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Example Questions
Example Question #338 : Systems Physiology
An investigational drug prevents skeletal muscle contraction by preventing ATP hydrolysis at the active site in muscle tissue. Where is this drug most likely to act?
Actin head
Intermediate filament tail
Myosin head
Actin tail
Myosin tail
Myosin head
ATP binds to myosin head regions and is hydrolyzed to ADP and inorganic phosphate when muscle relaxes. The release of these products allows the contraction to occur as the myosin head changes position. The binding of new ATP releases the myosin head from actin, and allows the muscle to relax prior to another round of hydrolysis. This explains why, in the absence of adequate ATP, muscle can remain in a contracted state. This phenomenon, when seen in the deceased, is called rigor mortis.
Example Question #1 : Help With Sarcomere Physiology
Ions are key in mediating muscle contraction. Which of the following structures interacts directly with ions to expose actin binding sites in contracting muscle?
Tropomyosin
Myofibrils
Myosin
Troponin
Cross-bridges
Troponin
Troponin (also called troponin C) is the most direct structure that interacts with ions involved in initiating muscle contractions. Once bound to calcium ions, troponin facilitates the movement of tropomyosin away from actin binding sites, allowing myosin to bind and, ultimately, contract. Without the binding of calcium ions to troponin, the myosin-binding site on actin remains obscured by tropomyosin and contraction cannot occur.
Example Question #341 : Systems Physiology
Which of the following sarcomere portions does not decrease in length during muscular contraction?
I band
A band
H zone
None of these portions decrease during contraction
All of these portions decrease during contraction
A band
During muscular contraction, the myosin heads pull the actin filaments toward one another resulting in a shortened sarcomere. While the I band and H zone will disappear or shorten, the A band length will remain unchanged. This is because the A band corresponds to the full length of the myosin filament, or thick filament. Since the myosin filament does not actually change length, the A band remains constant.
The I band corresponds to the region of action that does not overlap with myosin. The length of the actin filament does not change during contraction, but the region of overlap increases. This results in a decrease of the non-overlapped I band.
The H zone refers to the region of myosin that is not overlapped by action. As the region of overlap grows, the H zone shrinks.
Example Question #1 : Help With Sarcomere Physiology
In excitation-contraction coupling in skeletal muscle, the calcium released from the smooth endoplasmic reticulum binds to which of the following?
Calmodulin
Troponin
Tropomyosin
Myosin
Actin
Troponin
When calcium is released in muscle cells, it binds to troponin. This binding allows tropomyosin to change its orientation, exposing the myosin-binding sites on actin. Myosin heads can then bind to actin, and contraction can occur.
Calmodulin is a molecule that can bind calcium; however, it plays important roles in cell signal cascades and is not involved in skeletal muscle contraction.
Example Question #3 : Help With Sarcomere Physiology
In a muscle cell, the H-zone has __________.
thick filaments only
thin filaments only
thick and thin filaments overlapping
Z-discs
thick filaments only
The H-zone is an area made up of only thick filaments (myosin). The I-band is thin filaments (actin) only, and the A-band is where there are thick and thin filaments. The Z-disc is dividing feature between sarcomeres and appears as dark lines in electron micrographs.
Example Question #2 : Help With Sarcomere Physiology
During muscle contraction, which band(s) of the sarcomere shorten(s)?
The I-band only
The H-band and I-band
The H-band only
The A-band and H-band
The A-band only
The H-band and I-band
Muscle contraction results in both the H-band and I-bands shortening, but the A-band remains the same length (A band is Always the same). The Z-band is a static structure and doesn't change size.
Example Question #1 : Help With Sarcomere Physiology
Where within the sarcomere is myosin contained?
Sarcoplasmic reticulum
Thick filaments
Transverse tubules
Thin filaments
Thick filaments
Thick filaments contain myosin. Thick filaments are present in the A band in the center of the sarcomere. Myosin has six polypeptide chains, including one pair of heavy chains and two pair if light chains. Each myosin molecule has two “heads” attached to a single “tail.” The myosin heads are capable of ATP hydrolysis and bind ATP and actin, and are involved in cross bridge formation.
Example Question #4 : Help With Sarcomere Physiology
Troponin binds with which ion?
Troponin is the regulatory protein that permits cross bridge formation when it binds . Troponin is a complex of three globular proteins. Troponin C () is the binding protein, that when bound to , permits the interaction of actin and myosin via conformational change that reveals the myosin binding site on actin, and thus muscular contraction.
Example Question #1 : Help With Sarcomere Physiology
Where can you find a ryanodine receptor?
Thick chain
Transverse tubules
Sarcoplasmic reticulum
A band
Sarcoplasmic reticulum
The ryanodine receptor is a calcium channel that is responsible for the release of calcium ions. It is located in the sarcoplasmic reticulum. The release of calcium is a required step in muscle contraction. The ryanodine receptor pumps calcium ions from the intracellular fluid into the interior of the sarcoplasmic reticulum, this process keeps the intracellular calcium ions low and creates a concentration gradient.
Example Question #5 : Help With Sarcomere Physiology
Muscle myofibrils are arranged longitudinally into sarcomeres. Which of the following correctly lists the boundaries of a single sarcomere?
M line to H band
Z line to M line
Z line to Z line
Z line to H band
Z line to Z line
Each myofibril contains interdigitating thick and thin filaments arranged longitudinally in sarcomeres. Repeating units of sarcomeres account for the unique banding pattern in striated muscle. A sarcomere runs from Z line to Z line.
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