Muscular contraction

Question 1

What are the three muscle types?

Answer 1

Smooth muscle
Cardiac muscle
Skeletal muscle

Question 2

What type of control is smooth muscle under control by?

Answer 2

Involuntary control from the autonomic nervous system

Question 3

Describe the nucleation of smooth muscle

Answer 3

Mononucleated

Question 4

Describe the nucleation of cardiac muscle

Answer 4

Mononucleated

Question 5

How are cardiac cells connected?

Answer 5

Physically and electrically connected, ensuring that contraction signals are transmitted through cells, and the entire heart contracts as a single unit

Question 6

What type of nervous control, controls cardiac muscles?

Answer 6

Autonomous (myogenic)

and under influence of autonomic nervous system (cardiac control centre)

Question 7

What is the nucleation of skeletal muscles?

Answer 7

Multinucleate

Question 8

Which type of control are skeletal muscles subjected to?

Answer 8

Voluntary control by the somatic nervous system

Question 9

How are skeletal muscles attached to bone?

Answer 9

Attached via tendons, consequently facilitating movement of bone through contraction

Question 10

What connective tissue sheath wraps muscle?

Answer 10

Epimysium

Question 11

What is the purpose of the epimysium?

Answer 11

Enables muscle to contract and more powerfully while maintain structural integrity.

Question 12

How are muscle fibres arranged?

Answer 12

Arranged in bundles, known as fascicles

Question 13

Which connective tissue layer surrounds the fascicles?

Answer 13

Perimysium

Question 14

How does the fascicular arrangement support muscular contraction?

Answer 14

Triggers specific movement of a muscle by activating a subset of muscle fibres within a fascicle of the muscle

Question 15

What is contained within each fascicle?

Answer 15

Myofibres, encased in a thin layer of collagen and reticular fibres, the endomysium

Question 16

Which layer surrounds the outer layer of each myofibre?

Answer 16

Endomysium

Question 17

What is the endomysium?

Answer 17

Surrounds the extracellular matrix of cells, plays a role in transferring force produced by muscle fibres to tendons

Question 18

What is the term used to describe the plasma membrane of myofibres?

Answer 18

Sarcolemma

Question 19

What is the term used to define the cytoplasm of myofibres?

Answer 19

Sarcoplasm

Question 20

Which proteins are spent in myofibrils?

Answer 20

Myosin and actin

Question 21

What is the smallest functional unit of a skeletal muscle fibre?

Answer 21

Sarcomere

Question 22

What are t tubules?

Answer 22

Extensions of the sarcolemma that penetrate into the centre of skeletal muscle cells, a conduit of action potentials

Question 23

What is the role perfumed by the sarcoplasm?

Answer 23

Cytoplasm of myocyte consisting of greater proportion of glycogen granules, myoglobin and mitochondria

Question 24

What is the sarcoplasmic reticulum?

Answer 24

Network of fluid-filled tubules, constitutes the main intracellular calcium store in striated muscle, cardinal role in the regulation of excitation-contraction coupling.

Question 25

What is the line that defines the region of a micofibril contained between two cytoskeletal structures?

Answer 25

z lines

Question 26

Why is there a strained appearance of skeletal muscle fibres?

Answer 26

This is due to the arrangements of the thick and thin myofilaments within each sarcomere.

Question 27

What is the A band?

Answer 27

Composed of thick filaments, containing myosin, span the centre of the sarcomere, extending towards the Z-discs

Question 28

Which protein comprises the thick filaments?

Answer 28

Myosin

Question 29

What is the M-line?

Answer 29

Thick filaments are anchored at the middle of the sarcomere by myomesin

Question 30

What is the I band?

Answer 30

Lighter regions contain thin actin filaments anchored at the z-discs by alpha-actinin. The thin filaments extend into the A band towards the M-line overlapping the regions of thick filaments.

Question 31

Why is the A band darker?

Answer 31

Due to the thicker composition of myosin filaments, in addition to overlapping actin filaments

Question 32

What is the H-zone?

Answer 32

Middle of the A band, thin filaments do not extend into this region, there is no actin present.

Question 33

What does a single sarcomere contain?

Answer 33

Single dark A band, with half of the I band on either side

Question 34

What effects does contraction have on the distance between z-discs?

Answer 34

Distance shortens

Question 35

What effect does contraction have on the length of myofilaments?

Answer 35

The length of myofilametns are not altered, however slide across each other

Question 36

How is the length of the A band affected during contraction?

