Posts tagged science

April 24, 2012

Older animals show cellular changes in the brain “clock” that sets sleep and wakeful periods, according to new research in the April 25 issue of The Journal of Neuroscience. The findings may help explain why elderly people often experience trouble sleeping at night and are drowsy during the day.

Like humans, mice experience shifts in daily activities and sleep patterns as they age. To find out why, researchers directed by Johanna Meijer, PhD, at the Leiden University Medical Center in the Netherlands studied the electrical activity of cells in the suprachiasmatic nucleus (SCN), an area of the brain responsible for setting sleep-wake cycles.

Consistent with previous studies, the researchers found aged mice showed disrupted sleep behavior and weakened brain network activity in the SCN. But Meijer and colleagues also found changes occurring in individual SCN cells, not just in their networks.

"In fact, the changes at the single-cell level were more severe than the changes at the network level," said Meijer. This represents a shift in understanding of aging’s effects on the brain.

The researchers made electrophysiological recordings from isolated SCN neurons, a difficult experiment given the advanced age of the animals and the small size of this type of neuron. They found aged SCN neurons lack day-night rhythms in some membrane properties. In addition, the team identified age-related reductions of certain potassium currents that are important to the neurons’ rhythmic firing.

Because potassium and other ion channels can be manipulated with drugs, “This work provides a new target for potential therapeutic interventions that can mitigate the age-related decline in the sleep-wake cycle,” said Christopher Colwell, PhD, an expert in circadian clock function at the University of California, Los Angeles, who was not involved in the study.

Provided by Society for Neuroscience

Source: medicalxpress.com

April 24, 2012

A history of binge eating — consuming large amounts of food in a short period of time — may make an individual more likely to show other addiction-like behaviors, including substance abuse, according to Penn State College of Medicine researchers. In the short term, this finding may shed light on the factors that promote substance abuse, addiction, and relapse. In the long term, may help clinicians treat individuals suffering from this devastating disease.

"Drug addiction persists as a major problem in the United States," said Patricia Sue Grigson, Ph.D., professor, Department of Neural and Behavioral Sciences. "Likewise, excessive food intake, like binge eating, has become problematic. Substance-abuse and binge eating are both characterized by a loss of control over consumption. Given the common characteristics of these two types of disorders, it is not surprising that the co-occurrence of eating disorders and substance abuse disorders is high. It is unknown, however, whether loss of control in one disorder predisposes an individual to loss of control in another."

Grigson and her colleagues found a link between bingeing on fat and the development of cocaine-seeking and -taking behaviors in rats, suggesting that conditions promoting excessive behavior toward one substance can increase the probability of excessive behavior toward another. They report their results in Behavioral Neuroscience.

The researchers used rats to test whether a history of binge eating on fat would augment addiction-like behavior toward cocaine by giving four groups of rats four different diets: normal rat chow; continuous ad lib access to an optional source of dietary fat; one hour of access to optional dietary fat daily; and one hour of access to dietary fat on Mondays, Wednesdays, and Fridays. All four groups also had unrestricted access to nutritionally complete chow and water. The researchers then assessed the cocaine-seeking and -taking behaviors.

"Fat bingeing behaviors developed in the rats with access to dietary fat on Mondays, Wednesdays, and Fridays — the group with the most restricted access to the optional fat," Grigson said. 

This group tended to take more cocaine late in training, continued to try to get cocaine when signaled it was not available, and worked harder for cocaine as work requirements increased.

"While the underlying mechanisms are not known, one point is clear from behavioral data: A history of bingeing on fat changed the brain, physiology, or both in a manner that made these rats more likely to seek and take a drug when tested more than a month later," Grigson said. "We must identify these predisposing neurophysiological changes."

While the consumption of fat in and of itself did not increase the likelihood of subsequent addiction-like behavior for cocaine, the irregular binge-type manner in which the fat was eaten proved critical. Rats that had continuous access to fat consumed more fat than any other group, but were three times less likely to exhibit addiction-like behavior for cocaine than the group with access only on Mondays, Wednesdays and Fridays.

