No sedative necessary: Scientists discover new “sleep node” in the brain

A sleep-promoting circuit located deep in the primitive brainstem has revealed how we fall into deep sleep. Discovered by researchers at Harvard School of Medicine and the University at Buffalo School of Medicine and Biomedical Sciences, this is only the second “sleep node” identified in the mammalian brain whose activity appears to be both necessary and sufficient to produce deep sleep.

Published online in August in Nature Neuroscience, the study demonstrates that fully half of all of the brain’s sleep-promoting activity originates from the parafacial zone (PZ) in the brainstem. The brainstem is a primordial part of the brain that regulates basic functions necessary for survival, such as breathing, blood pressure, heart rate and body temperature.

“The close association of a sleep center with other regions that are critical for life highlights the evolutionary importance of sleep in the brain,” says Caroline E. Bass, assistant professor of Pharmacology and Toxicology in the UB School of Medicine and Biomedical Sciences and a co-author on the paper.

The researchers found that a specific type of neuron in the PZ that makes the neurotransmitter gamma-aminobutyric acid (GABA) is responsible for deep sleep. They used a set of innovative tools to precisely control these neurons remotely, in essence giving them the ability to turn the neurons on and off at will.

 “These new molecular approaches allow unprecedented control over brain function at the cellular level,” says Christelle Ancelet, postdoctoral fellow at Harvard School of Medicine. “Before these tools were developed, we often used ‘electrical stimulation’ to activate a region, but the problem is that doing so stimulates everything the electrode touches and even surrounding areas it didn’t. It was a sledgehammer approach, when what we needed was a scalpel.”

“To get the precision required for these experiments, we introduced a virus into the PZ that expressed a ‘designer’ receptor on GABA neurons only but didn’t otherwise alter brain function,” explains Patrick Fuller, assistant professor at Harvard and senior author on the paper. “When we turned on the GABA neurons in the PZ, the animals quickly fell into a deep sleep without the use of sedatives or sleep aids.”

How these neurons interact in the brain with other sleep and wake-promoting brain regions still need to be studied, the researchers say, but eventually these findings may translate into new medications for treating sleep disorders, including insomnia, and the development of better and safer anesthetics.

“We are at a truly transformative point in neuroscience,” says Bass, “where the use of designer genes gives us unprecedented ability to control the brain. We can now answer fundamental questions of brain function, which have traditionally been beyond our reach, including the ‘why’ of sleep, one of the more enduring mysteries in the neurosciences.”

Scientists Link Alcohol-Dependence Gene to Neurotransmitter

Scientists at The Scripps Research Institute (TSRI) have solved the mystery of why a specific signaling pathway can be associated with alcohol dependence.

This signaling pathway is regulated by a gene, called neurofibromatosis type 1 (Nf1), which TSRI scientists found is linked with excessive drinking in mice. The new research shows Nf1 regulates gamma-aminobutyric acid (GABA), a neurotransmitter that lowers anxiety and increases feelings of relaxation.

“This novel and seminal study provides insights into the cellular mechanisms of alcohol dependence,” said TSRI Associate Professor Marisa Roberto, a co-author of the paper. “Importantly, the study also offers a correlation between rodent and human data.”

In addition to showing that Nf1 is key to the regulation of the GABA, the research, which was published recently in the journal Biological Psychiatry, shows that variations in the human version of the Nf1 gene are linked to alcohol-dependence risk and severity in patients.

Pietro Paolo Sanna, associate professor at TSRI and the study’s corresponding author, was optimistic about the long-term clinical implications of the work. “A better understanding of the molecular processes involved in the transition to alcohol dependence will foster novel strategies for prevention and therapy,” he said.

A Genetic Culprit

Researchers have long sought a gene or genes that might be responsible for risk and severity of alcohol dependence. “Despite a significant genetic contribution to alcohol dependence, few risk genes have been identified to date, and their mechanisms of action are generally poorly understood,” said TSRI Staff Scientist Vez Repunte-Canonigo, co-first author of the paper with TSRI Research Associate Melissa Herman.

This research showed that Nf1 is one of those rare risk genes, but the TSRI researchers weren’t sure exactly how Nf1 affected the brain. The TSRI research team suspected that Nf1 might be relevant to alcohol-related GABA activity in an area of the brain called the central amygdala, which is important in decision-making and stress- and addiction-related processes.

