Muscles and Muscle Tissue PDF

Summary

This chapter explores muscle tissue, including its three types: skeletal, cardiac, and smooth. It describes their structure, characteristics, and functions. The text also touches upon the importance of muscles in movement, posture, and heat generation.

Full Transcript

Muscles and
Muscle Tissue
In t his c hapter , you will learn that

Muscles use actin and myosin molecules to convert the energy of ATP into force

I

...,

beginning w ith

Overview of muscle
types, special characteristics,
and functions

...,

next exploring

I

...,

and investigating

"'
I

...,

...,

and asking

then asking

9.2
and

then exploring

•

.J,
•

and

How does smooth muscle
differ from skelet al muscle?

•

r

.J,

- and
- -finally,
- -exploring
- - - .,
Developmental Aspects
of

L

and

-

-

- -

- -

-

-

...J

and

CAREER CONNECTION
and

O

Watch a video to learn how
the chapter content is used
in a real health ca re setting.
Go to Mastering A&P® > Study A rea >
Animations and Videos or use quick
access URL https://goo.gl/88srfV

279

280

UNIT 2 Covering, Support, and Movement of the Body

Card iac Muscle

Because f lexing muscles look like mice scurrying beneath
the skin, some scientist long ago dubbed them muscles, from the
Latin nius meaning "little mouse." Indeed, we tend to think of
the rippl ing muscles of professional boxers or weight lifters
when we hear the word 111uscle. But muscle is also the dominant
tissue in the heart and in the walls of other hollow organs. In all
its forms, muscle tissue makes up nearly half the body's mass.
Muscles are distinguished by their ability to transfonn chemical energy (ATP) into directed mechanical energy. In so doing,
they become capable of exerting force.

Cardiac muscle tissue occurs only in the heart, where it constitutes the bulk of the heart walls. Li ke skeletal muscle cells,
cardiac muscle cells are striated, but cardiac muscle is not voluntary. Indeed, it can and does contract without being stimulated by the nervous sys tem. Most of us have no consc ious
control over how fast our heart beats.
• Key words to remember for cardiac muscle are cardiac, striGirvcleated
ated, and involuntary.
↓

Cardiac muscle usually contracts at a fairly steady rate set
by the heart's pacemaker, but neural controls allow the heart to
speed up for brief periods, as whe n you race across the te nnis
court to make that overhead smash.

There are three types
of muscle tissue

Smooth Muscle

Learning Outcomes

Smooth muscle tissue is found in the walls of hollow visceral
organs, such as the stomach, urinary bladder, and respiratory
passages. Its role is to force flu ids and other substances through
internal body channels. Smooth muscle also forms valves to
regulate the passage of substances through internal body openings, d ilates and constricts the pupils of your eyes, and forms
the arrector pili muscles attached to hair follicles.
L ike skele ta l muscle, smooth muscle consists of elongated
cells, but smooth muscle has no striations. Like cardiac muscle,
smooth muscle is not subject to voluntary control. Its contractions are slow and sustained.

II- Com pare and contrast the three basic types of
muscle tissue.
II- List fo ur important functions of muscle t issue.

Types of Muscle Tissue
Chapter 4 introduced the three types of muscle tissue-skeletal,
cardiac, and snwoth ( <1111 pp. 138- 140). In this chapter, we first
examine the structure and function of skeletal muscle. Then we
consider smooth muscle more briefly, largely by comparing it
\Vith skeletal muscle. We describe cardiac muscle in detail in
Chapter 18, but for easy comparison, Table 9.3 on pp. 312-3 13
summarizes the characteristics of all three muscle types.
Let's introduce some term inology before we describe each
type of muscle.

• We can describe smooth muscle tissue as visceral, non.striated, and involuntary.

named in muscles

"Sarcoplasmic

• Skeletal and smooth muscle cells (but not card iac muscle
cells) are elongated, and are called muscl e fibers. endoplasmic
•

reticulum"

Characteristics of Muscle Tissue

a

⑤
Whenever you see the prefixes 1nyo or 1nys (both are word

What enables ,nuscle tissue to perform its duties? Four special
important
characteristics
are key. mousin (Contractical
facilitate between

reticular is

roots meaning "muscle") or sarco (flesh), the reference is to
muscle. For example, the plasma me,nbrane of muscle cells
is called the sarcolem111a (sar"ko-Jem'ah), literally, "muscle"
(sarco) "husk" (lemma), and muscle cell cytoplasm is called
sa rcoplas,n.
Okay, Jet's get to it.

Skeletal Muscle

having

Since[a

actin and

->

is essential

and its

• Excitability, also termed responsiveness, is the ability of a
cell to receive and respond to a stimulus by changing its membrane potential. In the case of muscle, the stimulus is usually
a chemical-for example, a neurotransmitter released by a
be
nerve cell. e recenters that bind technics

stored there

of

recessed

Slower

↑

large

Arclecules

agg
are
an membranes I

>

the ability to

ofeffort,

and the

S

contract will require certain amount

ability of the sells to utilize ATD.

whererates

the ATR

• Contr actility is the ab ility to shorten forcibly when adequately stimulated. T his ability sets muscle apart from all
other tissue types. MadiateourrepbetweenIrelaxedoverloopsanerlur
• Extensibility is the ability to extend or stretch. Muscle cells
shorten when contract ing, but they can be stretc hed, even
beyond their rest ing le ngth, when relaxed. back

Skeletal 1nuscle tissue is packaged into the skeletal ,nuscles, from
organs that attach toelongated
and cover the skeleton. Skeletal muscle
represent
fibers are the lo ngest muscle cells and have obvious stripes
the alligme<
Relaxed
restiny length
Myo filamentscalled striations. Al though it is often activated by reflexes,
•
Elas
ticity
is
the
ability
of
a
muscle
cell
to
recoil
and
resume
muscle is called voluntary 111uscle because it is the only
actie/musin skeletal
its resting length after stretching. heart
amount of ATP
getting
cells
type subj ect to conscious control.
trop I
there's consequences. like
recoil
if

dfaster

to its

of

the sufficient

on in

tropomyosin

• When you think of skeletal muscle tissue, the key words to
time
keep in mind are skeletal, striated, and voluntary.
Without

and multi

muscle

exercise for
long period of

excessive

not

restiny

nucleated

and resume

after

contraction

Muscle Functions

or

proper
Skeletal muscle is responsible for overall body mobility. It can intake, Muscles perform at least four important functions for the
all three
contract rapidly, but it tires easily and n1ust rest after short periods eventually body:
get
of activity. Nevertheless, it can exert tremendous power. Skeletal Muscle
• Produce movement. Skeletal ,nuscles are responsible for all
muscle is also remarkably adaptable. For example, your forearm fatigue. locomotion and manipulation. They e nable you to respond
muscles can exert a force of a fraction of an ounce to pick up a
quickly to jump out of the way of a car, direct your eyes, and
paper clip--0r a force of about 6 pounds to pick up this book!
smile or frown.
On

Will

muscle cells

May

go

through

the cellular components

or

acids

generated when

muscle cell

dont have enough

(they will be

able

ATR
to contract but there

will

be

a

drawback)

in the muscle

function

usofto

ions

Masks

in summary

Skeletal
long,

muscles
#

stricted, Multialted

Smooth

↓

key

:

term

"spindle

shape

from its

muscles

toT

end

packed making
together closely

:stricted, veinin
and connected
interculated

discs

more

name

cardiac muscle

with

(has

*
**

(specialized functions

I for fast communication because heart muscles

contract

constantly, (

sheets

than

one)

