Deck 10: Muscle Tissue

A) protein that accounts for elasticity of resting muscle
B) repeating unit of striated myofibrils
C) storage site for calcium ions
D) thin filaments are anchored here
E) largely made of myosin molecules

A) protein that accounts for elasticity of resting muscle
B) repeating unit of striated myofibrils
C) storage site for calcium ions
D) thin filaments are anchored here
E) largely made of myosin molecules

A) sarcomeres.
B) myofibrils.
C) myoblasts.
D) fascicles.
E) myomeres.

A) tendon.
B) satellite cell.
C) ligament.
D) tenosynovium.
E) sheath.

A) fascicle.
B) tendon.
C) ligament.
D) epimysium.
E) myofibril.

A) endomysium.
B) perimysium.
C) epimysium.
D) superficial fascia.
E) periosteum.

A) protein that accounts for elasticity of resting muscle
B) repeating unit of striated myofibrils
C) storage and release site for calcium ions
D) thin filaments are anchored here
E) largely made of myosin molecules

A) produce movement
B) maintain posture
C) maintain body temperature
D) guard body entrances and exits
E) All of the answers are correct.

A) contract much more forcefully.
B) produce more ATP with little oxygen.
C) store extra DNA for metabolism.
D) produce large amounts of muscle proteins.
E) produce nutrients for muscle contraction.

A) muscle fatigue.
B) the conduction of neural stimulation to the muscle fiber.
C) muscle contraction.
D) muscle relaxation.
E) the striped appearance of skeletal muscle.

A) fasciae
B) retinaculum
C) aponeurosis
D) interstitium
E) tympanum

A) conduction.
B) contraction.
C) peristalsis.
D) cushioning.
E) secretion.

A) group of muscle fibers that are encased in the perimysium.
B) layer of connective tissue that separates muscle from skin.
C) group of muscle fibers that are all part of the same motor unit.
D) group of muscle fibers and motor neurons.
E) collection of myofibrils in a muscle fiber.

A) sarcolemma.
B) sarcomere.
C) sarcoplasmic reticulum.
D) myofibril.
E) myofilament.

A) lack a plasma membrane.
B) have many nuclei.
C) are very small.
D) lack mitochondria.
E) have large gaps in the cell membrane.

A) Z line.
B) M line.
C) H band.
D) A band.
E) I band.

A) 1, 5, 4, 3, 2, 6
B) 6, 2, 5, 4, 1, 3
C) 6, 2, 4, 5, 1, 3
D) 1, 3, 5, 6, 4, 2
E) 2, 3, 1, 4, 6, 5

A) sarcolemma.
B) sarcomere.
C) sarcosome.
D) sarcoplasmic reticulum.
E) sarcoplasm.

A) tendon.
B) epimysium.
C) endomysium.
D) perimysium.
E) fascicle.

A) 1
B) 2
C) 3
D) 5
E) 8

A) myosin molecules.
B) troponin molecules.
C) tropomyosin molecules.
D) calcium ions.
E) ATP molecules.

A) sarcoplasmic reticulum.
B) sarcoplasm.
C) sarcomere.
D) sarcolemma.
E) endomysium.

A) lengthens.
B) shortens.
C) strengthens.
D) weakens.
E) pulls from the middle.

A) 4
B) 5
C) 6
D) 7
E) 8

A) 6
B) 7
C) 1
D) 3
E) 2

A) actin
B) myosin
C) titin
D) tropomyosin
E) All of the answers are correct.

A) sarcoplasm
B) acetylcholine
C) protein
D) calcium ions
E) acetylcholinesterase

A) mitochondria
B) glycogen
C) ATP
D) myofibril
E) synaptic vesicle

A) H bands and I bands get larger.
B) zones of overlap get larger.
C) Z lines move further apart.
D) width of the A band increases.
E) All of the answers are correct.

A) two actin protein strands coiled helically around each other.
B) chains of myosin molecules.
C) six molecules coiled into a helical structure.
D) a rod-shaped structure with "heads" projecting from each end.
E) a double strand of myosin molecules.

A) actin molecules.
B) myosin molecules.
C) troponin molecules.
D) ATP molecules.
E) calcium ions.

A) Z line.
B) M line.
C) H band.
D) I band.
E) zone of overlap.

A) 6
B) 7
C) 1
D) 3
E) 2

A) actin, myosin, and titin filaments.
B) a transverse tubule and two terminal cisternae.
C) filaments, myofibrils, and sarcomeres.
D) A bands, H bands, and I bands.
E) actin, myosin, and sarcomeres.

A) 1
B) 2
C) 4
D) 8
E) 9

A) Z line.
B) M line.
C) H band.
D) A band.
E) I band.

A) actin.
B) tropomyosin.
C) troponin.
D) titin.
E) None of the answers is correct; there are no exceptions.

A) release of neurotransmitter
B) conduction of the action potential into the cell interior
C) activity of acetylcholinesterase
D) release of protein and calcium ions into the muscle fiber
E) opening of sodium channels and subsequent influx of sodium

A) Z line.
B) M line.
C) H band.
D) A band.
E) I band.

A) motor end plates.
B) neuromuscular junctions.
C) transverse tubules.
D) triads.
E) sarcoplasmic reticulum.

A) actin.
B) titin.
C) myosin.
D) tropomyosin.
E) nebulin.

A) acetylcholine.
B) sodium ions.
C) potassium ions.
D) calcium ions.
E) hydrogen ions.