“As GABA release in the central amygdala has been shown to be critical in the transition from recreational drinking to alcohol dependence, we thought that Nf1 regulation of GABA release might be relevant to alcohol consumption,” said Herman.

The team tested several behavioral models, including a model in which mice escalate alcohol drinking after repeated withdrawal periods, to study the effects of partially deleting Nf1. In this experiment, which simulated the transition to excessive drinking that is associated with alcohol dependence in humans, they found that mice with functional Nf1 genes steadily increased their ethanol intake starting after just one episode of withdrawal. Conversely, mice with a partially deleted Nf1 gene showed no increase in alcohol consumption.

Investigating further, the researchers found that in mice with partially deleted Nf1 genes, alcohol consumption did not further increase GABA release in the central amygdala. In contrast, in mice with functional Nf1 genes, alcohol consumption resulted in an increase in central amygdala GABA.

In the second part of the study, a collaboration with a distinguished group of geneticists at various U.S. institutions, the team analyzed data on human variations of the Nf1 gene from about 9,000 people. The results showed an association between the gene and alcohol-dependence risk and severity.

The team sees the new findings as “pieces to the puzzle.” Sanna believes future research should focus on exactly how Nf1 regulates the GABA system and how gene expression may be altered during early development.

Discovery of New Drug Targets for Memory Impairment in Alzheimer’s Disease

We are now a step closer to having a drug that can cure dementia and memory loss. Research team in Korea has discovered that reactive astrocytes, which have been commonly observed in Alzheimer’s patients, aberrantly and abundantly produce the chief inhibitory neurotransmitter GABA and release it through the Best1 channel. The released GABA strongly inhibits neighboring neurons to cause impairment in synaptic transmission, plasticity and memory. This discovery will open a new chapter in the development of new drugs for treating such diseases.

Alzheimer’s disease, which is the most common cause of dementia, is fatal and currently, there is no cure. In Alzheimer’s disease, brain cells are damaged and destroyed, leading to devastating memory loss. It is reported that 1 in 8 Americans aged 65 or over have Alzheimer’s disease. In 2011, 7,600 elderly people with dementia lost their way back home and became homeless in Korea. However, to date, there has been no clear understanding of the mechanisms underlying dementia in Alzheimer’s disease. So far, neuronal death is the only proposed mechanism available in scientific literature.

The research team discovered that reactive astrocytes in the brains of Alzheimer’s disease model mice produce the inhibitory transmitter GABA by the enzyme Monoamine oxidase B(MAO-B) and release GABA through the Bestrophin-1 channel to suppress normal information flow during synaptic transmission. Based on this discovery, the team was able to reduce the production and release of GABA by inhibiting MAO-B or Bestrophin-1, and successfully ameliorate impairments in neuronal firing, synaptic transmission and memory in Alzheimer’s disease model mice.

In the behavioral test, the team used the fact that mice tend to prefer dark places. If a mouse experiences an electric shock in a dark place, it will remember this event and avoid dark places from then on. However, a mouse with modeled Alzheimer’s disease cannot remember if such shock is related to dark places and keeps going back to dark places. The team demonstrated that treating these mice with a MAO-B inhibitor fully recovered the mice’s memory. The selegiline is currently used in Parkinson’s disease as an adjunct therapy and considered as a one of best promising medicine for MAO-B inhibitor. But it has been previously shown to be less effective in Alzheimer’s disease.

The team proved that selegiline is effective for a short time, but when it is used in long term, it loses its efficacy in Alzheimer’s disease model mice. When treated for 1 week, selegiline brought the neuronal firing to a normal level. But when it was treated for 2 and 4 weeks, neuronal firing came back to the levels of untreated mice. From these results, the team proposed that there is a pressing need for a new drug that has long lasting effects.

Dr. C. Justin Lee said, “From this study, we reveal the novel mechanism of how Alzheimer’s patients might lose their memory. We also propose new therapeutic targets, which include GABA production and release mechanisms in reactive astrocytes for treatment of Alzheimer’s disease. Furthermore, we provide a stepping stone for the development of MAO-B inhibitors with long lasting efficacy.”

