
– Axon branches end on muscle fiber, forming the NMJ
§ Each muscle fiber has one NMJ with one motor neuron
– NMJ is a synapse [a synapse is a junction between 2 nerve
cells or a nerve and muscle fiber, with a tiny gap across
which impulses pass].

Axon

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 Overview of Skeletal Muscle Contraction

Axon of
a motor
neuron

NMJ

Muscle
fiber

NMJ is the region where motor neuron contacts the skeletal muscle. Consists of
multiple axon terminals and underlying junctional folds of the sarcolemma

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The Neuromuscular Junction
Axon terminal (end of
axon) and muscle fiber are
separated by gel-filled
space called synaptic cleft

Stored within axon
terminals are membrane-
bound synaptic vesicles
containing neurotransmitter
acetylcholine (ACh)

Motor end plate The motor end plate is
The specialized postsynaptic region of a formed by infoldings of
muscle cell is called a motor end plate. The sarcolemma, called
motor endplate is immediately across the junctional folds. They
synaptic cleft from the presynaptic axon terminal. contain millions of ACh
receptors
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The Big Picture - Four steps must occur for skeletal muscle to contract:

1. Events at neuromuscular junction

2. Muscle fiber excitation

3. Excitation-contraction coupling

4. Cross bridge cycling

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Events at the Neuromuscular Junction

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 When a Nerve Impulse Reaches an NMJ, Acetylcholine (ACh) is
Released

1. Motor neuron fires an AP
down its axon
2. Voltage-gated Ca2+
channels open
3. Ca2+ enters the axon
terminal down its
electrochemical gradient.
4. Ca2+ entry causes ACh to
be released into the
synaptic cleft by
exocytosis

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 ACh diffuses across the
synaptic cleft and binds to
receptors on the sarcolemma

ACh binding opens ions
channels in the receptors
that allow simultaneous
passage of Na+ into the
muscle fiber and K+ out of
the muscle fiber.

More Na+ enters than K+ exit,
producing a local change in
the membrane potential (end
plate potential)

ACh effects are terminated
by its breakdown in the
synaptic cleft by
acetylcholinesterase
(enzyme) and diffusion away
from junction.

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A&P Flix: Events at the Neuromuscular
Junction

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Events at the Neuromuscular Junction

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Summary of events at the neuromuscular junction
1. AP arrives at axon terminal
2. Voltage-gated calcium channels open, calcium enters motor neuron
3. Calcium entry causes release of ACh neurotransmitter into synpatic
cleft
4. ACh diffuses across to ACh receptors, opening chemical-gated Na+
channels on sarcolemma. Na+ entry causes local depolarization (end
plate potential, EPP)
5. Acetylcholinesterase degrades ACh

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Clinical – Homeostatic Imbalance
Many toxins, drugs, and diseases interfere with events at the NMJ
– Example: myasthenia gravis: disease characterized by drooping
upper eyelids, difficulty swallowing and talking, and generalized
muscle weakness
– Involves shortage of ACh receptors because person’s ACh
receptors are attacked by own antibodies (autoimmune)

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Muscle Fiber Excitation – Generation
of an Action Potential

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Generation of an Action Potential Across the Sarcolemma

Resting sarcolemma is polarized, meaning a voltage exists across
membrane
– Inside of cell is negative compared to outside
Action potential is caused by changes in electrical charges
Occurs in three steps
1. Generation of end plate potential
2. Depolarization
3. Repolarization

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Generation of an Action Potential Across the Sarcolemma

1. End plate potential (EPP)
– ACh released from motor neuron binds to ACh receptors on
sarcolemma
– Causes chemically gated ion channels (ligands) on sarcolemma to
open
– Na+ diffuses into muscle fiber
§ Some K+ diffuses outward, but not much
– Because Na+ diffuses in, interior of sarcolemma becomes less
negative (more positive)
– Results in local depolarization called end plate potential

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2. Depolarization:
– An Action Potential (AP) will only be generated if depolarization
exceeds a certain threshold
– If end plate potential causes enough change in membrane voltage
to reach critical level called threshold, voltage-gated Na+ channels
in membrane will open
– Large influx of Na+ through channels into cell triggers AP that is
unstoppable and will lead to muscle fiber contraction
– AP spreads across sarcolemma from one voltage-gated Na+
channel to next one in adjacent areas, causing that area to
depolarize

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Summary of Events in the Generation and Propagation of an
Action Potential in a Skeletal Muscle Fiber
Voltage-gated Na+ and K+ channels

