2.2.5. Muscle Tissue

Question 1

What are the major contractile proteins involved in muscle contraction? (2 of them)

Answer 1

Actin

Myosin

Question 2

What are the three major classifications of muscle tissue in the human body?

Answer 2

Skeletal

Smooth

Cardiac

Question 3

What are some functions of skeletal muscle?

Name 3

Answer 3

Movement

Regulation of Body Temperature (Shivering when cold)

Protecting body entrances (swallowin, defecating)

Question 4

Describe the formation of skeletal muscle

Answer 4

Myoblasts aggregate in an area, fuse together and form myotubes, which then increase their production of sarcomeric proteins, leading to mature myofibers once innervated.

Question 5

What is the name of the tissue that surrounds skeletal muscles?

Answer 5

Epimysium

Question 6

What is the name of the tissue that surrounds muscle fascicles?

Answer 6

Perimysium

Question 7

What is the name of the tissue that surroundsmuscle fibers?

Answer 7

Endomysium

Question 8

Name the indicated regions/structures.

Answer 8

Question 9

Sarcoplasmic Reticulum surrounds which structural portion of skeletal muscles?

Answer 9

Myofibrils

Question 10

What are some distinguishing histological features of myofibrils?

Answer 10

Elongated cells

Striated formation

Multi-nucleated, nuclei at periphery

Question 11

In what pattern do thin filaments surround the thick filaments?

Answer 11

Hexagonal pattern

Thin outnumber thick by about 6:1

Question 12

How do the thick filaments surround the thin?

Answer 12

In a triangular pattern

Question 13

What protein makes up the thin filaments?

Answer 13

Actin

Question 14

What protein makes up the thick filaments?

Answer 14

Myosin

Question 15

What is the sliding filament theory?

Answer 15

It’s a theory explaining the mechanics of how muscle cells generate force

Question 16

What does the sliding filament theory state?

Answer 16

It states the muscle is composed of sarcomeres, where thin filaments, anchored to the Z line, “attach” to thick filaments and these filaments pull each other to shorten the sarcomere.

Question 17

What composes a thin filament?

Answer 17

Actin

Troponin (3 parts: I, T, and C)

Tropomyosin

Question 18

What do each of the troponins do (Troponin I, T, and C)?

Answer 18

I - binds actin

T - binds tropomyosin

C - binds calcium

Question 19

What does tropomyosin do?

Answer 19

Tropomyosin binds the cross-bridging site of actin, preventing it from binding myosin during times of non-contraction

Question 20

What is the purpose of titin?

Bonus: Why is it called titin?

Answer 20

Titin serves as a spring, stabilizing the location of myosin chains in the sarcomere by linking them to the Z line.

Bonus: It is called titin because it is a massive protein (each one has a Molecular Weight of 3 million :O)

Question 21

What is the purpose of troponin?

Answer 21

Troponin lies on actin and tropomyosin, and serves to move tropomyosin when exposed to calcium. This movement opens the cross-bridging sites of actin to myosin

Question 22

During a contraction what happens to the length of the sarcomere and each of the filaments?

Answer 22

The sarcomere gets shortened.

The filaments never change their length (in a healthy cell).

Question 23

Velocity of sliding is dependent upon which of the fibers?

Answer 23

The myosin

Question 24

Each skeletal muscle fiber is innervated by how many neurons?

Answer 24

Typically, just one

Question 25

How many different types of skeletal muscle fibers are there?

Answer 25

Two: named I and II

Question 26

Describe Type I Muscle Fibers:

Type of Metabolism

Speed of Fatigue

Speed of myosin hydrolysis

Main function

Answer 26

Red Fibers

Type of Metabolism: Oxidative Glycolytic (Mitochondria)

Speed of Fatigue: Slow

Speed of myosin hydrolysis: Slow

Main function: Posture

Question 27

Describe Type IIb Muscle Fibers:

Type of Metabolism

Speed of Fatigue

Speed of myosin hydrolysis

Main function

Answer 27

White Fibers

Type of Metabolism: Glycolytic (not many mitochodria)

Speed of Fatigue: Fast

Speed of myosin hydrolysis: Fast

Main function: Force Generation (Sprinting, Lifting, Fighting)

Question 28

What are satellite cells in skeletal muscle?

