AP Biology : AP Biology

Study concepts, example questions & explanations for AP Biology

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Example Questions

Example Question #4 : Understanding Types Of Cellular Communication

G proteins function as signal transmitters in coordination with G protein-coupled receptors. They are active when bound to which of the following chemical energy carriers?

Possible Answers:

GDP

ADP

ATP

GTP

Correct answer:

GTP

Explanation:

G proteins are a class of protein signaling molecules that are activated by G protein-coupled receptors (GPCRs). When a ligand binds to the transmembrane domain of GPCRs, the GPCR undergoes a conformational change. This conformational change activates the G protein, which binds to GTP rather than lower energy GDP. The active G protein can then dissociate and transmit the signal by interacting with other proteins.

Example Question #11 : Cellular Communications And Junctions

Which of the following describes what happens to tyrosine kinase receptors upon ligand binding?

Possible Answers:

Dimerization

Trimerization

Remain stable as monomers

Form oligomers

Correct answer:

Dimerization

Explanation:

Tyrosine kinase receptors exist as single monomers but possess the capability to polymerize. Tyrosine kinase receptors have a transmembrane domain, an extracellular N terminus, and an intracellular C terminus. When a ligand binds to the extracellular N terminus, the tyrosine kinase receptor dimerizes. There are multiple models of receptor dimerization. One of the models is that dimerization is aided by the ligand itself, which binds to the N termini of both tyrosine kinase receptors. Another is that dimerization occurs after each tyrosine kinase receptor monomer binds to a ligand. A final model postulates that the binding of a ligand induces a conformation change that allows dimerization.

Example Question #402 : Cellular Biology

Which of the following regions of tyrosine kinase receptors are autophosphorylated upon ligand binding?

Possible Answers:

Amino acids in dimerized transmembrane domains

Transmembrane domains

Tyrosine residues on the intracellular C terminus

Extracellular N terminus ligand-binding domains

Correct answer:

Tyrosine residues on the intracellular C terminus

Explanation:

Tyrosine kinase receptors are composed of a transmembrane domain, an extracellular N terminus, and an intracellular C terminus. Ligand binding to the extracellular N terminus stimulates receptor dimerization. The dimerization stimulates kinase activity on the intracellular C terminus, leading to the autophosphorylation of the tyrosine residues on the C terminus. This phosphorylation of tyrosine residues creates binding sites for relay proteins, which are then phosphorylation by the tyrosine kinase receptors. The phosphorylated relay proteins then transmit the signal to other cellular pathways. 

Example Question #472 : Ap Biology

Which of the following messengers mediate long-distance cell signaling in animal cells?

Possible Answers:

Vesicles

Ions

Ligands

Hormones

Correct answer:

Hormones

Explanation:

In animal cells, hormones mediate long distance cell signaling. Hormones are chemical messengers secreted by cells that travel through the circulatory system to the target cell receptors. Hormones communicate between diverse cell types and initiate diverse transduction pathways. Hormones are used for long distance cell signaling in both plant and animal cells. 

Example Question #473 : Ap Biology

Which of the following choices is not an example of an animal hormone?

Possible Answers:

Testosterone

Insulin

Tyrosine kinase

Growth hormone

Correct answer:

Tyrosine kinase

Explanation:

Hormones are chemical messengers responsible for long distance cell signaling. Hormones are involved in diverse signaling pathways and have a variety of effects on cellular activities; therefore, there are many types of hormones. Animal hormones can be organized into classes based on their chemical makeup—peptide hormones, steroid hormones, lipid-based hormones, and amino acid-derived hormones. Insulin and growth hormones are both in the class of peptide hormones, and they are responsible for promoting the absorption of glucose from the bloodstream and promoting cell growth and reproduction, respectively. Testosterone is a steroid hormone that controls the development of male reproductive features.

 

Example Question #471 : Ap Biology

Which of the following choices is the best example of a plant hormone?

Possible Answers:

Cortisol

Auxin

Estrogen

Melatonin

Correct answer:

Auxin

Explanation:

Plant hormones, like animal hormones, are involved in long distance cell signaling. Most plant hormones are involved in regulating plant growth and are secreted by plant cells. Because plants lack a circulatory system, plant hormones move through cells via passive transport. This demands that the chemical composition of plant hormones must be simple. Auxin is a plant hormone whose distribution controls plant growth in response to environmental conditions. Other common plant hormones include abscisic acid, cytokinin, ethylene, and gibberellin.

Example Question #411 : Cellular Biology

Which of the following choices best describes the chemical change that occurs when kinases bind to substrates?

Possible Answers:

Phosphorylation

Adenylation

Acetylation

Methylation

Correct answer:

Phosphorylation

Explanation:

Kinases are enzymes that phosphorylate the substrates they bind to, meaning that the kinase transfers a phosphate group to the substrate. ATP donates the phosphate group used in this process. Phosphorylation by kinases can lead to a variety of effects including: activation, inhibition, stabilization, destabilization, and localization. Kinases are very important in cellular activities and metabolic processes. 

Example Question #472 : Ap Biology

Which of the following statements about receptors are true?

Possible Answers:

The native state of receptors is inactive

They receive only extracellular signals

They are embedded in the plasma membrane

Receptors are always activated when they bind to ligands

Correct answer:

They are embedded in the plasma membrane

Explanation:

Receptors are proteins embedded in the plasma membrane that receive and transmit signals from extracellular and intracellular sources. Receptors can also be embedded in the plasma membrane of the nucleus. Receptors bind to ligands, which can elicit a variety of responses including: activation, partial activation, and inhibition.

Example Question #473 : Ap Biology

Which of the following statements are true for all ligands?

Possible Answers:

Ligands bind to specific receptors

Binding to a receptor causes a conformation change

Ligands always activate receptors

Ligands only bind to proteins

Correct answer:

Binding to a receptor causes a conformation change

Explanation:

Ligands are molecules that form complexes with other molecules, proteins, or genetic material. The binding of a ligand causes a conformational change to the complex that leads to a response. This response by associated molecules is not limited to activation, but also includes inhibition, partial activation, and inhibition of constitutive activity. Ligands can be either selective or non-selective, meaning that they can bind to only specific molecules or to many receptors, respectively.

Example Question #412 : Cellular Biology

In second messenger signaling systems (i.e.as the cAMP system), where do second messenger molecules function in the cell?

Possible Answers:

Second messenger molecules function only in the nucleus

Intracellular space

Within the phospholipid layers of the plasma membrane

Extracellular space

Correct answer:

Intracellular space

Explanation:

Second messenger systems begin with an extracellular ligand that binds to a receptor on the cell surface. The receptor then activates intracellular primary effectors (proteins that transduce the signal from the plasma membrane to the cytosol). In the cytosol, effectors activate second messenger molecules, which regulate intracellular process including transcription, neurotransmitter release, and enzyme activation. Second messengers have several common characteristics: they are localized, are easily synthesized and degraded, and are intracellular. These systems are responsible for diverse cellular processes and are able to amplify signals through kinase cascades. Common second messenger systems are the cAMP system and the tyrosine kinase system.

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