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In the human brain, neurons perform complex calculations on the information they receive
The researchers found that within a single neuron, different types of dendrites receive input from different parts of the brain and process it differently
In the neurons the researchers examined in this study, this dendritic processing appears to help cells take in visual information and combine it with motor feedback, a circuit involved in navigation and motor planning
"Our hypothesis is that these neurons have the ability to pick out specific features and landmarks in the visual environment and combine them with information such as running speed, where I'm going, when to start, etc.
Mathieu Lafourcade, a former MIT postdoc, is the lead author of the paper published today in the journal Neuron
complex calculation
Any given neuron can have dozens of dendrites, which receive synaptic input from other neurons
Previous research has shown that dendrites can amplify incoming signals through specialized proteins called NMDA receptors
This phenomenon, known as superlinearity, is thought to help neurons distinguish between inputs that are closer or farther apart in time or space, Harnett said
In the new study, the MIT researchers wanted to determine whether different types of input target different types of dendrites, and if so, how that would affect the computations these neurons perform
Harnett and his colleagues chose a part of the brain called the retrosplenial cortex (RSC) for their study because it is a good model of the correlative cortex
In a study in mice, the researchers first showed that three distinct types of input enter the pyramidal neurons of the RSC: from the visual cortex to the basal dendrites, from the motor cortex to the apical oblique dendrites, and from the lateral thalamic nucleus (Visual Processing Zone) into clustered dendrites
"Until now, there hasn't been a lot of mapping of which inputs go into these dendrites," Harnett said
a series of reactions
The researchers then measured the electrical activity in each compartment
On the basal dendrites, the researchers saw what they expected: Input from the visual cortex stimulated ultralinear electrical spikes produced by NMDA receptors
"It was shocking because no one had ever reported it before," Harnett said
These linear inputs may represent information such as running speed or destination, while visual information entering the basal dendrites represents landmarks or other features of the environment, Harnett said
In clustered dendrites receiving thalamic input, NMDA spikes appear to be generated, but not readily
.
Like apical oblique dendrites, clustered dendrites have a lower density of NMDA receptors
.
Harnett's lab is now studying what happens in all these different types of dendrites when mice perform navigation tasks
.
DOI
10.
1016/j.
neuron.
2022.
01.
025
Article Title
Differential dendritic integration of long-range inputs in association cortex via subcellular changes in synaptic AMPA-to-NMDA receptor ratio