Answer 28

These are cells that function in skeletal muscle repair, and give us the basis of lifting weights to make our muscles stronger.

When activated, they become mature muscle cellsin order to replace those damaged or lost

Question 29

What is the skeletal muscle triad?

Answer 29

The triad refers to the structure of sarcoplasmic reticulum “split” by the transverse tubule (T tubule) on histological examination

Question 30

What is the name of cardiac muscle cells?

Answer 30

Myocytes

Question 31

Where is cardiac muscle found? Is it voluntary or involuntary?

Answer 31

Only found in the heart

Involuntary muscle fiber

Question 32

What are some key structural features of cardiac muscle?

Name 5

Answer 32

1) Cross striations (similar to those in skeletal muscle, but more stair-like)
2) Intercalated discs: Zonula adherens and Macula adherens (desmosome) hold cells together in a “stair and riser arrangement”
3) Intermittent Mitochondria
4) Centrally located spherical nuclei
5) Gap Junctions between cells

Question 33

How is the contraction of heart muscle controlled?

Answer 33

Cardiac muscle contracts due to electrical stimulation originating from the Sino-Atrial Node in the heart itself

Question 34

What specialized groups of cells are responsible for the electrical stimulus generated at the Sino Atrial (SA) node?

Answer 34

The pacemaker cells generate signals without specific instructions from nerves (though their activity may be modulated by nerves).

Question 35

What is the purpose of Purkinje fibers?

Answer 35

Purkinje fibers help to spread electrical stimulation throughout the heart extremely quickly.

They allow our ventricles and atria to contract in synchronicity.

Question 36

Purkinje fibers are rich in what two things?

Answer 36

Mitochondria

Glycogen granules

Question 37

Purkinje fibers are a modified version of what other fiber?

Answer 37

Cardiac Myofibers!

Question 38

Identify the indicated structure

Answer 38

Question 39

Identify the indicated structures

Answer 39

Question 40

What is the bundle of His?

Answer 40

A section of conducting fibers (like Purkinje Fibers) that carry the electric stimulus from the Atrio-Ventricular (AV) Node to the Ventricles

Question 41

What is the Atrio-Ventricular Node (AV Node)?

Answer 41

It is an area filled with specialized conducting cells similar to the Sino-Atrial Node.

Question 42

What is the function of the AV Node?

Answer 42

It serves to delay the impulses from the SA node so that the atria have time to squeeze blood into the ventricles before the ventricles contract.

Question 43

How does the heart respond to injury/stress?

Think two processes

Answer 43

Hypertrophy (cells here do not replicate, they just get larger)

Injured tissue is replaced by fibrotic scars (preserves ability to contract)

Question 44

What is the function of cardiac muscle?

Answer 44

To contract in a rhythmic manner to pump blood throughout our body

Question 45

What is the main function of smooth muscles?

What are some examples?

Answer 45

Involuntary control of organ shape:

Blood vessels

Respiratory Passages

Bladder

etc

Question 46

From which embryonic layer do smooth muscle cells originate?

Answer 46

Mesoderm

Question 47

Through what process are smooth muscle cells created?

Answer 47

Myogenesis

Question 48

How are smooth muscles typically organized as a whole?

Answer 48

In sheets or bundles

Question 49

What is the organization of the contractile unit of smooth muscle cells?

Answer 49

Still actin-myosin unit, but there are no Z lines or sarcomeres.

Instead, actin is bound to the plasma membrane at structures called dense bodies

Question 50

What are the two types of smooth muscles?

Answer 50

Multi-unit

Single-unit (Unitary)

Question 51

Why are multi-unit muscles called multi-unit?

Answer 51

NOT structural

These muscle fibers have many motor units that are each innervated separately from one another and contract INDEPENDENTLY from each other

Thus there are many units within one “muscle”

Question 52

Why are single-unit muscles called single-unit?

Answer 52

NOT structural

These muscles have many units that are interconnected to each other through gap junctions, and therefore contract as one large unit

Question 53

What muscle type is similar to unitary smooth muscle?

Answer 53

Cardiac muscle

Question 54

Where might one find multi-unit smooth muscles within the human body?

Answer 54

In arteries, iris, pulmonary air passages, and arrector pili muscles

Question 55

Where might one find unitary smooth muscle in the human body?