A) sliding filament
B) excitation-contraction coupling
C) neuromuscular
D) muscle contraction
E) action-myosin interaction

A) active transport of calcium across the sarcolemma.
B) active transport of calcium into the sarcoplasmic reticulum.
C) active transport of calcium into the synaptic cleft.
D) diffusion of calcium out of the cell.
E) diffusion of calcium into the sarcoplasmic reticulum.

A) titin.
B) actin.
C) G actin.
D) nebulin.
E) myosin.

A) titin.
B) actin.
C) G actin.
D) nebulin.
E) myosin.

A) tropomyosin rolls away from the active site.
B) active sites on the myosin are exposed.
C) actin heads will bind to myosin.
D) muscle relaxation occurs.
E) myosin shortens.

A) synaptic knob.
B) sarcomere.
C) neuromuscular junction.
D) synaptic cleft.
E) transverse tubule.

A) titin.
B) actin.
C) G actin.
D) nebulin.
E) myosin.

A) actin.
B) titin.
C) myosin.
D) tropomyosin.
E) nebulin.

A) constant distance between Z lines during contraction.
B) decreased width of the H band during contraction.
C) increased width of the I band during contraction.
D) decreased width of the A band during contraction.
E) the I band + H band distance is constant during contraction.

A) I band.
B) A band.
C) Z line.
D) M line.
E) zone of overlap.

A) trimer.
B) triad.
C) triptych.
D) trisome.
E) trilogy.

A) myocytes.
B) satellite cells.
C) endocytes.
D) sarcocytes.
E) creatinocytes.

A) actinin.
B) titin.
C) nebulin.
D) myosin.
E) actin.

A) titin
B) actin
C) G actin
D) nebulin
E) myosin

A) 3
B) 6
C) 3 and 6
D) 7
E) 3 and 7

A) actin binds to troponin.
B) troponin binds to tropomyosin.
C) calcium binds to troponin.
D) calcium binds to tropomyosin.
E) myosin binds to troponin.

A) actin.
B) titin.
C) myosin.
D) tropomyosin.
E) nebulin.

A) increases tone in the muscle
B) causes a strong contraction similar to a "charlie horse" cramp
C) increases the muscle's excitability
D) produces a strong, continuous state of contraction
E) reduces the muscle's ability for contraction

A) ATP
B) calcium
C) magnesium
D) acetylcholine
E) acetylcholinesterase

A) It binds to receptor membrane channels.
B) It diffuses across the synaptic cleft.
C) It is stored in the neuron in vesicles.
D) It enters the muscle fiber to release calcium form the sarcoplasmic reticulum.
E) It is digested by acetylcholinesterase.

A) tropomyosin.
B) actin.
C) myosin.
D) troponin.
E) calcium channels.

A) acetylcholine binds to chemically-gated channels in the motor end plate.
B) acetylcholinesterase is released from synaptic vesicles into the synaptic cleft.
C) calcium ion binds to channels on the motor end plate.
D) the action potential jumps across the neuromuscular junction.
E) Any of these can produce an action potential in the muscle cell.

A) synaptic knob.
B) motor end plate.
C) motor unit.
D) synaptic cleft.
E) M line.

A) nervous units.
B) synaptic terminals.
C) motor end plates.
D) motor units.
E) neuromuscular junctions.

A) thin filaments and thick filaments
B) thick filaments and titin filaments
C) z disks and actin filaments
D) thick filaments and t-tubules
E) thin filaments and t-tubules

A) Calcium ions travel through the transverse tubule.
B) Calcium ion is released from the sarcoplasmic reticulum.
C) Tropomyosin moves to expose myosin binding sites on actin.
D) Troponin binds calcium ion and signals tropomyosin to move.
E) Relaxation requires uptake of calcium ion by the sarcoplasmic reticulum.

A) It would make the muscles less excitable.
B) It would produce muscle weakness.
C) It would cause muscles to stay contracted.
D) It would cause muscles to stay relaxed.
E) It would have little effect on skeletal muscles.

A) the myosin heads are attached to actin.
B) ATP is depleted.
C) calcium ions keep binding to troponin.
D) sustained contractions occur.
E) All of the answers are correct.

A) bind to ligand gated sodium channels.
B) activate acetylcholine.
C) release acetylcholine into the synaptic cleft.
D) transport acetylcholine across the synaptic cleft.
E) break down acetylcholine into acetate and choline components.

A) endocytosis
B) apoptosis
C) exocytosis
D) hydrolysis
E) sodium

A) neuromuscular junction.
B) action potential propagation.
C) excitation-contraction coupling.
D) cross bridge formation.
E) sliding filament theory.

A) tetany.
B) treppe.
C) depolarization.
D) rigor mortis.
E) oxygen debt.

A) epinephrine.
B) norepinephrine.
C) acetylcholine.
D) antidiuretic hormone.
E) adrenaline.

A) during calcium ion reuptake into the sarcoplasmic reticulum
B) when sodium channels open up on the motor end plate
C) during acetylcholine release from the synaptic terminal
D) when the action potential surges through the T-tubules
E) when ATP splits into ADP and P on the free myosin head

A) zone of overlap.
B) A band.
C) I band.
D) M line.
E) H band.

A) more permeable to sodium ions.
B) less permeable to sodium ions.
C) more permeable to calcium ions.
D) less permeable to potassium ions.
E) less permeable to potassium and sodium ions.

A) 1, 3, 5, 4, 6, 2
B) 5, 1, 4, 6, 2, 3
C) 3, 5, 1, 2, 4, 6
D) 3, 5, 1, 4, 6, 2
E) 1, 4, 6, 2, 3, 5