"Indeed, while about 20 percent of those rats and humans exposed to cocaine will develop addiction-like behavior for the drug under normal circumstances, in our study, the probability of addiction to cocaine increased to approximately 50 (percent) for subjects with a history of having binged on fat," Grigson said.

Future studies will look more closely at how bingeing can lead to addiction-like behaviors — whether bingeing on sugar or a mixture of sugar and fat also promotes cocaine or heroin addiction, for example, and whether bingeing on a drug, in turn, increases the likelihood of bingeing on fat.

Provided by Pennsylvania State University

Source: medicalxpress.com

ScienceDaily (Apr. 24, 2012) — Scientists at The Scripps Research Institute have found clinical evidence that the drug gabapentin, currently on the market to treat neuropathic pain and epilepsy, helps people to quit smoking marijuana (cannabis). Unlike traditional addiction treatments, gabapentin targets stress systems in the brain that are activated by drug withdrawal.

In a 12-week trial of 50 treatment-seeking cannabis users, those who took gabapentin used less cannabis, experienced fewer withdrawal symptoms such as sleeplessness, and scored higher on tests of attention, impulse-control, and other cognitive skills, compared to patients who received a placebo. If these results are confirmed by ongoing larger trials, gabapentin could become the first FDA-approved pharmaceutical treatment for cannabis dependence.

"A lot of other drugs have been tested for their ability to decrease cannabis use and withdrawal, but this is the first to show these key effects in a controlled treatment study," said Barbara J. Mason, the Pearson Family Chair and Co-Director of the Pearson Center for Alcoholism and Addiction Research at Scripps Research. "The other nice thing about gabapentin is that it is already widely prescribed, so its safety is less likely to be an issue."

Mason led the new gabapentin study, recently published online ahead of print by the journal Neuropsychopharmacology.

Stress Circuits

Addiction researchers have long known that recreational drugs hook users by disrupting the normal tuning of their brains’ reward and motivation circuitry. But as scientists at Scripps Research and other institutions have shown in animal studies, cannabis withdrawal after prolonged heavy use also leads to the long-term activation of basic stress circuits. “In human cannabis users who try to quit, this stress response is reflected in reports of drug craving, sleep disturbances, anxiety, irritability, and dysphoria, any one of which can motivate a person to return to using, because cannabis will quiet these symptoms,” said Mason.

A 2008 study by Pearson Center Co-Director George Koob and his colleagues found that gabapentin, an FDA-approved anticonvulsant drug that resembles the neurotransmitter GABA, can quiet this withdrawal-related activation in stress circuitry in alcohol-dependent rats. That finding motivated Mason to set up a pilot trial of gabapentin in cannabis-dependent individuals, whose withdrawal syndrome features a similar over-activation of stress circuits.

She and her colleagues recruited cannabis users with local newspaper and web ads headlined: “Smoking too much pot? We want to help you stop.” "We needed only 50 subjects, but we quickly got more than 700 queries from cannabis users who were eager to quit," Mason said. "Some people deny that cannabis can be addictive, but surveys show that between 16 and 25 percent of substance use treatment admissions around the world every year involve people with primary cannabis dependence."

Twice as Many Abstinent from Cannabis Use

The trial was based at Mason’s laboratory at The Scripps Research Institute. Half of the 50 recruits were randomly assigned to take 1,200 mg/day of gabapentin; the rest were given identical-looking placebo capsules. Over 12 weeks, Mason and her colleagues, including a medical team from the nearby Scripps Clinic, monitored the subjects with tests. Using standard behavioral therapy techniques, they also counseled the patients to stay off cannabis.

The subjects’ self-reports and more objective urine tests revealed that gabapentin, compared to placebo, significantly reduced their continuing cannabis use. “Urine metabolite readings indicate about twice as many of the gabapentin subjects had no new cannabis use during the entire study, and, in the last four weeks of the study, all of the gabapentin subjects who completed the study stayed abstinent,” Mason said.

