Muscle Contraction PDF

Summary

This document provides an explanation of muscle contraction. It covers the process from the initial nerve signals to the molecular events within the muscle fibers that lead to contraction. It details the sliding filament theory and excitation-contraction coupling.

Full Transcript

MUSCLE CONTRACTION.

HOW A SKELETAL MUSCLE CONTRACTION BEGINS
Excluding reflexes, all skeletal muscle contractions occur as a result of
conscious effort originating in the brain. The brain sends electrochemical
signals through the somatic nervous system to motor neurons that
innervate muscle fibers. A single motor neuron with multiple axon
terminals can innervate multiple muscle fibers, thereby causing them to
contract at the same time. The connection between a motor neuron axon
terminal and a muscle fiber occurs at a neuromuscular junction site. This
is a chemical synapse where a motor neuron transmits a signal to muscle
fiber to initiate a muscle contraction.
The process by which a signal is transmitted at a neuromuscular junction
is illustrated in Figure 15.4.2. The sequence of events begins when an
action potential is initiated in the cell body of a motor neuron, and the
action potential is propagated along the neuron’s axon to the
neuromuscular junction. Once the action potential reaches the end of the
axon terminal, it causes the neurotransmitter acetylcholine (ACh) from
synaptic vesicles in the axon terminal. The ACh molecules diffuse across
the synaptic cleft and bind to the muscle fiber receptors, thereby initiating
a muscle contraction. Muscle contraction is initiated with the
depolarization of the sarcolemma caused by the sodium ions' entrance
through the sodium channels associated with the ACh receptors.

Figure 15.4.2: This diagram represents the sequence of events that occurs
when a motor neuron stimulates a muscle fiber to contract. The action
potential travels down the t-tubules and excites the sarcoplasmic
reticulum which releases calcium. Calcium when bound to troponin
causes conformational changes in the sarcomere. Consequently, the
interaction of thick and thin filaments of the sarcomere leads to muscle
contraction.
Things happen very quickly in the world of excitable membranes (think
about how quickly you can snap your fingers as soon as you decide to do
it). Immediately following depolarization of the membrane, it repolarizes,
re-establishing the negative membrane potential. Meanwhile, the ACh in
the synaptic cleft is degraded by the enzyme acetylcholinesterase (AChE).
The ACh cannot rebind to a receptor and reopen its channel, which would
cause unwanted extended muscle excitation and contraction.
Propagation of an action potential along the sarcolemma enters the T-
tubules. For the action potential to reach the membrane of the
Sarcoplasmic Reticulum (SR), there are periodic invaginations in the
sarcolemma, called T-tubules (“T” stands for “transverse”). The
arrangement of a T-tubule with the membranes of SR on either side is
called a triad (Figure 15.4.3). The triad surrounds the cylindrical
structure called a myofibril, which contains actin and myosin. The T-
tubules carry the action potential into the interior of the cell, which
triggers the opening of calcium channels in the membrane of the adjacent
SR, causing Ca++ to diffuse out of the SR and into the sarcoplasm. It is
the arrival of Ca++ in the sarcoplasm that initiates contraction of the
muscle fiber by its contractile units, or sarcomeres.

https://bio.libretexts.org/@go/page/16812
 In skeletal muscle, this sequence begins with signals from the somatic
motor division of the nervous system. In other words, the “excitation”
step in skeletal muscles is always triggered by signaling from the nervous
system.

SLIDING FILAMENT THEORY OF MUSCLE CONTRACTION

Once the muscle fiber is stimulated by the motor neuron, actin, and
myosin protein filaments within the skeletal muscle fiber slide past each
other to produce a contraction. The sliding filament theory is the most
widely accepted explanation for how this occurs. According to this theory,
muscle contraction is a cycle of molecular events in which thick myosin
filaments repeatedly attach to and pull on thin actin filaments, so they
slide over one another. The actin filaments are attached to Z discs, each of
which marks the end of a sarcomere. The sliding of the filaments pulls the
Z discs of a sarcomere closer together, thus shortening the sarcomere. As
this occurs, the muscle contracts.

Figure 15.4.3: Narrow T-tubules permit the conduction of electrical
impulses. The SR functions to regulate intracellular levels of calcium.
Two terminal cisternae (where enlarged SR connects to the T-tubule) and
one T-tubule comprise a triad—a “threesome” of membranes, with those
of SR on two sides and the T-tubule sandwiched between them.

EXCITATION-CONTRACTION COUPLING
Although the term excitation-contraction coupling confuses or scares
some students, it comes down to this: for a skeletal muscle fiber to
contract, its membrane must first be “excited”—in other words, it must be
stimulated to fire an action potential. The muscle fiber action potential,
which sweeps along the sarcolemma as a wave, is “coupled” to the actual
contraction through the release of calcium ions (Ca++ ) from the SR.
Once released, the Ca++ interacts with the shielding proteins, troponin
and tropomyosin complex, forcing them to move aside so that the actin-
Figure 15.4.5: The top diagram shows a relaxed sarcomere, and the
binding sites are available for attachment by myosin heads. The myosin
bottom diagram shows a contracted sarcomere. Please note the z discs, h
then pulls the actin filaments toward the center, shortening the muscle zone, and M line. In a contracted sarcomere the H zone reduces as
fiber. compared to relaxed sarcomere because actin fibers (greenish-yellow
double helix) move towards the M line.

CROSSBRIDGE CYCLING
Crossbridge cycling is a sequence of molecular events that underlies the
sliding filament theory. There are many projections from the thick myosin
filaments, each of which consists of two myosin heads (you can see the
projections and heads in Figures 15.4.5 and 15.4.3). Each myosin head
has binding sites for ATP (or ATP hydrolysis products: ADP and P i) and
actin. The thin actin filaments also have binding sites for the myosin
heads—a cross-bridge forms when a myosin head binds with an actin
filament.
The process of cross-bridge cycling is shown in Figure 15.4.6. A cross-
bridge cycle begins when the myosin head binds to an actin filament.
ADP and Pi are also bound to the myosin head at this stage. Next, a power
stroke moves the actin filament inward toward the sarcomere center,
thereby shortening the sarcomere. At the end of the power stroke, ADP
and Pi are released from the myosin head, leaving the myosin head
attached to the thin filament until another ATP binds to the myosin head.
Figure 15.4.4: Tropomyosin Troponin complex shields the cross-bridge When ATP binds to the myosin head, it causes the myosin head to detach
sites on actin. Myosin can only bind with actin when this complex is from the actin filament. ATP is again split into ADP and Pi and the energy
removed with the help of Calcium ions.
released is used to move the myosin head into a "cocked" position. Once

https://bio.libretexts.org/@go/page/16812
in this position, the myosin head can bind to the actin filament again, and another cross-bridge cycle begins.

Figure 15.4.6: Crossbridge cycling

https://bio.libretexts.org/@go/page/16812