Answer 36

Does not change (thick myosin filaments remain constant length)

Question 37

Which zones and bands decreases during contraction?

Answer 37

H-zone

I band

Question 38

Why does the H-zone and I band decrease?

Answer 38

These regions represent areas where filaments do not overlap, however during contraction area of filament overlap increases

Question 39

Which protein comprises the thin filaments?

Answer 39

Actin

Question 40

Which site does myosin bind upon on each globular actin monomer?

Answer 40

Myosin binding site

Question 41

Which two regulatory proteins are associated with the myosin binding site?

Answer 41

Troponin

Tropomyosin

Question 42

Describe the structure the thick myofilaments:

Answer 42

Myosin protein complexes: 6 polypeptides: Two myosin heavy chains, four light chain molecules.

Heavy chains consist of a tail region, flexible hinge region, and globular head which contains an actin binding site, and a binding site for ATP

Question 43

Which chain interacts with actin?

Answer 43

Globular heavy chain head (comprises of actin binding site)

Question 44

How are myosin protein filaments arranged in respect to M-lines and Z-discs? (Direction)

Answer 44

Tails towards M-line, head extending towards the Z-discs

Question 45

Briefly describe the sliding filament theory:

Answer 45

Arrangement and interactions between thin and thick filaments enable for shortening of the sarcomeres, subsequently generating force.

Question 46

In which direction are actin filaments pulled during sarcomere contraction?

Answer 46

Pulled towards the M-lines, sliding passed the thick myosin filaments within the sarcomere

Question 47

Which cation influence is responsible for sarcomere contraction?

Answer 47

Calcium ions

Question 48

What does tropomyosin do?

Answer 48

Tropomyosin is wound around actin filaments, and encapsulates the myosin-binding sites, preventing actin binding to myosin.

Question 49

Where are calcium ions released upon stimulation in muscle cells?

Answer 49

Sarcoplasmic reticulum

Question 50

At a presynaptic membrane, action potentials cause which voltage gated ion channels to open?

Answer 50

Calcium ion voltage gated ion channels

Question 51

The influx of calcium into the pre-synaptic knob results in what occurring?

Answer 51

Vesicles fusing with the presynaptic membrane, and releasing acetylcholine into the synaptic cleft by exocytosis

Question 52

What is the fate of acetylcholine during a synapse within the neuromuscular junction?

Answer 52

ACh diffuses across synaptic cleft, binding to ACh receptors on the post-synaptic membrane within the motor end plate of the sarcolemma.
Inducing an action potentials
Voltage gated sodium channels open to depolarise membrane

Acetylcholinesterase regulate ACh activity

Question 53

What type of coupling is induces by action potentials?

Answer 53

Excitation-contraction coupling

Question 54

Which enzyme hydrolyses acetylcholine in the synaptic cleft?

Answer 54

Acetylcholinesterase

Question 55

Which structure propagates action potentials along the sarcolemma into the muscle cell?

Answer 55

T-tubules

Question 56

Which voltage-sensitive receptors are present on the sarcolemma respond to action potential propagation via t tubules?

Answer 56

Dihydropyridine receptors (DHPR)

Question 57

Which receptors are mechanically linked with DHPR?

Answer 57

Ryanodine receptors

Question 58

What are ryanodine receptors?

Answer 58

Calcium channel in sarcoplasmic reticulum membrane

Question 59

What effect is induced by action potential stimulation of DHPR?

Answer 59

DHPR undergoes conformational change by detecting potential difference, triggers opening of RyR, enabling calcium ion efflux from SR into the sarcoplasm.

Question 60

Which channels do calcium ions efflux from the SR into the sarcoplasm?

Answer 60

Ryanodine receptors

Question 61

Upon calcium binding to TnC, what effect is induced?

Answer 61

Causes tropomyosin to exposure the myosin binding sites of actin filament

Question 62

How do the myosin globular heads bind to the myosin binding site?

Answer 62

Actin binding site of myosin globular head forms cross bridge with myosin binding site

Question 63

How are calcium ions removed from the sarcoplasm?

Answer 63

Actively transported into the sarcoplasmic reticulum continuously whilst action potential continue

ATP driven pump, uptake > release rate

Question 64

When does muscle contact stop?

Answer 64

Signal termination from the motor neurone, depolarisation of sarcolemma and t-tubules
Ryanodine receptors close, and tropomyosin occupies the myosin binding sites on the actin filaments

Question 65

What is the first stage of excitation-contraction coupling? (Calcium)

Answer 65

In the presence of calcium, movement of troponin from tropomyosin chain, movement exposed the myosin binding site on the surface of actin chain.

