1. Skeletal Muscle Histology
ANPS 19
Skeletal Muscle Histology
Dr. Tompkins
Department of Neurological Sciences
Given D408
Reading: Anatomy & Physiology: An Integrative approach, McKinley et al., Chapter 10, Muscle Tissue, pages (Sections )

2. Muscle Tissue Muscle tissue distributed almost everywhere
Some functions of muscular tissue
Produces skeletal movement
Propels food we eat along gastrointestinal tract
Expels waste we produce
Changes amount of air that enters the lung
Pumps the blood to body tissues
(all these functions accomplished by different types of muscle tissue)
- smooth muscle in bladder
- Cardiac muscle

3. Muscle Tissue Three types of muscle tissue:
Skeletal muscle, cardiac muscle, smooth muscle
In contrast to cardiac and smooth muscle, skeletal muscle is under voluntary control
Composes 40-50% of weight of the adult
700 skeletal muscles in the muscular system
Cardiac muscle- more specialized, cells communicate to each other, electrical signals
Smooth muscle- digestive system

4. Skeletal Muscle Functions
Produce skeletal movement
Maintain posture and body position
Support soft tissues
Storage and movement of materials
sphincters - circular bands of skeletal muscle
ensure the voluntary expulsion of feces and urine
Maintain body temperature
sphincters: bladder
Maintain body temperature metabolism

5. Characteristics of Skeletal Muscle Tissue
Excitable - responds to electrical stimulation (like neurons)
Conductive – action potential moves along membrane (like neurons)
Contracts
Elastic
Extendable
-Skeletal Muscle Tissue have resting membrane potential
-Proteins of muscle cells allow contraction
-Elasticity due to coiled protein

6. Levels of Functional Organization in Skeletal Muscle Fiber
-muscle fiber= muscle cell

7. Structural Organization of Skeletal Muscle (Figure 10.1)
A skeletal muscle is composed of thousands of muscle cells, connective tissue, blood vessels & nerves.
Muscle cells (referred to as muscle fibers) are typically as long as the entire muscle.
Bundles of muscle fibers termed fascicles.
Tendon (connects muscle to bone)
Deep fascia (ensheathes functionally distinct muscles)
Epimysium
Skeletal muscle
Artery
The epimysium, perimysium and endomysium are three concentric layers of connective tissue.
Provide protection, sites for blood vessel and nerve distribution, and are a means of attachment to the skeleton or other structures.
- Mysium-association with muscle
Deep fascia connects muscle to tendon
Vein
Perimysium
Nerve
Fascicle
Endomysium
Muscle fiber
(This should look familiar to you. It’s similar to the structure of a nerve.)

8. Organization of connective tissues
Epimysium surrounds whole muscle
Perimysium sheathes bundles of muscle fibers: surrounds fascicles
Epimysium and perimysium contain blood vessels & nerves which branch into the muscle
Endomysium which covers individual muscle fibers
Tendons attach muscle to bone.

9. A cross sectional view of skeletal muscle. Where is the perimysium
A cross sectional view of skeletal muscle. Where is the perimysium? Endomysium?

10. A high magnification view of skeletal muscle in cross section
A high magnification view of skeletal muscle in cross section. C is for capillaries and P is for perimysium. Where is the endomysium?
muscle fiber

11. Longitudinal section of skeletal muscle. Where is the endomysium?
- Muscle fiber as long as muscle
Purple nuclei- multinucleated
Endomysium around each fiber

12. Skeletal muscle fibers formed by fusion of myoblasts
myo- or  ( before a vowel ) my-
from Greek mus muscle
These are the embryonic cells which fuse to form skeletal muscle fibers during development. Each contributes a nucleus to total number of nuclei.
Myoblasts
Muscle fiber
Myoblasts fuse
to form a skeletal
muscle fiber.
Satellite cell
Satellite cells myoblast cells that have not fused with muscle fiber- for regrowth of new fiber
Muscle fiber
Unfused myoblasts termed “satellite cells”. These cells may be stimulated to differentiate if muscle is injured.
Nuclei
Satellite cell
muscle fiber is a multinucleated cell
cytoplasm of muscle fiber termed sarcoplasm
(Figure 10.2)

13. Box of spaghetti
This is a diagram of a muscle fiber or a muscle cell showing the large number of myofibrils in the sarcoplasm

14. Inside a Skeletal Muscle Fiber
Sarcoplasmic
reticulum
the endoplasmic reticulum of a muscle cell
surrounds bundles of contractile proteins (myofibrils)
contains the Ca2+ necessary for muscle contraction
Muscle
Triad
Fascicle
part of the sarcoplasmic reticulum
a reservoir for Ca2+ ions
- 2 terminal cisternae + 1 T-tubule = 1 Triad
T-tubule
Terminal
cisternae
Muscle fiber
- plasma membrane of the muscle fiber
- invaginations of this membrane termed T-tubules or transverse tubules
Sarcolemma
Nucleus
- long cylindrical structure of fibers
- extend length of muscle fiber
- 80% of muscle fiber volume
- each fiber has hundreds to thousands
Myofibrils
Sacro: muscle
T tubules: pipes from outside into cell, connection with SR
Terminal cisternae- storage tanks for Ca ions, where ca ions released from when action potential comes in
Myofilaments
protein filaments
thick and thin
Nucleus
Openings into
T-tubules
Sarcoplasm
Sarcomere
Nucleus
- functional unit of myofibril
Mitochondrion
(a) Skeletal muscle fiber
(Figure 10.3 a)