Answer 55

In blood vessels and viscera as circular/longitudinal muscle layers

Question 56

What are some distinguishing structural characteristics of smooth muscle?

Name 3

Answer 56

1. Cells are spindle-shaped
2. One nucleus per cell, located in the center of the cell. “Corkscrewed” nucleus indicates a cell that is contracted
3. NO STRIATIONS

Question 57

Through what structure are skeletal muscles innervated?

What about smooth muscles?

Answer 57

Skeletal: Neuromuscular Junction (NMJ)

Smooth: Varicosities of innervating nerves

Question 58

How does smooth muscle respond to stress?

Answer 58

Both hypertrophy AND hyperplasia

Question 59

Identify the muscle types and some characterisitics:

Answer 59

Question 60

What is Excitation-Contraction (EC) Coupling?

Answer 60

It is the process by which a nerve’s excitation of a muscle cell leads to its contraction

Question 61

What happens when a nerve excites a muscle cell?

(Up to Ca release from SR)

Answer 61

1) At NMJ, action potential leads to acetylcholine release from synaptic bouton
2) acetylcholine binds acetylcholine-gated channels, allowing Na to flow into and K to flow out of the muscle cell
3) muscle cell becomes depolarized, leading to opening of voltage gated Na and K channels
4) as the depolarization spreads throughout the muscle cell, it dives into the cell through the transverse tubule to cause Ca release from the sarcoplasmic reticulum

Question 62

What happens once Ca is released from the SR?

Go to end of Myosin cycling

Answer 62

1) Calcium binds to troponin, opening cross-bridge sites on Actin
2) Actin forms cross-bridge with Myosin-ADP-P
3) Myosin ratchets, pulling actin towards the M line, ADP and P released
4) ATP binds Myosin, causing release of Actin
5) Myosin hydrolyzes ATP, cocking itself back to the start

This is the process of Myosin hydrolysis, or “cycling”

Question 63

What happens once nerve excitation of a muscle cell ends?

Answer 63

1) Calcium channels in SR (sarcoplasmic reticulum) close
2) Ca is rapidly taken into the SR by Ca ATPase pump
3) once Ca levels are low (happens very quickly), troponin C no longer binds Ca
4) tropomyosin is moved back into its place, covering the cross-bridging sites of actin
5) Contraction ceases

Question 64

What two things (1 molecule, 1 ion) are directly critical for skeletal muscle contraction?

Answer 64

Calcium

ATP

Question 65

The muscle cell’s plasma membrane s also known as …

Answer 65

The sarcolemma

Question 66

The channel which releases the calcium from the SR is known as the…

Answer 66

Ryanodine Receptor

Question 67

What is the name of the protein that reaches from the T-tubule to interact with the Ryanodine Receptor?

Answer 67

The Dihydropyridine Receptor

Question 68

What is the source of Ca for muscle cell contraction?

Is it intracellular, or extracellular?

Answer 68

The Sarcoplasmic Reticulum (SR), which is intracellular

Question 69

How can you increase the force generated by a muscle contraction?

Answer 69

Increase the frequency of muscle cell excitation

Increase the number of motor units recruited

Question 70

What are two major difference between cardiac muscle and skeletal muscle in regards to generating a muscle contraction?

Answer 70

No NMJ (neuromuscular junction) for cardiac muscle

Calcium Induced Calcium Release (via voltage gated calcium channels in the T-tubules)

Question 71

What is the function of Calcium Induced Calcium Release (CICR)?

Answer 71

It is the mechanism by which cardiac myocytes release calcium from the SR for muscle contraction.

Question 72

What is different about the role of Calcium in smooth muscle contraction versus skeletal muscle contraction?

Answer 72

In smooth muscle, calcium binds Calmodulin to change myosin activity

In skeletal muscle, calcium binds troponin C to change actin activity.

Question 73

How does calcium activate contraction in smooth muscles?

Answer 73

1) Calcium binds calmodulin (forming Ca-Calmodulin)
2) Ca-Calmodulin binds to and activates Myosin Light Chain Kinase (MLCK)
3) Ca-MLCK phosphorylates a regulatory myosin light chain head, allowing associated myosin heads to form a cross-bridge with Actin
4) Muscle contraction occurs

Question 74

How does smooth muscle contraction halt?

