neuromuscular/case 9

Question 1

What is fitness?

What types of fitness?

Answer 1

physically and psychologically able to meet demands of your environment

health related fitness
skill related fitness

Question 2

What is endurance? (aerobic and muscular)

Answer 2

aerobic: ability of body to sustain a high work rate, maintain technical quality and concentration throughout a training session or event without fatigue
muscular: ability of muscles to carry our repeated contractions without fatigue

Question 3

How is chemical energy generated?

Answer 3

ATP through:

• anaerobic resp: glycolysis in absence of 02 (produces lactate)
• aerobic respiration (in presence of 02)

Question 4

What are the different anaerobic systems?

Answer 4

• lactate

- ATP-PC (ATP-phosphocreatine)

Question 5

What are the different stages in training load?

Answer 5

stimulus
fatigue
compensation
overcompensation (when you do better than initial fitness)

Question 6

What is overtraining syndrome?

Answer 6

training loads too intense and fitness becomes a negative improvement (instead of pos improvement)

• -> physical changes such as stress fractures
• -> emotional and behavioural changes

Question 7

What is VO2 max?

Answer 7

rate of volume of oxygen consumption while working at maximal capacity ml/O2/Kg/min

Question 8

What does VO2 max show?

Answer 8

innate ability to perform endurance sports

Question 9

What is the anaerobic threshold?

Answer 9

change from using mitochondrial pathways to glycolytic pathways

Question 10

How does anaerobic threshold relate to recovery from surgery?

Answer 10

the higher it is, the better you will do post surgery

Question 11

What is isometric contraction?

Answer 11

maintain constant length, but increase in tension

Question 12

Why can’t muscles contract beyond their optical length?

Answer 12

actin and myosin have been pulled so far apart/ too squished

Question 13

What is isotonic contraction?

Answer 13

muscle shortens but constant load

Question 14

What is fine control?

Answer 14

few muscle fibres per motor unit

Question 15

What is coarse control?

Answer 15

many muscle fibres per motor unit

Question 16

large motor unit:
motor neuron
muscle fibres
activity

Answer 16

large, fast conduction, hard to excite
many, type 2 (glycolytic)
recruited if strong, contraction is required, usually inactive

Question 17

small motor unit:
motor neuron
muscle fibres
activity

Answer 17

small, slow conduction, easy to excite
few, type 1 (oxidative)
first to be recruited, frequently active

Question 18

lower motor neurone lesion:
muscle strength
paralysis
muscle tone
reflexes

Answer 18

weakness
flaccid
hypotonia
hyporefelxia

Question 19

upper motor neurone lesion:
muscle strength
paralysis
muscle tone
reflexes

Answer 19

weakness
spastic (up regulation of Ach receptors: respond to stray Ach)
hypertonia (muscles hard to move, feel heavy)
hyperreflexia (CNS is not inhibiting reflexes)

Question 20

What happens in the stretch reflex?

Answer 20

tendon tap - stretch muscle - stimulate muscle spindles -excite motor neurone/excites inhibitory interneurone - agonist muscle contraction/antagonist muscle relaxation

Question 21

What distance does the muscle shorten at every contraction?

Answer 21

4nm

Question 22

What are the ELC and RLC parts of myosin? Where are they found?

Answer 22

ELC: essential light chain (also called Alkali)
RLC: regulatory light chain

light chains

Question 23

What is a myofibril?

Answer 23

collection of sarcomeres

Question 24

What regulates binding of myosin to actin?

Answer 24

troponin T, C and I molecules
alpha-tropomyosin: wraps around actin and covers actin binding sites (release and binding of Ca to troponin uncovers binding sites)

Question 25

What roles do troponin T, C and I have in muscle proteins contraction?

Answer 25

globular protein

troponin C: Ca binding site: makes conformational change in TnI

troponin T: binds to tropomyosin and forms troponin-tropomyosin complex + inhibits actin-myosin binding unless Ca present

troponin I: binds to actin: holds troponin-tropomyosin complex in place

Question 26

How many cycles of binding and detachment to actin does a muscle go through every time it twitches?