Question 66

How does the myosin head bind to the myosin binding sites on actin filaments?

Answer 66

Charged myosin head is attracted to actin, binding actin at its respective actin-binding site forming the cross bridge.
Cross bridge formation occurs when myosin head attaches to actin, ADP and Pi bound to myosin.

Question 67

What happens to ADP and Pi upon myosin head binding to actin?

Answer 67

Released, resulting in myosin to form a stronger attachment to the actin, myosin head retracts towards the M-line, consequently pulling the actin filament inwards tinpot the A band
Movement is defined as power stroke.

Question 68

What is the power stroke?

Answer 68

Movement of thin actin filament

Question 69

What molecule is required for myosin head detachment?

Answer 69

ATP

Question 70

Where does ATP bind to the myosin head?

Answer 70

ATP binding site on myosin globular head

Question 71

How is ATP hydrolysed upon binding to the ATP-binding site on myosin globular head?

Answer 71

Intrinsic ATPase activity on myosin into ADP and Pi

Question 72

Why is ATP hydrolysed by intrinsic ATPase enzymes on the myosin globular head?

Answer 72

The energy released from ATP hydrolysis changes the angle of the myosin head into a cocked position, position for further movement.

Question 73

What is the cocked position?

Answer 73

Myosin is in a high energy configuration.
Energy is expended during the power stroke, end of power stroke, myosin head is in a low energy stage. ADP is released during the power stroke, however the cross bridge is intact, actin and myosin are bound
ATP readily attaches to myosin globular head, detachment enables cross bridge cycle to recur.

Question 74

Where are the upper motor neurones located?

Answer 74

The primary motor cortex, provides the descending corticospinal tract, decussating at the medullary pyramids within the medulla oblongata

Question 75

What is a motor unit?

Answer 75

Term used to describe a lower motor neurone, and all the muscle fibres it innervates

Question 76

What is an innervation ratio?

Answer 76

Defines the number of muscle fibres innervated by a single motor neurone,

Question 77

What is the relationship between innervation ratio and level of control?

Answer 77

The innervation ratio is inversely proportional to the level of control.

Question 78

What expected innervation ratios enable fine control and delicate movements?

Answer 78

Innervation ratios will tend to be small, enabling nuances of movement of the entire movement.

Question 79

What effect does a high innervation ratio have on muscular movements?

Answer 79

Coarse movements
No necessity for individual muscle fibres to undergo highly coordinated, differentiated contractions to produce a fine movement.

Question 80

Which type of motor fibres are fast, fatigue resistant?

Answer 80

FR type IIa

Question 81

Which muscle fibre type is oxidative?

Answer 81

Type IIa

Question 82

Why are type IIa fibres fast?

Answer 82

ATP hydrolysis is faster, resulting in a faster cross-bridge cycling
Actin filaments are pulled to the M-line of the sarcomere at a faster rate
Oxidative fibres are more resistant to fatigue considering that ATP is primarily produced through acerbic pathways

Question 83

What is the structure of type IIA fibres?

Answer 83

Large diameter cell bodies, large dendritic tress, thicker axons and faster conduction velocity

Question 84

Which type of fast fibres are glycolytic?

Answer 84

Type IIb

Question 85

Which type of muscle fibres are fast and fatiguable?

Answer 85

Type IIb

Question 86

Why are TypeIIb fibres fast and fatiguable?

Answer 86

Primarily generate ATP through anaerobic glycolysis, produce less ATP per cycle, thus fatigue at a quicker rate, permitting them to be used for short periods
Rapid forceful contractions associated with quick powerful movements

Question 87

What is the structure of FF typeIIb fibres?

Answer 87

Large diameter, and volume of glycogen

Do not posses substantial numbers of mitochondria, limited capillary supply, insignificant amounts of myoglobin.

Question 88

Which type of fibre is type 1?

Answer 88

Slow oxidative

Question 89

Why are slow type 1 fibres oxidative?

Answer 89

Maximises ability to generate ATP through aerobic metabolism
High presence of mitochondria increases sites of oxidative phosphorylation to synthesis ATP
Enabling slow oxidation fibres to contract for longer periods due to ATP supply

Question 90

How are type 1 fibres supplied in accordance to their respective ability?

Answer 90

Extensibly supplied with blood capillaries to continuously supply oxygen.
High presence of myoglobin, oxygen binding molecules (high affinity); stores oxygen within fibre, results in dark red pallor

Question 91

What colour are slow type 1 fibres?

