Lecture 7 Muscle Tissue Notes PDF

Summary

These lecture notes provide an overview of muscle tissue, including descriptions of skeletal, cardiac, and smooth muscles. The notes cover the characteristics, structure, functions, and sources of ATP for each type of muscle. The notes also mention the concept of motor units and the sliding filament model of muscle contraction.

Full Transcript

Muscle Tissue
Dr. Elita Partosoedarso
Links to the segment recordings: Part A, Part B

1
 Muscle Tissue overview
Properties

Basics Types of muscles
Basics of smooth and cardiac
muscle
Cells
Structure of the
Myofilament
Muscle Tissue

skeletal muscle
Sarcomere
Neuromuscular Junction
Function of the Contraction of skeletal muscle
skeletal muscle
Relaxation of skeletal muscle
Sources of ATP
Others Muscle tension
Motor unit
2
General Properties
of Muscle Tissue Characteristics of ALL Functions of skeletal
muscles
1. Contractility: ability to 1.muscles
Posture: Continuous partial
contract (shorten) and relax contraction of some skeletal muscles
to produce movement lead to sitting, standing and staying
2. Extensibility: ability to still
extend, or stretch, to allow 2. Heat production: Catabolic process
muscles to return to their which produces body heat and
resting length maintains homeostasis
3. Excitability (irritability): 3. Movement: pulls on bones (other
ability to be stimulated and muscles) to move the body as a
respond to regulatory signals whole or its parts
from nerves, hormones & 4. Protection: covers internal organs,
local stimuli supports weight of organs, keeps
joints and bones from being over
stressed
All muscles are also richly supplied by blood vessels for
nourishment, oxygen delivery, and waste removal
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Types of Muscle Tissue
1.Skeletal muscle
○ Structure (anatomy): multinucleated, Regular arrangement of
actin and myosin fibers into bands of light and dark (striated)
○ Function (physiology): move the skeleton, especially the limbs
○ Location: usually connected to bones or fascia

2.Cardiac muscle
○ Structure (anatomy): 1-2 nuclei, branching cells with
intercalated disks organized as a syncytium to allow for
coordinated contraction
○ Function (physiology): pump blood through the circulatory
system
○ Location: Heart

3.Smooth muscle
○ Structure (anatomy): 1 nucleus, no regular arrangement of
actin and myosin proteins in cytoplasm (non-striated/smooth)
○ Function (physiology): Goosebumps, moves food through
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digestive tract, blood through circulatory system
 Characteristics of Cardiac
Muscle

1.Highly coordinated contractions of cardiac muscle pump blood into blood
vessels of the circulatory system. Pacemaker cells control rate of cardiac
contractions
2.Similarity with skeletal muscle: striated, organized into sarcomeres
3.Differences with skeletal muscle: only 1-2 nuclei, multiple mitochondria
and myoglobin, extensively branched fibers cells, intercalated discs.
4.Intercalated discs consist of sarcolemma with gap junctions &
desmosomes which allow heart to work as a pump by coordinating
cardiac contraction
Gap junctions: channels between adjacent cells that allow ions to flow
from one cell to another quickly. Depolarization spreads quickly between
cells to allow for coordinated contraction of entire heart. This electric
coupling creates a syncytium (functional unit of contraction).
Desmosomes anchor the ends of cardiac muscle fibers together so the
cells do not pull apart during the stress of individual fibers contracting 5
 Smooth Muscle

1.Similarity with skeletal muscle: actin & myosin contractile
proteins, thick & thin filaments.
2.Differences with skeletal muscle: 1 nucleus, spindle-
shaped , no striations, sarcomere, troponin, tropomyosin
3.Thin filaments are anchored by dense bodies (similar to
Z-discs) attached to sarcolemma.
4.Ca++ enters sarcoplasm from SR and ECF and binds to
regulatory protein calmodulin

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Structure of a skeletal
Three layers of connective tissue enclose a muscle
to provides structure while compartmentalizing
fibers within it
1
1
1.Epimysium
sheath of dense, irregular connective tissue
around each muscle organ
allows a muscle to contract/move while
muscle

