Lecture: 11 Muscle Tissue

Question 1

Compare and contrast cardiac & smooth muscle (3 points).

Answer 1

C+S= 1 contractile unit 
C+S= central nuclei
C+S= Act as syncytium (multiple cells fused as 1)
C+S= Myocytes communicate via gap junctions
C+S= indirect nerve-muscle communication 

C= striated (sarcomeres)        S= not striated
C= troponins 1+2           S= no troponins
C= specialised electrical conduction cells (purkinje)
C= 1/2 nuclei        S= only 1 nucleus

Question 2

Compare and contrast cardiac & skeletal muscle (3 points).

Answer 2

C+S= both striated
C+S= both contain myoglobin
C+S=both have T tubules

C= sarcomere contractile unit  S=slow/fast twitch contractile unit
C= direct nerve-muscle communication      S=indirect
C= central nuclei     S= peripheral 
C= few T tubules     S= many T tubules

Question 3

Compare and contrast smooth & skeletal muscle (3 points).

Answer 3

Both= both have actin and myosin

SK= striated   SM= not striated
SK= troponin    SM= no troponin
SK= Myb            SM= no Myb
SK= peripheral nuclei    SM= central nuclei
SK= voluntary   SM= involuntary

Question 4

Which of the 3 types of muscles are striated?

Answer 4

Skeletal and cardiac

Question 5

Which of the 3 muscles uses indirect nerve-muscle communication?

Answer 5

Cardiac and smooth

Question 6

What is myoglobin and compare it to haemoglobin?

Answer 6

A red protein similar to a singular subunit of Hb and has a higher affinity for solely O2.

Question 7

What is myoglobinaemia and what are the consequences of it?

Answer 7

High Myb blood levels due to muscle necrosis or rhabdomyolysis. Too much Myb causes renal damage as this can block the glomerulus since the kidney is supposed to remove it from blood. Causes tea-coloured urine.

Question 8

When is myoglobin (Myb) used instead of Hb?

Answer 8

Myb stores O2 for when needed in anaerobic conditions. The higher affinity of O2 means it can more easily bind to O2.

Question 9

What are the muscular equivalents of…

1. Cell membrane
2. Cytoplasm
3. SER
4. Mitochondria

Answer 9

1. Sarcolemma
2. Sarcoplasm
3. Sarcoplasmic reticulum
4. Sarcosome

Question 10

What is a sarcomere?

Answer 10

Contractile unit of cardiac and smooth muscle where 1 unit is between 2 adjacent Z lines.

Question 11

What does the skeletal hierarchal muscle structure consist of?

Answer 11

Muscle–>Fascicles–>Muscle fibre/cell/myocyte—> Myofibrils

Question 12

If the muscle striations are vertical, in which direction will the muscle contract?

Answer 12

Imagine the striations are the z lines. During contraction the z lines move closer together, resulting in lateral contraction.

Question 13

What are the connective tissues surrounding the structures of the muscle?

Answer 13

Epimysium around muscle; perimysium around fascicles; endomysium around fibres

Question 14

Name 3 muscle shapes in terms of muscle movement direction.

Answer 14

Convergent Parallel
Unipennate Fusiform
Bipennate Circular

Question 15

What is created at the point of origin?

Answer 15

Tension

Question 16

Where is tension created (in terms of anatomy)?

Answer 16

Point of origin

Question 17

What is created at the insertion tendon point?

Answer 17

Movement

Question 18

Where is movement created (in terms of anatomy)?

Answer 18

Insertion tendon point

Question 19

What is an extrinsic muscle and give an example?

Answer 19

Part of the muscle where the origin is further from the movement and typically has insertions in bone/cartilage. Eg: tongue geniohyoid muscle.

Question 20

What is an intrinsic muscle and give an example?

Answer 20

Completely contained in an organ or contained in the part that it acts on: typically muscle attached to muscle. Eg: vertical or transverse muscles of tongue.

Question 21

Describe the dark band of sarcomeres.

Answer 21

Mostly myosin band called A band and found between I bands.

Question 22

Describe the light band of sarcomeres.

Answer 22

Actin band called I band and found between A bands.

Question 23

What happens in a muscular contractile unit during contraction?

Answer 23

Sarcomere shortens.
Z lines come closer together.
Myosin and actin slide over each other.
M line doesn’t move.

Question 24

What is the H band of sarcomeres?

Answer 24

Part of the A band where there is no actin at all.

Question 25

What are the 2 contractile units of skeletal muscles?

Answer 25

Fast and slow twitch muscles

Question 26

What type of catabolic processes do slow twitch fibres rely on?

Answer 26

Slow oxidative processes like oxidative phosphorylation.

Question 27

What type of catabolic processes do fast twitch fibres rely on?

Answer 27

Fast glycolytic processes

Question 28

Give 5 differences between fast and slow twitch fibres.

Answer 28

F= white colour S= Red colour
F= few mitochondria S= Many mitochondria
F= few cytochromes S= many cytochromes
F= poorer blood supply S= richer blood supply
F=fast contraction speed S=slow contraction speed
F= short contractions S= longer contractions
F= larger fibre diameter S= smaller fibre diameter
F= lots ATP/few CO2 S= few ATP/ lots CO2
F= running, jumping S= walking, standing

Question 29

Which muscle do you find intercalated discs and what do they do?

Answer 29

Cardiac muscle. They allow electrical signals and ions to pass cell to cell; connect adjacent cells to form a bigger, syncytium-like cell.

Question 30

Why is cardiac muscle not considered true syncytium tissue?

Answer 30

Cardiac muscles are originally individual myocytes. They only act like syncytial tissue due to intercalated discs interacting with other cells: hence multiple cells acting as 1 larger cell.

