Smooth Muscle Physiology PDF

Summary

This document provides an overview of smooth muscle physiology, including its characteristics, types, and the mechanisms of its contraction and relaxation. It explains the differences between smooth and striated muscle, and how it is regulated. The document is a valuable resource for students and professionals.

Full Transcript

EXCITATION AND
CONTRACTION OF
SMOOTH MUSCLE
Dr. Arzu Temizyürek

https://directorsblog.nih.gov/2013/01/16/the-beauty-of-smooth-muscle/

Classification of smooth muscle according to their activity
• Tonic smooth muscles:
To provide the tonus continuosly active.
- smooth muscle of the vessel,
- respiratory system,
- certain sphincters (gastrointestinal system)
• Phasic smooth muscles:
Contracts rhytmically and intermittently
- In walls of certain gastrointestinal
- uro-genital organs (uterus etc…)

Smooth vs. Striated
Muscle
• Involuntary
• In contrast, skeletal muscle fibers are as much as 30
times greater in diameter and hundreds of times as long
• Same attractive forces between myosin and actin
filaments cause contraction

but the internal physical arrangement of
smooth muscle fibers is different

General Properties of Smooth Muscle
Cell has 3 types of filaments
1. Thick filaments: myosin - longer than those in skeletal muscle
2. Thin filaments : - actin,
- tropomyosin,
- caldesmon (CaD is the actin and tropomyosin
binding protein)
- calponin (CaP is the actin binding protein that
inhibits actomyosin ATPase activity
in vitro )

CaD and CaP inhibit the ATP hydrolyze of myosin which is activated
by actin

3. Intermediate filaments

– Filaments of intermediate size
- attach dense bodies to each other.
- serve as cellular skeleton
- contain proteins names as desmin,
flamin, crystalin and vimentin
- not directly participate in contraction
• Form part of cytoskeletal framework
that supports cell shape

TYPES OF SMOOTH MUSCLE

Generally smooth muscles can be divided
into two major types:
1.multi-unit smooth muscle
2. unitary (or single-unit) smooth muscle

(Single Unit)
Innervation of smooth muscle by autonomic
nerve fibers that branch diffusely and secrete
neurotransmitter from multiple varicosities.

Unitary (visceral) smooth muscle cells are
connected by gap junctions so that
depolarization can rapidly spread from one
cell to another, permitting the muscle cells to
contract as a single unit.
In multiunit smooth muscle, each cell is
stimulated
independently
by
a
neurotransmitter released from closely
associated autonomic nerve varicosities

Single Unit (Visceral) Smooth Muscle
• A group of smooth muscle fibers that contract together as a
single unit.
• Are electrically coupled to one another via gap junctions
• Often exhibit spontaneous action potentials
• Are arranged in opposing sheets and exhibit
stress-relaxation response
- Found primarily in the walls of viscera
e.g. - the musculature of the intestine,
─ the uterus, and
─ the ureters,
─ bile,
─ duct,
─ bladder
─ small arteries.

Figure 12.23a (1 of 2)

Single-unit smooth muscle cells are connected by
gap junctions, and the cells contract as a single unit.
Autonomic neuron
varicosity

Gap
junctions

Neurotransmitter
Receptor

Smooth muscle
cell

Multi-Unit Smooth Muscle
➢ Each fiber can contract independently of the others,
and their control is exerted mainly by nerve signals.

➢In contrast, a major share of control of
unitary smooth muscle is exerted by
non-nervous stimuli.
➢ Some examples of multi-unit smooth muscle are the

ciliary muscle of the eye,
the iris muscle of the eye
the piloerector muscles

Figure 12.23b (2 of 2)

Multi-unit smooth muscle cells are not electrically linked,
and each cell must be stimulated independently.

Eye

Varicosity

Neuron

General Properties of Smooth Muscle
• Innervated by autonomic nervous system (ANS- parasympathetic
and sympathetic). ANS does not initiates smooth muscle activity
but controls (accelerates or decelerates)
• Many visceral organs’s smooth muscle has impulse generating
pacemaker cells.
• As in the eye some of the smooth muscle cells can not generate
impulses by themselves.

Unitary Smooth Muscle

Unitary smooth muscle is also called syncytial smooth muscle
or visceral smooth muscle.