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3. Repolarization: restoration of resting conditions (electrically)
– Na+ voltage-gated channels close, and voltage-gated K+ channels
open
– K+ efflux out of cell rapidly brings cell back to initial resting membrane
voltage
– Refractory period: muscle fiber cannot be stimulated for a specific
amount of time, until repolarization is complete

– Ionic conditions of resting state are restored by Na+-K+ pump
§ Na+ that came into cell is pumped back out, and K+ that flowed
outside is pumped back into cell
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Action Potential Tracing Indicates Changes in Na+ and K+ ion
Channels

Recording of an action potential (AP) in a muscle fiber.
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Excitation-Contraction (E-C) Coupling

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Excitation-Contraction (E-C) Coupling
Excitation-contraction (E-C) coupling: events that transmit AP along
sarcolemma (excitation) are coupled to sliding of myofilaments
(contraction)
AP is propagated along sarcolemma and down into T tubules,
where voltage-sensitive proteins in tubules stimulate Ca2+ release
from SR
– Ca2+ release leads to contraction
AP is brief and ends before contraction is seen

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Excitation-Contraction
(E-C) Coupling is the
Sequence of Events by
Which Transmission of
an Action Potential
Along the Sarcolemma
Leads to the Sliding of
Myofilaments

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Transmission of the AP along the T- tubules of Triads causes
voltage-sensitive tubule proteins to change shape. Shape change
stimulates the interacting Ca2+ release channels in the terminal cisterns
of the SR to release Ca2+ ions into the cytosol.

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 Calcium binds to troponin;
troponin changes shape, and
removes blocking action of
tropomyosin. Myosin-
binding sites on the thin
filaments are exposed.

Myosin binding to actin
forms cross bridges and
contraction begins,
concluding the E-C coupling.
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Muscle Fiber Contraction: EC-Coupling

At low intracellular Ca2+ concentration:
– Tropomyosin blocks active sites on actin
– Myosin heads cannot attach to actin
– Muscle fiber remains relaxed
In response to AP, voltage-sensitive proteins in T tubules change
shape, causing sarcoplasmic reticulum (SR) to release Ca2+ to cytosol
At higher intracellular Ca2+ concentrations, 2 Ca2+ bind to troponin
Troponin changes shape and moves tropomyosin away from myosin-
binding sites
Myosin heads is then allowed to bind to actin, forming cross bridge
Cycling is initiated, causing sarcomere shortening and muscle
contraction

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Muscle Fiber Contraction: EC-Coupling
When nervous stimulation ends, the voltage sensitive tubule
proteins return to their original shape, and the Ca2+ release
channels of the SR close.

Ca2+ in the sarcoplasm is actively pumped back into the SR
by active transport. In the absence of Ca2+, the blocking action
of tropomyosin is restored, myosin can no longer interact with
actin, and relaxation occurs.

The E-C sequence is repeated every time an AP arrives at the
NMJ.

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A&P Flix: Excitation-Contraction Coupling

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Excitation-Contraction Coupling

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Muscle Fiber Contraction: Cross-Bridge Cycling
Four steps of the cross bridge cycle:
1. Cross bridge formation: high-energy myosin head attaches to
actin thin filament active site

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Muscle Fiber Contraction: Cross Bridge Cycling
2. Working (power) stroke: myosin head pivots and pulls thin
filament toward M line

M-line
Z-line Z-line

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Muscle Fiber Contraction: Cross Bridge Cycling
3. Cross bridge detachment: ATP attaches to myosin head,
causing cross bridge to detach

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Muscle Fiber Contraction: Cross Bridge Cycling
4. Cocking of myosin head: energy from hydrolysis of ATP “cocks”
myosin head into pre-stroke high-energy position
§ This energy will be used for power stroke in next cross bridge cycle

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The Cross Bridge Cycle

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A&P Flix: Cross Bridge Cycle

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Cross Bridge Cycle

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Clinical – Homeostatic Imbalance
Rigor mortis
– 3–4 hours after death, muscles begin to stiffen
§ Peak rigidity occurs about 12 hours postmortem
– Intracellular calcium levels increase because extracellular Ca2+
comes into cell.
§ Results in cross bridge formation
– Shortly after breathing cessation, ATP continues being consumed
although no more is synthesized.
§ Cross bridge detachment impossible after all the ATP is
depleted
§ Results in myosin head staying bound to actin, causing
constant state of contraction
– Muscles stay contracted until muscle proteins break down,
causing myosin head to release

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