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| This is a reconstruction of a pair of synaptically connected neurons. |
Neurons, the cells of the nervous system, communicate by transmitting
chemical signals to each other through junctions called synapses. This
"synaptic transmission" is critical for the brain and the spinal cord to
quickly process the huge amount of incoming stimuli and generate
outgoing signals. However, studying synaptic transmission in living
animals is very difficult, and researchers have to use artificial
conditions that don't capture the real-life environment of neurons. Now,
EPFL scientists have observed and measured synaptic transmission in a
live animal for the first time, using a new approach that combines
genetics with the physics of light. Their breakthrough work is published
in Neuron.
Aurélie Pala and Carl Petersen at EPFL's Brain Mind Institute used a
novel technique, "optogenetics," that has been making significant
inroads in the field of neuroscience in the past ten years. This method
uses light to precisely control the activity of specific neurons in
living, even moving, animals in real time. Such precision is critical in
being able to study the hundreds of different neuron types, and
understand higher brain functions such as thought, behavior, language,
memory -- or even mental disorders.
Activating neurons with light
Optogenetics works by inserting the gene of a light-sensitive protein
into live neurons, from a single cell to an entire family of them. The
genetically modified neurons then produce the light-sensitive protein,
which sits on their outside, the membrane. There, it acts as an
electrical channel -- something like a gate. When light is shone on the
neuron, the channel opens up and allows electrical ions to flow into the
cell; a bit like a battery being charged by a solar cell.
The addition of electrical ions changes the voltage balance of the
neuron, and if the optogenetic stimulus is sufficiently strong it
generates an explosive electrical signal in the neuron. And that is the
impact of optogenetics: controlling neuronal activity by switching a
light on and off.
Recording neuronal transmissions
Pala used optogenetics to stimulate single neurons of anesthetized
mice and see if this approach could be used to record synaptic
transmissions. The neurons she targeted were located in a part of the
mouse's brain called the barrel cortex, which processes sensory
information from the mouse's whiskers.
When Pala shone blue light on the neurons that contained the
light-sensitive protein, the neurons activated and fired signals. At the
same time, she measured electrical signals in neighboring neurons using
microelectrodes that can record small voltage changes across a neuron's
membrane.
Using these approaches, the researchers looked at how the
light-sensitive neurons connected to some of their neighbors: small,
connector neurons called "interneurons." In the brain, interneurons are
usually inhibitory: when they receive a signal, they make the next
neuron down the line less likely to continue the transmission.
The researchers recorded and analyzed synaptic transmissions from
light-sensitive neurons to interneurons. In addition, they used an
advanced imaging technique (two-photon microscopy) that allowed them to
look deep into the brain of the live mouse and identify the type of each
interneuron they were studying. The data showed that the neuronal
transmissions from the light-sensitive neurons differed depending on the
type of interneuron on the receiving end.
"This is a proof-of-concept study," says Aurélie Pala, who received
her PhD for this work. "Nonetheless, we think that we can use
optogenetics to put together a larger picture of connectivity between
other types of neurons in other areas of the brain."
The scientists are now aiming to explore other neuronal connections
in the mouse barrel cortex. They also want to try this technique on
awake mice, to see how switching neuronal activity on and off with a
light can affect higher brain functions.
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