When we learn the connections between neurons strengthen.
Addiction or other neurological diseases are linked to abnormally strong
connections. But what does learning look like on the cellular and molecular
level? How do our cells change when we learn? Using super-resolution live-cell
microscopy, researchers at Thomas Jefferson University zoomed into the
connections between neurons that strengthen to discover structural changes that
had never been seen before.
The research was published April 23rd in Nature
Neuroscience.
"Our observations give the field a new way of
thinking about how normal learning and the maladaptive learning we see in
disorders, such as addiction or autism, might occur," said Matthew Dalva
Professor of Neuroscience at The Vickie and Jack Farber Institute for
Neuroscience and Director of the Synaptic Biology Center at Jefferson
(Philadelphia University + Thomas Jefferson University).
Rather than simply seeing bigger connections during
learning, which has been observed before, Dr. Dalva and his colleagues found
that the molecules involved in sending and receiving the signals between
neurons appeared to be organized in clumps or "nanomodules" that both
dance and multiply when stimulated by learning-like signals.
The researchers made their observations using living
neurons in real-time, zooming into synapses, the sites of neuronal connection
where information is passed from one cell to another to enable learning and
other behavior. Dr. Dalva's colleagues visualized the key molecules involved in
the neurotransmission from neuron to neuron with two colors, green on sending side
(the pre-synaptic side) and red on the receiving side (postsynaptic side).
The team made a number of surprising observations about
the synaptic nanomodules. They saw that the key molecules on the presynaptic
side clumped together and tracked, as if linked, to the key molecules clumped
on the postsynaptic side. These pre/post molecular clumps or nanomodules appear
to have a uniform size. They also multiplied when the neurons were stimulated
in a way that mimicked changes in the size of the spines which protrude
from neurons to
nearly touch at the synapse. And as the number of nanomodules increased, so did
the size of the spines. "The key finding is that changes in synaptic
strength might be more digital than analog - with same sized units added to
change synaptic strength," said Dr. Dalva.
Another surprise was how the nanomodules behaved when
stimulated. "When we activated the neuron with signals that would
strengthen the synaptic connection, a non-moving nanomodule would begin to
jiggle and move around the synaptic spine, with the pre- and post-synaptic
components always in lock step," said first author Dr. Martin Hruska, an
Instructor in Dr. Dalva's lab.
"Although it's yet unclear how these nanomodules
might behave in disease states, our observations offer a new way to explore
those questions," said Dr. Dalva.
Like the best scientific research, the research suggests
many more questions for the field to investigate: How is the neuron able to
make the clumps or nanodomains of the same size? Why are they the same size?
How do they increase in number - do they split in two, or are new ones made?
Why do they move around when the synapse is stimulated? Finally, how do
nanomodules behave in disorders such as addiction or autism?
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