➢ The fibers usually are arranged in sheets or bundles

➢ their cell membranes are adherent to one
another at multiple points

➢ The cell membranes are joined by many gap junctions
through which ions can flow freely from one muscle cell to

cause the muscle fibers to
contract together.
the next

Examples, the

gastrointestinal tract,

bile ducts, ureters, uterus, blood vessels

CONTRACTILE MECHANISM IN SMOOTH MUSCLE
Chemical Basis for Smooth Muscle Contraction

Smooth vs. Striated Muscle

❑Smooth muscle contains both actin and myosin filaments, having chemical
characteristics similar to those of the actin and myosin filaments in skeletal
muscle.
❑Actin and myosin filaments interact with each other in much the
same way that they do in skeletal muscle

❑The contractile process is activated by calcium ions, and adenosine
triphosphate (ATP) is degraded to adenosine diphosphate (ADP) to
provide the energy for contraction.

CONTRACTILE MECHANISM IN SMOOTH MUSCLE
Chemical Basis for Smooth Muscle Contraction Smooth vs. Striated Muscle
➢ It does not contain the troponin complex that is required in the control of skeletal muscle
contraction, and thus the mechanism for control of contraction is different

➢ major differences

The physical organization of smooth muscle
Excitation-contraction coupling
Control of the contractile process by calcium

Duration of contraction
The amount of energy required for contraction

CONTRACTILE MECHANISM IN SMOOTH MUSCLE
Physical Basis for Smooth Muscle Contraction
➢ Smooth muscle does not have the same striated
arrangement of actin and myosin filaments as is found in
skeletal muscle
➢ Large numbers of actin filaments attached to dense

bodies.
➢ This contractile unit is similar to the contractile unit of
skeletal muscle, but without the regularity of the skeletal
muscle structure; in fact, the

dense bodies of
smooth muscle serve the same role as the Z
disks in skeletal muscle.
❑ In skeletal muscle, overlapping actin and myosin anchored to both
the M line and Z-discs by titin, provides structural stability and also
contributes to force transmission through the sarcomeres.

➢Most of the myosin filaments have
“sidepolar” cross-bridges arranged
so that the bridges on one side
hinge in one direction and those on
the other side hinge in the opposite
direction.
➢This configuration allows the myosin
to pull an actin filament in one
direction on one side while
simultaneously pulling another actin
filament in the opposite direction on
the other side.

Smooth muscle myosin has
hinged heads all along its length.

Myosin
filament
Actin
filament

Figure 12.25b (2 of 2)

Comparison of Smooth Muscle Contraction and Skeletal Muscle Contraction

1. Slow Cycling of the Myosin Cross-Bridges

2. Low Energy Requirement to Sustain Smooth
Muscle Contraction

• Slowness of attachment and
detachment of the cross-bridges
• Cross-bridge heads have far less
ATPase activity than in skeletal
muscle
• Because of slow attachment and
detachment cycling of the cross-bridges
• Only one molecule of ATP is required
for each cycle
• Sustainability for the intestines

• urinary bladder
• Gallbladder and other viscera
maintain tonic muscle contraction

3. Slowness of Onset of Contraction and
Relaxation of the Total Smooth Muscle Tissue

• Caused by the slowness of attachment and
detachment of the cross-bridges with the actin
filaments.
• The initiation of contraction in response to calcium
ions is much slower than in skeletal muscle

4. The Maximum Force of Contraction Is Often
Greater in Smooth Muscle Than in Skeletal
Muscle

5. The “Latch” Mechanism Facilitates
Prolonged Holding of Contractions of Smooth
Muscle

6. Stress-Relaxation of Smooth Muscle

Results from the prolonged period of
attachment of the myosin cross-bridges to the
actin filaments.

• It can maintain prolonged tonic
contraction with little use of energy.
• Little continued excitatory signal is
required from nerve fibers or hormonal
sources
• Seen in visceral unitary type of smooth muscle of many
hollow organs
• Ability to return to nearly its original force of contraction
seconds or minutes after it has been elongated or shortened
• Except for short periods, they allow maintain about the
same amount of pressure inside its lumen despite sustained,
large changes in volume.