16. Cross section of skeletal muscle fibers in which myofibrils can be seen.

17. Molecular Structure of Thick and Thin Filaments (Figure 10.4)
Muscle fiber
Myofilaments
Myofibril
- come in ‘thick’ and ‘thin’
Myosin molecule
Heads
Tail
Actin binding site
ATP and ATPase binding site
Myosin heads
Myosin molecule: intertwined
Thin filament: composed of Actin molecules (g-actin=globular actin, fibrous strand actin=f-actin)
Tropomyosin- twine for actin, covers myosin binding sites
Troponin= calcium sensor
(a) Thick filament
Tropomyosin
Troponin
Ca2+ binding site
G-actin
F-actin
Myosin binding site
(b) Thin filament

18. Molecular Structure of Thick and Thin Filaments (Figure 10.4)
Myosin molecule
Heads
Actin binding site
ATP and ATPase binding site
Myosin heads
Tail
Thick filaments
assembled from bundles of protein molecules, myosin
each myosin protein has two intertwined strands
each strand has globular head and elongated tail
tails pointing toward center of thick filaments
heads pointing toward edges of thick filaments
head with a binding site for actin (on thin filaments)
head has site where ATP attaches and is split by ATPase

19. Molecular Structure of Thick and Thin Filaments (Figure 10.4)
Tropomyosin
- globular protein attached to tropomyosin
- has binding site for Ca2+
- together form troponin-tropomyosin complex
Troponin
- twisted stringlike protein
- covers small bands of F-actin
- covers myosin binding sites in noncontracting muscle
G-actin
Tropomyosin
F-actin
Myosin binding site
Troponin
Ca2+ binding site
Thin filaments
composed primarily of two strands of actin
strands twisted around one another
actin strands composed of spherical molecules, globular actin (G-actin)
connect to form a fibrous strand, filamentous actin (F-actin)
G-actin has myosin binding site - where myosin head attaches during contraction
We will learn more about how these proteins work together in the next lecture.

20. Organization of a Sarcomere
Myofibrils consist of repeating units called sarcomeres.
- number varies with length of myofibril.
- composed of overlapping thick and thin filaments
- delineated at both ends by Z discs
A band (DARK regions)
- central region of sarcomere
- contains entire thick filament
- contains partially overlapping thin filaments
- appears dark under a microscope
Muscle fiber
Sarcomeres
Myofilaments
Myofibril
I band
A band
Z disc
H zone
M line
Sarcomere
(Figure 10.5 a)
Z discs
- contains specialized proteins running perpendicular to myofilaments which anchor thin filaments
I bands (LIGHT regions)
- contains only thin filaments
- extend from both directions of Z disc
- appear light under a microscope
- disappear at maximal muscle contraction
H zone
- central portion of A band
- only thick filaments present; no thin filaments
- disappears during maximal muscle contraction
M line
- protein meshwork structure at center of H zone
- attachment site for thick filaments

21. A Sarcomere: The Functional Unit of Skeletal Muscle Contraction
Connectin
(Titin)
Z disc
Thin filament
Thick filament
Sarcomere
I band
A band
H zone
M line
- Z disc- specialized proteins that anchor filaments
A band can contain either thick or thin filaments
Connectin- coiled protein gives springy nature to muscles
H zone- only thick filaments, when muscle contracts, H zone fully disappears
M line- proteins that contain thick filaments in place
(LIGHT)
(DARK)
(Figure 10.5 b)

22. Specific Banding Patterns in a Skeletal Muscle Fiber
I – I band
Z – Z disk
A – A band
N – nucleus
These units aligned in a single fiber which contains many stacked myofibrils.

23. Structure of a Sarcomere
Transverse
sectional plane
M line
Thick filaments
and accessory
proteins
H zone
Thick filaments
A band
Thick filaments
Thin filaments
I band
Thin filaments
Connectin
Z disc
Thin filaments
Connectin
and accessory
proteins
(Figure 10.5 c)

24. Sarcomere Shortening (Figure 10.12) Relaxed sarcomere
Z disc
Thick filament
Z disc
Connectin
Thin filament
Thin filament
M line
Z disc
Z disc
M line
H zone
H zone
I band
A band
I band
I band
A band
I band
(a) Relaxed skeletal muscle
Contraction
Contraction
M line
Z disc
Z disc
Z disc
Z disc
M line
A band
A band
Fully contracted
sarcomere
Fully contracted
sarcomere
(b) Fully contracted skeletal muscle
(Figure 10.12)

25. Summary:
Sacromere (many)  myofibril (thousands)  muscle fiber muscle fasicle  skeletal muscle  muscles of muscular system