Lecture 1 The Muscular Tissue PDF

Summary

This document covers the histology of muscular tissue, discussing skeletal, cardiac, and smooth muscle. It explains the structure, function, and types of muscle tissue, and touches on related medical applications.

Full Transcript

PROF Dr Noha A Makhlouf

The MUSCULAR
TISSUE
Lecture 1: Histology of muscular
By the end of the lecture the student will be able to :
tissue.
Classify the muscular tissue according to structure & function.
Describe the organization of skeletal muscle and its surrounding connective tissue.
Describe the types and characters of skeletal muscle fibers.
Describe the LM & EM structure of skeletal muscle fibers and the correlated function.
Define the sarcomere.
Describe the ultrastructure of sarcomere and different filaments and the bands.
Identify regulation of sarcoplasmic contraction and its deficiency.
Correlate the disturbed structure to different clinical conditions (e.g. Duchenne’s Muscular
Dystrophy)
Describe regeneration in skeletal muscle, muscular atrophy & hypertrophy in different situations.
Describe the LM & EM structure of cardiac muscle fibers and the correlated function.
Identify the contractile properties of cardiac myocytes.
Discriminate sarcoplasmic reticulum organization in different types of muscles.
Describe smooth muscle structure.
State the mechanism of contraction of smooth muscle and its regulation.
Compare between different types of muscles(skeletal, cardiac and smooth).
Compare between regeneration, atrophy & hypertrophy in the three types of muscle fibers.
Classification
1. According to morphology:
A. Striated B. Non striated

2. According to function:
A. Voluntary B. Involuntry
TYPES OF MUSCLE
1.Skeletal muscle: striated &voluntary
2.Cardiac muscle: striated & involuntary
3.Smooth muscle: non striated & involuntary

Terms:
Sarco
Myo
mysium
 Skeletal muscle
Muscle responsible for voluntary movement.

Sites:
Muscle attached to skeleton
Face muscles.
Eye muscle.
Tongue muscle.
The diaphragm (involuntary).
 Connective tissue of
skeletal muscle
1) Epimysium: dense CT covers the
whole muscle.
2) Perimysium: dense CT surrounding
each muscle bundle (fascicles).
3) Endomysium: loose CT surrounds
individual muscle fibers.
Function: it carries blood vessels &
lymphatic & nerves to muscle fibers.
C.T also firmly attach the muscle
bundles together.
Skeletal Muscle
▪ Shape and size :The muscle cell (fiber) is a
contractile cell called muscle fiber (myocyte).
▪ Fibers are long cylindrical (1-40mm length) and
appear polygonal in cross section.
▪ Fibers don’t branch (except in tongue and face)
▪ Structure:
▪ 1- L/M:
▪ Cell membrane (sarcolemma): is distinct
▪ Nuclei: multiple, oval and peripheral in position.
▪ Cytoplasm (sarcoplasm): acidophilic, shows clear
transverse striation (alternating dark and light
bands).
▪ 2-polarized microscope:
▪ The dark band is called anisotropic or A band
▪ The light band is called isotropic or I band
3-E/M of skeletal muscle
A-Membranous organelles:
1-well developed SER named sarcoplasmic reticulum
2. Rows of mitochondria in-between myofibrils
3. Numerous golgi apparatus.
4. Few RER.
5. Inclusions:-myoglobin & glycogen.
 3-Electron microscope of skeletal muscle
B-Non membranous organelles:
1-well developed parallel longitudinally arranged myofibrils composed of
myofilaments (thick and thin filaments)
2. Few ribosomes.
C-Inclusions:-myoglobin & glycogen.
 Sarcomere
 Inclusions
❑ Glycogen acts as a source of
energy for muscle contraction
❑ Myoglobin:-
It is Oxygen binding protein.
It is functionally & chemically
related to HB
It is red to brown in color
according to its concentration
in muscle fibers:-
1) Red fibers
2) White fibers
 1) Red fibers (type 1) 1) White fibers ( type 2)
❖ Small in diameter ❖ Larger
❖ Large amount of ❖ Less myoglobin
myoglobin ❖ More glycogen (pale)
❖ Many mitochondria. ❖ Few mitochondria
❖ Rich in oxidative ❖ Poor in oxidative
enzymes. enzymes.
Types of sk. ❖ Gets energy from aerobic ❖ Gets energy from
M. oxidative glycolysis.
phosphorylation of FAs.
❖ Slow continuous ❖ Fast (sprinting), and in
contraction over time fingers(playing music &
(long distance running) computer games)
and muscles of posture
of the back. ❖ Easily fatigued
❖ Not easily fatigued
 Skeletal muscle fibers contain myofibrils that lie in
the sarcoplasm (cytoplasm ) parallel to the long axis
of the muscle fibers.
Myofibrils consist of series of sarcomeres that
consist of thin & thick filaments.

