(Image caption: 3D image of the hippocampus of a rat. Credit: M. Pyka)

A glimpse into the 3D brain

People who wish to know how memory works are forced to take a glimpse into the brain. They can now do so without bloodshed: RUB researchers have developed a new method for creating 3D models of memory-relevant brain structures. They published their results in the trade journal “Frontiers in Neuroanatomy”.

Sea Horse gave the hippocampus the name

The way neurons are interconnected in the brain is very complicated. This holds especially true for the cells of the hippocampus. It is one of the oldest brain regions and its form resembles a sea horse (hippocampus in Latin). The hippocampus enables us to navigate space securely and to form personal memories. So far, the anatomic knowledge of the networks inside the hippocampus and its connection to the rest of the brain has left scientists guessing which information arrived where and when.

Signals spread through the brain

Accordingly, Dr Martin Pyka and his colleagues from the Mercator Research Group have developed a method which facilitates the reconstruction of the brain’s anatomic data as a 3D model on the computer. This approach is quite unique, because it enables automatic calculation of the neural interconnection on the basis of their position inside the space and their projection directions. Biologically feasible network structures can thus be generated more easily than it used to be the case with the method available to date. Deploying 3D models, the researchers use this technique to monitor the way neural signals spread throughout the network time-wise. They have, for example, found evidence that the hippocampus’ form and size could explain why neurons in those networks fire in certain frequencies.

Information become memories

In future, this method may help us understand how animals, for example, combine various information to form memories within the hippocampus, in order to memorise food sources or dangers and to remember them in certain situations.

(Image caption: The structure determines the function: AMPA receptors in the nerve cells of the brain are composed of a range of more than 30 different proteins. Source: Bernd Fakler)

Understanding the Components of Memory

Dr. Uwe Schulte, Dr. Jochen Schwenk, Prof. Dr. Bernd Fakler, and their team have elucidated the enormous spatial and temporal dynamics in protein composition of the AMPA-type glutamate receptors, the most important excitatory neurotransmitter receptors in the brain. These receptors are located in the synapses, the contact points between two nerve cells, where they are responsible for the rapid signal transduction and information processing. The results illustrate that the receptors are far more diverse than previously anticipated and pave the way for research into their functions in the various regions of the brain. The biologists published their findings in the journal Neuron.

The researchers have thus opened up the possibility to investigate the properties and functions of the AMPA receptors in the various regions of the brain at the level of their protein components. This is of particular significance as the AMPA receptors and their dynamics are regarded as central elements for memory formation. The researchers succeeded in elucidating the subunit structure of the AMPA receptors in various regions of the brain and even in different groups of distinct nerve cells. It became clear that the receptors exhibit an enormous range of variation in structure and molecular architecture and can evidently be precisely adapted to the function of the nerve cells and brain region in which they are located. In addition, the researchers demonstrated that this diversity in protein composition of the receptors is also exploited during the development of the brain.

In 2012, Fakler’s research team already used novel proteomic technologies to show that AMPA receptors in the brain are assembled from a pool of more than 30 different proteins - whose primary function(s) is are most parts as yet unknown. In fact in another recent study, also published in Neuron, the researchers demonstrated just how significant these unknown components are or can be: They showed that the cornichon protein dictates the time course of the AMPA receptor-mediated synaptic transmission and thus accounts for the difference between various types of nerve cells in the brain.

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Scientists Discover Pain Receptor on T-Cells

Researchers at University of California, San Diego School of Medicine have discovered that T-cells – a type of white blood cell that learns to recognize and attack microbial pathogens – are activated by a pain receptor.

The study, reported online Oct. 5 in Nature Immunology, shows that the receptor helps regulate intestinal inflammation in mice and that its activity can be manipulated, offering a potential new target for treating certain autoimmune disorders, such as Crohn’s disease and possibly multiple sclerosis. 

“We have a new way to regulate T-cell activation and potentially better control immune-mediated diseases,” said senior author Eyal Raz, MD, professor of medicine.

The receptor, called a TRPV1 channel, has a well-recognized role on nerve cells that help regulate body temperature and alert the brain to heat and pain. It is also sometimes called the capsaicin receptor because of its role in producing the sensation of heat from chili peppers.

The study is the first to show that these channels are also present on T-cells, where they are involved in gating the influx of calcium ions into cells – a process that is required for T-cell activation.

“Our study breaks current dogma in which certain ion channels called CRAC are the only players involved in calcium entry required for T-cell function,” said lead author Samuel Bertin, a postdoctoral researcher in the Raz laboratory. “Understanding the physical structures that enable calcium influx is critical to understanding the body’s immune response.”

T-cells are targeted by the HIV virus and their destruction is why people with AIDS have compromised immune function. Certain vaccines also exploit T-cells by harnessing their ability to recognize antigens and trigger the production of antibodies, conferring disease resistance. Allergies, in contrast, may occur when T-cells recognize harmless substances as pathogenic.