Sympathetic
and

nervous

Control

few

With out
you

knowing
Smooth and Cardin

muscle

~athelete

system

unconsciously

desirable

more

parasympathetic

has

one

which

or

-

engage all

A

they

specific part
on
enlarging it

work

body building

of muscles

Chapter 9 Muscles and Muscle Tissue

brokhwlard

->

S

contraction

Since

skeleful

completely

disagrees about that

muscles

Blood courses through your body because of the rhythmically beating cardiac
muscle of your heart and the smooth muscle in the walls of your blood vessels, which
helps maintain blood pressure. Smooth muscle in organs of the digestive, uri nary, and
reproductive tracts propels substances (foodstuffs, uri ne, semen) through the organs
and along the tract.
Since they're
the flesh of the
called

body

• Ma inta in posture a nd bod y position. We are rarely aware of the skeletal muscles
that maintain body posture. Yet these muscles function almost continuously, maki ng
o ne tiny adj ustment after another to cou nteract the never-ending dow nward pull of
slain, there
layers, (epidermis, dermis,
gravity. Whenever
hypodermis/adipose) there's muscle,
face, skeletal muscles
you

see

are

the

even

• Sta bilize joints. Even as they pull o n bones to cause movement, they strengthen and
stabilize the joints of the skeleton. elbow, knee, wrists. Support by skeletal muscles, facilitate joint

Contract
d
&
Kinetic
d
beat

movement

(a)

• Generate heat. Muscles generate heat as they contract, which plays a role in mainvasoconstriction
taining normal body temperature.
vasodilation

- -

- mediated by
muscles

Check Your Understanding
1. When describing muscle, what does "striated" mean ?
2.
At right are photomicrographs of three types of muscle tissue
(introduced in Chapter 4). For each, identify the type of muscle, state whether it
is striated, whether it is volunta ry, and its major location. Create a short table that
summarizes this information.

--

- -··-·

-------------===="'"'- For answers, see Answers Appendix.
A skeletal muscle is made up of muscle fibers,
nerves, blood vessels, and connective tissues

(b)

Learning Outcome
ll> Describe t he g ross struct ure of a skeletal muscle.
is migue

individually

separate

Each skeletal muscle is a d iscrete organ, made up of several ki nds of tissues. Skeletal
muscle fibers predominate, but blood vessels, nerve fibers, and substantial amounts of
all
con nective tissue are also present. We can easily examine a skeletal muscle 's shape and
found
there
its attachments in the body without a microscope.
in

Nerve and Blood Supply
nerve end

waste

managment

accomplishingaftermuscle contractas

->

~

In general, one nerve, one artery, and o ne or more veins serve each muscle. These structures all enter or exit near the central part of the muscle and branch profusely through its
con nective tissue sheaths (described below). Unlike cells of cardiac and smooth muscle
tissues, which can contract without nerve stirn ulation, every skeletal rnuscle fiber is supplied with a nerve ending that controls its activity.
Skeletal muscle has a rich blood supply. This is understandable because contracting muscle fibers use huge amounts of energy and require almost continuous delivery
of oxygen and nutrients via the arteries. Musc le cells also give off large amounts of
metabolic wastes that must be removed through veins if contraction is to remain effic ient. Capillaries, the smal lest of the body's blood vessels, take a Jong and winding path
through muscle, and have numerous cross-links, features that accommodate changes in
muscle length . They straighten when the muscle stretches and contort when the muscle
contracts.

Connective Tissue Sheaths
In an intact muscle, there are several different connective tissue sheaths. Together these
sheaths support each cell and reinforce and hold together the muscle, preventing the
bulging muscles from bursting duri ng exceptionally strong contractions.

(c)

•

-

281

outer

& pi:

282

UNIT 2 Covering, Support, and Movement of the Body

peri:

around

endo: inside

Connecting
Skeletal muscle

S

d

needs
a tendon

Epim sium

↓

.~ -Muscle fiber
in middle of
a fascicle
(b)

separated
bY

..-- - - - - --

S

Blood vessel
around

Sheet covering the bridles of
the

muscle

muscles

& Pimy Sirm

fascicles (Portion)
perimysium

(Coveringfusicleare
s

endomysium

between
(Covering
the

musefibers

musclefibers

,.,-- Endomysium
(between individual muscle fibers)

Muscle fiber

covering

(a)

muscle

dense irregular
t
<

C.t

separating
fasicles

↑

Figure 9.1 Connective tissue sheaths of ske letal muscle: epimysium, perimysium,

(fascicle outerlayer

and endomysium. (b) Photomicrograph of a cross section of part of a skeletal muscle (30X).
separating

muscle

fibers

Attachments

Let's consider these connective tissue sheaths from external to internal (see Figure 9 .1 and the top three rows of
• Epimysium. The epimysiu1n (ep''i-mis' e-um; "outside the
muscle") is an "overcoat" of dense irregular connective tissue
that surrounds the whole muscle. Sometimes it ble nds with
the deep fascia that lies bel\veen neighbori ng muscles or the
superficial fascia deep to the skin (~ p. 151).

as

epi my Swim

• Endomys ium. The endo1nysium (en"do-mis'e-um; "within
the muscle") is a wispy sheath of con nective tissue that surrounds each individual muscle fiber. It consists of fine areolar connective tissue.

As shown in Figure 9. l , all of these connective tissue sheaths
are continuous with one another as well as with the tendons that
join muscles to bones. When muscle fibers contract, they pull
o n these sheaths, which transmit the pulling force to the bone to
be moved. The sheaths contribute somewhat to the natural elasticity of muscle tissue, and also provide routes for the entry and
exit of the blood vessels and nerve fibers that serve the rnuscle.

your

ever
hand

muscles

you're

you

have

(Connection

movingones

of

attainment
and

Recall from Chapter 8 that most skele tal muscles span joints
and attach to bones (or other structures) in at least two places.
When a muscle co ntracts, the movab le bone, the muscle's
insertion, moves toward the immovable or Jess movable bone,
the rnuscle's origin. In the muscles of the limbs, the origin typiknown
cally lies prox irnal to the insertion.
Muscle attachments, whether orig in or insertion, may be
d irect or indirect.

Table 9.1 ) .

• Pe rimysium a nd fascicles. Within each skeletal muscle, the
muscle fibers are grouped into fascicles (fas'T-klz; "bund les") that resemble bundles of st icks. Surrounding each
fascicle is a layer of dense irregular connective tissue called
perimysium (per''i-mis' e-um; "around the muscle"). ↳ same

When

Origin

is

Origin

from

f

shoulder plates
o elbow

↓

& insertion

to be

the proximal to the insertion

layer of the muscle
outer most

• In direct, or fleshy, attachments, the epimysium of the muscle is fused to the periosteum of a bone or perichondrium of
layer
layer
a cartilage.
tillage

directly

• In indirect attachn1ents, the rn uscle's connective tissue wrapS pings extend beyond the muscle either as a ropelike tendon

from

outer must

of the

Must

Common
d
said

Uc

need

7o

know
more than

that

bon

Outer most
car

of the

(Figure 9. Ia) or as a sheetlike a poneurosis (ap"o-nu-ro' sis)
(see Figure l 0. l 2a on p. 347). The tendo n or a po neurosis
anchors the muscle to the connective tissue covering of a
skeletal element (bone or cartilage) or to the fascia of other
On
muscles.