REGULATION OF CONTRACTION BY CALCIUM IONS

• The initiating stimulus for most smooth muscle contraction is an
increase in intracellular calcium ions.
This increase can be caused in different types of smooth muscle by

➢Nerve stimulation of the smooth muscle fiber
➢Hormonal stimulation
➢Stretch of the fiber
➢Change in the chemical environment of the fiber

Smooth muscle contraction is activated by an
entirely different mechanism
• Smooth muscle does not contain troponin
• Neuromuscular junctions do not occur in smooth
muscle

• No regular motor plate (like in skeletal muscle)
• Not arranged in orderely sarcomers
• Ordered diagonally
• No regular pattern of overlap
• Varicosities are present
• Instead, the autonomic nerve fibers that
innervate smooth muscle generally branch
diffusely on top of a sheet of muscle fibers

In place of troponin, smooth muscle cells contain a large amount of another regulatory protein called calmodulin

Intracellular calcium ion (Ca++ ) concentration increases when Ca++
enters the cell through calcium channels in the cell membrane or is
released from the sarcoplasmic reticulum.
The Ca++ binds to calmodulin (CaM) to form a Ca++ -CaM complex,
which then activates myosin light chain kinase (MLCK).
The active MLCK phosphorylates the myosin light chain leading to
attachment of the myosin head with the actin filament and contraction
of the smooth muscle.

ADP, adenosine diphosphate; ATP, adenosine triphosphate; P, phosphate.

Source of Calcium Ions That Cause Contraction
❑ An important difference is that the sarcoplasmic reticulum, which provides virtually all the calcium
ions for skeletal muscle contraction, is only slightly developed in most smooth muscle
❑ Instead, most of the calcium ions that cause contraction enter the muscle cell from the extracellular
fluid at the time of the action potential or other stimulus.

❑ That is, the concentration of calcium ions in the extracellular fluid is greater than 10−3 molar, in
comparison with less than 10−7 molar inside the smooth muscle cell; this situation causes rapid
diffusion of the calcium ions into the cell from the extracellular fluid when the calcium channels open.

Role of the Smooth Muscle Sarcoplasmic Reticulum
Figure 8.4 shows a few slightly developed sarcoplasmic
tubules that lie near the cell membrane in some larger
smooth muscle cells.
• Small invaginations of the cell membrane, called caveolae, abut
the surfaces of these tubules.
• CAVEOLA instead of T-TUBULES in skeletal muscles
• The caveolae suggest a rudimentary analog of the transverse
tubule system of skeletal muscle

Smooth Muscle Contraction Is Dependent on
Extracellular Calcium Ion Concentration.
➢ When the extracellular fluid calcium ion concentration decreases
smooth muscle contraction usually ceases.

➢ Therefore, the force of contraction of smooth muscle is usually highly
dependent on the extracellular fluid calcium ion concentration.

❑ Relaxation of smooth muscle occurs when calcium ion (Ca++ )
concentration decreases below a critical level as Ca++ is pumped
out of the cell or into the sarcoplasmic reticulum.
❑ Ca++ is then released from calmodulin (CaM) and myosin
phosphatase removes phosphate from the myosin light chain,
causing detachment of the myosin head from the actin filament
and relaxation of the smooth muscle.

This pump requires ATP and is slow acting in comparison with
the fast-acting sarcoplasmic reticulum pump in skeletal muscle.

Therefore, a single smooth muscle contraction often lasts for
seconds rather than hundredths to tenths of a second, as
occurs for skeletal muscle.

Myosin Phosphatase Is Important in Cessation
of Contraction.
➢ Relaxation of the smooth muscle occurs when the calcium
channels close and the calcium pump transports calcium
ions out of the cytosolic fluid of the cell.

When the calcium ion concentration falls below a critical level,
the aforementioned processes automatically reverse, except for
the phosphorylation of the myosin head.
Reversal of this situation requires another enzyme, myosin
phosphatase located in the cytosol of the smooth muscle cell,
which splits the phosphate from the regulatory light chain.
Then the cycling stops and contraction ceases.
The time required for relaxation of muscle contraction,
therefore, is determined to a great extent by the amount of
active myosin phosphatase in the cell.

MEMBRANE POTENTIALS AND ACTION POTENTIALS IN SMOOTH MUSCLE

The action potentials of visceral smooth muscle occur in one
of two forms:
(1) spike potentials or
(2) action potentials with plateaus

Membrane Potentials in Smooth Muscle.
The quantitative voltage of the membrane potential of smooth
muscle depends on the momentary condition of the muscle. In
the normal resting state, the intracellular potential is usually
about −50 to −60 millivolts, which is about 30 millivolts less
negative than in skeletal muscle

Action Potentials in Unitary Smooth Muscle. Action potentials
occur in unitary smooth muscle (such as visceral muscle) in the
same way that they occur in skeletal muscle.