Question 31

What happens when an intercalated disc breaks/separates between 2 muscle cells?

Answer 31

The myocyte is going to die and fibroblasts will fill the space with connective tissue; leaving a scar.

Question 32

What is an intercalated disc?

Answer 32

Made of gap junctions, tight junctions, desmosomes, adherence junctions that attach myocytes together into branches.

Question 33

What does the heart release during heart failure?

Answer 33

ANP (atrial natriuretic peptide) and BNP (brain natriuretic peptide)

Question 34

When is ANP released?

Answer 34

During congestive heart failure

Question 35

When is BNP released?

Answer 35

During left ventricular hypertrophy or bicuspid/mitral valve disease.

Question 36

How do ANP and BNP reduce heart failure?

Answer 36

Both hormones work to reduce BP in the heart by decreasing blood vol. and vascular resistance.
This is done by increasing more fluid into kidneys’ collecting duct so less water goes to the blood vol.

Question 37

Briefly give an overview of the heart conducting system.

Answer 37

1. SAN signals via Bachmann bundles.
2. Signal causes atrial systole and stimulates AVN.
3. AVN sends impulse down septum and reaches purkinje fibres.
4. Cause ventricular systole from the bottom up.

Question 38

Why is it important for the atria and ventricles to not contract simultaneously?

Answer 38

This allows ventricles to fill up fully with blood before systoles so more blood is pumped out of the heart at once.

Question 39

How are purkinje fibres adapted to their function?

Answer 39

Lots of glycogen and intercalated cells!!! Electricity can move rapidly due to many gap junctions (in intercalated discs) so ventricles contract simultaneously.

Question 40

What clinical problems can occur due to involuntary muscles and why?

Answer 40

Painful menstruation IBS
Hypertension Incontinence (bladder)
Asthma

Involuntary muscle can have a mind of its own.

Question 41

What can happen if there is Ca2+ ions in the muscle for a prolonged period of time?

Answer 41

Ca2+ are required for muscle contraction so having it in muscles for a long time means that the contraction will last a longer time. Too long could lead to cell damage.

Question 42

Which of the 3 mature muscle types repair itself?

Answer 42

Cardiac adult = not really as stem cells from bone marrow- instead fibroblast divide and lay down scar tissue.

Cardiac children= can due to retaining fetal myotubules

Skeletal= need satellite cells mitosis so differentiates into skeletal then hyperplasia or hypertrophy + fusing with existing cells.

Smooth= very well as retain mitotic ability

Question 43

A patient is diagnosed with multisystemic SM dysfunction syndrome where they have GI problems, a weak bladder and respiratory infections. Which structure of muscle tissue is unique to SM and could be responisble?

Answer 43

The fact that actin and myosin filaments assemble on the dense bodies during contraction.

Question 44

A 5 yrs boy has a small tear in his calf muscle (falling off his bike) and is told to rest so the muscle can regenerate. Which MSK repair mechanism is likely to take place?

Answer 44

Muscle satellite cells can proliferate then differentiate into myofibres.

Question 45

If a patient comes is and has a suspected MI, their plasma troponin would be monitored. Which troponin(s) would be a clinical marker and describe how long they would remain in the blood for.

Answer 45

Troponin I+T (not C) would be released over the next 7 days where you have a very sudden increase then a gradual decline.

Question 46

A healthy person’s muscle I band is 1.0μm and their A band is 1.5μm. During contraction, their sarcomeres shorten by 10%. How long would the A band be now?

a) 0.45μm
b) 0.90μm
c) 1.00μm
d) 1.35μm
e) 1.50μm

Answer 46

e) 1.50μm

When striated muscle fibres contract, sarcomeres shorten and the z-lines come closer together. However, A and I bands don’t shorten because they slide over each other.

Question 47

A 15yrs boy has ptosis (drooping eyelids) and other symptoms of myasthenia gravis. Which structure in a normal neuromuscular junction would be missing from this patient?

Answer 47

Endplate invaginations which is where ACh receptors are inserted.

Question 48

2 people are discussing the mechanism of striated muscle contractions. Which primary contraction event is caused by Ca2+ ions?

Answer 48

Ca2+ interacts with the troponin-tropomyosin complex so a conformational change occurs within the complex to reveal the myosin binding site on G-actin.

Question 49

A boy is diagnosed with Duchenne muscular dystrophy which is caused by a dystrophin protein mutation. Describe how the mutation causes this condition.

Answer 49

X-linked recessive condition that affects the dystrophin protein. This protein usually inserts into the sarcolemma but the mutated protein doesn’t do that. Resulting in: poor balance, strange gait, shoulders and back are held posterior to the midline.

Question 50

A farmer uses a organophosphate pesticide without proper protective equipment. Consequently, he presents in a state of delirium, GI cramps and MSK fasciculations (involuntary twitches). Which component of the neuromuscular junction is affected?

Answer 50

Organophosphates bind and inactivate ACh esterase in the neuromuscular junction. As a result, ACh is degraded by this enzyme: which results in these signs and symptoms.

Question 51

After undergoing surgery, the patient is given succinylcholine as part of their anaesthetic regimen. However, they develop symptoms of hyperthermia due to an unrecognised gene mutation. Which part of the contraction pathway is likely to be defective in the this patient?

a) sarcolemma
b) sarcoplasmic reticulum
c) transverse tubule
d) ryanodine receptor (RyR1)
e) dihydropyridine receptor (DHPR)

Answer 51

d) ryanodine receptor (RyR1)

Mutations in the RyR1 can cause malignant hypothermia.
Since the patient has hyperthermia, there is probably a mutation in this receptor as it concerns internal temperature.