Myofibrils
 The arrangement of myofibrils beside each other shows transverse striations.
Each dark band of one myofibril is present beside the dark band of the adjacent
myofibril and so on.
These arrangements of dark and light bands give the muscle fiber the
appearance of transverse striations.
The transverse striations in the muscle fiber are due to presence of alternating
dark and light bands on each myofibril.. Myofibrils
Sarcomere
Thick filaments occupy the central portion of the sarcomere.
Thin filaments attach to the z line and run parallel to & between
thick filaments but not reaching the center of A band.
I band is composed of thin filaments only.
A bands are formed of thick filaments & thin filaments between
them.
H band is formed of thick filaments only.
M line is a dark line in the middle of the H zone
 Sarcomere
Definition: It is the basic unit of contraction of striated muscle,
It is the distance between 2 successive Z line.
By EM:
1-Dark bands (A bands)in the middle of the sarcomere & are
composed of thick filaments & thin filaments between them. In
the center of A band a paler region, H zone, is seen in relaxed
muscle
2-Light bands (I bands): are composed of thin filaments only.
Darker transverse line, the Z line, bisects each I band.
3-H bands: are composed of thick filaments only.
The sarcomere consists of : dark band in the middle and Half of
light band (I band) on either side.
Z lines.(α actinin)
 Item Light band (I band) Dark band (A band)

L/M Pale acidophilic Dark acidophilic

E/M Light with central dark Z dark with lighter H zone
line and middle dark M line.

Molecular Only actin Both actin and myosin
structure
 Desmin
a. Arrangement of myofibrils
results in a characteristic
banding (alternating dark &
light bands.
b. Intermediate filament called
desmin; joins Z disks of
adjacent myofibrils together.
Medical application
Desmin-related myopathy (DRM)
The absence of desmin results in disorganized myofilaments and
skeletal muscle fibers.
The symptoms of the disease begin as progressive weakness in the
muscles of the legs, followed by the rest of the body.
DRM can affect cardiac muscles also (fatal).
Medical application
Duchenne muscular dystrophy
(DMD)
Dystrophin is a protein that binds actin
& link it with the sarcolemma of skeletal
muscle fibers then to extracellular
matrix.
Duchenne muscular dystrophy: a defect
in dystrophin can lead to atrophy of
muscle fibers.
 Sarcomere (thin & thick filaments) nice to know
Consist of 3 types of proteins: actin ,
troponin, tropomyosin.
Actin is formed of (f actin) 2 strands of
globular G-actin twisted in double helix.
Tropomyosin are filaments in the grooves of
actin.
Troponin It is present in skeletal & cardiac
muscle only.
Thick filaments consist of myosin (has a tail
and two heads). The heads are active sites
The transverse tubular system
T-tubule
Definition: finger like invagination of the
sarcolemma that surrounds each myofibril.
These invaginations constitute the transverse T
tubule system.
-The sarcolemma sends this transverse(T-tubules)
invagination into sarcoplasm at A-I junction
Function: It conducts the impulse from outer
to deeper parts of skeletal muscle.
 Sarcoplasmic Reticulum
It is SER
Consists of longitudinal network and transverse parts. The transverse part is called terminal
cisternae.
Each t tubule lies between 2 terminal cisternae of the sarcoplasmic reticulum to form a triad.
There are 2 triads in each sarcomere which are present in the junction between A and I bands
(A-I junction).
Function:- regulation of muscle contraction by releasing or sequestering Calcium. these units
serve to couple excitation of muscle cells to their contraction (excitation contraction coupling.
 Contraction of the muscle
✔ when nerve impulse arrives, the wave of
depolarization sweeps along sarcolemma
into T- tubules
✔ Depolarization of T- tubules releases Ca
from sER + energy from ATP in mitochondria
lead to interaction of actin & myosin pushing
the 2 z lines inward shortening the distance
between them & muscle contraction.
During muscle contraction: H zone
disappears as it contains now both actin &
myosin. I band decreases in length while A
band remains the same.
The sarcomere & whole myofibril are
shortened.
Growth & Growth:-

1.In length{by satellite cells}
regeneration 2.In width{by synthysis of new proteins by ribosomes}
of skeletal Regeneration:-

muscle By activity of satellite cells.
Satellite cells
After injury the satellite cells become activated,
proliferating and fusing to form new skeletal muscle fibers
Effect of exercise on
muscle
During prolonged inactivity: muscle shrink in
mass (disuse atrophy)
Exercise (strength training: muscle
contraction against resistance, e.g weight
lifting) increases the muscle size
(hypertrophy) without increase in number of
muscle fibers.
Medical application Anabolic steroid use
is used by athletes to
increase their muscle
mass with serious
side effects.
The presence of
anabolic steroids is
detectable in the
body fluids for 6
months after the last
dose was taken.
 Cardiac muscle
Contract spontaneously & display
rhythmic beat.
Shape and size: 1-Fibers are formed
of individual short cylinderical cells
connected together by cell junction
to form long fibers.
These junctions are called
Intercalated discs
2-Fibers branch & anastomose
forming network.
3-fibers are intermediate in
diameter between skeletal &
smooth m.
 Cardiac muscle