Ind irect attac hments are much more commo n because of
thei r durability and small size. Tendons are mostly tough collagen fibers, which can withstand the abrasion of rough bony
projections that would tear apart the more delicate muscle tissues. Because of their relatively small size, more tendons tha n

from

muscle to

bone/curtillage

to

muscle

tendons

aP onerosis

to

bone/cartillage

S

283

Chapter 9 Muscles and Muscle Tissue
Table 9.1

Structure and Organizational Levels of Skeletal Muscle

STRUCT URE AND ORGANIZATIONAL LEVEL

Muscle (organ)
Contain
many
muscle

bliegel, and

neuromuscular

junctions

A muscle consists of hundreds to tho usands of
muscle cells, plus connective t issue wrappings,
blood vessels, and nerve fibers.

to be

establishanatomres

forbers

were

Muscle

I Pristing I

⑤@

fascicles

DESCRIPTION

we expect

Epimysium

CONNECTIVE TISSUE
WRAPPINGS

or

Covered externally by
the epimysium

each muscle

hisfusicles

Fascicle (a portion of the muscle)

G

Part of fascicle

1----:

A fascicle is a discrete bundle of muscle cells,
segregated from the rest of the muscle by a
connective tissue sheath.
UC @S

bentle
fam

I

Contain

hundreds
muscle

Muscle fiber
Muscle fiber (cell)
Muscle

enclosed

b represents

->

S

endemyscie

and under in Surcolemma

fibers

by

muscle

new

the

Part of muscle fiber

G

fiber

in

Myofibril

a cell

membrane

membrane, has

Stimelesting

affect

Within
muscle

Surro unded by
endomysium

cell

Should be

(wrapped

of

A muscle fiber is an elongated multi nucleate
cell; it has a banded (striated) appearance.

Nucleus - -

by

muscle

Likers

fascicle

perimyrsin

cell

of

each

Surro unded by
perimysium

sad

components, enclosing

them

estorage

mere

ensuringas

and

moveunce
every

by

inside all cellular

enter

to

layers

7-table
and

side

to

inner

way

of it

by

f twirle

nerve

layers

R

releasing

All to receptors
enter to

and

F-tubule

and side

SR

signal

high

↓

Sucroplasm
d

to inner

Cytoplasm

ways

of muscle

-

organelle

Myofibrils are rodlike contractile elements s.6.4.0y etc
lot
that occupy most of the muscle cell volume.
Sacromeres
Composed of sarcomeres arranged end to
end, they appear banded, and bands of
adj acent myofibrils are alig ned.

Myofibril (complex o rganelle composed of bundles of
myofilaments)

-

a

each myofibril
Will Contain Many
sucremeres

Contracting
Unit in

one

&

any given
muscle

Sarcomere

cell

of the

most

important

cellular

component

Sarcomere (a segment of a myofibril)

A sarcomere is the contractile un it, composed
of myofilaments made up of contractile
proteins.

Sarcomere

/

actin

Thin (actin) filament

one of

Thick filament

Myrsin

Thick (myosin) filament

Myofilament, or filament (extended macromolecular structure)
them should have the ability to breakdown
AtP
needs support from an
enzyme that Can Convert Atr

poit

&

represent

-

S

represent

or

when

muscles sent wasting

S

release

energy

->
major
Changes happen

ADR

to

Contractile myofilaments are of two typesthick and thin. Thick f ilaments contain
bundled myosin molecules; th in fi laments
contain actin molecules (plus other proteins).
The slid ing of the thin f ilaments past the thick
filaments produces muscle shortening. Elastic
filaments (not shown here) provide elastic
recoil when tension is released and help
maintain myofilament o rganization.

it won't

be able to

contract

Ca27

Compare fa

of

fiber

284

UNIT 2 Covering, Support, and Movement of the Body
fiber, the dark A bands and light I bands are nearly perfectly
aligned, giving the cell its striated appearance.
As illustrated in Figure 9.2c:

fleshy muscles can pass over a joint-so tendons also conserve space.

Check Your Understanding

• Each dark A bru1d has a lighter region in its midsection called
the H zone (H for helle; "bright").

3. How does the term epimysium relate to the role and position
of th is connective tissue sheath?
What is the difference between a tendon
4.
and a ligament? (Hint: See Chapter 4, p. 133.)

• Each H zone is bisected vert ically by a dark line called the
M line (M for middle) formed by molecules of the prote in
myomes1n.

-==---------" For answers, see Answers Appendix.

• Each light I band also has a midline interruption, a darker
area called the Z disc (or Z line).

Skeletal muscle fibers contain
calcium-regulated molecular motors

Sarcomeres

has to have the

ability to store

and release

calcin, and rsetlements

The region of a myofibril between two successive Z discs is a
need to know the
sa rcomer e (sar'ko-mer; "muscle segment"). Averaging 2 µm
Learning Outcomes
for
units to
II- Describe the microscopic structure a nd functional roles of contract Jong, a sarcomere is the smallest contractile un it of a muscle
the functional unit of skeletal muscle. It contains an A
t he myofibrils, sa rcoplasmic reticu lum, a nd T tubules of (overlapbetweenfiberS
band flanked by half ru1 I band at each end. Within each myofiskeletal muscle fibers.
bril, the sarcomeres align end to e nd like boxcars in a train.
II- Describe the slid ing filament model of muscle contraction.

to

breakdown

ATP to go

back to normal

all

one component

act in

Each skeletal muscle fiber is a Jong cylindrical cell with mul tiple oval nuclei j ust beneath its sarcole1nma or plasma membrane (Figure 9 .2b). Skeletal muscle fibers are huge cells.
Their d iruneter typically ranges from JO to JOO µm-up to ten
times that of an average body cell-ru1d their length is phenomenal, some up to 30 cm Jong. T he ir large size ru1d multiple nuclei are not surprising once you learn that hundreds of
embryonic cells fuse to produce each fiber.
Sa r coplasm , the cytoplasm of a muscle cell, is similar to
the cytoplasm of o ther cells, but it contains u nusually large
amounts of glycosomes (granules of stored glycogen that provide glucose during muscle cell activity for AT P production)
and 1nyoglobin, a red pigment that stores oxygen. Myoglobin
is similar to hemoglobin, the pigment that transports oxygen in
blood.
In add ition to the usual organelles, a muscle cell contains
three specialized structures: myofibrils, sarcoplasm ic ret iculum, and T tubules. Let's look at these structures rnore closely
because they play important roles in muscle contraction.