GABA actions and ionic plasticity in epilepsy

Concepts of epilepsy, based on a simple change in neuronal excitation/inhibition balance, have subsided in face of recent insights into the large diversity and context-dependence of signaling mechanisms at the molecular, cellular and neuronal network level. GABAergic transmission exerts both seizure-suppressing and seizure-promoting actions. These two roles are prone to short-term and long-term alterations, evident both during epileptogenesis and during individual epileptiform events. The driving force of GABAergic currents is controlled by ion-regulatory molecules such as the neuronal K-Cl cotransporter KCC2 and cytosolic carbonic anhydrases. Accumulating evidence suggests that neuronal ion regulation is highly plastic, thereby contributing to the multiple roles ascribed to GABAergic signaling during epileptogenesis and epilepsy.

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Rescue of Alzheimer’s Memory Deficit Achieved by Reducing ‘Excessive Inhibition’

A new drug target to fight Alzheimer’s disease has been discovered by a research team led by Gong Chen, a Professor of Biology and the Verne M. Willaman Chair in Life Sciences at Penn State University. The discovery also has potential for development as a novel diagnostic tool for Alzheimer’s disease, which is the most common form of dementia and one for which no cure has yet been found. A scientific paper describing the discovery will be published in Nature Communications on 13 June 2014. 

Chen’s research was motivated by the recent failure in clinical trials of once-promising Alzheimer’s drugs being developed by large pharmaceutical companies. “Billions of dollars were invested in years of research leading up to the clinical trials of those Alzheimer’s drugs, but they failed the test after they unexpectedly worsened the patients’ symptoms,” Chen said. The research behind those drugs had targeted the long-recognized feature of Alzheimer’s brains: the sticky buildup of the amyloid protein known as plaques, which can cause neurons in the brain to die. “The research of our lab and others now has focused on finding new drug targets and on developing new approaches for diagnosing and treating Alzheimer’s disease,” Chen explained.

"We recently discovered an abnormally high concentration of one inhibitory neurotransmitter in the brains of deceased Alzheimer’s patients," Chen said. He and his research team found the neurotransmitter, called GABA (gamma-aminobutyric acid), in deformed cells called "reactive astrocytes" in a structure in the core of the brain called the dentate gyrus. This structure is the gateway to hippocampus, an area of the brain that is critical for learning and memory.  

Chen’s team found that the GABA neurotransmitter was drastically increased in the deformed versions of the normally large, star-shaped “astrocyte” cells which, in a healthy individual, surround and support individual neurons in the brain. “Our research shows that the excessively high concentration of the GABA neurotransmitter in these reactive astrocytes is a novel biomarker that we hope can be targeted in further research as a tool for the diagnosis and treatment of Alzheimer’s disease,” Chen said. 

Chen’s team developed new analysis methods to evaluate neurotransmitter concentrations in the brains of normal and genetically modified mouse models for Alzheimer’s disease (AD mice). “Our studies of AD mice showed that the high concentration of the GABA neurotransmitter in the reactive astrocytes of the dentate gyrus correlates with the animals’ poor performance on tests of learning and memory,” Chen said. His lab also found that the high concentration of the GABA neurotransmitter in the reactive astrocytes is released through an astrocyte-specific GABA transporter, a novel drug target found in this study, to enhance GABA inhibition in the dentate gyrus. With too much inhibitory GABA neurotransmitter, the neurons in the dentate gyrus are not fired up like they normally would be when a healthy person is learning something new or remembering something already learned.

Importantly, Chen said, “After we inhibited the astrocytic GABA transporter to reduce GABA inhibition in the brains of the AD mice, we found that they showed better memory capability than the control AD mice. We are very excited and encouraged by this result because it might explain why previous clinical trials failed by targeting amyloid plaques alone. One possible explanation is that while amyloid plaques may be reduced by targeting amyloid proteins, the other downstream alterations triggered by amyloid deposits, such as the excessive GABA inhibition discovered in our study, cannot be corrected by targeting amyloid proteins alone. Our studies suggest that reducing the excessive GABA inhibition to the neurons in the brain’s dentate gyrus may lead to a novel therapy for Alzheimer’s disease. An ultimate successful therapy may be a cocktail of compounds acting on several drug targets simultaneously.”

Mice with ‘mohawks’ help scientists link autism to 2 biological pathways in brain

"Aha" moments are rare in medical research, scientists say. As rare, they add, as finding mice with Mohawk-like hairstyles.

