[PHYSIO]1.08_Smooth muscle.pdf

Full Transcript

1.08 Smooth muscle PHYSIOLOGY
Maria Carmelita Vera Cruz, MD 1ST BIMONTHLY
14 September 2021 TRANS 07
○ Attached to the cell membrane, other dense bodies scattered
SMOOTH MUSCLE PHYSIOLOGY all over
Types: multi-unit, single-unit ○ Dense bodies linked to other dense bodies by a scaffolding
of protein bridges
○ Lots of actin, sparse myosin
○ dense bodies - same role as Z disc in skeletal muscle
Smooth Muscle Contraction Characteristics
Skeletal - rapid contraction
Smooth - prolonged, tonic contraction, lasting for hours, even
days
○ A. slow cycling of cross-bridges (attachment to actin, release
from actin)
Much, much slower in smooth muscles than in skeletal
muscles
Longer time that actin and myosin are attached to each
other
○ B. very low energy requirement, very economical
○ C. slow onset, prolonged/sustained duration
○ D. force of contraction - greater than skeletal muscle
probably due to the longer time actin is attached to myosin
○ E. percentage of shortening of muscle - can shorten far
greater percentage of its length and still maintain almost full
force of contraction, smooth muscle very “flexible” /
○ 1. Multi-unit adjustable
Discrete muscle fibers, each fiber operating entirely ○ F. latch mechanism - once smooth muscle has developed
independently of the others, innervated by single nerve full contraction, the degree of activation of the muscle can be
ending (like skeletal muscles) reduced to far less than the initial level and yet the muscle
Most important characteristics: each fiber can contract will still maintain its full strength of contraction
independently of the others Energy consumed to maintain contraction - miniscule
Examples: ciliary muscles of the eye, iris of the eye, Importance:
piloerector muscles Maintain prolonged tonic contraction in smooth muscle
○ 2. Single-unit / unitary / syncytial / visceral for hours and hours with very little use of energy
A whole mass of fibers (hundreds to thousands contract Also very little excitatory signal is required from nerve
together as a single unit) fibers or hormonal sources.
Fibers aggregated into sheets or bundles Cause of latch phenomenon: prolonged attachment of
Cell membranes adherent to each other at multiple points myosin cross-bridges to actin
Many GAP JUNCTIONS ○ G. stress-relaxation of smooth muscle - ability to return to
Examples: found in the walls of most viscera in the body, its original force of contraction seconds or minutes after it
like the gut, bile ducts, ureters, uterus, blood vessels has been elongated or shortened
Gap junctions Importance: allows a hollow organ to maintain
○ Intimate connections between cells thru which ions can flow approximately the same amount of pressure inside its
freely from one cell to the next so that APs travel from one lumen regardless of length of muscle fibers
fiber to the next → entire muscle mass contracts together
Regulation of contraction by Ca++
Chemical basis:
SMOOTH MUSCLE SKELETAL MUSCLE

actin actin

Myosin myosin

calcium-activated calcium-activated

ATP needed ATP needed

No troponin With troponin

Physical basis:
Dense bodies - where actin filaments attach Steps:

TRANS (7) CORE 1 of 2
1.08 Smooth muscle
○ A. Ca++ bind with calmodulin ○ Remember: calcium channels open more slower than
○ B. calmodulin-Ca++ combination joins with and activates sodium channels → slow action potentials of smooth muscle
myosin kinase (a phosphorylating enzyme) Two roles of Ca++ in smooth muscle contraction
○ C. One of the light chains (called the regulatory chain of each ○ To cause depolarization : by the entrance of Ca++ into cell,
myosin head becomes phosphorylated in response to the the cell depolarizes
myosin kinase. When the light chain is phosphorylated, the ○ To remove the inhibition, exposing the active sit, allowing the
head has the capability of binding with the actin filament. myosin head to attach to the active site - power stroke.
○ D. Power stroke occurs.
Slow Wave Potentials (pacemaker waves)
Source of Calcium Some smooth muscle cells = self-excitatory
SR in smooth muscles APS arise within the muscle itself without an extrinsic stimulus
○ Rudimentary, not very well developed Associated with a slow wave rhythm of the action potential
○ Main source of calcium for contraction is the ECF Slow wave - NOT an action potential
Caveoli - rudimentary analogs of the t-tubule system ○ Does not spread over the entire muscle membrane
○ Found in some smooth muscle cells ○ Localized
○ Small invaginations of the membrane ○ Importance: can initiate an action potential
If slow wave reaches -35 mV (the threshold in smooth muscle
How do the Ca++ enter the cell to cause depolarization and action potential develops and spread over the entire muscle)
contraction?
○ 1. Diffusion - smooth muscle fibers are very small compared Stimulation by stretch
to skeletal muscle, calcium can easily diffuse through Stretch - visceral (single-unit) smooth muscle is stretched
membrane sufficiently, spontaneous action potentials are usually
○ 2. Hormone-gated calcium channels generated
○ Results from a combination of the normal slow wave
Calcium potentials plus a decrease in negativity of the membrane
○ Ca++ concentration in the ECF - very important in smooth potential caused by the stretch itself
muscle contraction ○ Example: when the gut is overstretched by intestinal
○ Very low Ca++ in the ECF → muscle contraction almost contents, a local automatic contraction often sets up
ceases peristalsis wave that moves the contents away from the
○ Force of contraction is highly dependent on ECF calcium overfilled intestine
concentration
Smooth muscle contraction without action potentials
The Calcium pump 1. Local tissue factors - local environment control
○ What causes relaxation? ○ Example: factors that cause vasodilation
​calcium pump - pumps calcium ions out of the smooth ○ A. lack of oxygen in local tissues
muscle fiber back into the extracellular fluid or into a ○ B. excess carbon dioxide
sarcoplasmic reticulum ○ C. increased hydrogen ion concentration
Pump is very slow-acting ○ D. increased lactic acid
Prolonged duration of contraction in smooth muscle ○ E. Increased potassium ions
○ F. Decreased body temperature
Neural and hormonal control of smooth muscle contraction 2. Hormones that affect contraction:
○ NE, epi, Ach, angiotensin, vasopressin, oxytocin, serotonin,
Neural control histamine
○ Diffuse junctions ○ A hormone causes contraction when the muscle cell fiber
○ Varicosities contains hormone-gated excitatory receptors for a particular
○ Contact junctions hormone
The neurotransmitters: acetylcholine, norepinephrine ○ A hormone cause inhibition instead of contraction if the
Type of receptor - determines whether the smooth muscle will membrane contains inhibitory receptors rather than
be excited or inhibited by the neurotransmitter that arrives. excitatory receptors
Resting membrane potential : -50 to -60 mV

Action Potential of visceral smooth muscle
1. Spike potential - similar to skeletal AP, occurs in unitary
smooth muscle, duration is 10 to 50 milliseconds
○ Can be elicited by electrical stimulation, hormones,
transmitter subs, spontaneous generation in the muscle itself
2. Action potential with plateau - onset is similar to typical
spike potential but instead of rapid repolarization, there is a
plateau or a delay in repolarization for several hundred to
several thousand milliseconds
Importance of Ca++ channels in generating smooth muscle
action potentials
Smooth muscle cell membranes - have more voltage-gated
calcium channels than skeletal muscle bu with very, very few
sodium channels
○ Flow of calcium ions into the cell thru the channel → mainly
responsible for the action potential

PHYSIOLOGY 2 of 2