Spike Potentials. Typical spike action potentials, such as
those seen in skeletal muscle, occur in most types of
unitary smooth muscle.

Such action potentials can be elicited in many
ways—for example
➢ by electrical stimulation
➢ by the action of hormones on the smooth
muscle
➢ by the action of transmitter substances from
nerve fibers
➢ by stretch or as a result of spontaneous
generation in the muscle fiber itself

Slow Wave Potentials in Unitary Smooth Muscle
Can Lead to Spontaneous Generation of Action
Potentials.
➢ Some smooth muscle is self-excitatory—that is,
action potentials arise within the smooth muscle
cells without an extrinsic stimulus.
➢ This activity is often associated with a basic slow
wave rhythm of the membrane potential.

Calcium Channels Are Important in Generating the Smooth Muscle Action Potential.
▪ The smooth muscle cell membrane has far more voltage-gated calcium channels than
does skeletal muscle but few voltage-gated sodium channels.
Therefore, sodium participates little in the generation of the action potential in most
smooth muscle.

This flow occurs in the same self-regenerative way as occurs for the sodium channels in nerve fibers and in
skeletal muscle fibers.
However,

the calcium channels open many times more slowly than do sodium
channels, and they also remain open much longer.
These characteristics largely account for the prolonged plateau
action potentials of some smooth muscle fibers.
Another important feature of calcium ion
entry into the cells during the action
potential is that the calcium ions act
directly on the smooth muscle contractile
mechanism to cause contraction.
Thus, the calcium performs two tasks at
once.

Slow Wave Potentials in Unitary Smooth Muscle Can Lead to Spontaneous Generation of Action Potentials.

The slow wave itself is not the action potential.
That is, it is not a selfregenerative process that spreads
progressively over the membranes of the muscle
fibers.
Instead, it is a local property of the smooth muscle
fibers that make up the muscle mass.

The cause of the slow wave rhythm is unknown.

The importance of the slow waves is that, when they are strong enough, they can initiate action potentials.
The slow waves themselves cannot cause muscle contraction.

However, when the peak of the negative slow wave potential inside the cell membrane rises in the positive
direction from −60 to about −35 millivolts (the approximate threshold for eliciting action potentials in most
visceral smooth muscle), an action potential develops and spreads over the muscle mass and contraction occurs.
Figure 8-7B demonstrates this effect, showing that at each peak of the slow wave, one or more action potentials
occur

These repetitive sequences of action potentials elicit
rhythmical contraction of the smooth muscle mass.
Therefore, the slow waves are called pacemaker waves.

this type of pacemaker activity controls the rhythmical
contractions of the gut.

Effect of Local Tissue Factors and Hormones to Cause Smooth Muscle Contraction Without Action Potentials
Approximately half of all smooth muscle contraction is likely initiated by stimulatory factors acting directly on
the smooth muscle contractile machinery and without action potentials.
Two types of non-nervous and nonaction potential stimulating factors often involved are
(1) local tissue chemical factors
(2) various hormones

❑ Action potentials usually do not develop because the

fibers are too small to generate an

action potential.
❑ In small smooth muscle cells, even without an action potential, the local depolarization (called the junctional
potential) caused by the nerve transmitter substance itself spreads “electrotonically” over the entire fiber

Effects of Hormones on Smooth Muscle Contraction
Among the more important of these hormones are norepinephrine, epinephrine, angiotensin II, endothelin,
vasopressin, oxytocin, serotonin, and histamine.

❖ Smooth muscles have considerable diversity in
how they initiate contraction or relaxation in
response to different hormones,
neurotransmitters, and other substances.
❖ In some instances, the same substance may
cause either relaxation or contraction of
smooth muscles in different locations.
For example, norepinephrine

inhibits
contraction of smooth muscle in the intestine
but
stimulates contraction of
smooth muscle in blood vessels.

Disruption of PDGFRalpha signaling disturbs the growth of
dental cusp and interferes with the critical extension of
palatal shelf during craniofacial development.

Andrae J. et al. 2008

Smooth Muscle
• Contracts and relaxes much more slowly
• Uses less energy
• Sustains contractions for extended periods

Figure 12.24

Duration of Muscle Twitch in the Three Types of Muscle
Smooth muscles are the slowest to contract and to relax.
Skeletal
Smooth

Tension

Cardiac

0

1

2
Time (sec)

3

4

5