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Muscles
Muscle cells are elongated
„ Cells are called muscle fibers
„ myo- and sarco- = muscle
„ Cell membrane is sarcolemma
„ cytoplasm is sarcoplasm
„
Muscles
Skeletal- striated, contracts rapidly, tires easily,
multinucleate
„ Cardiac- striated, intercalated disks, uninucleate
„ Smooth- uninucleate, found in walls of organs
„
Functions
Movements
„ Maintain posture
„ Stabilize joints
„ Heat- Skeletal muscle mass is 40 % of body mass- generates
the most heat
„
Characteristics
Excitability
„ Contractibility
„ Extensibility
„ Elasticity
„
Structure
Each fiber is surrounded by sheath of areolar CT=
endomysium
„ Fibers are gathered into bundles (fascicles) covered by
collagen sheath called perimysium
„ Fascicles are bound together by close fibrous CT called
epimysium
„
Structure
„
Fibrous CT called fascia binds the epimysium to other
muscle or bone
Each skeletal muscle fiber has its own nerve ending
„ Blood vessels supply each muscle fiber- muscle cells have
constant supply of O2 and give off waste
„
Attachments
„
Muscles are attached at two locations
‹ Insertion
at the movable bone
‹ Origin at immovable bone
„
Direct and Indirect Attachments
‹ Direct
attachments- epimysium is fused to the periosteum of a bone
or the perichondrium of cartilage
Indirect Attachments
Fascia extends beyond the muscle as a tendon, or an
aponeurosis- anchors the muscle to a bone, or to facia of
other muscles
„ Most common in body
„
Fascicles
Arranged in different patterns
„ Parallel
„ Pennate- fascicles are short and oblique to central spinelooks like a feather- can have unipennate and bipennate
„ Convergent- all fascicles converge on single tendon- looks
triangular
„
Fascicles
Patterns determine power
„ Skeletal muscle shortens to 70 % of resting length
„
‹ Longer
parallel fibers give greater range of motion, but not much
power
‹ Power actually depends on number of cells
„
Pennate pattern has most cells
‹ It
doesn’t shorten as much, but has most power
Structure
„
Muscle cell is long and cylindrical
‹ 1-40
mm long, .01- .1 mm wide
Multinucleate
„ Sarcoplasm is similar to other cytoplasms but has larger
amounts of stored glycogen and myoglobin
„ Each cell contains myofibrils
„
Myofibrils
Contractile element of cell
„ Comprise 80 % of volume of cell
„ Contain smaller subunits called sarcomeres
„ There are repeating sequences of alternating light and dark
bands
„
Myofibrils
„
Dark bands are A bands (anisotropic)
‹ Polarize
„
visible light
Light bands are I (isotropic)
‹ Nonpolarizing
„
Each A band has a light stripe down the middle (H band)
(Hell band)
‹H
zones are only visible in relaxed cells
Myofibrils
Each H zone is bisected by a dark line- M line
„ I band has a midzone line called Z line
„
‹ Sarcomere
„
is inbetween Z lines
Myofibril consists of two types of protein myofilaments
‹ Central
thick filaments extends the length of the A band- myosin
Myofibrils
Thin filaments extend across the I band and partway into A
band- actin
„ Z line serves as point of attachment for actin- connects
sarcomeres
„ H zone in middle of A band has thin filaments that connect
the thick filaments M band
„
Myosin
„
Each molecule has a tail and two heads
The heads form cross- bridges to the actin
„ Each thick filament contains 200 myosin molecules
„ The heads contain ATP and ATP ases
„
Actin
Thin filaments contain binding sites which connect to myosin
cross- bridges
„ Contains regulatory proteins
„
‹ Tropomyosin-
helps to stiffen actin chains
+2
‹ Troponin- binds Ca ions
Sarcoplasmic Reticulum
Similar to ER
„ Surrounds myofibrils and forms terminal cisternae (saclike
channels) in regions of A-I junctions
„ At each junction, the sarcolemma dives into the cell interior
to form a hollow tube called the T tubule
„
‹ Continuous
