110 Chapter 6
A Signals from the nervous
system travel along spinal
cord, down motor neuron.
B Endings of
motor neuron
terminate next to
muscle cells.
C Signals travel along muscle cell’s plasma membrane
to sarcoplasmic reticulum around myofibrils.
D Signals trigger the release of calcium ions from sarcoplasmic reticulum
threading among the myofibrils. The calcium allows actin and myosin
filaments in the myofibrils to interact and bring about contraction.
part of one muscle cell
section from
spinal cord
motor
neuron
section from a skeletal muscle
Axon of neuron
Neuromuscular
junction
Plasma
membrane
of muscle fiber
T tubule
Myofibrils
Z line Z line
muscle’s outer sheath
(connective tissue)
how the nervous system Controls muscle Contraction
n skeletal muscles move the body and its parts in response to
signals from the nervous system.
n Link to the Endomembrane system 3.7
Calcium ions are the key to contraction
The nervous system controls the contraction of skeletal
muscles, sending commands to muscle fibers by way of
motor (“movement”) neurons. A motor neuron travels to a
muscle and issues signals that trigger or halt contraction of
the sarcomeres in the muscle’s fibers (Figure 6.9A and 6.9B).
Figure 6.9 Animated! Signals from the nervous system stimulate contraction of skeletal muscle. (© Cengage Learning)
When nerve impulses arrive at a muscle fiber, they
quickly spread. Eventually they reach small extensions of
the cell’s plasma membrane. These “T tubules” connect with
a membrane system that laces around the fiber’s myofibrils
(Figure 6.9C and 6.9D). The system, called the sarcoplasmic
reticulum (SR), is a version of the endoplasmic reticulum
described in Chapter 3. SR takes up and releases calcium
ions (Ca^11 ). An incoming nerve impulse triggers the release
of calcium ions from the SR. The ions diffuse into myofibrils,
and when they reach actin filaments the stage is set for
contraction.
Two proteins on the surface of actin filaments have
important roles in muscle contraction (Figure 6.10). One of
them, called troponin (tropo- means “turn or change”), has a
rounded shape. It attaches to the actin filament and also to
the second protein, called tropomyosin (“myosin changer”),
which winds along the actin filament. Importantly, in a rest-
ing muscle fiber troponin covers up the sites where myosin
can link up with actin. This changes when incoming calcium
binds to troponin. Then the troponin moves, twisting tropo-
myosin away from the actin binding sites. Myosin now can
attach to the sites, and muscle contraction can occur.
When nerve impulses stop, calcium is actively trans-
ported back into the SR. Tropomyosin covers the binding
sites on actin again, myosin can’t bind to actin, and the
muscle fiber relaxes. Notice the importance of calcium in
these events. Its central role in muscle contraction is one
reason why mechanisms of homeostasis that maintain
proper blood levels of calcium are so important.
6.4
A Signals from the nervous
system travel along spinal
cord, down motor neuron.
B Endings of
motor neuron
terminate next to
muscle cells.
C Signals travel along muscle cell’s plasma membrane
to sarcoplasmic reticulum around myofibrils.
D Signals trigger the release of calcium ions from sarcoplasmic reticulum
threading among the myofibrils. The calcium allows actin and myosin
filaments in the myofibrils to interact and bring about contraction.
part of one muscle cell
section from
spinal cord
motor
neuron
section from a skeletal muscle
Axon of neuron
Neuromuscular
junction
Plasma
membrane
of muscle fiber
T tubule
Myofibrils
Z line Z line
muscle’s outer sheath
(connective tissue)
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