2
maintaining structural integrity
separates muscle from other regional

Deeper
3
2 tissues/organs in the area, allowing
independently movement
2.Perimysium
middle layer of connective tissue
3 allows nervous system to trigger a specific
movement of a muscle by activating fascicle
3.Endomysium
thin layer of collagen and reticular fibers around
each muscle fiber
organizes muscle fibers into fascicle (individual
bundles)
contains extracellular fluid and nutrients 7
 Skeletal Muscle Fibers (Cells)
Skeletal muscle cells are also called muscle fibers as they
are long and cylindrical
During early development, embryonic myoblasts, each with
its own nucleus, fuse with up to hundreds of other
myoblasts to form the multinucleated skeletal muscle fibers
(myofibrils) with multiple copies of genes to allow bulk
production of proteins and enzymes for muscle contraction.

1
1. Sarcolemma: plasma membrane of muscle fibers
2. Sarcoplasm: cytoplasm of muscle fibers
3.
3 Sarcoplasmic reticulum (SR): specialized smooth
endoplasmic reticulum: stores, releases, and retrieves
4 calcium ions (Ca++)
4. Sarcomere: functional unit of skeletal muscle fiber:
highly organized arrangement of contractile
proteins (actin, myosin myofilaments) and regulatory
proteins (troponin, tropomyosin)
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 The Sarcomere (functional unit of skeletal
muscles)
The sarcomere is the functional unit of skeletal
muscles: 3D cylinders with striations (bands of light
and dark due to arrangement of actin and myosin
myofilaments)
Each myofibril can contain 100-1000s sarcomeres
connected end to end
All sarcomeres within a myofibril contracts (and
relaxes) simultaneously, contracting (and relaxing)
the entire myofibril & muscle cell

1.Thin filament
Starts from Z-discs and projects partway to the
center
consists of thinner actin strands and its troponin-
tropomyosin complex
2.Thick filament
Starts from the center and projects partway to
the Z-discs
consists of thicker strands and their multiple
heads
3.Z-discs (Z-lines) 9
Forms the boundary of sarcomeres at both ends
 Myofilaments
▪ Each myofibril contains 1000s of thick and thin
myofilaments
▪ Four different kinds of protein molecules make up
myofilaments

1
Protein molecules
1.
2 Actin (thin filaments): contains active sites (myosin
binding sites) which bind to myosin heads
2.
3 Myosin (thick filament): Contains myosin heads that
are chemically attracted to actin and forms cross
4 bridges with actin

3. Tropomyosin (regulatory protein): at rest, it blocks
the myosin binding sites on actin molecules when
4. Troponin (regulatory protein): at rest, it holds
tropomyosin in place, can bind to calcium (Ca2+)
ions

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The Neuromuscular Junction

Ion
1.Location: site where nerve ending meets the muscle
channel
fiber
2.All living cells have membrane potentials (electrical
gradients across their membranes): -60 to -90 mV
3.When the membrane potential becomes LESS negative,
depolarization occurs and an action potential can start
4.Membrane potentials change when ions either enter or
leave the cell through ion channels which can open and
close depending on the stimuli. This change generates
electrical signals (action potential) which travel quickly
over long distances. An action potential in a nerve at the
NMJ releases a neurotransmitter which leads to the start
of an action potential in the muscle. This action potential
in the muscle causes muscle contraction (Excitation-
contraction coupling)
5.Every skeletal muscle fiber is innervated by a motor
neuron at the NMJ 11
A signal from the motor neuron can cause the
 Contraction of a skeletal muscle Part 1
Action potential (AP) reaches the end of the motor 1
neuron
Neurotransmitter (acetylcholine or ACh) is released
into the NMJ
ACh binds to specific receptors on ligand gated ion 2
channels for sodium on the skeletal muscle fiber

1
Sodium channels open: sodium enters sarcoplasm of 3
muscle fiber
Membrane potential of muscle fiber changes
AP starts along the sarcolemma of muscle fiber: AP
4
travels into the interior of the cell via T-tubules
(extensions of the sarcolemma)
Continued on the next
slide
4