Gabapentin also clearly reduced the reported symptoms of withdrawal such as sleep disturbances, drug cravings, and dysphoria. And even though gabapentin normally is thought of as a brain-quieting drug that can cause sleepiness as a side effect, there was some evidence that it sharpened cognition among the cannabis users. Seven gabapentin and ten placebo patients sat for tests of attention, impulse-control, and other executive functions just before the start of the trial and at week four. While the placebo patients tended to score lower after four weeks of attempted abstinence, the gabapentin patients generally scored higher.

Help Resisting Cravings

Addiction researchers now recognize that one of the effects of repeated drug use is the weakening of executive functions — which can happen through the over-activation of reward circuitry as well as by withdrawal-related stress. “That weakening of self-control-related circuits makes it even harder for people to resist drug cravings when they’re trying to quit, but gabapentin may help restore those circuits, by reducing stress and enabling patients to sleep better, so that they function better while awake,” Mason said.

She is now conducting a larger, confirmatory study of gabapentin in cannabis users, as well as a new study of a novel drug that targets the same stress circuitry.

"People in the treatment community have told me that they’re eager for these trial results to come out, because until now nothing has been shown to work against both relapse and withdrawal symptoms," Mason said.

Source: Science Daily

ScienceDaily (Apr. 24, 2012) — Stanford University School of Medicine neuroscientists have demonstrated, in a study published online April 24 in Stroke, that a compound mimicking a key activity of a hefty, brain-based protein is capable of increasing the generation of new nerve cells, or neurons, in the brains of mice that have had strokes. The mice also exhibited a speedier recovery of their athletic ability.

These results are promising, because the compound wasn’t administered to the animals until a full three days after they had suffered strokes, said the study’s senior author, Marion Buckwalter, MD, PhD, an assistant professor of neurology and neurological sciences. This means that the compound works not by limiting a stroke’s initial damage to the brain, but by enhancing recovery.

This is of critical significance, said Buckwalter, a practicing clinical neurologist who often treats recently arrived stroke patients in Stanford Hospital’s intensive care unit.

"No existing therapeutic agents today enhance recovery from stroke," Buckwalter said. "The only approved stroke drug, tissue plasminogen activator, can bust up clots that initially caused the stroke but does nothing to stimulate the restoration of brain function later." Furthermore, to be effective, tPA has to be given within four and a half hours after a stroke has occurred, she added. "In real life, many people don’t get to the hospital that quickly. They may live alone or have their stroke while sleeping, or they and the people close to them didn’t recognize the stroke’s symptoms well enough to realize they’d just had one."

Looking for an alternative, Buckwalter chose to focus on a compound called LM22A-4, which had shown promise in previous research. LM22A-4 is a small molecule whose bulk is less than one-seventieth that of the brain protein it mimics: brain-derived neurotrophic factor, a powerful and long-studied nerve growth factor. BDNF is critical during the development of the nervous system and known to be involved in important brain functions including memory and learning.

Stem-cell therapy, while an exciting prospect, is a relatively invasive and expensive way to replace lost or damaged tissue. A drug that could achieve similar results in such a delicate and complex organ as the brain would be a welcome development.

Read more …

ScienceDaily (Apr. 24, 2012) — In an important test of one of the first drugs to target core symptoms of autism, researchers at Mount Sinai School of Medicine are undertaking a pilot clinical trial to evaluate insulin-like growth factor (IGF-1) in children who have SHANK3 deficiency (also known as 22q13 Deletion Syndrome or Phelan-McDermid Syndrome), a known cause of autism spectrum disorder (ASD).

This study builds on findings announced by the researchers in 2010, which showed that after two weeks of treatment with IGF-1 in a mouse model, deficits in nerve cell communication were reversed and deficiencies in adaptation of nerve cells to stimulation, a key part of learning and memory, were restored.

"This clinical trial is part of a paradigm shift to develop medications specifically to treat the core symptoms of autism, as opposed to medications that were developed for other purposes but were found to be beneficial for autism patients as well," said Joseph Buxbaum, PhD, Director of the Seaver Autism Center at Mount Sinai. "Our study will evaluate the impact of IGF-1 vs. placebo on autism-specific impairments in socialization and associated symptoms of language and motor disability."