Answer 91

Red

Question 92

Why are slow type 1 fibres red?

Answer 92

High proportion of myoglobin content

Question 93

Describe the aerobic capacity of slow type 1 fibres?

Answer 93

Aerobic capacity is high

Question 94

What functions are performed by slow type 1 fibres?

Answer 94

Posture, isometric contractions and stabilising bones & joints.

Do not produce high tension, thus not used for powerful fast movements that require high amounts of energy and rapid cross bridge cycling

Question 95

Describe the structure of slow type 1 fibres:

Answer 95

Small soma diameter, small dendritic tress, thin axons, slowest conduction velocity.

Question 96

Describe the proportion & distribution of slow and fast twitch muscles:

Answer 96

Random distribution and proportions

Question 97

What colour are fast fatigue resistant type IIa fibres?

Answer 97

Pink

Question 98

What colour are FF IIb fibres?

Answer 98

White

Question 99

Describe the aerobic capacity of FF Type IIB fibres:

Answer 99

Low

Question 100

Describe the anaerobic capacity of FF TypeIIA/B fibres:

Answer 100

High

Question 101

Which fibres produce high tension?

Answer 101

Type IIb

Question 102

Which fibre produce low tension?

Answer 102

Type I

Question 103

What are the two methods of regulating muscle contraction and activation of motor units?

Answer 103

Recruitment and rate coding

Question 104

What is recruitment of motor units?

Answer 104

Refers to the activation of additional motor units to accomplish an increase in contractile strength in a muscle.

Activation of motor neurone will subsequently result in the respective muscle fibres being stimulated.

Multiple activated motor neurones will result in further muscle fibre activation, thus stronger muscle contraction.

Higher recruitment = stronger contractile force

Question 105

In which order premotor units recruited?

Answer 105

In order of smallest to largest (Slow to fast twitch), as contraction increased, governed by size principle

Question 106

Under low levels of required force, how is fine control adopted?

Answer 106

Activation of low innervation ratio motor units.

Question 107

What is rate coding?

Answer 107

Force produced by a single motor unit is determined by the number of muscle fibres it innervates
Determinant of force is the frequency in which the muscle fibres are stimulated by their inneverating axon.

Motor units fire range of frequencies = slow units fire at a lower frequency

Question 108

How does motor unit firing rate influence force produced?

Answer 108

Increasing firing rate increases the force produced by the unit

Summation occurs when units fire at frequency too fast, allows mucle to relax between arriving action potentials.

Question 109

What are neurotrophic factors?

Answer 109

Peptides that support the growth, survival and differentiation of developing and mature neurones

Prevents neuronal death and promotes growth post injury ]

Motor unit and fibre characteristics depends on the nerve that innervates them

Question 110

What happens to slow muscles when cross innervated with fast twitch nerves?

Answer 110

Exhibits characteristics functions and properties of that to fast muscle
Muscle emulates the properties of the innervating nerve

Question 111

What are the two main types muscular contractions?

Answer 111

Isometric and isotonic

Question 112

What is an isometric contraction?

Answer 112

Tension in the muscle is constant
Tension is produced, however muscle length does not change (Sarcomere shortening)
increasing muscle tensioN Though the force produced cannot overcome resistance provided by load

Question 113

What is a concentric contraction?

Answer 113

Involves the muscle shortening to move a load

Question 114

What is an eccentric contraction?

Answer 114

Muscle tension diminishes, and the muscle lengthens.

Question 115

What is muscle plasticity?

Answer 115

Muscle plasticity is defined as the ability of a given muscle to alter its structural and functional properties in accordance with the environmental conditions imposed on it.

Question 116

During conditions of severe conditions, muscle fibres are converted into which type?

Answer 116

Type 1 fibres to II

Question 117

What effect does microgravity have on muscle fibre types?

Answer 117

Promotes shift from slow to fast muscle fibre types

Question 118

Which system senses gravity?

Answer 118

Vestibular system

Question 119

How does microgravity cause deconditioning?

Answer 119

Results in diminished land on the msk system and hydrostatic pressure difference, contributes towards muscular atrophy

Question 120

How does ageing influence the types of fibres present?

Answer 120

Associated with loss of type 1 and 2 fibres

Preferential loss of type II fibres

Results in a larger proportion of type 1 fibres in aged muscle

(Evidence = slower contraction time)

Question 121

How does muscle training influence muscle fibre types?

Answer 121

Conversion from IIb to IIa