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Neuroscientists at the University of Tübingen identify cortical modules in the mouse brain which represent the direction the animal is facing
Landmarks like a church steeple or a yellow house on the corner play an important role in the ability to navigate. But so does an internal compass, thought to be supported by specialized neurons in the brain – called ‘head-direction’ cells. These neurons respond to direction, and there are still many unsolved puzzles as to how they work. A team of neuroscientists at the University of Tübingen has established exactly where they are located, how they are connected to other parts of the brain, and which mechanisms support their activity. The researchers believe they may have found the location in the brain where the information from the internal compass meets inputs about external landmarks. The international team is headed by Dr. Patricia Preston-Ferrer at the Institute of Neurobiology and the Werner Reichardt Centre for Integrative Neuroscience (CIN). The study, conducted in cooperation with the Shenzhen Institute of Advanced Technology, has been published in the journal Cell Reports.
“The existence of head-direction cells was documented more than 30 years ago in rodents. Much like a compass, these neurons follow the movement of the animal in its environment, thus giving rise to an internal representation of direction in the brain,” Dr. Patricia Preston-Ferrer explains. “If you are to understand how neurons work in the brain, you first need to make them visible,” she adds. In order to understand information processing in the brain – the software – you need to resolve the underlying brain circuits – the hardware. As early as 2016, the team established an experimental approach for making head-direction neurons visible under the microscope.
Corresponding structures in the human brain
Head-direction neurons are known to be preferentially located in the presubiculum, a specialized area of the cortex. “We were very surprised by finding that the mouse presubiculum was not homogeneous, but clearly divided into modules”, says CIN researcher Giuseppe Balsamo. “We identified two different types of modules which were molecularly distinct, and were differently interconnected with other parts of the brain.” The team found that these modules were present not only in the rodent brain, but also in the human brain.
By labelling individual head-direction neurons, the authors made two striking observations. Firstly, head-direction neurons were found only in one cortical module, pointing to a precise structure-function organization of the presubicular cortex. Second, this module type was densely innervated by one particular nucleus of the thalamus, which is involved in the processing of visual landmark information. “We know that efficient navigation relies on the use of an internal compass, plus external visual landmark information” says Professor Andrea Burgalossi, head of a CIN research unit. “We may have found the place in the brain where the internal sense of direction and visual information are combined to support navigation.”
Switching off the compass
The team also found that, whenever they artificially perturbed the activity of the cortical modules, head-direction neurons became suddenly silent. “It seemed that our manipulation had switched off the internal compass” says Dr. Eduardo Blanco-Hernandez. Yet not all head-direction neurons were silenced. “We currently do not know whether silenced and stable head-direction neurons serve different functions during behavior, but clearly the internal compass has a more complex structure than previously assumed.”
“We have gained insights into fundamental organization principles of the cortex,” says Dr. Preston-Ferrer. In fact, modularity has been observed in other cortical areas. The cortex is a thin layer of neural tissue on the surface of the brain, which is primarily responsible for high-order cognitive functions. By focusing on the head-direction system, the team was able to map one of these functions – internal representation of direction – onto the underlying cortical structure. “Now it will be important to understand when and how the presubicular cortical modules emerge during development”, says Prof. Burgalossi “and whether they are disrupted in neurodegenerative disorders, like Alzheimer’s disease, where problems with the internal sense of direction are one of the earliest signs.”
University of Tübingen
Institute of Neurobiology
Werner Reichardt Centre for Integrative Neuroscience (CIN)
Dr. Patricia Preston-Ferrer
Phone +49 7071 29-88797
patricia.preston[at]cin.uni-tuebingen.de
Professor Dr. Andrea Burgalossi
andrea.burgalossi[at]cin.uni-tuebingen.de
Giuseppe Balsamo, Eduardo Blanco-Hernández, Feng Liang, Robert Konrad Naumann, Stefano Coletta, Andrea Burgalossi and Patricia Preston-Ferrer: Modular microcircuit organization of the presubicular head-direction map. Cell Reports 39, 110684 April 12. https://doi.org/10.1016/j.celrep.2022.110684
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