But both events happened in a lab at NYU Langone Medical Center, months after an international team of neuroscientists bred hundreds of mice with a suspect genetic mutation tied to autism spectrum disorders.

Almost all the grown mice, the NYU Langone team observed, had sideways,”overgroomed” hair with a highly stylized center hairline between their ears and hardly a tuft elsewhere. Mice typically groom each other’s hair.

Researchers say they knew instantly they were on to something, as the telltale overgrooming — a repetitive motor behavior — had been linked in other experiments in mice to the brain condition that prevents children from developing normal social, behavioral, cognitive, and motor skills. People with autism, the researchers point out, exhibit noticeably dysfunctional behaviors, such as withdrawal, and stereotypical, repetitive movements, including constant hand-flapping, or rocking.

Now and for what NYU Langone researchers believe to be the first time, an autistic motor behavior has been traced to specific biological pathways that are genetically determined.

The findings, says senior study investigator Gordon Fishell, PhD, the Julius Raynes Professor of Neuroscience and Physiology at NYU Langone, could with additional testing in humans lead to new treatments for some autism, assuming the pathways’ effects as seen in mice are reversible.

In the study, to be published in the journal Nature online May 25, researchers knocked out production in mice of a protein called Cntnap4. This protein had been found in earlier studies in specialized brain cells, known as interneurons, in people with a history of autism.

Researchers found that knocking out Cntnap4 affected two highly specialized chemical messengers in the brain, GABA and dopamine. Both are so-called neurotransmitters, chemical signals released from one nerve cell to the next to stimulate similar sensations throughout the body. GABA, short for gamma-aminobutyric acid, is the main inhibitory neurotransmitter in the brain. It not only helps control brain impulses, but also helps regulate muscle tone. Dopamine is a well-known hormonal stimulant, highly touted for producing soothing, pleasing sensations.

Among the researchers’ key findings was that in Mohawk-coiffed mice, reduced Cntnap4 production led to depressed GABA signaling and overstimulation with dopamine. Researchers say the lost protein had opposite effects on the neurotransmitters because GABA is fast acting and quickly released, so interfering with its action decreases signaling, while dopamine’s signaling is longer-acting, so impairing its action increases its release.

"Our study tells us that to design better tools for treating a disease like autism, you have to get to the underlying genetic roots of its dysfunctional behaviors, whether it is overgrooming in mice or repetitive motor behaviors in humans," says Dr. Fishell. "There have been many candidate genes implicated in contributing to autism, but animal and human studies to identify their action have so far not led to any therapies. Our research suggests that reversing the disease’s effects in signaling pathways like GABA and dopamine are potential treatment options."

The U.S. Centers for Disease Control and Prevention estimate that one in 68 American children under age 8 has some form of autism, with five times as many boys as girls suffering from the spectrum of disorders.

As part of their study, researchers performed dozens of genetic, behavioral, and neural tests with growing mice to isolate and pinpoint where Cntnap4 acted in their brains, and how it affected chemical signaling among specific interneuron brain cells, which help relay and filter chemical signals between neurons in localized areas of the brain.

They found that Cntnap4 in mature interneurons strengthened GABA signaling, but did not do so in younger interneurons. When researchers traced where Cntnap4 acted in immature brain cells, Dr. Fishell says tests showed that it stimulated “a big bolus of dopamine.”

As part of testing to confirm the hereditary link among Cntnap4, the two pathways, and grooming behaviors, researchers exposed young mice with normal levels of Cntnap4, who did not groom each other, to mature mice with and without Cntnap4. Only mature mice deficient in Cntnap4 preened the hairstyle on other mice. Further tests in young mice without Cntnap4 showed that other, mature mice with normal amounts of Cntnap4 largely let them be, without any particular grooming or hairstyle.

Dr. Fishell and his team plan further analyses of how GABA and dopamine production changes as brain cells mature, and precisely what cellular mechanisms are involved in autism. Their goal is to control and rebalance any biological systems that go awry, as a possible future therapy for the disease.

Sleep Researchers at SRI International Identify Promising New Treatment for Narcolepsy

Neuroscientists at SRI International have found that a form of baclofen, a drug used to treat muscle spasticity, works better at treating narcolepsy than the best drug currently available when tested in mice.

According to the National Institute of Neurological Disorders and Stroke (NINDS), narcolepsy, a chronic neurologic disorder characterized by excessive daytime sleepiness, is not a rare condition, but is under-recognized and under-diagnosed. It is estimated to impact 1 in 2,000 people worldwide.

