Cardio 2: Smooth Muscle

Question 1

SM

Main populations surround

Answer 1

“hollow organs”:

blood vessels, airways, GI tract, uterus and Fallopian tubes, ureters and bladder

Question 2

SM

Also important in (2)

Answer 2

ocular function, piloerection

Question 3

SM Contraction may cause (2)

Answer 3

propulsion or resistance

Question 4

SM

Stimulus for contraction may be

Answer 4

intrinsic

Question 5

SM

“Involuntary”: regulated by

Answer 5

efferent autonomic neurons, hormones,

and autocrine/paracrine signals

Question 6

SM cell size

Answer 6

Smaller cells with single central nucleus

Question 7

SM Specialized for (3) contractions (compared to skeletal muscle)

Answer 7

slow, steady, long

Question 8

Specialized for slow, steady, long contractions (compared to skeletal muscle) (4)

Answer 8

1. Contractions are slower to develop (1/10 to 1/300 speed)
2. Contractions last significantly longer (30x longer)
3. Maximum force generation greater (up to 2x greater/cm2)
4. Primarily oxidative metabolism

Question 9

SM cell shape

Answer 9

elongated &

tapered

Question 10

SM striation

Answer 10

Smooth muscle is non-striated (

Question 11

Smooth muscle lacks —

and only has rudimentary

Answer 11

T-tubules

SR

Question 12

Types of Smooth Muscle (2)

Answer 12

multi unit
single unit (unitary visceral)

Question 13

Multi-unit (6)

Answer 13

No Gap Junctions
Each cell responds independently
Muscle behaves as multiple units
Control exerted mainly by nerve 
signals 
 Cells function independently
 No tone

Question 14

Single-Unit (Unitary, Visceral) (6)

Answer 14

 Cells connected by gap junctions
 Functional Syncytium
 Control by variety of stimuli
 Pacemaker cells
 Cells organizes into sheets or 
bundles
 May have tone

Question 15

Smooth myocytes contain (2)

Answer 15

actin & myosin

Question 16

Actin (3)

Answer 16

• Higher levels and longer than in skeletal/cardiac myocytes
• Alpha actinin attaches actin to dense bodies (Intracellular and
  Membrane bound)
• Arranged diagonally to long axis of cell

Question 17

Myosin (2)

Answer 17

• Fewer myosin fibers than skeletal/cardiac myocytes

- Myosin Filaments interspersed with actin

Question 18

Smooth myocytes lack —

Answer 18

troponin

Question 19

Calcium binds to —

Answer 19

Calmodulin

Question 20

Two actin-binding proteins: (2)

Answer 20

a. Calponin inhibits myosin ATPase

b. Caldesmon inhibits myosin/actin bond

Question 21

Contraction results in — — of cell

Answer 21

rounding up

Question 22

May contract efficiently over a wide

range of

Answer 22

resting lengths

Question 23

Requirements for contraction: (3)

Answer 23

1. Calcium (*Extracellular/Some Intracellular)
2. ATP for contraction (myosin head has an ATPase)
3. Myosin Light Chain Phosphorylation

Question 24

1. Calcium (*Extracellular/Some Intracellular) (2)

Answer 24

 Binds to calmodulin for contraction

Removes calponin & caldesmon from actin

Question 25

3. Myosin Light Chain Phosphorylation (3)

Answer 25

 Required for myosin head to interact with Actin
 Myosin light chain kinase – adds phosphate and begins contraction
 Myosin light chain phosphatase – removes phosphate and stops contraction

Question 26

Smooth muscle contraction can be stimulated by (3)

Answer 26

1. Stretch
2. Ligands (neurotransmitters/hormones/paracrines/autocrines)
3. Intrinsic activity (pacemaker cells)

Question 27

Action potentials are not necessarily required for — in contractile force

Answer 27

increases

Question 28

Many smooth muscle cells (ex: vascular) are — smooth muscle cells.

Answer 28

tonic

They are normally contracted (have “tone”), but can alter their force of contraction.