The seven-month study, which begins this month, will be conducted under the leadership of the Seaver Autism Center Clinical Director Alex Kolevzon, MD, and will utilize a double-blind, placebo-controlled crossover design in children ages 5 to 17 years old with SHANK3 deletions or mutations. Patients will receive three months of treatment with active medication or placebo, separated by a four-week washout period. Future trials are planned to explore the utility of IGF-1 in ASD without SHANK3 deficiency.

The primary aim of the study is to target core features of ASD, including social withdrawal and language impairment, which will be measured using both behavioral and objective assessments. If preliminary results are promising, the goal is to expand the studies into larger, multi-centered efforts to include as many children as possible affected by this disorder.

IGF-1 is a US Food and Drug Administration-approved, commercially available compound that is known to promote neuronal cell survival as well as synaptic maturation and plasticity. Side effects of IGF-1 administration include low blood sugar, liver function abnormalities, and increased cholesterol and triglyceride levels. Study subjects will undergo rigorous safety screening before they are enrolled in the trial, and will be carefully monitored every two to four weeks with safety and efficacy assessments.

"We are excited that the researchers at the Seaver Autism Center are undertaking this pilot study to evaluate a possible treatment for SHANK3 deficiency, which may also help everyone with ASD," said Geraldine Bliss, Research Support Chair of the Phelan-McDermid Foundation. "This will be the first clinical trial in Phelan-McDermid Syndrome to emerge from convincing preclinical evidence in a model system."

The cause of autism has been debated for many years. Currently the best scientific evidence indicates that genetic mutations are the most likely culprits, acting either directly or indirectly, in upwards of 80 to 90 percent of individuals with ASDs. In the past few years, gene mutations and gene copy number variations have been identified that cause approximately 15 percent of cases of ASD. However, it is thought that hundreds of genes may be involved in causing autism.

One copy of the q13 portion of chromosome 22 is either missing or otherwise mutated in SHANK3 deficiency, also known as Phelan-McDermid Syndrome or 22q13 Deletion Syndrome (22q13DS). The area in question contains the gene SHANK3, and there is overwhelming evidence that it is the loss of one copy of SHANK3 that produces the neurological and behavioral aspects of the syndrome. The SHANK3 gene is key to the development of the human nervous system, and loss of SHANK3 can impair the ability of neurons to communicate with one another.

Source: Science Daily

ScienceDaily (Apr. 24, 2012) — Chronic fatigue syndrome, a medical disorder characterized by extreme and ongoing fatigue with no other diagnosed cause, remains poorly understood despite decades of scientific study. Although researchers estimate that more than 1 million Americans are affected by this condition, the cause for chronic fatigue syndrome, a definitive way to diagnose it, and even its very existence remain in question. In a new study, researchers have found differing brain responses in people with this condition compared to healthy controls, suggesting an association between a biologic functional response and chronic fatigue syndrome.

The findings show that patients with chronic fatigue syndrome have decreased activation of an area of the brain known as the basal ganglia in response to reward. Additionally, the extent of this lowered activation was associated with each patient’s measured level of fatigue. The basal ganglia are at the base of the brain and are associated with a variety of functions, including motor activity and motivation. Diseases affecting basal ganglia are often associated with fatigue. These results shed more light on this mysterious condition, information that researchers hope may eventually lead to better treatments for chronic fatigue syndrome.

The study was conducted by Elizabeth R. Unger, James F. Jones, and Hao Tian of the Centers for Disease Control and Prevention (CDC), Andrew H. Miller and Daniel F. Drake of Emory University School of Medicine, and Giuseppe Pagnoni of the University of Modena and Reggio Emilia. An abstract of their study entitled, “Decreased Basal Ganglia Activation in Chronic Fatigue Syndrome Subjects is Associated with Increased Fatigue,” will be discussed at the meeting Experimental Biology 2012, being held April 21-25 at the San Diego Convention Center. The abstract is sponsored by the American Society for Investigative Pathology (ASIP), one of six scientific societies sponsoring the conference which last year attracted some 14,000 attendees.