Myofibrils

Many myofibrils

necromuscularjunction

will have the nerve

Myofilaments
If we examine the bandi ng pattern of a rnyofibril at the molecular level, we see that it arises from orderly arrru1gement of even
smaller structures within the sarcomeres. These smaller structures, the 1n yofila1nents or fila,nents, are the muscle equivalents of the actin-contain ing microfilruuents and myosin motor
prote ins described in Chapter 3 ( <Ill p. 88). As you will recall,
the proteins actin and myosin play a role in motility and shape
change in virtually every cell in the body. This property reaches
its highest development in the contractile muscle fibers. There
are two types of contractile myofilaments in a sarcomere:

• The central thick filaments containing myosin (red) extend
the entire length of the A band (Figure 9 .2c and d). They are ↳
connected in the middle of the sarcomere at the M line. arrangment
• The more lateral thin fila,n ents containing actin (blue) extend across the I band and partway into the A band. The Z
disc, a protein sheet, anchors the thi n filaments. We describe
the third type of myofilament, the elastic fila,11e11t, in the
next section.

terminals

A close look at myofibril arrangement and banding patterns
A single muscle fiber contains hundreds to thousands of rod- maybe reveals that:
like myofibr ils that run parallel to its length (Figure 9.2b). The
• A hexagonal arrangement of six thin filaments surrounds each
elements
myofibrils, each 1-2 µm in diameter, are so densely packed in inside? thick filruuent, and three thick filaments enclose each thin filathe fiber that mitochondria and other organelles appear to be inside
ment. This is shown in Figure 9.2e (far right), which shows a
fusicles
plante
80%
of
celsqueezed between them. They account for about
cross section of a sarcomere in ru1 area where thick and thi n
elements.
lular volume.
they
contract filaments overlap.
Myofibrils are made up of a chain of sarcomeres linked
• The H zone of the A band appears Jess dense because the
end to end. Sarco,neres (shown in Figure 9.2c and decribed
thin fila,nents do not extend into this region.
shortly) contain even smaller rodlike structures called r11yojila• The M line in the center of the H zo ne is sl ightly darker
,11ents. Table 9. 1 (bottom three rows; p. 283) summarizes these
because of the fine protein strands there that hold adjacent
system
structures.
thick filaments together.
Stimulating
S

somewhere near, so

is

it going to penetrate through

the

C.T? along

with

Scrollema?
or

Medinte

the whole

are

of

all

same time.

S

nerves

one

Striations

fiber and

stimulation

goes deeper
of muscle

into the

fibers

Striations, a repeat ing series of dark and light bands, are evident along the length of each myofibri l. In an intact muscle

• The myofilaments are he ld in alignment at the Z discs and
the M lines, and are anchored to the sarcolemma at the Z
discs.

layers

->

sacromere

285

Chapter 9 Muscles and Muscle Tissue
(a) Photomicrograph of portio ns
of two muscle fibers (700 X).
Notice the striations
(alternating dar1< and light
bands).

...

............ . .

I

(b) Diagram of part of a
muscle fiber showing
the myofibrils. One
myofibril extends from
the cut end of the fiber.

------------------'.,,.

Dark A band

Light I band

Nucleus

,

---- -

I

Thin (actin) , , - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -'
filament , , '
z disc
z disc

I

(c) Small part of one
myofibril enlarged to
show the myofilaments
responsible for the
banding pattern. Each
sarcomere extends from
one Z disc to the next.
Thick (myosin)
filament

I

I

---------'

•

Overlap

cross

Zdisc
(d) Enlargement of one
sarcomere (sectioned
lengthwise).

I

Part in h

I band
I band
A band contraction,
1
- + - - - - Sarcomere - - - + -:'
the

M line

'

-:::--~~t~::~!~~!i~=~=-

other.

M line

•-----------

each

A goes

absent

- •

r.h,
111 - -"
· ~ - -~

!:::!!!!!!::j~

'

•••••
••••
I band
thin filaments
only

Hzone
thick filaments
only

Figure 9.2 Microscopic anatomy of a skeletal muscle fi ber.

-

~fii4.- ~D~~~~-

-

(e) Cross sections of a
sarcomere cut through
in different locations.

-

''

~

~

Thin (actin)
filament
Elastic (titin)
filaments

~ - - Thick
(myosin)
filament

L- ~ ~ , - - Myosin
filament
~ - - Actin
filament

-'

-

M line
thick filaments linked
by accessory proteins

Outer edge of A band
thick and thin
filaments overlap

UNIT 2 Covering, Support, and Movement of the Body

286

Longit udinal section of filaments within one
sarcomere of a myofibril
Zd~

r1-i

r1-i

.........--:-_Ill= ....................

In the center of the sarcomere, the thick filaments
lack myosin heads. Myosin heads are present only
in areas of myosin-actin overlap.

Thick filament

Thin filament

Each thick filament consists of many myosin molecules
whose heads protrude at opposite ends of the filament

A thin filament consists of two strands of actin subunits
twisted into a helix plus two types of regulatory proteins
(troponin and tropomyosin).

Portion of a thick filament

Portion of a thin filament

-

inhibitory

Myosin h e a d ~

Tropomyosin

-

Proteins
to

move

it

facilitate Contraction

returning

Actin

it to

relaxing

Cr

State

sirding releasein

Actin-binding sites

Tail
ATPbinding
site
break

I

•- ~ ~ - Myosinbinding sites

Flexible hinge region

down
AT4

Actin subunits

Myosin molecule

for Overlap

Figure 9.3 Composit ion of th ick and t hin filaments.

Contraction from
CNS Motor

nervous

nevretrani
& ng

chemical
opened

↓
junction between terminus
S.
end and Sacrofema
->

M olecular Composition of Myofilament s
Muscle contraction depends on the rn yosin- and actin-containing
myofilaments. As noted earlier, thick filaments are composed
pri marily of the protein myosin. Each myosin molecule consists
of six polypeptide chains: two heavy (high-molecular-weight)
fast
is

with

by ACH.

Casensed by
opened

by

irns

opposite, eliminate

muscle

cells

Voltage gated Channels

(Figure 9.3) .

The globular heads, each associated with t\vo light chains, are
the "business end" of myosin. During contraction, they link the
Sudden
- burst

alot
in

Slow

myoglobin
one

↓
use energy

fairly to

slowly

-

"One submit"

Cholding

twitch

and

make it

Act)

action potential

chai ns and four light chains. The heavy chains twist together
to form myosin 's rodlike ta il, and each heavy chai n ends in a
globular head that is attached to the tail via a flex ible hinge

faster

dealing

needs

and return
free Ca

twitch

much

when

Creturning

gated In Channels

synapse

last long

Onl

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of

energy
like jump
0,

or

Vcc

ATP contracts
and returns it

Scentures
actin gets

"musked" to
prevent
contraction
for

and

"relaxing"

State

in

exac
a

->

What protein
for

muscle

needed

to be inactivated

contraction?

(Sliding theory

Traponin orthosin
b
d

Chapte r 9 Muscles and Muscle Tissue

-

needed to

its

blocking

(a

287

binding

be inactivated
site, in order to expose it
to facilitate Contraction

th ick a nd thin filaments together, forming cr oss bridges, and
swivel around their point of attachment, acting as motors to generate force. Myosin itself splits ATP (acts as an ATPase) and uses
the released energy to drive movement.
Each th ick filament contains about 300 myosin molecules
bundled together, with their tails form ing the central part of the
thick filament and the ir heads facing oul\vard at the e nd of each
molecule (Figure 9 .3). As a result, the central portion of a thick
filament (in the H zone) is smooth, but its ends are studded with
a staggered array of myosin heads.
The thin filaments are composed chiefly of the protein a ctin
(blue in Figure 9.3). Actin has kid ney-sh aped polypeptide
subunits, called globular acti11 or G actin. Each G actin has a
,nyosin-binding site (or active site) to which the myosin heads
attach during contraction. G actin subunits polymerize into long
acti n filaments called fila,11e111ous, or F, actin. l\vo intemvined
actin filaments, resembl ing a twisted double strand of pearls,
form the backbone of each thin filament (Figure 9.3).
Thin fila,ne nts also contai n several regulatory proteins.

