Muscle

Question 1

Three Major Function of Muscles

Answer 1

1. movement of body
2. movement of materials throughout the body
3. maintenance of body temp through heat production (homeostasis)

Question 2

Three different Types of Muscle:

Answer 2

1. Skeletal: attaches to skeleton
2. cardiac: heart
3. smooth: walls of hollow structures

Question 3

Structure of skeletal muscle fiber:

Answer 3

• elongated cylindrical shape
• multi-nucleated
• 10-100 microns in diameter
• up to 20cm long

Question 4

What is the plasma membrane in muscle cells called

Answer 4

Sarcolemma

Question 5

What is the cytoplasm of skeletal muscle Fibers called

Answer 5

Sarcoplasm

Question 6

Contents of Sarcoplasm of Skeletal Muscle Fibers

Answer 6

• high conc. glycogen for energy for contraction
• myoglobin: high O2 levels that can be used for energy production
• myofibrils
• sarcoplasmic reticulum
• T-Tubules

Question 7

Myofibrils in Skeletal Muscle Cells:

Answer 7

• cylindrical bundles of filaments
• 1-2 microns
• 80% vol of sarcoplasm
• contain myofilaments which comprise contractile elements of muscle fibre

Question 8

Sarcoplasmic Reticulum in Skeletal Muscle Fibers:

Answer 8

• interconnected series of segments that surround microfibrils
• has lateral sacs
  high conc of Ca2+ essential for muscle contraction

Question 9

Transverse (or T-) Tubules in Skeletal Muscle Fibers:

Answer 9

• continuous with extracellular space
• runs across thickness of muscle fiber
• closely associated with lateral sacs of sarcoplasmic reticulum
• initiate muscle contraction by conducting electrical signals from sarcolemma into muscle fiber

Question 10

What subdivision of the nervous system are motor-neurons apart of?

Answer 10

Somatic Nervous System (of the Efferent (motor) division

Question 11

Structural Features of Motor-neurons:

Answer 11

• nerves cells whose axons innervate skeletal muscle fiber
• cell bodies (somata) located in brain-steam or anterior horns of spinal cord
• large myelinated axon (rapid conduction)
• axon branches to innervate multiple muscle fibers
• each muscle fiber on innervated by one motor-neuron

Question 12

Structural Features of Motor Unit:

Answer 12

a motor-neuron + muscle fiber it innervates.
unit size determine muscle function:
muscles producing large forces = large motor unit
muscles producing small forces = small motor unit

Question 13

Structural Significance of motor-neurons having myelinated axons

Answer 13

Allows conducting electrical signals (APs) at high velocities from CNS to skeletal muscle fibers, with minimum delay

Question 14

Structural Components of Neuromuscular Junction:

Answer 14

• Axon Terminals

- Motor Endplate

Question 15

Function of Neuromuscular Junction

Answer 15

Synaptic site for the transmission of action potential from nerve to the muscle

Question 16

Axon Terminal of Neuromuscular Junction:

Answer 16

• loose myelinsheath as they approach muscle fiber but Schwan cells maintain insulation.
• terminals contain ACh (neurotransmitter) & mitochondria
• membrane of terminal has large no. of voltage-gated ca2+ channels
• terminal is separated from sarcolemma * contains enzymes (acetylcholinesterase) responsible for degradation of ACh
• choline molecules released are transported back to terminal & reused to form ACh. choline recycling allows neuromuscular transmission of reaction potentials to continue

Question 17

Motor Endplate of Neuromuscular Junction:

Answer 17

• is opposite axon terminal
• highly folded to increase SA
• large no. of nicotinic acetylcholine receptors
• acetylcholinesterase enzyme metabolises acetylcholine

Question 18

Effect of ACh is limited by Two Mechanisms:

Answer 18

1. diffusion of ACh from endplate

2. ACh degradation by acetylcholinesterase in cleft

Question 19

Describe the mechanism of excitation-contraction coupling

Answer 19

efers to AP produced at the end-plate which travels along through muscle fibre length in both directions causing contraction

Question 20

Muscle Fiber Contraction:

Answer 20

• AP travels along muscle fiber -> meets T-Tubule -> flows down T-Tubule in middle of fiber
• presence of AP in T-Tubule triggers opening of Ca2+ channels is sarcoplasmic reticulum
• Ca2+ runs down conc gradient in sarcoplasm
• increases sarcoplasmic Ca2+ triggers myofibrils to shorten -> contraction of whole muscle fiber

