The guitar strings and the cell membrane both act as barriers to signal transmission.

The electric pickup and the receptor both convert external signals into internal messages.

The amplifier and the phosphorylation cascade both reduce the signal strength.

The guitar strings and the ligand both directly enter the cell to transmit signals.

The G-protein acts as a barrier to prevent signal transmission.

The G-protein's snaky structure allows it to move freely within the cell.

The G-protein's subunits allow it to change shape and activate other proteins.

The G-protein directly releases glucose from glycogen.

ATP is converted to cAMP to store energy for later use.

ATP is converted to cAMP to amplify the signal within the cell.

ATP is converted to cAMP to deactivate the signal transduction pathway.

ATP is converted to cAMP to directly release glucose from glycogen.

Protein kinase directly breaks down glycogen into glucose.

Protein kinase activates phosphorylase, which then releases glucose from glycogen.

Protein kinase deactivates the G-protein, stopping the signal.

Protein kinase stores glucose for future use.

Secondary messengers like cAMP reduce the signal strength.

Secondary messengers like cAMP are not involved in signal amplification.

Secondary messengers like cAMP increase the number of active protein kinases.

Secondary messengers like cAMP directly release glucose from glycogen.

It causes the receptor to release glucose directly.

It activates the alpha subunit, which then activates adenylyl cyclase.

It deactivates the receptor, stopping the signal.

It causes the receptor to bind directly to glycogen.

Adenylyl cyclase stores ATP for future use.

Adenylyl cyclase converts ATP to cAMP, initiating the signal amplification.

Adenylyl cyclase directly releases glucose from glycogen.

Adenylyl cyclase deactivates the G-protein.