In back-to-back papers published in the May 7 issue of The Journal of Neuroscience, Thomas Kilduff, Ph.D., who directs the Center for Neuroscience within SRI Biosciences, Sarah Wurts Black, Ph.D., a research scientist in the Center for Neuroscience, and colleagues present a mouse model of narcolepsy that mimics the human disorder better than other models currently in use. Kilduff, Black and the SRI team then used the new narcolepsy model alongside a standard model to investigate a novel therapeutic pathway and to identify a promising way of treating narcolepsy.

"Our work is an example of how basic research can lead to a potential new therapy for a disease," said Kilduff. His team found that a form of baclofen, R-baclofen, works in both mouse models much better than the leading FDA-approved therapeutic for narcolepsy. (Baclofen, which has been available for more than 50 years, is a chemical compound that exists as a mixture of two isomers, designated R and S.)  "The next step would be to perform a study in narcoleptic patients to determine its potential for treatment of human narcolepsy."

In humans, narcolepsy onset is typically during adolescence or later, but diagnosis may take more than a decade, making it difficult to study the progression of the disease. The lack of definitive mechanisms to explain what goes awry in the brain’s ability to regulate sleep-wake cycles has consequently yielded drugs that only address the symptoms, rather than the underlying causes, of narcolepsy.

In the first of the two papers, “Conditional Ablation of Orexin/Hypocretin Neurons: A New Mouse Model for the Study of Narcolepsy and Orexin System Function,” Kilduff and Black teamed with colleagues at five institutions in Japan to generate a model of narcolepsy that better mimics the human disorder. The existing model, called “Ataxin mice,” has been available for over 10 years. Although Ataxin mice have enabled researchers to study narcolepsy, an important limitation is that these mice are born with the deficiency of the neurotransmitter hypocretin that has been implicated in causing narcolepsy, whereas the onset of human narcolepsy typically occurs after puberty.

"The mouse model developed by Dr. Kilduff and his colleagues offers a new approach to study narcolepsy and to explore potential therapies for this devastating sleep disorder. This new model allows more precise control of the timing and extent of hypocretin/orexin neuron loss, and thus may better mimic human narcolepsy," said Janet He, Ph.D., program director at the National Institute of Neurological Disorders and Stroke (NINDS), part of the National Institutes of Health.

In collaboration with Professor Akihiro Yamanaka of Nagoya University in Japan, formerly an SRI International Fellow in Dr. Kilduff’s laboratory, the research team genetically engineered a mouse in which the hypocretin neurons could be selectively eliminated at any age simply by removal of an antibiotic in the mouse food. In the new “DTA” model, degeneration of hypocretin neurons can be initiated after puberty, causing the mice to exhibit the two major symptoms of narcolepsy: excessive daytime sleepiness and cataplexy, the brief loss of muscle tone experienced by most narcoleptics.

In the second paper, “GABA_B Agonism Promotes Sleep and Reduces Cataplexy in Murine Narcolepsy,” Black, Kilduff and colleagues used the new DTA model and the Ataxin model to compare R-baclofen against gamma-hydroxybutyrate (GHB).  Sodium oxybate, the sodium salt of GHB, was approved by the FDA in 2002 as the only therapeutic for narcolepsy that simultaneously alleviates cataplexy, excessive daytime sleepiness and nocturnal sleep disruption. However, it remains unclear how this drug exerts its beneficial effects.

It was suspected that GHB works by affecting brain cells that respond to a neurotransmitter known as gamma-aminobutyric acid (GABA), which primarily functions to inhibit excitability and regulate muscle tone. To study the mechanism of action of GHB, SRI Biosciences’ researchers tested R-baclofen, which blocks the GABA receptors suspected to be the target of GHB.

The research team found that R-baclofen promoted sleep time and longer bouts of wakefulness during the appropriate times for mice and also suppressed cataplexy. GHB modestly reduced cataplexy and increased sleep intensity, but did not improve other symptoms of narcolepsy to the extent that R-baclofen did. “The improvement in wakefulness that we observed after R-baclofen was a particularly unexpected and important finding,” said Black.

