In this article we talk about what is synapse and what is gaba and glutamate .as all you know that the action potential is the language used by neurons to communicate their signals from one end of the cell to the other.
But how does that message get passed from one neuron to the next? Each neuron is separated from its neighbors. How do they do it?
WHAT IS A SYNAPSE
Now we talk about my favorite part of the neuron - the synapse!
your neurons use ions and electrical potential differences to transmit signals from one end to the other. As that signal reaches the end of the axon, it comes to a structure called the “synaptic terminal”.
This structure has several parts.
he side of the cell sending the signal is
called the “pre-synaptic terminal”.The gap in the middle is called the synaptic cleft.
And finally, on the other cell receiving the signal is the “post-synaptic terminal”.
TYPES OF SYNAPSES
There are two basic categories of synapses:
1.The electrical synapse (or “gap junction”) and 2.the chemical synapse.
THE ELECTRICAL SYNAPSE
The electrical synapse is the more simple of the two, allowing direct ionic current transfer between cells to pass the action potential across the synaptic cleft.
These types of synapses have very little space between the pre and post synaptic terminals.About three nanometers.
and use specialized proteins called connexins to form channels that allow the ionic current to pass between cells.
It’s sort of like a skywalk between two buildings.They're still two distinct buildings, but it’s easy to send a message across to the next building because you can just walk across the bridge. Because the gap is so small, electrical synapses allow cells to respond very quickly to signals,
and mean that the cells connected tend to react together.
Because of this, they are important for tasks that require very fast signaling. Like defensive reflexes in animals.
2. CHEMICAL SYNAPSE
The other type of synapse, the chemical synapse, is wider and more complex, with slower signalling.
In these synapses, the synaptic cleft can be 20-50 nanometers wide. Still pretty tiny, but a lot bigger than a gap junction! Because of this, using ions to directly signal on the next cell isn’t practical.There's no skybridges connecting these two buildings! instead, chemical synapses came up with a different way to send their messages.
Remember the pre-synaptic terminal? Let’s think of it as a cellular post-office.
In the pre-synaptic terminal, you can find these itty bitty spherical structures, called vesicles.Think of them like packages.
These vesicles are little pockets of membrane that hold the information to be transmitted,
keeping the message contained until the “post office” of the synapse is told to release the information.
Inside each packet are chemicals known as a “neurotransmitters”.
Quite literally, these molecules transmit information between neurons.
These are like the letters contained within the envelope.
As the signal arrives in the pre-synaptic terminal, it tells these vesicles to move to the edge of the cell,where the vesicle membrane fuses with the cell membrane and opens up, dumping its neurotransmitter into the synaptic cleft.
Once the neurotransmitters reach the post-synaptic terminal, they attach to receptors.
You can think of these receptors like a key.
The neurotransmitter binds to the portion of the receptor that sticks out of the cell membrane,(like a lock) and the information they contain is interpreted by the receptor into some kind of a response.
Sometimes that response means opening an ion channel attached to the receptor itself
letting ions flow and changing the electrical potential of the cell.
Often, the receptor passes the message along to other proteins that rush off into the cell to make other kinds of changes that will affect the electrical potential.
WHAT IS GABA AND GLUTAMATE
There are two main neurotransmitter come in handy
1.glutamate (found at glutamatergic synapses)
and
2. gamma-aminobutyric acid, or GABA (found at GABAergic synapses).
These two neurotransmitters usually have opposite effects on the cells they are signaling.Glutamate is considered “excitatory”, while GABA is considered “inhibitory”.
TYPES OF GLUTAMATE RECEPTORS
Let’s talk about each of these separately.
There are two main types of glutamate receptors:
1. the N-methyl-D-aspartate receptor (NMDAR for short)
and
2.the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (or, AMPAR for short.
When glutamate binds to an NMDAR or AMPAR, it opens a channel in the cell membrane attached to the receptor, letting positively charged ions move in and out of the cell. Because these receptors are part of an ion channel, the binding of glutamate results in a very fast response, which lets the cell rapidly depolarize and start transmitting the action potential down to the other end.
This is why they are called “excitatory” synapses.
Because glutamate binding to the receptor excites the cell to spark an action potential, making the post-synaptic cell spike. Inhibitory synapses have the opposite effect.
The GABA binding to the receptor actually represses signalling, blocking the post-synaptic cell from firing.GABA can bind to two kinds of receptors.The GABAa receptor is much like the AMPARs and NMDARs, opening a pore that lets negative ions into the cell, which makes it harder for the cell to fire an action potential,
WHAT IS METABOTROPIC RECEPTOR
because the inside of the cell becomes even more negative than normal.GABAb receptors are called “metabotropic” receptors. They’re the kind I mentioned before where the receptor sends off a messenger protein to signal elsewhere in the cell, generally resulting in the same thing: making the inside of the cell more negative, to prevent it from firing a signal.
Hope you find all your answers .
See you in next article.
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