More Fatigue, Less Activation

Dr. Unger says that she and her colleagues became curious about the role of the basal ganglia after previous studies by collaborators at Emory University showed that patients treated with interferon alpha, a common treatment for chronic hepatitis C and several other conditions, often experienced extreme fatigue. Further investigation into this phenomenon showed that basal ganglia activity decreased in patients who received this immune therapy. Since the fatigue induced by interferon alpha shares many characteristics with chronic fatigue syndrome, Unger and her colleagues decided to investigate whether the basal ganglia were also affected in this disorder.

The researchers recruited 18 patients with chronic fatigue syndrome, as well as 41 healthy volunteers with no symptoms of CFS. Each study participant underwent functional magnetic resonance imaging, a brain scan technique that measures activity in various parts of the brain by blood flow, while they played a simple card game meant to stimulate feelings of reward. The participants were each told that they’d win a small amount of money if they correctly guessed whether a preselected card was red or black. After making their choice, they were presented with the card while researchers measured blood flow to the basal ganglia during winning and losing hands.

The researchers showed that patients with chronic fatigue syndrome experienced significantly less change in basal ganglia blood flow between winning and losing than the healthy volunteers. When the researchers looked at scores for the Multidimensional Fatigue Inventory, a survey often used to document fatigue for chronic fatigue syndrome and various other conditions, they also found that the extent of a patient’s fatigue was tightly tied with the change in brain activity between winning and losing. Those with the most fatigue had the smallest change.

Results Suggest Role of Inflammation

Unger notes that the findings add to our understanding of biological factors that may play a role in chronic fatigue syndrome. “Many patients with chronic fatigue syndrome encounter a lot of skepticism about their illness,” she says. “They have difficulty getting their friends, colleagues, coworkers, and even some physicians to understand their illness. These results provide another clue into the biology of chronic fatigue syndrome.”

The study also suggests some areas of further research that could help scientists develop treatments for this condition in the future, she adds. Since the basal ganglia use the chemical dopamine as their major neurotransmitter, dopamine metabolism may play an important role in understanding and changing the course of this illness. Similarly, the difference in basal ganglia activation between the patients and healthy volunteers may be caused by inflammation, a factor now recognized as pivotal in a variety of conditions, ranging from heart disease to cancer.

Estimates from the CDC suggest that annual medical costs associated with chronic fatigue syndrome total about $14 billion in the United States. Annual losses to productivity because of lost work time range between $9 and $37 billion, with costs to individual households ranging between $8,000 and $20,000 per year.

Source: Science Daily

ScienceDaily (Apr. 24, 2012) — Toxic prions in the brain can be detected with self-illuminating polymers. The originators, at Linköping University in Sweden, has now shown that the same molecules can also render the prions harmless, and potentially cure fatal nerve-destroying illnesses.

Linköping researchers and their colleagues at the University Hospital in Zürich tested the luminescent conjugated polymers, or LCPs, on tissue sections from the brains of mice that had been infected with prions. The results show that the number of prions, as well as their toxicity and infectibility, decreased drastically. This is the first time anyone has been able to demonstrate the possibility of treating illnesses such as mad cow disease and Creutzfeldt-Jacobs with LCP molecules.

"When we see this effect on prion infections, we believe the same approach could work on Alzheimer’s disease as well," says Peter Nilsson, researcher in Bioorganic Chemistry funded by ERC, the European Research Council.

Along with professors Per Hammarström and Adriano Aguzzi and others, he is now publishing the results in The Journal of Biological Chemistry.

Prions are diseased forms of normally occurring proteins in the brain. When they clump together in large aggregates, nerve cells in the surrounding area are affected, which leads to serious brain damage and a quick death. Prion illnesses can be inherited, occur spontaneously or through infection, for example through infected meat — as was the case with mad cow disease.

The course of the illness is relentless when the prions fall to pieces and replicate at an exponential rate. When researchers inserted the LCP molecules into their model system, the replication was arrested, possible through stabilizing the prion aggregates.

The variable components in an LCP are various chemical subgroups attached onto the polymer. In the published study, eight different substances were tested, and all of them had significant effect on the toxicity of the prions.

"Based on these results, we can now customise entirely new molecules with potentially even better effect. These are now being tested on animal models," Nilsson says.

