Using cutting-edge visualization and genetic techniques, the researchers at Salk Institute have uncovered a new subtype of nerve cell in the visual cortex.
To understand the working of the brain, researchers need to know not only what types of nerve cells exist, but also how they work together. Researchers at the Salk Institute have gotten one step closer to unlocking this mystery. Using cutting-edge visualization and genetic techniques, the team uncovered a new subtype of nerve cell, or neuron, in the visual cortex. The group also detailed how the new cell and two similar neurons process images and connect to other parts of the brain. Learning how the brain analyzes visual information at such a detailed level may one day help doctors understand elements of disorders like schizophrenia and autism.
‘Unlocking the detailed workings of the brain has been a slow-going challenge. Salk scientists have uncovered a new subtype of neuron, in the visual cortex. They also detailed how the new cell and two similar neurons process images and connect to other parts of the brain.’
Edward Callaway, Salk professor and senior author of the paper published December 6, 2015, in Neuron, said, "Understanding these cell types contributes another piece to the puzzle uncovering neural circuits in the brain, circuits that will ultimately have implications for neurological disorders."Unlocking the detailed workings of the brain has been a slow-going challenge. Historically, scientists used stains to show that various neurons have distinct shapes, and are likely different types of cells. Yet, the true number of neuron types in the brain remains a mystery. Callaway compares the task of unraveling neuronal connectivity and function to intelligence surveillance. Twenty years ago, the technology to track connections between various neurons in the brain was about as sophisticated as filming a group of people on a city corner talking on cell phones: each person is talking to another, but the person on other end of the conversation may be a block away, or across the country. The content of the conversations would be impossible to deduce.
Callaway said, "Similar to those cell phone conversations, each type of neuron is only connected to certain other types of neurons, but it could be a cell anywhere else in the brain. New mouse models and other technology developed in the past five years offer mapping tools as powerful as phone-tapping surveillance, allowing scientists to track what are the neuron types, which cell types are talking to each other, and what are they talking about."
In their new paper, Callaway and colleagues chipped away at these questions by selectively genetically manipulating specific cell types in animal models to visualize the size, shape and electrical activity unique to individual types of neurons.
The three neuron types the team studied are part of a larger classification of neurons called excitatory pyramidal (named for their shape) neurons, and play an important role across the cortex of the brain. Although all the experiments were done in the visual cortex of mice, the same neuron cell types likely exist and play similar roles in the brains of many animals, including humans.
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The Salk scientists used special imaging techniques to show how, and when, the three cell types were activated in response to different images shown to a living mouse. To trace the new cell's neural circuit, the team used a modified rabies virus method invented by Callaway's lab to map the connections between the three neuron types and cells in the rest of the brain.
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Two neuronal types that were sensitive to fine-detailed spatial information in the visual tests were also mapped to parts of the brain responsible for parsing various bits of information. Similarly, the neurons that responded to direction and speed in the visual tests were shown to connect differently to the parts of the brain in the rabies mapping experiment.
Callaway said, "It's not an accident that a particular cell type responds to fast-moving stimuli because those neurons connect to a part of the brain that is responsible for controlling eye movement. The outputs are matched to the function of the circuit."
Callaway expects future experiments will likely determine even more functions of these neurons.
Callaway said, "Now that we have this understanding of these neurons, it leads to new hypotheses and new ideas about what the neurons are doing. We can set up new experiments with these cell types and see how it changes behavior in the mice."
Learning how cell types are connected and function under different circumstances can ultimately help explain what goes wrong in various conditions such as autism and schizophrenia.
Callaway said, "The part of the brain we studied was the visual cortex, but the cell types we're looking at are also found in every other part of the cerebral cortex, such as areas involved in motor or cognitive functions."
Source-Eurekalert