2

3
4
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 Contraction of a skeletal muscle
AP starts along the sarcolemma Part
of muscle2 fiber: AP travels into
the interior of the skeletal muscle cell via T-tubules (extensions4
4

of the sarcolemma)
SR: Sarcoplasmic
Reticulum
Action potential depolarizes the cell membrane 5
Ca++ : Calcium ions
Voltage-gated Ca++ channels Ca++ diffuses out of SR into
5
in SR sarcoplasm
Ca++ binds to troponin on thin filament 6 6
Troponin-tropomyosin complex moves to expose myosin-binding
sites 7

Myosin binds actin at its myosin-binding site to form cross-
7
bridge 8
Adenosine diphosphate (ADP) and inorganic phosphate (Pi)
generated in the previous contraction cycle are released

Myosin head pivots toward M-line at center of the sarcomere- 8
power stroke
New ATP attaches to the myosin head
9
9
Cross-bridge is detached
ATPase in myosin head Angle of myosin head moves into a
hydrolyzes ATP to ADP cocked position (re-cock), ready to 10
and Pi, releasing form another crossbridge with next 10
energy myosin -binding site
Cross-bridge cycling: power stroke, detach, re-cock, power stroke,
Sliding Filament Model of Contraction

1.Overview: contraction of skeletal muscle fiber contracts as the
thin filaments are pulled and then slide past the thick filaments
within the fiber’s sarcomeres

2.Requires Ca++ and ATP
Ca++ initiates contraction by exposing actin-binding site to
form myosin crossbridges
ATP sustains contraction: Each cycle in cross-bridge cycling
requires energy provided by hydrolysis of ATP
Without ATP, the myosin head remains attached to actin: rigor
mortis
Myosin is in a high-energy configuration when myosin head is
cocked: this energy is used during the power stroke

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 Relaxation of a Muscle Fiber
Muscle contraction usually stops when 1
Nerve signal stops
Muscle runs out of ATP and becomes 2 4 5
fatigued
3
Nerve signal stops 1

Release of ACh stops 2
6

Ligand gated Na+ channels close 3

7
Sarcolemma and T-tubules repolarizes 4

Voltage-gated Ca++ channels in the SR 5 8
close
Ca++ ions are pumped back into SR using 6
ATP
Tropomyosin moves to cover myosin- 7
binding sites
Thick and thin filament interaction 8
relaxes
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 Skeletal muscle only has a small amount of ATP
stored
In order to sustain contraction, ATP must be 1
Sources of ATP
replaced quickly
1
Sources of ATP
1. Creatine phosphate: Excess ATP transfers
energy by producing ADP and creatine
phosphate. When energy is needed, creatine
2 phosphate transfers its phosphate back to ADP
2
to form ATP and creatine. Can only provide 15
seconds worth of energy
3 Glycolysis anaerobic breakdown of glucose to
2.
produce ATP, at a slower rate than creatinine
phosphate. Provides 1 minute burst of energy
3. Aerobic respiration aerobic breakdown of
glucose or other nutrients in the presence of
3
oxygen (O2) to produce carbon dioxide, water,
and ATP. More efficient, produces 95% of ATP

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 Motor Units
1
Each skeletal muscle fiber is innervated by only one motor neuron.
Each motor neuron innervates more than one muscle fiber, the
number depends on the nature of the muscle

1.Motor
1 unit: group of muscle fibers innervated by a single motor skeletal muscle fiber

neuron
Small motor units can innervate less than 10 muscle fibers and
permit very fine motor control of the muscle, eg eyeball
movements. have smaller, lower-threshold motor neurons that are
more excitable
Larger motor units can supply 1000s of muscle fibers in a muscle
are concerned with simple, or “gross,” movements, eg thigh
2 muscles. bigger, higher-threshold motor neurons
2

2.Recruitment process where smaller motor units tend to be
recruited first before larger ones, increasing the muscle contraction.
Recruitment of more motor units will increase the strength of
muscle contraction: allows for variation in picking up a feather vs a
heavy weight.
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