ATP’s role in the sliding filament theory of muscle contraction includes (select all that apply): a)...

What is the role of Ca2+ in the control of muscle contraction? a. It causes depolarization...

What is the role of Ca2+ in the control of muscle contraction? a. It causes depolarization of the T tubule system. b. It binds to tropomyosin and breaks actin–myosin cross-bridges. c. It changes the conformation of troponin, which ultimately results in myosin-binding sites being exposed. d. It changes the conformation of myosin heads, causing actin and myosin filaments to slide past each other. e. It blocks the ATP-binding site on myosin heads, enabling muscles to relax.

Put the steps of muscle contraction into the correct order Troponin releases calcium and the actin...

Put the steps of muscle contraction into the correct order Troponin releases calcium and the actin binding sites are covered by the twisting of tropomyosin A stimulus from the nerve cell is brought down the T tubule Calcium is released from the SR into the cytoplasm Myosin binds to Actin Calcium is removed from the cytoplasm and actively transported to the sarcoplasmic reticulum tropomyosin untwists and exposes the actin binding sites The thin filament slides closer to the M line,...

What is the role of ATP in muscle contraction and relaxation? Multiple Choice It is hydrolyzed...

What is the role of ATP in muscle contraction and relaxation? Multiple Choice It is hydrolyzed from the myosin head to attach to actin. All apply. It powers the Ca2+ pumps to return Ca2+ to the SR. It causes myosin head to detach from actin.

Activity 1 Using the list of (10) events for muscle contraction. match the numbers of the...

Activity 1 Using the list of (10) events for muscle contraction. match the numbers of the steps from with the correct periods below in which they would occur. Latent period: Contraction period: Relaxation period Hint- 10 events of muscle contraction 1. Action potential (electrical stimulation) from somatic (motor) nerve stimulates skeletal muscle fibers (cells) at neuromuscular junction 2.“AP” causes the opening of Na+ channels on the sarcolemma thus causing a wave of depolarization to travel from the neuromuscular junction. 3....

1/Which process in the cycle of skeletal muscle contraction is called the power stroke? Select one:...

1/Which process in the cycle of skeletal muscle contraction is called the power stroke? Select one: a. Rotation of myosin heads to pull actin filaments inward b. Separation of myosin from actin c.Hydrolysis of ATP at the myosin heads d. Formation of cross bridges between myosin and actin 2/The correct formula for estimating the ejection fraction is to divide the stroke volume by: Select one: a. after load b. cardiac output c. end diastolic volume d. end systolic volume 3/Baby...

Place the following events in the correct order they occur during excitation-contraction coupling in skeletal muscle:...

Place the following events in the correct order they occur during excitation-contraction coupling in skeletal muscle: Myosin forms a tight bond with actin and undergoes the ‘power stroke’. The troponin/tropomyosin complex shifts, exposing the myosin binding sites on the actin filament. Ca2+ binds to troponin. Ca2+ moves out of the sarcoplasmic reticulum (called a “calcium spark”). An action potential in the alpha motor neuron leads to the release of neurotransmitter at the neuromuscular junction. Nicotinic receptors on the motor end...

Draw a diagram! The purpose of the diagram is to show the steps from a neuron...

Draw a diagram! The purpose of the diagram is to show the steps from a neuron stimulating a skeletal muscle cell to contraction of that muscle cell. Include in your diagram: •axon terminal of motor neuron •synaptic cleft •neurotransmitter •neurotransmitter binding channels on muscle cell •t-tubules •depolarization •sarcoplasmic reticulum •receptors/channels that work together to release Ca2+ •Ca2+, Where is it? Where does it go? What does it bind to? •Sarcomeres-components (actin, myosin, tropomyosin, troponin, ATP) and how it works (sliding...

1. When an action potential reaches the T-tubule, it will activate the dihydropyridine receptor at the...

1. When an action potential reaches the T-tubule, it will activate the dihydropyridine receptor at the T-tubule to change conformational shape. Dihydropyridine receptor will trigger ryanodine receptor channel to secrete Ca2+ from the sarcoplasmic reticulum into the cytosol. When action potential is absent, Ca2+ ATPase at the sarcoplasmic reticulum will pump cytosolic Ca2+ into the sarcoplasmic reticulum. Select one: a. True b. False 2. What is TRUE about the myofibril? Select one: a. The thick and thin filaments on the...

Put these steps in neuromuscular junction synaptic transmission and excitation-contraction coupling in chronological order. (Type the...

Put these steps in neuromuscular junction synaptic transmission and excitation-contraction coupling in chronological order. (Type the letters in the appropriate order with no spaces between them). A. Ryanodine receptors open B. Voltage-gated Na+ channels open in the muscle cell membrane near the neuromuscular junction C. Tropomyosin rotates into the groove of the thin filament (out of the way of the myosin binding site) D. Depolarization of motoneuron axon terminal E. Ca2+ dissociates from troponin F. [Ca2+] rises in the muscle...

The molecular process that makes muscle contraction possible is that ATP binds to myosin, which releases...

The molecular process that makes muscle contraction possible is that ATP binds to myosin, which releases the energy needed to make the muscle contract. In this problem, we will examine the quantities of energy involved in this process. Part 1 The reaction of ATP hydrolysis catalyzed by myosin (M) occurs in several steps*: M + ATP → M·ATP M·ATP → M·ADP·Pi M·ADP·Pi → M·ADP + Pi (aq) M·ADP → M + ADP * T. Kodama & R.C. Woledge, "Enthalpy Changes...