 |
|
Deafness and seizures result when mysterious protein deleted in mice
January 25, 2008Scientists have discovered that mice genetically engineered to lack a particular protein in the brain have profound deafness and seizures. The finding suggests a pathway, they say, for exploring the hereditary causes of deafness and epilepsy in humans.
More broadly, the discovery provides an entry point for gaining new insight into the role of glutamate, the chemical messenger carried by the protein, says the team, led by scientists at the University of California, San Francisco. Glutamate is involved in virtually every brain function, including sensory perception, learning and memory.
The missing protein is a particular "vesicular neurotransmitter transporter," a machine within nerve cells that ferries chemical messengers, or "neurotransmitters," from the fluid-filled cytoplasm into vesicles that are positioned at the tips of nerve cells and serve to release neurotransmitters onto neighboring cells. Transporters and neurotransmitters work together to make possible essentially all neural communication in the brain.
While the neurotransmitter glutamate is the major excitatory messenger in the brain, the neurotransmitter GABA is the major inhibitory messenger, sending signals that reduce excitation and anxiety. Two other neurotransmitters, dopamine and serotonin, modulate the activity of neural circuits to influence mood, sleep and other aspects of behavior.
Scientists have known for several years about two vesicular glutamate transporters, VGLUT1 and VGLUT2. As would be predicted, they are expressed on nerve cells that release glutamate. More recently, scientists have identified VGLUT3. To their surprise, they have discovered that VGLUT3 is expressed primarily by nerve cells that release GABA, serotonin and acetylcholine, another neurotransmitter. VGLUT3 is also released in some non-nerve cells, in tissues outside the brain. These findings led scientists to suspect that VGLUT3 might support some function other than neurotransmission.
In the current study, published in the Jan. 24, 2008 issue of "Neuron," the team explored the role of VGLUT3 in mice genetically engineered to lack the transporter. The effect was dramatic.
"Mice lacking the transporter are completely deaf from birth," says the senior author of the study, Robert Edwards, MD, professor of neurology and physiology at University of California, San Francisco. "Moreover, they had significant seizures."
As the gene that encodes VGLUT3 is known to have sequence variations in humans, it is possible that these or other variations may be the underlying cause of deafness or epilepsy in humans, according to the researchers. They plan to screen people with these conditions for variations in the vglut3 gene, says the first author of the study, Rebecca Seal, PhD, a postdoctoral fellow in the Edwards laboratory
In addition, because the mice in the study lacked the protein in all cells that would normally make it, the team plans to make a "conditional knockout," in which the gene is inactivated only in specific types of nerve cells. This will reveal which nerve cells expressing VGLUT3 account for a particular brain function.
At the outset of the study, the team knew that VGLUT3 was expressed during brain development by a population of inhibitory GABAergic neurons in the brainstem pathway that transmits information about sound. They suspected that the absence of VGLUT3 -- which would allow the release of the excitatory glutamate -- might produce a subtle defect in sound localization. Instead, the animals were completely deaf.
The explanation, they learned, was that VGLUT3 contributes to the release of glutamate at a key point in the production of sound. It turns out that inner hair cells of the cochlea, which are known to convert the auditory input, or signal, into glutamate release, express VGLUT3, and the transporter contributes to the release of glutamate onto the first neuron in the pathway that carries sound into the brain. Without VGLUT3, no glutamate is released at that synapse.
The scientists also knew from the outset that VGLUT3 is expressed by a subset of neurons in the hippocampus and cortex that are known to release the inhibitory transmitter GABA. The presence of VGLUT3 suggested that these neurons might also release the excitatory glutamate. Since inhibitory neurons contribute to a range of oscillations in brain wave activity, the team hypothesized that disruption of these systems might affect brain wave activity in the cortex.
In fact, an EEG (electroencephalograph) revealed that all of the mice had seizures, and even when they weren't having full blown attacks they had abnormal electrical discharges in the brain, known as "epilepiform" activity. Surprisingly, the seizures -- which last up to two minutes -- were accompanied by little or no change in behavior.
The team plans to screen young patients with hereditary or early-onset epilepsy to see if they have mutations in this protein, says Edwards.
Since VGLUT3 may be required for relatively subtle aspects of behavior not easily elicited in a mouse, the researchers would also like to identify and study human patients, according to Edwards. The neuromodulatory effect of glutamate release by serotonin neurons, he says, may be easier to detect in humans.
"If we found patients lacking VGLUT3," he says, "we could carry out psychological testing, which would in turn give us an idea why most serotonin neurons also release glutamate.
"This is a case of a mouse model leading us to patients, who will, in turn, suggest additional functional roles for glutamate that we can test in the mouse. The results will help us to understand basic brain function and how it goes awry in disease."
University of California - San Francisco
While the neurotransmitter glutamate is the major excitatory messenger in the brain, the neurotransmitter GABA is the major inhibitory messenger, sending signals that reduce excitation and anxiety. Two other neurotransmitters, dopamine and serotonin, modulate the activity of neural circuits to influence mood, sleep and other aspects of behavior.