Researchers want to go even further and test whether the molecules will function on fruit flies with an Alzheimer’s-like nerve disorder. Alzheimer’s is caused by what is known as amyloid plaque, which has a similar but slower course than prion diseases.

Source: Science Daily

April 23rd, 2012

A team of scientists from Johns Hopkins and elsewhere have developed nano-devices that successfully cross the brain-blood barrier and deliver a drug that tames brain-damaging inflammation in rabbits with cerebral palsy.

Schematic picture of a dendrimer with multiple branches that are tagged with drug molecules and imaging agents. Image adapted from press release image from Johns Hopkins.

A report on the experiments, conducted at Wayne State University in collaboration with the Perinatology Research Branch of the National Institute of Child Health and Human Development, before the lead and senior investigators moved to Johns Hopkins, is published in the April 18 issue of Science Translational Medicine.

For the study, researchers used tiny, manmade molecules laced with N-acetyl-L-cysteine (NAC), an anti-inflammatory drug used as antidote in acetaminophen poisoning. The researchers precision-targeted brain cells gone awry to halt brain injury. In doing so they improved the animals’ neurologic function and motor skills.

The new approach holds therapeutic potential for a wide variety of neurologic disorders in humans that stem from neuro-inflammation, including Alzheimer’s disease, stroke, autism and multiple sclerosis, the investigators say.

The scientists caution that the findings are a long way from human application, but that the simplicity and versatility of the drug-delivery system make it an ideal candidate for translation into clinical use.

“In crossing the blood-brain barrier and targeting the cells responsible for inflammation and brain injury, we believe we may have opened the door to new therapies for a wide-variety of neurologic disorders that stem from an inflammatory response gone haywire,” says lead investigator Sujatha Kannan, M.D., now a pediatric critical-care specialist at Johns Hopkins Children’s Center.

Cerebral palsy (CP), estimated to occur in three out of 1,000 newborns, is a lifelong, often devastating disorder caused by infection or reduced oxygen to the brain before, during or immediately after birth. Current therapies focus on assuaging symptoms and improving quality of life, but can neither reduce nor reverse neurologic damage and loss of motor function.

Neuro-inflammatory damage occurs when two types of brain cells called microglia and astrocytes — normally deployed to protect the brain during infection and inflammation — actually damage it by going into overdrive and destroying healthy brain cells along with damaged ones.

Directly treating cells in the brain has long proven difficult because of the biological and physiological systems that have evolved to protect the brain from blood-borne infections. The quest to deliver the drug to the brain also involved developing a technique to get past the brain-blood barrier, spare healthy brain cells and deliver the anti-inflammatory drug exclusively inside the rogue cells.

To do all this, the scientists used a globular, tree-like synthetic molecule, known as a dendrimer. Its size — 2,000 times smaller than a red blood cell — renders it fit for travel across the blood-brain barrier. Moreover, the dendrimer’s tree-like structure allowed scientists to attach to it molecules of an anti-inflammatory NAC. The researchers tagged the drug-laced dendrimers with fluorescent tracers to monitor their journey to the brain and injected them into rabbits with cerebral palsy six hours after birth. Another group of newborn rabbits received an injection of NAC only.

Not only did the drug-loaded dendrimers make their way inside the brain but, once there, were rapidly swallowed by the overactive astrocytes and microglia.

“These rampant inflammatory cells, in effect, gobbled up their own poison,” Kannan says.

“The dendrimers not only successfully crossed the blood-brain barrier but, perhaps more importantly, zeroed in on the very cells responsible for neuro-inflammation, releasing the therapeutic drug directly into them,” says senior investigator Rangaramanujam Kannan, Ph.D., of the Center for Nanomedicine at the Johns Hopkins Wilmer Eye Institute.

Animals treated with dendrimer-borne NAC showed marked improvement in motor control and coordination within five days after birth, nearly reaching the motor skill of healthy rabbits. By comparison, rabbits treated with dendrimer-free NAC showed minimal, if any, improvement, even at doses 10 times higher than the dendrimer-borne version. Animals treated with the dendrimer-delivered drug also showed better muscle tone and less stiffness in the hind leg muscles, both hallmarks of CP.

