Scientists at Duke University Medical Center have uncovered clues to memory and learning by exploring the function of a single gene that governs how neurons form new connections. The finding may also provide insights into a form of human mental retardation.

In a study published in the Journal of Neuroscience, the scientists explored the gene WRP’s functions in the brain cell (neuron) and then demonstrated how acutely memory and learning are affected when WRP is missing in mice.

“Human genomics studies have opened the floodgates of information that will benefit people with many different diseases,” said Scott Soderling, an assistant professor in the Duke Department of Cell Biology. “But it is impossible to correct something without knowing what the exact underlying problem is.”

The researchers knew from earlier human research into the genetics of one individual that when WRP is disrupted, there might be a possible link with severe mental retardation.

The group conducted experiments using neuronal cells in a lab dish which showed that cells enriched with WRP went on to form many filopodia, finger-like protrusions that neurons use to connect with one another.

Without WRP, neurons ultimately were defective in making filopodia, which meant they could not make the correct number of connections, called synapses.

In studies on mice with and without the WRP gene, the researchers were able to see behavior differences.

In one experiment, they tested normal and WRP-deleted mice for their behavior in recognizing a previously unseen toy versus a familiar toy.

A mouse with the gene will typically spend less time investigating a toy it has seen before, but the knockout mice spent the same amount of time with each toy, suggesting they don’t remember the toy they saw yesterday.

“There was a striking difference between the groups of mice,” said Soderling, who is part of the Neonatal Perinatal Research Institute. “The mice without WRP had difficulty learning and didn’t display typical memory ability in several experiments.”

“Because the excitatory synapses that we are studying form their connections right after birth in humans, we think these specific pathways may even provide an opportunity for early intervention after birth,” Soderling said. “Abnormalities in these types of synapses have been linked to mental retardation, and also to schizophrenia and fetal alcohol syndrome, where there are abnormalities that could later affect learning and memory.”

“What surprised me most is that we had a preconceived notion that WRP would be part of a process that helped the neuronal cell surface fold inward,” said lead author Benjamin Carlson, a graduate student in the Soderling lab. “Eventually we figured out it was just the opposite. When we placed the WRP protein on the inside of the neurons, we could see these buds forming out of the neurons, which then became the longer filopodia and synapses. It is rewarding when you finally think through the possibilities and take a different approach that turns out to yield something valuable.”

Soderling credits his collaborators in the Duke Transgenic Mouse and Bacterial Recombineering Core Facility, which helped to produce the right type of mouse for the research.

Other authors include Krissey E. Lloyd, Allison Kruszewski, Il-Hwan Kim, Clifford Heindel and William C. Wetsel of the Duke Departments of Cell Biology and Neurobiology and the Neonatal Perinatal Research Institute; and Wetsel, Ramona M. Rodriguiz and Marika Faytell of Duke Psychiatry and Behavioral Sciences. Faytell is also with the Mouse Behavioral and Neuroendocrine Analysis Core Facility at Duke. Serena M. Dudek is with the National Institute of Environmental Health Sciences in Research Triangle Park, NC.

This work was supported by National Institutes of Health Grant, March of Dimes Grant Basil O’ Connor Starter Scholar Research Grant, Dana Foundation Grant, and by the Intramural Research Program of the National Institute of Environmental Health Sciences Grant.

Source: Duke Medicine News and Communications

Why do some people fret over the most trivial matters while others remain calm in the face of calamity? Researchers at the University of California, Berkeley, have identified two different chinks in our brain circuitry that explain why some of us are more prone to .

Their findings, published today (Wednesday, Feb. 9) in the journal Neuron may pave the way for more targeted treatment of chronic fear and anxiety disorders. Such conditions affect at least 25 million Americans and include panic attacks, social phobias, obsessive-compulsive behavior and post-traumatic stress disorder.

In the brain imaging study, researchers from UC Berkeley and Cambridge University discovered two distinct neural pathways that play a role in whether we develop and overcome fears. The first involves an overactive amygdala, which is home to the brain’s primal fight-or-flight reflex and plays a role in developing specific phobias.

The second involves activity in the ventral prefrontal cortex, a neural region that helps us to overcome our fears and worries. Some participants were able to mobilize their ventral prefrontal cortex to reduce their fear responses even while negative events were still occurring, the study found.

“This finding is important because it suggests some people may be able to use this ventral frontal part of the brain to regulate their fear responses – even in situations where stressful or dangerous events are ongoing,” said UC Berkeley psychologist Sonia Bishop, lead author of the paper.

“If we can train those individuals who are not naturally good at this to be able to do this, we may be able to help chronically anxious individuals as well as those who live in situations where they are exposed to dangerous or stressful situations over a long time frame,” Bishop added.

Bishop and her team used functional Magnetic Resonance Imaging (fMRI) to examine the brains of 23 healthy adults. As their brains were scanned, participants viewed various scenarios in which a virtual figure was seen in a computerized room. In one room, the figure would place his hands over his ears before a loud scream was sounded. But in another room, the gesture did not predict when the scream would occur. This placed volunteers in a sustained state of anticipation.

Participants who showed overactivity in the amygdala developed much stronger fear responses to gestures that predicted screams. A second entirely separate risk factor turned out to be failure to activate the ventral prefrontal cortex. Researchers found that participants who were able to activate this region were much more capable of decreasing their fear responses, even before the screams stopped.

The discovery that there is not one, but two routes in the brain circuitry that lead to heightened fear or anxiety is a key finding, the researchers said, and it offers hope for new targeted treatment approaches.

“Some individuals with anxiety disorders are helped more by cognitive therapies, while others are helped more by drug treatments,” Bishop said. “If we know which of these neural vulnerabilities a patient has, we may be able to predict what treatment is most likely to be of help.”

In addition to Bishop, coauthors of the study are Anwar O. Nunez Elizalde at UC Berkeley; Iole Indovina of the Neuroimaging Laboratory of the Santa Lucia Foundation in Rome, Italy;  Trevor Robbins at Cambridge University in the United Kingdom; and Barney Dunn at the MRC Cognition and Brain Sciences Unit in Cambridge, U.K.

Source: UC Berkeley

Event date: 13-16 December 2009
Location: Alexandria, Egypt
Organizer: Alexandria University Faculty of Science
Topic: Neuroscience

Call for Symposia for the 3rd Mediterranean Conference of Neuroscience organized by the Zoology Department, Faculty of Science, Alexandria University, EGYPT. It will be held on the 13-16 of December 2009 and welcomed by Bibliotheca Alexandrina.

 More information about the event