.---""'- HOMEOSTATIC
..., A IMBALANCE 9.1

Praten

or
↑
or

gene mutated
develops muscle
weakness

girls

Y

CLINICAi!

1l1e term muscnlar dystrophy refers to a group of inherited muscledestroying diseases that generally appear duri ng childhood. The
affected muscles initially enlarge due to deposits of fat and connective tissue, but the muscle fibers atrophy and degenerate.
The most common and serious form is Duchenne muscular
d ystrophy (DMD), which is inherited as a sex-linked reces s ive disease. It is expressed almost exclusively in males (one
in every 3600 male births) and is diagnosed when the boy
is between 2 and 7 years old (Figure 9.4). Active, normalappeari ng boys become clumsy and fall frequently as their
skeletal muscles weaken. The disease progresses relentlessly
from the extrem ities upward, fi nally affecting the head and
chest muscles, and cardiac muscle. The weakness continues to
progress, but with supportive care, DMD patients are living into
their 30s and beyond.

• Polypeptide strands of tropon1yosi11 (tro"po- mi 'o-sin), a rodshaped protein, spiral about the actin core and help stiffen
and stabi lize it. Successive tropomyosin molecules are arranged end to e nd along the acti n filaments, and in a relaxed
muscle fiber, they block myosin-binding sites on actin so that
myosin heads o n the thick filaments can not bi nd to the thin
filaments.
• Troponin (tro' po-nin), the other maj or prote in in thin filaments, is a globular protei n with three polypeptide subunits
(Figure 9.3). One subu nit attaches troponi n to actin. Another
subunit binds tropomyosin and helps position it on actin. The
third subunit binds calcium ions.
Both troponin and tropomyosin help control the myosin-actin
interactions involved in contraction. Several other proteins help
form the structure of the myofibril.
• The elastic filament we referred to earlier is composed of the
giant protein titin (Figure 9.2d). Titin extends from the Z disc
to the thick filament, and then runs within the thick filament
(forming its core) to attach to the M line. It holds the thick
filaments in place, maintai ning the organization of the A band,
and helps the muscle cell spring back into shape after stretching. (The part of the titin that spans the I bands is extensible,
unfolding when the muscle stretches and recoiling when the
tension is released.) Titin does not res ist stretching in the ordinary range of extension, but it stiffens as it uncoils, helping
the muscle resist excess ive stretching, which might pull the
sarcomeres apart.
• Another important structural protein is d ystrophin, wh ich
links the thin filaments to the integral proteins of the sarcolemma (\vhich in turn are anchored to the extracellular
matrix).
• Other proteins that b ind filaments or sarcomeres together
and rnai ntain their alignment include 11ebulin, myo,nesin, and
C proteins. Intermediate (desmin) filaments extend from the
Z disc and connect each myofibril to the next throughout the
width of the rn uscle cell.

Figure 9.4 A boy w it h Duchenne muscular d ystro phy
(DMD). Physiotherapy can help maintain mobility.

DMD is caused by a defective gene for dystrophin, the cytoplasmic protei n described above. Dystrophin links the cytoskeleton to the extracellular matrix and, like a girder, helps stabilize
the sarcolemma. The fragile sarcolemma of DMD patients tears
during contraction, allowing entry of excess Ca2 + , which damages the contractile fibers . Inflammatory cells (macrophages
and lymphocytes) accurnulate in the surrounding connective tissue. As the regenerative capacity of the muscle is lost, damaged
cells undergo apoptosis, and muscle mass drops.
There is still no cure for DMD. Current treatments are aimed
at preventing or reducing spine and joint deformities and helping those with DMD remain mobile as long as possible. Two
newly-approved drugs may broaden the treatment options for
certai n patients.
• •• • •

should
have 2
mutated

x
Y

bays

only

on e

no

proper

Muscle

contruction

Cardins,
respiratory
failure

UNIT 2 Covering, Support, and Movement of the Body

288

I band

Part of a skeletal
muscle fiber (cell)

I

Z disc

r

A band

I band

H zone

Z disc

Myofibril

-,-,;.,;=:....::'-,--,,...;.,;.,;~ ~,,..,:;~-'-- -• T tubule
~ ~.,..,..-- - -• Terminal
cisterns
of the SR (2)

Sarcolemma

I

Figure 9.5 Relationship of t he
sarcoplasm ic reticu lum and T t ubules
t o myofibrils of skeletal muscle. The
tubules of the SR (blue) fuse to form the

saclike terminal cisterns next to the A·I
junctions. The T tubules (gray) are inward
invaginations of the sarcolemma that run
deep into the cell between the terminal

Sarcoplasmic Reticulum and T Tubules
Skeletal muscle fibers contain two sets of intracell ular tubules
that help regulate muscle co ntraction: (1) the sarcoplasmic
reticulum and (2) T tubules.
Sa rco p lasm ic Re t icu lum
S hown in blue in Figure 9 . 5, the sa r coplas mic reticulum
(SR) is an elaborate smooth e ndopl asm ic reticulum. The SR
regulates intracell ular levels of ionic calcium. It stores calcium
and releases it on demand when the muscle fiber is stimulated
of
her to contract. As you will see, calcium provides the final "go"
signal for contraction.
Interconnecting tubules of SR surround each myofibril the
way the sleeve of a loosely knitted sweater surrounds your arm.
Most SR tubules run longitudinally along the myofibril, commun icating with each o ther at the H zone. Others called terrn in al cisten1s ("end sacs") form larger, perpendicular cross
channels at the A band-I band junctions, and they always occur
in pairs. Closely associated with the SR are large numbers of
mitochondria and glycogen granules, both involved in producing the energy used during contraction.
AR

T Tubu les
At each A band-I band j unction, the sarcolemma of the muscle
cell protrudes deep into the cell interior, forming an elongated
tube called the T tub ule (T for "transverse"), shown in gray in

Transverse
to

all

fibril

space

cisterns. (See detailed view in Focus Figure 9.2,
pp. 294- 295.) Sites of close contact of these
three elements (terminal cistern, T tubule,
and terminal cistern) are called triads.

Figure 9.5 . The lunien (cav ity) of the T tubule is co ntinuous
with the extracellular space. As a result, T tubules trernendously
increase the muscle fiber's surface area. This allows changes
in the membrane potential to rapidly penetrate deep into the
muscle fiber.
Along its length, each T tubule runs betv,een the paired terminal cisterns of the SR, forming triads (Figure 9.5), successive
groupings of the three membranous structures (terminal cistern,
T tubule, and termi nal cistern). As they pass from one myofibril
to the next, the T tubules also encircle each sarcomere.
Muscle contrac tion is ultimately controll ed by nerveinitiated electrical impulses that travel along the sarcolemma.
Because T tubules are cont inuations of the sarcolemma, they
conduct impulses to the deepest regions of the muscle cell and
every sarcomere. These impulses trigger the release of calcium
from the adjacent term inal cisten1s. Th ink of the T tubules as
a rap id commun ication or messaging system that ensures that
every myofibril in the muscle fiber contracts at virtually the
same time.
Triad Relationsh ips
The roles of the T tubules and SR in providing signals for contraction are tightly lin ked. At the triads, membrane-spanning
proteins from the T tubules and SR link together across the gap
between the two membranes.
• The protruding integral proteins of the T tubule act as voltage
sensors.