Answer 74

This is completed by two separate events, causing increased phosphatase activity, and decreased kinase activity:

1) A Myosin Light Chain Phosphatase (MLCP) removes the Phosphate from the regulatory myosin head
2) Ca levels are reduced due to the cessation of excitation, leading to lowered levels of Ca-calmodulin, and ultimately reduced levels of Ca-MLCK.

Question 75

What does curare do to skeletal muscle?

Answer 75

Curare blacks acetylcholine from reaching the acetylcholine-gated ion channels, halting the E-C process at the NMJ. This causes loose muscle paralysis

Bonus: Curare is a poison derived from plants in Central and South America used for arrow tip poisoning.

Question 76

What is an autoimmune condition affecting skeletal muscle at the NMJ?

Answer 76

Myasthenia Gravis

Antibodies block acetlycholine receptors

Question 77

What happens when you change the excitability of the sarcolemma?

Increase:

Decrease:

Answer 77

Increase: spontaneous voltage sensor activation leading to hypercontractility/stiffness

Ex: Congenital Myotonia

Decrease: Reduced membrane excitability leading to loose paralysis or weakness

ex: Periodic Paralysis

Question 78

What happens when you have an uncontrolled release of calcium from the sarcoplasmic reticulum?

Name a condition where this occurs and its cause.

Answer 78

Hypercontractility/stiffness

Condition: Malignant Hyperthermia

Cause: Mutations in the Ryanodine Receptor leading to decreased activation thresholds (easier to release Ca) and increased deactivation thresholds (harder to close Ca release channel)

Question 79

What happens when the myofilaments cannot bind calcium well?

Answer 79

You get fatigue which causes weakness

Question 80

What is dermatomyositis?

Answer 80

An inflammatory isorder of the skin and skeletal muscle

Question 81

What are the clinical features of dermatomyositis?

Answer 81

1) Bilateral, proximal muscle weakness (distal later in disease)
2) Heliotrope rash (upper eyelids), maybe malar rash (upper jaw)
3) Red papules on elbows, knuckles, and knees (flexor surfaces)

Question 82

What lab findings come with dermatomyositis?

Answer 82

1. increased creatine kinase
2. positive ANA and anti-Jo-1 antibody
3. perimysial inflammation (CD4 T cells) w/perifascicular atrophy on biopsy

Question 83

What is the treatment for dermatomyositis?

Answer 83

Corticosteroids

Question 84

What is polymyositis?

Answer 84

Inflammatory disorder of skeletal muscle

Question 85

What is a clinical difference between polymyositis and dermatomyositis?

Answer 85

The skin is not involved in polymyositis

Question 86

What lab finding do we have with polymyositis?

Answer 86

endomysial (CD8 T cells) w/necrotic muscle fibers seen on biopsy

Question 87

What happens in patients with x-linked muscular dystrophy?

Answer 87

muscle wasting and replacement of skeletal muscle by adipose tissue, degenrative disorder

Question 88

What is the defect found in x-linked muscular dystrophy?

Answer 88

Mutation in the dystrophin gene

Often mutations are spontaneous due to the large size of the dystrophin gene

Question 89

What is the function of dystrophin?

Answer 89

Anchors muscle cell cytoskeletons to the ECM

Question 90

What are two examples of x-linked muscular dystrophy?

Answer 90

Duchenne Muscular Dystrophy

Becker Muscular Dystrophy

Question 91

What is the difference between Becker and Duchenne muscular dystrophy

Answer 91

Duchenne is a DELETION of the dystrophin gene, whereas Becker is simply a mutation in that gene

Same issues between the diseases, but Becker is a milder version of Duchenne

Question 92

What are the clinical signs of Duchenne muscular dystrophy?

Answer 92

1. presents as proximal muscle weakness at ~1 year of age; progresses to distal muscles
   
   1. characteristic finding: calf pseudohypertrophy (enlargement of the calf)
2. serum creatine kinase is elevated
3. Death results from cardiac or respiratory failure; myocardium is commonly involved (average life expectancy = 25)

Question 93

Describe Type IIa Muscle Fibers

Type of Metabolism

Speed of Fatigue

Speed of myosin hydrolysis

Answer 93

Intermediate Fibers

Fast Oxidative Glycolysis

Do not fatigue easily (slow)

Intermediate