Question 29

Cross-Bridge Activation: (5)

Answer 29

Cross-bridge cycling in smooth muscle is controlled by a Ca2+ regulated enzyme that phosphorylates myosin.
Only the phosphorylated form of smooth muscle myosin can bind to actin and undergo cross-bridge cycling.
This is done by myosin light chain kinase (MLCK).
 To relax a contracted smooth muscle, myosin must be dephosphorylated because dephosphorylated myosin is unable to bind to actin.
Dephosphorylation is mediated by the enzyme myosin light-chain phosphatase (MLCP)

Question 30

Two sources of Ca2+ : (2)

Answer 30

1. The sarcoplasmic 
reticulum.
2. Extracellular Ca2+ 
entering the cell through 
plasma-membrane Ca2+ 
channels.

Question 31

To relax, the Ca2+ has to be removed: (2)

Answer 31

To SR via Ca++ ATPase

To ECF via Ca++ ATPase and Na+/Ca++ Exchanger

Question 32

Cross Bridge Cycling in              
Smooth Muscle (2)

Answer 32

A.Attachment of myosin to actin 
depends on the 
phosphorylation of the myosin 
by myosin light chain kinase 
(MLCK;  activated by calcium- 
calmodulin)
B. Phosphorylated cross-bridges 
continue to cycle (myosin 
ATPase is active) until myosin 
phosphatase 
dephosphorylates the myosin 
head.  Probably never get 
complete relaxation unless 
remove calcium.

Question 33

When myosin is
dephosphorylated, myosin and
actin may form

Answer 33

latch-bridges

Question 34

Tension is maintained although
Ca++ levels in cytosol — and ATP
usage —

Answer 34

decreases

decreases

Question 35

When myosin is 
phosphorylated, cross 
bridges repeatedly form 
& break if --- is 
present

Answer 35

ATP

Question 36

Latch State —

Answer 36

sustained contraction at low cost.

Tonic contractions creating smooth muscle tone.

Question 37

Several mechanisms influencing

Answer 37

smooth muscle cell activation

Question 38

Input to smooth muscle can be either

Answer 38

excitatory or inhibitory.

Question 39

inputs influencing smooth muscle contractile activity (5)

Answer 39

spontaneous electrical activity in the PM of the muscle cell
NT released by autonomic neurons
hormones
locally induced changes in the chemical composition (paracrine factors, acidity, oxygen, osmolarity, and ion concentrations) of the extracellular fluid surrounding the cell
stretch

Question 40

Smooth Muscle Activation: Autonomic Motor Neurons

Do not form —

Answer 40

synapses

Question 41

Smooth Muscle Activation: Autonomic Motor Neurons

Axons have —

Answer 41

Varicosities

Question 42

Smooth Muscle Activation: Autonomic Motor Neurons

NT released into

Answer 42

interstitial

fluid

Question 43

Smooth Muscle Activation: Autonomic Motor Neurons
Distribute to receptors on
smooth muscle cell surface
via

Answer 43

simple diffusion.

Question 44

Smooth Muscle Activation: Autonomic Motor Neurons
Each smooth muscle cell
may be influenced by more
than one

Answer 44

varicosity

Question 45

Smooth Muscle Activation: Autonomic Motor Neurons

(2) contraction

Answer 45

Stimulate or inhibit

Question 46

Depending on Receptor
 May or may not induce – change
 (2) contraction

Answer 46

Vm

Activate or inhibit

Question 47

Local factors, including (5), can also

alter smooth muscle tension.

Answer 47

paracrine signals, 
acidity, 
O2 and CO2 levels, 
osmolarity, and 
the ion composition of the extracellular fluid

Question 48

Responses to local factors provide a means for

Answer 48

altering smooth muscle
contraction in response to changes in the muscle’s immediate internal
environment, independent of long-distance signals from nerves and
hormones.

Question 49

Many of these local factors induce

Answer 49

smooth muscle relaxation (ex. Nitric

oxide (NO)).

Question 50

Some smooth muscles can also respond by contracting when they are

Answer 50

stretched

Question 51

Stretching opens

Answer 51

mechanosensitive ion channels, leading to
membrane depolarization. The resulting contraction opposes the forces
acting to stretch the muscle.

Question 52

Pacemaker Potentials (4)

Answer 52

Pacemaker smooth muscle cells
Resting membrane not stable, 
slow depolarization to threshold
Mechanism unknown
Pacemaker Cells found in GI Tract 
(contract rhythmically without 
input)