Chapte r 9 Muscles and Muscle Tissue
• The integral proteins of the SR form gated channels through
which the term inal cisterns release Ca2 + (see top right of
Focus Figure 9.2 on p. 295).

289

1 Fully relaxed sarcomere of a muscle fiber

-

Sliding Filament Model of Contraction
We almost always think "shortening" when we hear the word
contraction , but to physiologists contraction refers only to
the activation of myosin' s cross bridges, \vhich are the forcegenerat ing sites. Shortening only occurs if the cross bridges
generate enough tension on the thin filaments to exceed the
forces that oppose shortening, such as when you lift a bowling
ball. Contraction ends when the cross bridges become inactive,
the tension declines, and the muscle fiber relaxes.
In a relaxed muscle fiber, the thin and thick filaments overlap
only at the ends of the A band (Figure 9.6 G)). T he sliding
fila1nent model of contr action states that during contraction,
the thin filaments slide past the thick ones so that the actin and
myosin filaments overlap to a greater degree. Neither the thick
nor the thin filaments change length during contraction. Here's
how it works:
• When the nervous system stimulates muscle fibers, the myosin heads on the thick filaments latch onto myosin-binding
sites on actin in the thin filaments, and the sliding begins.
• These cross bridge attachments form and break several times
during a contract ion, acting like tiny ratchets to generate tension and propel the thin filaments toward the center of the
sarcomere.
• As this event occurs simultaneously in sarcomeres throughout the cell, the muscle cell shortens.
At the microscopic level, the following th ings occur as a
muscle cell shortens:
• The I bands shorten.
• The distance between successive Z discs shortens. As the
thin filaments slide centrally, the Z discs to which they attach
are pulled toward the M line (Figure 9.6 @).
• The H zones disappear.
• The contiguous A bands move closer together, but their
length does not change.

Check Your Understanding
5. Name proteins a, b, c, and d. Which protein can act as an
enzyme to hydrolyze (split) ATP? Wh ich bi nds Ca2 +? Wh ich
must move out of the way in order for cross bridges to form?

6. Which region or organelle-cytosol, mitochondrion, or SRcontains the highest concentration of calcium ions in a resting
muscle fiber? Which structure provides the ATP needed for
muscle activity?

• ,ti!•

.......

y

y

..~ ''

-----'

z

•

H

z

'

A

@ Fully contracted sarcomere of a
muscle fiber

y
.' ....
'

z

••''

A

'

..

y
z

,- I

•

Fi gure 9.6 Sliding filament model of contraction. At full

contraction, the Z discs approach the thick filaments and the thin
filaments overlap each other. The photomicrographs
(top view in G) and@) show enlargements of 33,000x .
7. l•);W/1 Draw four thick fi laments in each of two columns. Add
a column of fou r thi n filaments between the th ick filaments, as
they would appear in a relaxed myofibril. Then add two more
col umns, each with four th in filaments, on the left and right
sides of the original drawing. Label an A ba nd, an I band, and
an H zone. Draw and label an M line and a Z disc.
8.
Consider a phosphorus atom that is part
of the membrane of the sarcoplasmic reticulum in the biceps
muscle of your arm. Using the levels of structu ral organization
(described in Chapter 1), name in order the structu re that
corresponds to each level of organ ization. Begin at the atomic
level (the phosphorus atom) and end at the organ system level.
- - - - - - - - - - For answers, see Answers Appendix.

290

UNIT 2 Covering, Support, and Movement of the Body

Ill Motor neurons stimulate
skeletal muscle fibers to contract
Learning Outcomes
II- Explain how muscle fibers a re stimulated to contract
by describing events that occur at the neu rom uscula r
junction.
II- Follow the events of excitation-contraction coupling that
lead to cross bridge activity.
II- Describe the steps of a cross bridge cycle.
The sliding filament model tells us that myofilaments slide past
each other as the sarcomeres contract. In this module, we will
see exactly how th is happens. But before we begin, Jet's fill
in some background information that will help you understand
this topic, and then look at the big picture of how muscle contraction works.

Background and Overview

changes in the membrane potential (as we will see shortly).
Receptors for acetylcholine are an example of this class. An
ACh receptor is a single protein in the plasma membrane that
is both a receptor and an ion channel.
• Volta ge-gated ion channels open or close in respo nse to
c hanges in membrane potential.
They underlie all action potentials.
In skeletal muscle fibers, the initial
change in me,nbrane potential is created by chemically gated channels.
In other words, chemically gated ion
channels cause a small local depoVoltage-gated ion
larh.ation (a decrease in the mem- channel
brane potential) that then triggers the
voltage-gated ion channels to create
an action potential.
(We will describe ion channels in more detail in Chapter 11.)

Ion Channels
Rapidly changing the membrane potential in neurons and
muscle cells requires the opening and closing of membrane
channel proteins that allow certain ions to pass across the membrane (<Ill p. 70). The movement of ions
through these ion channels changes the
Chemical messenger
membrane voltage. 1\vo classes of ion (e.g.,
ACh)
c hannels are important for exc itation
and contraction of skeletal ,nuscle:

Anatomy of Motor Neuro ns and t he
Neurom uscu la r Junct ion
Mo tor neurons that activate skeletal muscle fibers are called
so,natic ,notor neurons, or nu>lor neurons of the somatic (voluntary) nervous syste,n (Figure 9.7). These neurons reside in
the spinal cord (except for those that supply the muscles of the
head and neck). Each neuro n has a Jong threadlike extension
called an axon that extends from the cell body in the spinal cord
to the muscle fiber it serves (<Ill see Chapter 4, p. 140, to review
the parts of a neuron). These axons exit the spinal cord and pass
throughout the body bundled together as nerves.
The axon of each motor neuron branches profusely as it
enters the ,nuscle so that it can innervate ,nultiple ,nuscle fibers.
When it reaches a muscle fiber, each axon divides agai n, giving
off several short, curling branches that collectively form an oval
neuromuscular junction, or m otor end plate, with a single
muscle fiber.
Each muscle fiber has o nly one neuromuscular junction,
located approx imately midway along its length. The end of
the axon, called the axon ter1ninal, and the muscle fiber are
exceedingly close (50-80 nm apart), but they remain separated
by a space, the synaptic cleft (Figure 9.7), which is filled with
a gel-like extracellular substance rich in glycoproteins and collagen fibers.
Within the mou ndlike axon terminal are syna ptic vesicles,
small membranous sacs contai ning the neurotransmitter acetylcholine. The trough-like part of the muscle fiber's sarcolemma
that helps form the neuromuscular j unction is highly folded.
These junctional folds provide a large surface area for the
thousands of ACh receptors located there.
To summarize, the neuromuscular junction is like a sandw ich: It is made up of part of a neuron (the axon term inals),
part of a muscle cell (the junctional fol ds), and the "filler"
between them (the synaptic cleft).