TRPV1 channels appear to offer a way to manipulate T-cell response as needed for health. Specifically, in in vitro experiments researchers showed that T-cell inflammatory response could be reduced by knocking down the gene that encodes for the protein that comprises the TRPV1 channel. Overexpression of this gene was shown to lead to a surge in T-cell activation, which in human health may contribute to autoimmune diseases. T-cells also responded to pharmaceutical agents that block or activate the TRPV1 channel.

In experiments with mice models, researchers were able to reduce colitis with a TRPV1-blocker, initially developed as a new painkiller. One of the promising discoveries is that colitis in mice could be treated with much lower doses than what is needed to dull pain. “This suggests we could potentially treat some autoimmune diseases with doses that would not affect people’s protective pain response,” Raz said.

Pictured: An inflammatory response and damage to the intenstinal wall (left) could be prevented by injecting TRPV1-deficient T-cells (right).
Credit: Nature Immunulogy, Bertin et al.

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Why are human faces so unique?

What’s in a face? The amazing variety of human faces — far greater than that of most other animals — is the result of evolutionary pressure to make each of us unique and easily recognizable, according to a new study out of UC Berkeley.

Behavioral ecologist Michael J. Sheehan explains that our highly visual social interactions are almost certainly the driver of this evolutionary trend. Many animals use smell or vocalization to identify individuals, making distinctive facial features unimportant, especially for animals that roam after dark, he said. But humans are different.

In the study, Sheehan and coauthor Michael Nachman asked, “Are traits such as distance between the eyes or width of the nose variable just by chance, or has there been evolutionary selection to be more variable than they would be otherwise; more distinctive and more unique?”

As predicted, the researchers found that facial traits are much more variable than other bodily traits, such as the length of the hand, and that facial traits are independent of other facial traits, unlike most body measures. People with longer arms, for example, typically have longer legs, while people with wider noses or widely spaced eyes don’t have longer noses. Both findings suggest that facial variation has been enhanced through evolution.

“Genetic variation tends to be weeded out by natural selection in the case of traits that are essential to survival,” Nachman said. “Here it is the opposite; selection is maintaining variation. All of this is consistent with the idea that there has been selection for variation to facilitate recognition of individuals.”

Human faces are so variable because we evolved to look unique →

Neuroimaging could be the key to a better society

Neuroimaging techniques are a strongly emerging technology and could bring about a revolution in various areas of society, as long as we choose the direction we want to steer these developments in on time. This is one of the conclusions from a series of dialogues between neuroscientists and future users, organised for the research project Towards an appropriate societal embedding of neuroimaging. The project is part of the NWO research programme Responsible Innovation.

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How to tell a missile from a pylon: a tale of two cortices

During the Second World War, analysts pored over stereoscopic aerial reconnaissance photographs, becoming experts at identifying potential targets from camouflaged or visually noisy backgrounds, and then at distinguishing between V-weapons and innocuous electricity pylons.

Now, researchers at the University of Cambridge have identified the two regions of the brain involved in these two tasks – picking out objects from background noise and identifying the specific objects – and have shown why training people to recognise specific objects improves their ability to pick out objects.

In a study funded by the Wellcome Trust, volunteers were given a series of 3D stereoscopic images with varying levels of background noise and asked first to find a target object and then to say whether the object was in the foreground or the background. During the task, researchers applied transcranial magnetic stimulation (TMS) – a technique whereby a magnetic field is applied to the head – to disrupt the performance of two regions of the brain used in object identification: the parietal cortex and the ventral cortex. Their results are published in the journal Current Biology.

The researchers showed that the parietal cortex was involved in selecting potential targets from background noise, while the ventral cortex was involved in object recognition. When TMS was applied to the parietal cortex, volunteers performed less well at selecting objects from the background; when the field was applied to the ventral cortex, they performed less well at identifying the specific objects.

However, the researchers found that after the volunteers had undergone training to discriminate between specific objects, the ventral cortex – which, until then, had only been used for this purpose – also became involved in selecting targets from noise, enhancing their ability to distinguish between objects. The reverse was not true – in other words, the parietal cortex did not become involved in object discrimination.

Dr Welchman, a Wellcome Trust Senior Research Fellow in the Department of Psychology, explains: “The parietal cortex and the ventral cortex appear to be involved in the overlapping tasks to a different extent. By analogy to the World War II analysts, the parietal cortex helped them spot suspect objects while the ventral cortex helped them distinguish the weapons from the pylons. But training these operatives to identify the weapons will have improved their ability to spot potential weapons in the first place.”

The research may have implications for therapies to help people with attentional difficulties. For example, people with damage to the parietal cortex, such as through stroke, are known to have difficulty in finding objects in displays, particularly when the display is distracting.

“These results show that training in clear displays modifies the brain areas that underlie performance in distracting situations. This suggests a route for rehabilitative training that helps individuals avoid distracting information by training individuals to make fine judgements,” he adds.