L/M:
Nucleus: mono or binucleated, oval
and central.
Cytoplasm: acidophilic and shows less
distinct striation than that in skeletal
muscle. Thick and thin filaments
arranged in poorly defined myofibrils.
 EM
1. Mitochondria are more abundant than in
skeletal muscle.
2. Sarcoplasmic Reticulum:- SR is poorly
defined and contributes to the formation
of diads, each of which consists of one T
tubule and one profile of SR at the level of
Z- line.
3-T tubules are larger than those in skeletal
muscle associated with sarcoplasmic
reticulum at the Z discs not at A–I junctions
as in skeletal muscle.
4. Contain glycogen granules, especially at
either pole of the nucleus, myoglobin.and
lipochrome pigment(increases with the
advance of age. Lippincot pp: 159
 Intercalated discs :a step-like junction forming end to-end attachments between
adjacent cardiac muscle cells.
It consists of transverse & lateral portions.
a. The transverse portion:
1-fasciae adherents: act as anchoring sites for actin filaments
2-Desmosomes (macula adherentes): bind muscle cells together and prevent their
pulling apart under constant contractile activity.
b. The lateral portion : large gap junctions, which facilitate ionic continuity between
cells and aid in coordinating contraction; thus, cardiac muscle behaves as a
functional syncytium.
Regeneration in cardiac muscle.

Cardiac muscle: do not regenerate because they have NO
satellite cells.

Injuries to cardiac muscle are repaired by the formation of
fibrous connective (scar) tissue by fibroblasts.
 Medical application

Glycogen pathway abnormalities:
muscle weakness due to muscle
glycogen accumulation.
Example is Pompe disease, which
causes muscle hypotonia from
lysosomal glucosidase deficiency
(lysosomal enzyme).
Glycogen accumulation leads to
skeletal muscle & heart problems.
 Smooth muscle
Smooth muscle cells are nonstriated & involuntary.
The muscle fiber having broad central part and tapering ends.
Sites:-
1.Wall of blood Vs.
2.Viscera.
3. Erector pili muscle of the skin.
 General appearance

Shape and size: They are small, non
branching spindle (FUSIFORM)shaped
cells
They have the smallest diameter.
They have variable length according to
the site. They range in length from 20
μm in small blood vessels to 500 μm in
the uterus of pregnant women.
They are arranged in layers
{circular,longitudinal or oblique}
Smooth muscle
L/M
Nucleus:- single, oval & central.
Cytoplasm:-
homogenous & acidophilic with no
striations.
Actin & myosin are present but are
arranged irregularly No striation.
 E/M
1-Small darkly stained Dense bodies (formed of α
actinin corresponding to Z line of striated muscle)
along internal surface of plasmalemma and in the
sarcoplasm.
2-Sarcolemma shows caveoli (invaginations): these
function like T tubules in conducting contraction
impulses.
3-T Tubules are not present in smooth muscle
4-No sarcomere
5-SR is poorly defined.
 The intermediate filaments insert into
dense bodies forming lattice like
arrangement.
The intermediate filaments and actin are
inserted into dense bodies.
Muscle fibers are connected by gap
junction that permit rapid passage of an
electrical impulse from one cell to
another.
There is no troponin.
Instead there is calmodulin.
T.S. smooth muscles

L.S. smooth muscle
Regeneration in smooth muscle
Smooth muscle can divide and regenerate.
 Smooth Cardiac Skeletal Item
Involuntary Involuntary Voluntary Action
Wall of blood vessels and Myocardium of heart and Muscles attached to skeleton, tongue, Site
viscera proximal aorta pharynx

Non-striated striated striated Appearance
Distinct Indistinct Distinct Structure
sarcolemma
Single, oval and central One or two, oval and central Numerous, oval and peripheral Nuclei

Irregular arrangement No less Less in amount, branching Numerous, regular distinct striation Myofibrils and
sarcomere distinct striation striation

Absent (replaced by caveolae) Diad at Z- line Triad at A-I junction T tubules

Absent present Absent Intercalated discs
From mitosis can’t occur From satellite cells Regeneration
 Resources

Integrated Systems Lippincott illustrated review,p.121-123
Kaplan medical - Anatomy- muscle pp: 35-40
BRS (board review series) joints p 120
Thank you