"R-Baclofen works better than GHB in these two mouse models, but it remains to be determined whether it will work better in humans," cautioned Kilduff. "Although baclofen is already known to be safe for use in humans, the dose that is effective for spasticity may be different than the dose of R-baclofen that has the potential to treat narcolepsy."

Eavesdropping on brain cell chatter

Everything we do — all of our movements, thoughts and feelings – are the result of neurons talking with one another, and recent studies have suggested that some of the conversations might not be all that private. Brain cells known as astrocytes may be listening in on, or even participating in, some of those discussions. But a new mouse study suggests that astrocytes might only be tuning in part of the time — specifically, when the neurons get really excited about something. This research, published in Neuron, was supported by the National Institute of Neurological Disorders and Stroke (NINDS), part of the National Institutes of Health.

For a long time, researchers thought that the star-shaped astrocytes (the name comes from the Greek word for star) were simply support cells for the neurons.

It turns out that these cells have a number of important jobs, including providing nutrients and signaling molecules to neurons, regulating blood flow, and removing brain chemicals called neurotransmitters from the synapse. The synapse is the point of information transfer between two neurons. At this connection point, neurotransmitters are released from one neuron to affect the electrical properties of the other. Long arms of astrocytes are located next to synapses, where they can keep tabs on the conversations going on between neurons.

In recent years, it has been shown that astrocytes may also play a role in neuronal communication. When neurons release neurotransmitters, levels of calcium change within astrocytes. Calcium is critical for many processes, including release of molecules from the cell, and activation of a host of proteins within the cell. The role of this astrocytic calcium signaling for brain function remains a mystery.

In this study, Baljit S. Khakh, Ph.D., of the University of California, Los Angeles and his colleagues wanted to know when astrocytes responded to neuron activity with changes in their internal calcium levels. Using calcium indicator dyes, the researchers were able to image, for the first time, changes in calcium levels in the entire astrocyte. Previously, it was only possible to look at certain areas of the cell at one time, which provided an incomplete picture of what was happening.

Dr. Khakh said one of the most important outcomes of this work was in the methods that were used. “What our use of these calcium indicators shows is that we can image calcium throughout the entire astrocyte. This provides a new set of tools for the research community to use and to extend these findings,” he said.

“There has been intense interest in understanding how astrocytes facilitate communication between neurons, but it is only recently that studies with this level of precision have been possible,” said Edmund Talley, Ph.D., program director at NINDS. “Dr. Khakh’s study is an example of an exciting basic, or fundamental, research project that could have an important contribution to the shifting field of astrocyte biology,” he added.

For these experiments, researchers focused on the mossy fiber pathway, which connects two areas of the hippocampus, the structure involved in learning and memory. “This pathway has a unique architecture and although it has been very well studied, the role of astrocytes in this circuit has not been previously explored. This study provides one of the first really detailed understandings of astrocytes within this particular circuit,” said Dr. Khakh.

Dr. Khakh’s team activated neurons (getting them to release neurotransmitter by a variety of techniques) and then looked for a response in the neighboring astrocyte. As calcium levels rose, the astrocyte would light up quickly. They discovered that two neurotransmitters, glutamate and GABA, triggered the astrocytes to release calcium from their internal stores. Importantly, the researchers discovered that calcium levels increased through the entire astrocyte only if there was a large burst of neurotransmitter being released.

“We found that astrocytes in the mossy fiber pathway do not listen to the constant, millisecond by millisecond synaptic chatter that neurons engage in. Instead, they listen when neurons get excessively excited during bursts of activation,” said Dr. Khakh.

These findings suggest that astrocytes in the mossy fiber system may act as a switch that reacts to large amounts of neuronal activity by raising their levels of calcium. These calcium increases occur over multiple seconds, a relatively long time period compared to that seen in neurons. The spatial extent of the astrocyte calcium increases was also relatively large in comparison to the size of the synapse.

“Astrocytes may be sitting there quietly and when there is excessive activation in the neuronal circuit, they immediately respond with an increase in calcium which we could detect. And the next big question becomes, what they do with that calcium?” said Dr. Khakh.

Dr. Khakh’s results in the mossy fiber system differ from those others have described in other brain regions. This raises the intriguing possibility that astrocytes are not all the same and may serve various roles throughout the brain.

“It would be really interesting and important to find that astrocytes function differently in different areas of the brain, in a circuit-specific manner. This study gives a hint that this might be true,” said Dr. Talley.