Dendrites are not just passive conduits, a new UCLA study reports. The finding could change scientists’ understanding of how the brain works, and lead to new approaches for treating neurological disorders.
The research investigates the structure and function of dendrites, which are components of neurons, the nerve cells in the brain. Neurons are large, tree-like structures made up of a body, the soma, with numerous branches called dendrites extending outward.
Somas generate brief electrical pulses called “spikes” in order to connect and communicate with each other. Scientists had generally believed that the somatic spikes activate the dendrites, which passively send currents to other neurons’ somas, but this had never been directly tested before.
This process is the basis for how memories are formed and stored.
90 Percent Of Neural Tissue
But the UCLA team’s research showed that dendrites are electrically active in animals that are moving around freely, generating nearly 10 times more spikes than somas.
The finding challenges the long-held belief that spikes in the soma are the primary way in which perception, learning and memory formation occur. UCLA neurophysicist Mayank Mehta, the study’s senior author, said:
“Dendrites make up more than 90 percent of neural tissue. Knowing they are much more active than the soma fundamentally changes the nature of our understanding of how the brain computes information. It may pave the way for understanding and treating neurological disorders, and for developing brain-like computers.”
Scientists have generally believed that dendrites meekly sent currents they received from the cell’s synapse to the soma, which in turn generated an electrical impulse. Those short electrical bursts, known as somatic spikes, were thought to be at the heart of neural computation and learning.
But the new study demonstrated that dendrites generate their own spikes 10 times more often than the somas.
Dendrites Both Analog And Digital
The researchers also found that dendrites generate large fluctuations in voltage in addition to the spikes; the spikes are binary, all-or-nothing events. The somas generated only all-or-nothing spikes, much like digital computers do.
In addition to producing similar spikes, the dendrites also generated large, slowly varying voltages that were even bigger than the spikes, which suggests that the dendrites execute analog computation.
“We found that dendrites are hybrids that do both analog and digital computations, which are therefore fundamentally different from purely digital computers, but somewhat similar to quantum computers that are analog,” said Mehta. “A fundamental belief in neuroscience has been that neurons are digital devices. They either generate a spike or not. These results show that the dendrites do not behave purely like a digital device. Dendrites do generate digital, all-or-none spikes, but they also show large analog fluctuations that are not all or none. This is a major departure from what neuroscientists have believed for about 60 years.”
Because the dendrites are nearly 100 times larger in volume than the neuronal centers, Mehta said, the large number of dendritic spikes taking place could mean that the brain has more than 100 times the computational capacity than was previously thought.
Recent studies in brain slices showed that dendrites can generate spikes.
But it was neither clear that this could happen during natural behavior, nor how often. Measuring dendrites’ electrical activity during natural behavior has long been a challenge because they’re so delicate.
In studies with laboratory rats, scientists have found that placing electrodes in the dendrites themselves while the animals were moving actually killed those cells. But the UCLA team developed a new technique that involves placing the electrodes near, rather than in, the dendrites.
Using that approach, the scientists measured dendrites’ activity for up to four days in rats that were allowed to move freely within a large maze. Taking measurements from the posterior parietal cortex, the part of the brain that plays a key role in movement planning, the researchers found far more activity in the dendrites than in the somas — approximately five times as many spikes while the rats were sleeping, and up to 10 times as many when they were exploring.
First author Jason Moore, a UCLA postdoctoral researcher, said:
“Many prior models assume that learning occurs when the cell bodies of two neurons are active at the same time. Our findings indicate that learning may take place when the input neuron is active at the same time that a dendrite is active —and it could be that different parts of dendrites will be active at different times, which would suggest a lot more flexibility in how learning can occur within a single neuron.”
Looking at the soma to understand how the brain works has provided a framework for numerous medical and scientific questions—from diagnosing and treating diseases to how to build computers. But, Mehta said, that framework was based on the understanding that the cell body makes the decisions, and that the process is digital.
“What we found indicates that such decisions are made in the dendrites far more often than in the cell body, and that such computations are not just digital, but also analog,” Mehta said. “Due to technological difficulties, research in brain function has largely focused on the cell body. But we have discovered the secret lives of neurons, especially in the extensive neuronal branches. Our results substantially change our understanding of how neurons compute.”
Jason J. Moore, Pascal M. Ravassard, David Ho, Lavanya Acharya, Ashley L. Kees, Cliff Vuong, Mayank R. Mehta
Dynamics of cortical dendritic membrane potential and spikes in freely behaving rats
Science; DOI: 10.1126/science.aaj1497
Image: Prof. M. Hausser, Sarah Rieubland & Arnd Roth, UCL, Wellcome Images. Scanning electron micrograph of the dendritic tree of a purkinje neurone in the cerebellar cortex of a rat brain.