with cell exterior and interior
Sarcoplasmic Reticulum
„
„
T tubule provides canals for fluids and ions to penetrate into
the cell
SR helps to regulate Ca+2
Contraction
Filaments do not change length- they slide
„ Actin slides past myosin filaments, causing the distance
between the Z lines to shorten
„ H zone disappears
„ A bands move closer together
„
Contraction
Cross bridges on the myosin attach to the actin and then
detach several times, like a ratchet
+2
„ Attachment of the cross bridges requires Ca
+2
„ Without Ca , the muscle cell is relaxed and the myosin
binding sites on actin are blocked by tropomyosin
„
Contraction
„
With Ca+2, Ca+2 binds to troponin
‹ Troponin
undergoes conformational change
‹ Causes tropomyosin to roll away from the binding site
‹ Causes exposure of myosin binding sites on actin, allowing binding
of actin to myosin
Contraction
1. Formation of cross bridges causes change of myosin from a
high- energy conformation to a low energy, bent form
2. Formation of the bent form causes actin to slide to middle of
the sarcomere
‹ ADP
and Pi formed earlier are released from the myosin head
Contraction
3. New ATP attaches to the myosin, causing the myosin to
detach from the actin
4. ATP is hydrolyzed by ATPase, releasing energy and causing
the mysoin head to cock (high energy position)
‹ Now
we are back to the starting point
Contraction
Each stroke is only a 1 % shortening
„ Total shortening is 30- 35 %
„ Need many strokes
„
Rigor Mortis
Muscles begin to stiffen 3-4 hours after death
„ Peak is reached 12 hours after death, then dissipates over
next 48-60 hours
+2
„ Dying cells cannot exclude Ca - ion flow promotes cross
bridge formation
„ Can’t make new ATP, so linkage is semi-permanent- later
things break down
„
Regulation of Contraction
„
Nerve stimulates each skeletal muscle cell by propagating an
action potential
„
Nerve comes from brain or spinal cord, but axon reaches out
to muscle
‹ Axon
divides and fragments as it enters the muscle
‹ Each axonal ending goes to muscle fiber
Contraction
Cell membrane of axon does not touch muscle, but are
separated by synapse
„ Within axonal ending are synaptic vessicles containing
acetylcholine
„ Motor end plate in muscle contains Ach receptors
+2
„ Nerve impulse reaches end of axon, opening Ca channels in
membrane
„
Contraction
Ca+2 flows in from extracellular fluid, causing vessicles to
release Ach into synapse
„ Ach attaches to Ach receptors in sarcolemma
„ Triggers action potential in sarcolemma
„
Action Potential
Resting cell is polarized- -60mV across the membrane
+
+
„ K is on the inside, Na on the outside
+
+
„ Attachment of Ach molecules opens Na gates and Na enters
the cell
„ Interior becomes less negative= depolarization and action
potential is generated, if strong enough
„
Action Potential
1. Depolarization- Na+ enters the cell and reduces the negative
charge
2. Propagation- Positive charges inside cell spread to adjacent
negative charges
3. Repolarization- Na+ gates close and K+ gates open
+
‹K
leaves the cell
‹ Interior becomes more negative
Action Potential
During repolarization, cell is in refractory state- no further
stimulus is possible
„ Ionic balance has been restored- not the chemical balance
+
+
„ Na - K pump restores the chemical balance
„
Contraction
All or nothing response for muscle cell
„ Action potential is brief- 1-2 ms
„ Contraction of muscle lasts 100ms
„ ACh must be destroyed by Acetylcholinesterase AChE
„ Curare binds to ACh receptors, cannot receive ACh
„
Excitation- Contraction Coupling
Period between action potential initiation and the beginning
of muscle contraction= latent period
1. Action potential propagates down the T tubules, from ACh
receptors
2. Terminal cisternae release Calcium into sarcoplasm
„
Coupling
3. Calcium binds to troponin, causing tropomyosin to move