• Chemically gated ion channels are
opened by chemical messengers
(e.g., neurotransmitters). This class
of ion channel creates small local

The Big Picture
Figure 9.7 presents an overview of skeletal muscle contraction and divides this process into four groups of steps. We will

Remember that skeletal muscle contractions are voluntary.
For example, you decide when you want to co ntract your
biceps muscle to pick up your cell phone. Making that decision involves many neurons in your brain, but the contraction
of a skeletal muscle ultimately comes down to activating a few
,notor neurons in the sp inal cord. Motor neurons are the way
that the nervous system connects wi th skeletal muscles and
"tells" the,n to contract.
Both neurons and muscles are excitable cells. That is, they
respond to external stimuli by changing their resting membrane
pote ntial. (Remember that all cells have a resting membrane
potential, \vhich is a vol tage across the plasma membrane;
<Ill pp. 79-80.) These changes in membrane potential act as signals. One type of electrical signal is called an action potential (AP ; sometimes called a nerve i,npulse). An AP is a large
c hange in membrane pote ntial that spreads rapidly over Jo ng
distances within a cell. Generally, APs don't spread from cell
to cell. For this reason, the signal has to be converted to a
c hemical signal-a chemical messenger called a neurotrans1niller (<Ill p. 81 ) that diffuses across the small gap between
excitable cells to start the signal again. The neurotransmitter
that motor neurons use to "tell" skeletal muscle to contract is
acetylcholine (as"e-til-ko' len), or ACh.
H

↓

With

we can

the cell

Chemically gated ion
channel

enter

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Chapter 9 Muscles and Muscl e Tissue

you

Brain------

&

291

would

expect least

the

Spinal cord---.._

reshold

Minimum

- - - - -Axon of
\
motor neuron

Charge

enough for
intake

a

The neuromuscular junction is the
region where the motor neuron
contacts the skeletal muscle. It
consists of multiple axon terminals
and the underlying junctional folds
of the sarcolemma.

a

lot

--- -- -- --

of

Sequence of events leading to contraction:

Axon of motor
neuron

A motor neuron fires an action potential
(AP) down its axon.

Ca

The motor neuron's axon terminal
releases acetylcholine (ACh) into the
synaptic cleft.

neuromuscular
junction (see
Focus Figure 9.1)

voltage
Ca

EPP

With

-

will

be

stimuli

ACH

AP in sarcolemma travels down T tubules.

@ Excitation-

explore each group of steps in more detail in the rest of this
module:

Sarcoplasmic reticulum releases Ca2 •.

contraction coupling
(see Focus Figure 9.2)

binding

site to be
shown

for

-

-

allows

Ca2 • binds to troponin, which shifts
tropomyosin to uncover the myosin-binding
sites on actin. Myosin heads bind actin .

(see Focus Figure 9.3)

actin

Muscle fiber excitation. The EPP triggers an action potential that travels across the entire sarcolemma (see Figure 9.8
on p. 293).

@

Excitation-contraction coupli ng (see Focus Figure 9.2
on pp. 294-295). The AP in the sarcolemma propagates along
the T tubules and causes release of Ca2 + frorn the tenninal
cisten1s of the SR. Ca2 + is the final trigger for contraction. It is
the internal messenger that links the AP to contraction. Ca2 +
binds to troponin and this causes the myosin-binding sites on
actin to be exposed so that myosin heads can bind to actin.

©

Cross bridge cycling (see Focus Figure 9.3 on p. 297). The
muscle contracts as a result of a repeating cycle of steps
that cause myofilaments to slide relative to each other.

vel
my as in

Contraction occurs via cross bridge cycling.
Myo filaments overlap

Figure 9.7 Overview of skeletal muscle contraction.

Events at t he neuromuscular junction (see Focus Figure 9.1
on p. 292). The rnotor neuron releases ACh that stimulates the skeletal muscle fiber, causing a local depolarization (decrease in membrane potential) called an end plale
potential (EPP).

@

far

myosin to kind on

© Cross bridge cycle

Cytoplasm
of skeletal
muscle fiber

c->--Junctional
folds of the
sarcolemma

G)

the actin

~

to release

The local depolarization (EPP) triggers an
AP in the adjacent sarcolemma.

S

release

ACh binding causes a local depolarization
called an end plate potential (EPP).

released

@Muscle fiber
excitation (see
Figure 9.8)

Ca

enters to

active

energy

ACh binds receptors on the junctional
folds of the sarcolemma .

enter

inSM

-

need

Outside

++f t

gated

Channels

ACI

G) Events at the

Muscle

Axon terminal of
motor neuron

sensed by
voltage

------

When a nerve impulse reaches a
Watch a 3·D an imat ion of t his process: MasteringA&P" >
neuromuscular junction, acetylcholine (ACh)
St udy Area > Animations & Videos > A&P Flix
is released. Upon binding to sarcolemma
"'
receptors, ACh causes a change in sarcolemma
··~ - - - Axon of
motor neuron
permeability leading to a change in
Action - - - -"....,.
membrane potential.
potential (AP)
Axon terminal of
neuromuscular
junction
I Sarcolemma of
I
the muscle fiber

r
J

G) Action potentia l arrives at
axon terminal of motor neuron.

@ Voltage-gated Ca 2•
channels open . Ca2• enters the
axon terminal, moving down its
electrochemica l gradient.

Synaptic vesicle
containing ACh

the resides
of

ALI

@ Ca 2• entry causes ACh (a

neurotransmitter) to be released
by exocytosis.

©
ACh d iffuses across the
synaptic cleft and binds to ACh

sarcolemma

receptors on the sarcolemma.

Sarcoplasm of
muscle fiber

@ ACh b ind ing opens chemically
gated ion channels that allow
simultaneous passage of Na• into
the muscle fiber and->
K• out of action
the muscle fiber. More Na• ions potential
enter than K• ions exit, which
produces a local change in the
membrane potential called the
end plate potential.

@ ACh effects are term inated by

its breakdown in the synaptic
1 - - - - - - - --1-----<
cleft by acetylcholinesterase and
diffusion away from the j unction.

292

_,,-; - - Postsynaptic membrane
ion channel opens;
ions pass.

/"'"1-- Ion

channel closes;
ions cannot pass.

Chapte r 9 Muscles and Muscle Tissue
Open voltagegated Na+ channel

ACh-containing
synaptic vesicle
Axon terminal of
neuromuscular
junction

No
->

entering

Na~

293

Closed voltagegated K + channel

..)v..J..)

de Polarization

Na5 K

Wave of
depolarization
after ACH

bind to receptors

Q) An end plate potential (EPP) is generated at the

-

depolarization Walls

->

occur

neuromuscular junction (see Focus Figure 9.1). The EPP causes
a wave of depolarization that spreads to the adjacent sarcolemma.

@Depolarization: Generating and propagating an action potential
(AP). Depolarization of the sarcolemma opens voltage-gated sodium
channels. Na+ enters, following its elect rochemical gradient. At a certain
membrane voltage, an AP is generated (initiated). The AP spreads to
adjacent areas of the sarcolemma and opens voltage-gated Na+ channels
there, propagating the AP. The AP propagates along the sarcolemma in all
directions, just like ripples from a pebble dropped in a pond.

!

Fig ure 9.8 Summa ry of events in the generation and
propagation of an action potential in a skeletal muscle fiber.

Open voltageClosed voltagegated Na+ channel gated K+ channel
+ ..)