Question 21

Relaxation of Muscle Fiber:

Answer 21

• when AP stops flowing down T-Tubule, Ca2+ is pumped out of sarcoplasm back to sarcoplasmic reticulum
• ca2+ conc in sarcoplasmic reticulum returns to resting levels & myofibrils return to normal length - relaxation

Question 22

Structure of Thin Myofilaments:

Answer 22

5-8nm in diameter & 1 micron long
has three constituent proteins:
1. actin
2. tropomyosin
3. troponin complex

Question 23

Myofilaments - Actin Structure:

Answer 23

• two chain globular protein molecules twisted around each other forming double helix
• high affinity binding site for myosin
• forms backbone of thin myofilaments

Question 24

Myofilaments - Tropomyosin Structure:

Answer 24

• 2 chains wrapped around actin helix. positioned on top so that myosin binding sites are blocked

Question 25

Myofilaments - Troponin Complex Structure:

Answer 25

• 3 polypeptides with high binding affinity
• 1st polypeptide: holds tropomyosin threads over myosin binding sits of actin
• 2nd polypeptide: binds to actin
• 3rd polypeptide: binds to ca2+, triggering contraction of myofibrils

Question 26

Structure of Thick Myofilaments:

Answer 26

• 12-18nm diameter
• 1.6 microns long
• made up of ~200 myosin molecules
• 1 end of myosin is made up of 2 folded protein strands
• heads form cross-bridges each have an actin binding site and an ATPase

Question 27

Thick & Thin Myofilament Arrangement:

Answer 27

• highly ordered
• striated appearance
• thick located in between thin & overlap
• thick surrounded by 6 thin in hexagonal arrangement

Question 28

What is a Sarcomere?

Answer 28

Contractile unit of a muscle fiber.

represented by distance between Z-lines

Question 29

how the sarcomere length changes during muscle contraction and relaxation

Answer 29

changes in sarcomere reflect changes in whole myofibril

Question 30

What is Rigor Mortis

Answer 30

• stiffness of skeletal muscles (starts 4hrs after death)
• reaches peak after 12 hrs
• subsides after 2-3 days
• stiffness due to leakage of Ca2+ into sarcoplasm from extracellular fluid & sarcoplasmic reticulum
• cells die & are unable to maintain large ion conc
• Some of this calcium binds to troponin & displaces troponin filament. Allows binding of some cross-bridges and initiates power stroke. Results in muscle fiber shortening
• There is no ATP available to detach the cross-bridges
  Muscle fibers remain contracted until filaments decompose after one’s death

Question 31

Isotonic Contraction of Skeletal Muscles:

Answer 31

tension of muscles remain constant as muscle shortens. Results in movement.
E.g. Length of biceps brachii muscle fibers decreases

Question 32

Isometric Contraction of Skeletal Muscles:

Answer 32

Tension of muscle increases, but no change in muscle length.
E.g. Maintenance of posture

Question 33

Motor Unit Recruitments:

Answer 33

• weak contraction -> less motor units recruited
• strong contraction -> more motor units recruited
• sustained contraction -> different motor neurons recruited
• coordinated by CNS

Question 34

Action Potential Frequency:

Answer 34

increased AP freq -> increases force generated

Question 35

Twitch Contraction:

Answer 35

smallest contractile response to a single electrical stimulus

Question 36

Tetanic Contraction

Answer 36

largest contractile response to a single electrical stimulus

Question 37

Slow Twitch (Type I) Fibers:

Answer 37

• develop at slow rate
• small in diameter
• rich capillary network
• high conc of myoglobin in sarcoplasm
• suited to movements that require low force but sustained contractions
  e. g. distance running

Question 38

Electromyography:

Answer 38

• recording of electrical activity in skeletal muscle during contraction
• recorded by two electrodes on skin surface
• connected to voltmeter & measures potential difference
  Plot: changes in potential diff over time

Question 39

electromyography in sport and clinical sciences.

Answer 39

• used to analyse muscle dysfunction in athletes, detects inappropriate muscle activation patters, assists in establishing & assessing treatment outcomes in conditions