Answer 26

100-1000

Question 27

What is the striatal muscle contraction cycle?

Answer 27

1. ATP binds to myosin head, causing the dissociation of the actin-myosin complex
   - -> released state
2. ATP is hydrolysed, causing myosin heads to return to their resting conformation (ADP+ P)
   - -> cocked state
3. a cross-bridge forms and the myosin head binds to a new position on actin
   - -> cross bridge state
4. P is released. myosin heads change conformation, resulting in the power stroke. the filaments slide past each other
   - -> power-stroke state
5. ADP is released
   - -> attached state

Question 28

What is myasthenia gravis?

Answer 28

long term neuromuscular disease that leads to varying degrees of skeletal muscle weakness due to autoimmune disease: have an antibody to the Ach receptors: muscles fatigue very quickly (inactive the receptor): CNS has to make huge demand on muscle to get a normal response

Question 29

Why are T tubules important?

Answer 29

spreads excitation deep into cell: for even contraction of the cell

Question 30

What is the sarcoplasmic reticulum and what does it contain?

Answer 30

folded bit of membrane that contains a lot of calcium

Question 31

What are the different receptors of the Sarcoplasmic reticulum?

Answer 31

• RoR (ryanodine receptors): detect change in membrane potential and in response with release calcium from SR
• dihydropirine receptor

Question 32

What happens when an AP reaches the sarcolemma until contraction?

Answer 32

• cytoplasmic calcium increases
• calcium interacts with troponin
• twitch force (slight delay)
• -> as long as there is Ca and ATP, there will be repeated cycling of myosin heads

Question 33

what is actin?

Answer 33

40KD globular protein that associates to form filaments: major component of thin filament

Question 34

What is tropomyosin?

Answer 34

thin filament component binding to actin

Question 35

What is myosin?

Answer 35

200kD globular head coupled to long coiled-coil tail + hinge
+ two 20kD light chains
–> binds and hydrolyses ATP, undergoing a conformational change in the head

Question 36

What is alpha-actinin?

Answer 36

cross-links actin filaments at the sarcomere Z line/disks: need it to create muscle fibres

Question 37

What is titin?

Answer 37

very long filamentous protein, links Z lines to M lines (largest protein that exists)

Question 38

What are myomesins?

Answer 38

binds to titin

generate hexagonal packing of thick filaments

Question 39

What does vinculin bind to?

Answer 39

alpha-actinin

Question 40

What does cap-Z do?

Answer 40

caps the +ends of actin filaments at the Zline/disk

Question 41

What does tropomodulin do?

Answer 41

caps the -ends of thin filaments

Question 42

What does desmin do?

Answer 42

links together myofibrils at the Zdisk/line

Question 43

What does dystrophin do?

In what disease is it mutated/absent?

Answer 43

links actin filaments to the muscle cell outer membrane

mutated/absent in Duchenne Muscular Dystrophy

Question 44

What does Nebulin do?

Answer 44

determines the length of thin filaments

Question 45

What determines the types of muscle cell it becomes (type 1, 2A or 2B)?

Answer 45

gene expression is governed by firing pattern of motor neurone

Question 46

When do you start expressing more than one type of myosin?

Answer 46

embryogenesis and early life

Question 47

How many ATP molecules are made from one 02 molecule?

Answer 47

38

Question 48

How many ATP molecules are made from glucose by substrate level phosphorylation?

Answer 48

2

Question 49

What is the Cori cycle?

Answer 49

oxygen is used by liver to produce glucose from lactate (regeneration of glucose)

Question 50

What are the different energy store use in muscles from seconds to minutes/hours?

Answer 50

• ATP-PC
• anaerobic glycolysis
• oxidative system (mitochondria)

Question 51

How does exercise affect mitochondria?

Answer 51

• increase muscle mitochondria biogenesis via
  1. Ca signalling pathway in the cell
  2. chronic imbalance of ATP demand virus production by mitochondria which case activation of signalling protein kinases

Question 52

What are the effects of lack of exercise (in relations to muscle atrophy?