Scientists have known for several years about two vesicular glutamate transporters, VGLUT1 and VGLUT2. As would be predicted, they are expressed on nerve cells that release glutamate. More recently, scientists have identified VGLUT3. To their surprise, they have discovered that VGLUT3 is expressed primarily by nerve cells that release GABA, serotonin and acetylcholine, another neurotransmitter. VGLUT3 is also released in some non-nerve cells, in tissues outside the brain. These findings led scientists to suspect that VGLUT3 might support some function other than neurotransmission.
In the current study, published in the Jan. 24, 2008 issue of "Neuron," the team explored the role of VGLUT3 in mice genetically engineered to lack the transporter. The effect was dramatic.
"Mice lacking the transporter are completely deaf from birth," says the senior author of the study, Robert Edwards, MD, professor of neurology and physiology at University of California, San Francisco. "Moreover, they had significant seizures."
As the gene that encodes VGLUT3 is known to have sequence variations in humans, it is possible that these or other variations may be the underlying cause of deafness or epilepsy in humans, according to the researchers. They plan to screen people with these conditions for variations in the vglut3 gene, says the first author of the study, Rebecca Seal, PhD, a postdoctoral fellow in the Edwards laboratory
In addition, because the mice in the study lacked the protein in all cells that would normally make it, the team plans to make a "conditional knockout," in which the gene is inactivated only in specific types of nerve cells. This will reveal which nerve cells expressing VGLUT3 account for a particular brain function.
At the outset of the study, the team knew that VGLUT3 was expressed during brain development by a population of inhibitory GABAergic neurons in the brainstem pathway that transmits information about sound. They suspected that the absence of VGLUT3 -- which would allow the release of the excitatory glutamate -- might produce a subtle defect in sound localization. Instead, the animals were completely deaf.
The explanation, they learned, was that VGLUT3 contributes to the release of glutamate at a key point in the production of sound. It turns out that inner hair cells of the cochlea, which are known to convert the auditory input, or signal, into glutamate release, express VGLUT3, and the transporter contributes to the release of glutamate onto the first neuron in the pathway that carries sound into the brain. Without VGLUT3, no glutamate is released at that synapse.
The scientists also knew from the outset that VGLUT3 is expressed by a subset of neurons in the hippocampus and cortex that are known to release the inhibitory transmitter GABA. The presence of VGLUT3 suggested that these neurons might also release the excitatory glutamate. Since inhibitory neurons contribute to a range of oscillations in brain wave activity, the team hypothesized that disruption of these systems might affect brain wave activity in the cortex.
In fact, an EEG (electroencephalograph) revealed that all of the mice had seizures, and even when they weren't having full blown attacks they had abnormal electrical discharges in the brain, known as "epilepiform" activity. Surprisingly, the seizures -- which last up to two minutes -- were accompanied by little or no change in behavior.
The team plans to screen young patients with hereditary or early-onset epilepsy to see if they have mutations in this protein, says Edwards.
Since VGLUT3 may be required for relatively subtle aspects of behavior not easily elicited in a mouse, the researchers would also like to identify and study human patients, according to Edwards. The neuromodulatory effect of glutamate release by serotonin neurons, he says, may be easier to detect in humans.
"If we found patients lacking VGLUT3," he says, "we could carry out psychological testing, which would in turn give us an idea why most serotonin neurons also release glutamate.
"This is a case of a mouse model leading us to patients, who will, in turn, suggest additional functional roles for glutamate that we can test in the mouse. The results will help us to understand basic brain function and how it goes awry in disease."
University of California - San Francisco
Glutamate Current Events and Glutamate News RSSMillisecond brain signals predict response to fast-acting antidepressant
Images of the brain's fastest signals reveal an electromagnetic marker that predicts a patient's response to a fast-acting antidepressant, researchers have discovered.
Study confirms benefit of combination therapy for Alzheimer's disease
Extended treatment with Alzheimer's disease drugs can significantly slow the rate at which the disorder advances, and combination therapy with two different classes of drugs is even better at helping patients maintain their ability to perform daily activities.
The first autism disease genes
The autistic disorder was first described, more than sixty years ago, by Dr. Leo Kanner of the Johns Hopkins Hospital (USA), who created the new label 'early infantile autism'.
Cocaine-induced synaptic plasticity linked to persistent addictive behaviors
The persistent nature of addiction is its most devastating feature. Understanding the mechanism underlying this phenomenon is the key for designing efficient therapy. Two separate studies published by Cell Press is the August 14 issue of the journal Neuron identify specific cocaine-induced changes in dopamine (DA) neurons that play a pivotal role in behaviors associated with drug addiction.
UNC researchers find MSG use linked to obesity
eople who use monosodium glutamate, or MSG, as a flavor enhancer in their food are more likely than people who don't use it to be overweight or obese even though they have the same amount of physical activity and total calorie intake, according to a University of North Carolina at Chapel Hill School of Public Health study published this month in the journal Obesity.
Halting retrieval of drug-associated memories may prevent addiction relapse
Disrupting the brain's retrieval of drug-associated memories may prevent relapse in drug addiction, according to new research in the August 13 issue of The Journal of Neuroscience.