Brain tissue analysis revealed that rabbits treated with dendrimer-borne NAC had notably fewer “bad” microglia — the inflammatory cells responsible for brain damage — as well as markedly lower levels of other inflammation markers. They also had better preserved myelin, the protein that sheaths nerves and is stripped or damaged in CP and other neurologic disorders. And even though CP is marked by neuron death in certain brain centers, animals who received dendrimer-borne NAC had higher number of neurons in the brain regions responsible for coordination and motor control, compared with untreated animals and those treated with NAC only.

The findings suggest that the treatment not only reduces inflammation in the cells, but may also prevent cell damage and cell death, the researchers said. The Kannans, who are married, say they plan to follow some treated animals into adulthood to ensure the improvements are not temporary.

Source: Neuroscience News

April 23, 2012

St. Jude Children’s Research Hospital scientists have rewritten the job description of the protein TopBP1 after demonstrating that it guards early brain cells from DNA damage. Such damage might foreshadow later problems, including cancer.

Researchers showed that cells in the developing brain require TopBP1 to prevent DNA strands from breaking as the molecule is copied prior to cell division. Investigators also reported that stem cells and immature cells known as progenitor cells involved at the beginning of brain development are more sensitive to unrepaired DNA damage than progenitor cells later in the process. Although more developmentally advanced than stem cells, progenitor cells retain the ability to become one of a variety of more specialized neurons.

"Such DNA strand breaks have great potential for creating mutations that push a normal cell toward malignancy," said Peter McKinnon, Ph.D., a St. Jude Department of Genetics member and the paper’s senior author. "When we selectively knocked out TopBP1 in mice, the amount of DNA damage we saw suggests that TopBP1 is likely to be a tumor suppressor. We are exploring that question now."

The work appeared in the April 22 online edition of the scientific journal Nature Neuroscience. The research builds on McKinnon’s interest in DNA repair systems, including the enzymes ATM and ATR, which are associated with a devastating cancer-prone neurodegenerative disease in children called ataxia telangiectasia, and a neurodevelopmental disorder called Seckel syndrome.

TopBP1 was known to activate ATR. Previous laboratory research by other investigators also suggested that activation made TopBP1 indispensable for DNA replication and cell proliferation. This study, however, showed that was not the case. Most progenitor cells in the embryonic mouse brain kept dividing after investigators switched off the TopBP1 gene. 

Read more …

April 23, 2012

A cellular protein called HDAC6, newly characterized as a gatekeeper of steroid biology in the brain, may provide a novel target for treating and preventing stress-linked disorders, such as depression and post-traumatic stress disorder (PTSD), according to research from the Perelman School of Medicine at the University of Pennsylvania.

Glucocorticoids are natural steroids secreted by the body during stress. A small amount of these hormones helps with normal brain function, but their excess is a precipitating factor for stress-related disorders.

Glucocorticoids exert their effects on mood by acting on receptors in the nucleus of emotion–regulating neurons, such as those producing the neurotransmitter serotonin. For years, researchers have searched for ways to prevent deleterious effects of stress by blocking glucocorticoids in neurons. However, this has proved difficult to do without simultaneously interfering with other functions of these hormones, such as the regulation of immune function and energy metabolism.

In a recent Journal of Neuroscience paper, the lab of Olivier Berton, PhD, assistant professor of Psychiatry, shows how a regulator of glucocorticoid receptors may provide a path towards resilience to stress by modulating glucocorticoid signaling in the brain. The protein HDAC6, which is particularly enriched in serotonin pathways, as well as in other mood-regulatory regions in both mice and humans, is ideally distributed in the brain to mediate the effect of glucocorticoids on mood and emotions. HDAC6 likely does this by controlling the interactions between glucocorticoid receptors and hormones in these serotonin circuits.

Experiments that first alerted Berton and colleagues to a peculiar role of HDAC6 in stress adaptation came from an approach that reproduces certain clinical features of traumatic stress and depression in mice. The animals are exposed to brief bouts of aggression from trained “bully” mice. In most aggression-exposed mice this experience leads to the development of a lasting form of social aversion that can be treated by chronic administration of antidepressants. 

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