Synapses: Structure & Function (Edexcel A Level Biology (A) SNAB): Revision Note
Synapses: Structure & Function
Structures known as synapses are found at the junctions between cells in the nervous system e.g.
In the sense organs there are synapses between sensory receptor cells and sensory neurones
In muscles there are synapses between motor neurones and muscle fibres
The structure of a synapse includes the following features
A gap between the neurones known as the synaptic cleft
The neurone before the synapse is known as the presynaptic neurone and has a rounded end known as the synaptic knob
The neurone after the synapse is known as the postsynaptic neurone
Nerve impulses are passed across the synaptic cleft by the diffusion of chemicals known as neurotransmitters e.g. acetylcholine
Neurotransmitters are contained within vesicles in the synaptic knob
Synapses are the junctions between neurones e.g. between a sensory neurone and a relay neurone
Synaptic transmission
Electrical impulses cannot ‘jump’ across the synaptic cleft
When an action potential arrives at the end of the axon of the presynaptic neurone the membrane becomes depolarised, causing voltage gated calcium ion channels to open
Calcium ions diffuse into the synaptic knob via calcium ion channels in the membrane
The calcium ions cause vesicles in the synaptic knob to move towards the presynaptic membrane where they fuse with it and release chemical messengers called neurotransmitters into the synaptic cleft by exocytosis
A common neurotransmitter is acetylcholine, or ACh
The neurotransmitters diffuse across the synaptic cleft and bind with receptor molecules on the postsynaptic membrane; this causes associated sodium ion channels on the postsynaptic membrane to open, allowing sodium ions to diffuse into the postsynaptic cell
If enough neurotransmitter molecules bind with receptors on the postsynaptic membrane then an action potential is generated, which then travels down the axon of the postsynaptic neurone
Whether or not an action potential is generated depends on whether or not threshold potential is reached, which in turn depends on the number of action potentials arriving at the presynaptic knob
Many action potentials will cause more neurotransmitter to be released by exocytosis
A large amount of neurotransmitter will cause many sodium ion channels to open
Many sodium ion channels opening will allow a large influx of sodium ions, increasing the likelihood of threshold being reached
The neurotransmitters are then broken down to prevent continued stimulation of the postsynaptic neurone
The enzyme that breaks down acetylcholine is acetylcholinesterase
Impulses are transmitted across the synaptic cleft by the diffusion of neurotransmitters such as acetylcholine
Additional roles of synapses
Synapses enable
Unidirectionality of impulse transmission
Synapses ensure the one-way transmission of impulses
Impulses can only pass in one direction at synapses because neurotransmitter is released on one side and its receptors are on the other; chemical transmission cannot occur in the opposite direction
Divergence of nerve impulses
One neurone can connect to several other neurones at a synapse, allowing nerve signals to be sent in several directions from a single presynaptic neurone
Amplification of nerve signals by summation
When an impulse arrives at a synapse it does not always cause an impulse to be generated in the next neurone; a single impulse that arrives at a synaptic knob may be insufficient to generate an action potential in the post-synaptic neurone
Only a small amount of acetylcholine may release into the synaptic cleft
A small number of sodium ion channels are opened in the postsynaptic axon membrane
An insufficient number of sodium ions pass through the membrane
The threshold potential is not reached
The effect of multiple impulses can be added together to overcome this in a process known as summation
Summation can be achieved by
Several presynaptic neurones converging to meet a single postsynaptic neurone
This is known as synaptic convergence
Many action potentials arriving at a postsynaptic knob in quick succession
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