.png){kind=icon}
Principles of Life 3e Student Resources is no longer available and it was replaced by Biology and Life Sciences.
Animation 31.3 Synaptic Transmission
INTRODUCTION
The ability of our nervous system to orchestrate complex behaviors, deal with complex concepts, and learn and remember depends upon communication between vast numbers of neurons. Communication between neurons occurs at specialized junctions called synapses. The most common type of synapse in the brain is the chemical synapse—one in which chemical messages released by a presynaptic cell induce changes in a postsynaptic cell. Neurons also communicate with muscle cells through chemical synapses. The classic synapse that has been extensively studied is the neuromuscular junction—the synapse through which a motor neuron causes a muscle cell to contract.
This animation depicts the events that are involved in transmitting the signal from the nerve ending of a motor neuron to a muscle cell at a chemical synapse using the neurotransmitter acetylcholine (ACh).
Please note: If you have been assigned this activity by your instructor, you must complete it within LaunchPad (or your school's learning management system) in order to receive credit.
Textbook Reference: Key Concept 33.1 Muscle Cells Develop Forces by Means of Cycles of Protein-Protein Interaction, p.831
CONCLUSION
We have just seen how the electrical signal—the action potential—is passed from a presynaptic cell (a neuron) to a postsynaptic cell (a muscle cell) via the chemical synapse using the neurotransmitter acetylcholine.
In the human brain, more than 25 neurotransmitters are now recognized, and which neurotransmitter is used by a particular neuron will determine whether a synapse is excititory or inhibitory. In addition, each neurotransmitter may bind to several receptor subtypes. Ultimately, the action of a particular neurotransmitter will depend on the receptor to which it binds.
Note that in this animation we have depicted only a single synaptic vesicle within the terminal. An actual synapse contains a multitude of synaptic vesicles. In addition, the arrival of the action potential triggers the release of neurotransmitter only from those vesicles closest to the synaptic membrane. Vesicles farther away from the membrane then move into position in preparation for another round of transmitter release.