Answer 52

drop in :

• protein levels
• fibre diameter
• force production
• fatigue resistance

–> increase protein degradation and reduce protein synthesis pathways contribute to muscle loss due to misuse

–> programmed biological process due to lack of exercise

Question 53

What pathway is involved in muscle atrophy? What transcription factors?

Answer 53

• proteolytic (ubiquitin-proteasome, lysosomal and calpaan)

- NF-KB and myostatin (transcription factors)

Question 54

Why is the presynaptic neurone of a neuromuscular junction wrapped in Schwann cell?

Answer 54

-stops extracellular ions, blood etc depolarising cell and changing cellular activity

Question 55

Why are junction folds used in post-synaptic terminals of neuromuscular junctions?

Answer 55

increase quantity of receptors: not miss any transmitters (make transmission as robust as possible

Question 56

What are the different steps in depolarisation?

Answer 56

• sodium channels open
• sodium moves in (down concentration and electrical gradient)
• AP reaches top peak, Na channels turn themselves off (ball and chain inactivation)

Question 57

What are the different steps in depolarisation?

Answer 57

• sodium channels close
• potassium channels open (open slower than Na channels)
• potassium moves out along concentration gradient
• return of electrical potential to neg inside
• takes 1 ms of ATPase to bring membrane to its normal resting potential (hyper polarised)

Question 58

What are the different steps of neurotransmission at NMJ?

Answer 58

1. AP
   - depolarised pre-synaptic terminal
   - activated voltage gated Ca channels
2. Ca2+ entry
   - triggers vescicole fusion
3. vesicle fusion
4. Ach release
5. ACh receptor activation
6. current propagation
7. ACh removal

Question 59

What happens in vesicle fusion?

Answer 59

SNARE hypothesis: (proteins)

• v-SNAREs (vesicle): synaptobrevin, synaptotagmin
• t-SNAREs (target membrane): syntax, SNAP-25
• -> as Ca comes in: binds to synaptotagmin, pulling proteins tighter and membranes to fuse

-happens at active zone (T bars): micro domain

Question 60

What are the different steps in and following ACh receptor activation?

Answer 60

1. ACh release
2. ACh bind to receptor and open ligand gated sodium channels (only respond to ligand or neurotransmitter: conscious pathway)
3. Na enters cell though electrical and concentration gradient (microdoamins causing depolarisation-)
4. voltage gated sodium channels open in response (allowing more Na in (micro domain)
5. Start an AP in muscle and spread down transverse tubule
6. Ca channels open (due to AP):
   -slight increase in intracellular AP
   + release from SR
   –> interaction of myosin and actin
7. muscle contraction

Question 61

What is acetylcholine made from? What synthesis it?

Answer 61

• choline
• acetyl coenzyme A

-ChAT (choline acetyltransferase)

Question 62

What is the vesicle ACh transporter?

Answer 62

VAChT (vesicular ACh transporter)

Question 63

What breaks ACh down? What ACh broken down into?

Answer 63

-AChE (ACh esterase)

• choline
• acetic acid

Question 64

What happens to choline and acetic acid?

Answer 64

• choline: gets transported back into presynaptic by choline transporters
• acetic acid is screwed as liquid waste though kidneys

Question 65

What are the different types of ACh receptors?

• location
• agonist/antagonists
• type

Answer 65

-nicotinic
skeletal muscles
agonist: nicotine
antagonists: curare
type: inotropic (Na, fast excitatory)

• muscarinic
  agonist: muscarine
  antagonist: atropine
  type: metabotropic (K permeability, slow excitatory and inhibitory)

Question 66

What is EPP and what does it do?

Answer 66

end plate potential

triggers AP is muscle fibre

Question 67

Which toxins affect the NMJ?

Answer 67

botulinum toxin
tetanus
tetrodotoxin (TTX)
curare
bungarotoxin
Sarin/VX

Question 68

What do the botulinum toxin and tetanus do?

Answer 68

enzymatically cleaves synaptobrevin

Question 69

What does Sarin/VX do?

Answer 69

irreversible inhibitor of AChE