4. Filaments slide
5. Calcium signal ends, because calcium pump removes
calcium
6. With low Ca+, tropomyosin moves back
Contraction
Sequence is repeated when new nerve impulse arrives
„ Levels of calcium rise for stronger stimulus, and muscle cells
don’t relax completely
„ Calcium concentrations are regulated by calsequestrin,
which releases it, and calmodulin, which binds it
„
Motor Unit
Each muscle is served by at least one motor neuron with
hundreds of axonal endings
„ One motor neuron and all the fibers that are served is a
„
motor unit
„ Average number of fibers is 150
Muscle Twitch
Response of muscle to a single stimulus- twitch
„ Three phases:
1. Latent period- no response seen
2. Period of contraction- 10- 100 ms
3. Period of relaxation- muscle tension relaxes
„
Twitch
Usually do not have one twitch- have waves of contraction
„ Continuous contraction is tetanus
„ Successive contractions are often stronger than earlier ones
„
‹ Heat
has been released which allows enzyme systems to be more
efficient
‹ Warm- up for sports- Called Treppe effect
Muscle Tone
Muscles are usually in some state of contraction
„ Maintains fitness
„ Spinal reflexes activate various groups of muscles
„
ATP
Muscles require ATP, but store very little
„ Generate ATP in three ways:
1. ATP already in muscle is used up in 6 seconds
„
‹ High
energy molecule, creatinine phosphate + ADP -> creatinine +
ATP
‹ Energy lasts an additional 10 seconds
ATP
2. Aerobic respiration- occurs in mitochondria - glu +O2->
water + carbon dioxide
3. Anaerobic respiration (glycolysis) can provide enough ATP
for 30- 40 seconds
‹ Produces
„
lactic acid
Total energy can last for about a minute
Fibers
Force of contraction is affected by the number of fibers
stimulated, and the size of the muscle
„ The greater the cross section affected, the more power
„
Fibers
1. Red slow- twitch- thin cells with slow acting myosin ATPases
and contract slowly
‹ Color
in red- twitch fibers comes from Fe in myoglobin
‹ Use lots of oxygen
‹ Fatigue resistant, high endurance
Fibers
2. White fast- twitch- pale, wide fibers with fast- acting myosin
ATPases
‹ Contract
rapidly and powerfully
‹ Tires
out
‹ Depend on glycolysis for ATP
Fibers
3. Intermediate fast- twitch- can be red or pink
‹ Intermediate
in size between the other two
‹ Have fast- acting ATPases like the white fibers, but require oxygen
like the red fibers
Fibers
Can contract quickly, but not as fast as white fibers
„ Fatigue resistant, but not as much as red fibers
„ Marathon runners have 80 % slow twitch fibers
„ Sprinters have 60 % fast twitch fibers
„
Smooth Muscle
Makes up walls of organ, except for heart
„ Fibers are small 2-10 um wide and 50-200 long
„
‹ Skeletal
is 1-40 mm long and 10- 100 um wide
Uninucleate
„ Poorly developed SR
„ Nonstriated
„
Characteristics
Ratio of thick to thin filaments is lower in smooth than in
skeletal
„ No troponin- smooth muscle is always ready for contraction
„ No sarcomeres
„ Fibers occur in sheets, usually at cross angles, longitudinal
and circular
„
‹ Allows
peristalsis
Characteristics
Entire sheet responds to a single stimulus
„ Individual cells can relay signal from cell to cell
„ Contraction is slow and long, resistant to fatigue
„ Low energy requirements, few mitochondria, uses anaerobic
respiration
„
Smooth Muscle
Can stretch more than skeletal muscles-no sarcomeres
„ Skeletal can contract or stretch 30 %- total 60 %
„ Smooth can double in length (200 %) or contract to half (50
%)
„
Miscellaneous
Skeletal muscle is 36 % of body weight in women, 42 % in
men
„ Muscular dystrophy- lacks dystrophin- muscles atrophychild needs wheelchair by age 12- dies in 20’s
„ Aging- CT in muscles increase, # fibers decrease, muscles
become stringy
„ Lose 50% muscle strength by 80- smooth muscle is ok
„