'Erasing' drug-associated memories may stop drug addiction relapses
'Erasing' drug-associated memories may prevent recovering drug abusers from relapsing, researchers at the University of Cambridge have discovered.
Scientists find how neural activity spurs blood flow in the brain
New research from Harvard University neuroscientists has pinpointed exactly how neural activity boosts blood flow to the brain. The finding has important implications for our understanding of common brain imaging techniques such as fMRI, which uses blood flow in the brain as a proxy for neural activity.
Taking a cue from breath fresheners, researcher develops new method for taste testing
Using the same concept behind commercial breath-freshening strips, a Temple University researcher has developed a new, easier method for clinical taste testing.
Discovery of new signal pathway important to diabetes research
Scientists at Karolinska Institutet in Sweden and Miami University have discovered that cells in the pancreas cooperate - signal - in a way hitherto unknown. The discovery can eventually be of significance to the treatment of diabetes.
More Glutamate Current Events and Glutamate News Articles
 | The Glutamate Receptors (The Receptors) (The Receptors) Glutamate receptors are critically important for normal brain function. The preceding decade has seen remarkable advances in our understanding of the physiological function and molecular structure of these proteins. The Glutamate Receptors provides an expansive review of the field with a topical update to two excellent books - The Ionotropic Glutamate Receptors and The Metabotropic Glutamate... |
 | The Metabotropic Glutamate Receptors (The Receptors) by P. Jeffrey Conn, Jitendra Patel The Metabotropic Glutamate Receptors offers state-of-the-art summaries and reviews of virtually everything known today about metabotropic glutamate receptors (mGluRs), including their molecular biology, pharmacology, anatomical distribution, and physiological and pathological roles. Illuminating the overall role played by this crucial class of receptors in brain function, the book also pinpoints... |
 | In Bad Taste: The Msg Symptom Complex : How Monosodium Glutamate Is a Major Cause of Treatable and Preventable Illnesses, Such As Headaches, Asthma, Epilepsy, heart by George R. Schwartz Did you know that you may have a poison in your pantry? A substance which can case migraine headaches and balance difficulties; precipitate severe shortness of breath, asthma attacks and heart irregularities; cause disabling arthritis, and even serious depressions? A substance that can induce disruptive behavior problems in your children? Monosodium glutamate (MSG), a universally used flavor... |
 | On Astrocytes and Glutamate Neurotransmission: New Waves in Brain Information Processing (Neuroscience Intelligence Unit) by Elisabeth Hansson, Torsten Olsson, Lars Ronnback G. Landes). Goteborg Univ., Sweden. Research on how the astroglia might interact with and modulate nerve cell activity at the synaptic level. Discusses the roles astroglia may play in information processing. 7 contributors, no... |
| Analysis of Adverse Reactions to Monosodium Glutamate (Msg) | |
| Missing MSG: monosodium glutamate has been a key savory flavor enhancer and food processor favorite for nearly a century, but it seems more consumers are ... An article from: Food Processing by David Feder This digital document is an article from Food Processing, published by Thomson Gale on November 1, 2005. The length of the article is 1314 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.Citation DetailsTitle: Missing... | |
 | Glutamate, Glutamine, Glutathione, and Related Compunds, Volume 113: Volume 113: Glutamente, Glutamine, Glutathione and Related Compounds (Methods in Enzymology) The critically acclaimed laboratory standard, Methods in Enzymology, is one of the most highly respected publications in the field of biochemistry. Since 1955, each volume has been eagerly awaited, frequently consulted, and praised by researchers and reviewers alike. The series contains much material still relevant today - truly an essential publication for researchers in all fields of life... |
 | Glutamate Receptors in Peripheral Tissue: Excitatory Transmission Outside the CNS (Endocrine Updates) When the brain suffers an injury such as a stroke, neurons release glutamate onto nearby neurons which become excited, overloaded with calcium, and die. Normal neurotransmission is altered during injury, causing excess calcium to activate enzymes which eventually leads to destruction of the cell. This damage occurs through glutamate receptors. At one time, glutamate receptors were thought to... |
 | Glutamate and Addiction (Contemporary Clinical Neuroscience) (Contemporary Clinical Neuroscience) In Glutamate and Addiction, world-renowned scientific experts critically review all of the evidence for the role of glutamatergic systems in opiate, stimulant, and alcohol addiction. Using a variety of pharmacological, biochemical, genetic, and brain imaging techniques, these investigators show precisely how glutamate affects such addictions and how modifying certain elements of the glutamatergic... |
 | Specific detection of l-glutamate in food using flow-injection analysis and enzymatic recycling of substrate [An article from: Analytica Chimica Acta] by W. Khampha, J. Yakovleva, D. Isarangkul, Wiyakrutt This digital document is a journal article from Analytica Chimica Acta, published by Elsevier in 2004. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.Description: A flow injection analysis (FIA) system for specific determination of l-glutamate in food samples based on a bi-enzymatic... |
| © 2008 BrightSurf.com |