Na ..J..) ..)..,

Events at the Neuromuscular Junction

+++ +++++

How does a motor neuron stimulate a skeletal muscle fiber?
Focus on Events at the Neurornuscular Junction (Focus
Figure 9.1) covers this process step by step. Study th is figure
before continuing.
The resul t of the events at the neuromuscular junction is
a transient change in membrane
poten tial that causes the interior C Complete an interactive
of the sarcolemma to become Jess tutorial: MasteringA&P " >
negative (a depolarization). This Study Area > Interactive
local depolarization is called an Physiology
end p la te potential (EP P). The
EPP spreads to the adjacent sarcolemma and triggers an AP
there.
After ACh binds to the ACh receptors, its effects are quickly
terminated by acetylcholinesterase (as"e-t il-ko"lin-es' ter-as),
an enzyme located in the synaptic cleft. Acetylchol inesterase
breaks down ACh to its building blocks, acetic acid and choline.
Removing ACh prevents continued muscle fiber contraction in
the absence of adclitional nervous syste,n stimulation.
auto

.- HOMEOSTATIC
~-.,.Ji~ IMBALANCE 9 . 2

immene:

attack

immone

normal

cells

attackingit receptors, spasm

repular: Zution

K

00 0

leaving

= - ++++

@ Repolarization: Restoring t he sarcolemma to its init ial polarized
state (negative inside, posit ive outside). The repolarization wave is also
a consequence of opening and closing ion channels-voltage-gated Na+
channels close and voltage-gated K + channels open. The potassium ion
concentration is substantially higher inside the cell than in the extracellular
fluid, so K + diffuses out of the muscle fiber. This restores the negatively
charged conditions inside that are characteristic of a sarcolemma at rest.

Generation of an Action Potential across
the Sarcolemma
Now let's consider the electrical events that trigger an action
potential along the sarcolemma. An action potential is the result
of a predictable sequence of electrical changes. Once in itiated,
an action potential sweeps along the entire surface of the sarcoJemma. Three steps are involved in triggering and then propagating an action potential. These three steps-generation of an
end plate potential followed by action potential depolarization
and repolarization-are shown in Fig ure 9.8. A tracing of the

Many toxins, drugs, and diseases interfere with events at the tone
neuromuscular junction. For example, myasthenia gravis
(asthen = weakness; gravi = heavy), a disease characterized
by drooping upper eyelids, difficulty swallowing and talking,
and generalized muscle weakness, involves a shortage of ACh autain menusmust appearmuuscurses, trams, hornoueet
receptors. Myasthenia gravis is an autoi,nmune disease in which
can
the immune system destroys ACh receptors.
•• •• •
with
end up

Candiovascular
and

respiratory
failure

(Texr co111i11ues on p. 296.)

Excitation-contraction (E-C) coupling is the sequence of
events by which transmission of an action potential along
the sarcolemma leads to the sliding of myofilaments.
Watch a 3-D animation of this process: MastcringA&P" >
Study Area> An imations & Videos> A&P Flix

Setting the stage
The events at the neuromuscular junction
(NMJ) set the stage for E-C coupling by
providing excitation. Released acetylcholine
binds to receptor proteins on the sarcolemma
and triggers an action potential in a muscle
fiber.
terminal

and

sacrolemn
tagether

&

Axon terminal of
motor neu ron at NMJ

/

after

pre
Action potential
is generated

the

Ap

triggers

(a

voltage gates

to open in the

Sarcolemma

SR to release

to

2

Muscle fiber

294

Ca +~

~···
.. : .........
"

~ ._.., "

"

~..,..»~····

feelingin for

contraction

Steps in E-C Coupling:
Sarcolemma

I

G) The action potential (AP) propagates

- + - - - - - - - - - - - - - - - - - - - - --< along t he sarcolemma and down t he
T t ubules.

;a~;=~~~'
.
.
_
!
1

@ calcium ions are released.

Transmission of th e AP along t he
T tubules of t he triads causes t he
voltage-sensit ive t ubule proteins to
change shape. This shape chan ge opens
the Ca2• release cha nnels in the terminal
cisterns of the sarcoplasmic reticulum
(SR), allowing Ca2• t o flow into t he
cytosol.
Cyte plasm

.
..
___ --.
. --. . ------c
•

..

-----2+•

a •

•
•

• •

••
• • •

•

--

within

organneles
like inside

....

-----

•

•

•

•

• • •

•
• •

sacromeres

•

Tropomyosin blocking
myosin-binding sites

"=c----------~

• •

• • • _ - Ca
•
• ••• ••
• • •• • • •
• •
•

-

excitors

Contraction

Myosin

hibitory

relaxin @ calcium b inds to t roponin and
the blocking action of Removes
&removes
,,---------------------1
tropomyosin. When Ca2• binds,

2
•

in

->

⑧

S

-

~

~

tropo nin changes shape, exposing
myosin-bind ing sites o n t he t hin
f ilaments.

Myosin-binding sites exposed
and ready for myosin binding

!
Myosin __,,,/
cross
bridge

The aftermath
When the muscle AP ceases, the voltage-sensitive tubule proteins return to their
original shape, closing the Ca2+ release channels of the SR. Ca2+ levels in the
sarcoplasm fall as Ca2+ is continually pumped back into the SR by active transport.
Without Ca2+, the blocking action of tropomyosin is restored, myosin-actin
interaction is inhibited, and relaxation occurs. Each time an AP arrives at the
neuromuscular junction, the sequence of E-C coupling is repeated.

© Cont raction begins: Myosin

binding to actin forms cross
bridges and contraction (cross
bridge cycling) begins. At this
point E-C coupling is over.

A reaching

1.

the tubule

2. In

released

voltage

by

sensitive

proteins

(Releasertram SM)

3. Calcrim Binds
troponin to mask

and expose the

4.

binding

off

sites

for

myosin heads

Contraction, Cross Bridge, Overlay

the

"Mask"

295

296

UNIT 2 Covering, Support, and Movement of the Body
14"leaving

-rustity

entering

--

+30

>

E
.;

--..
..8.

0

↓Na

↑

increasing

+

Depolarizatio n
due to Na• entry

c:

..

.J::j

E

Repolarizat ion
due to K• exit
Na•
channels
open

:;

K• channels
closed

- 90
0

5

10

15

Calcrim Binds
troponin

and expose the

Na• channels
close, K• channels
open

c:

..

Muscle Fiber Contraction:
Cross Bridge Cycling

20

Tim e (ms)

Figure 9.9 Record ing of an action potential (AP) in a mu scle

fibe r. An AP is a brief change in membrane potential.

resu lting membrane potential changes is shown in Figure 9.9 .
We will describe action potentials in more detail in Chapter 11.
During repolarization, a muscle fiber is said to be in a
refractor y pe riod, because the cell cannot be stimulated
again until repolarization is complete. Note that repolarization
restores only the electrical conditions of the resting (polarized)
state. The ATP-dependent Na +. K+ pump restores the ionic conditions of the resting state, but thousands of action potentials
can occur before ionic imbalances interfere with contractile
activity.
Once ini tiated, the action potential is unstoppable. It ul timately results in contraction of the muscle fiber. Although the
actio n pote ntial itself lasts o nly a few mill iseconds (ms), the
contraction phase of a muscle fiber may persist for I 00 ms or
more and far outlasts the electrical event that triggers it.

Excitation-Contraction Coupling
Excita tion-con