Posts tagged genetic mutations
Articles and news from the latest research reports.
Multiple neurodevelopmental disorders have a common molecular cause
Neurodevelopmental disorders such as Down syndrome and autism-spectrum disorder can have profound, lifelong effects on learning and memory, but relatively little is known about the molecular pathways affected by these diseases. A study published by Cell Press October 9th in the American Journal of Human Genetics shows that neurodevelopmental disorders caused by distinct genetic mutations produce similar molecular effects in cells, suggesting that a one-size-fits-all therapeutic approach could be effective for conditions ranging from seizures to attention-deficit hyperactivity disorder.
"Neurodevelopmental disorders are rare, meaning trying to treat them is not efficient," says senior study author Carl Ernst of McGill University. "Once we fully define the major common pathways involved, targeting these pathways for treatment becomes a viable option that can affect the largest number of people."
A large fraction of neurodevelopmental disorders are associated with variation in specific genes, but the genetic factors responsible for these diseases are very complex. For example, whereas common variants in the same gene have been associated with two or more different disorders, mutations in many different genes can lead to similar diseases. As a result, it has not been clear whether genetic mutations that cause neurodevelopmental disorders affect distinct molecular pathways or converge on similar cellular functions.
To address this question, Ernst and his team used human fetal brain cells to study the molecular effects of reducing the activity of genes that are mutated in two distinct autism-spectrum disorders. Changes in transcription factor 4 (TCF4) cause 18q21 deletion syndrome, which is characterized by intellectual disability and psychiatric problems, and mutations in euchromatic histone methyltransferase 1 (EHMT1) cause similar symptoms in a disease known as 9q34 deletion syndrome.
Interfering with the activity of TCF4 or EHMT1 produced similar molecular effects in the cells. Strikingly, both of these genetic modifications resulted in molecular patterns that resemble those of cells that are differentiating, or converting from immature cells to more specialized cells. “Our study suggests that one fundamental cause of disease is that neural stem cells choose to become full brain cells too early,” Ernst says. “This could affect how they incorporate into cellular networks, for example, leading to the clinical symptoms that we see in kids with these diseases.”
(Image: Wellcome Images)
Visual clue to new Parkinson’s Disease therapies
Dr Chris Elliott, of the Department of Biology, and Dr Alex Wade, of the Department of Psychology, have devised a technique that could both provide an early warning of the disease and result in therapies to mitigate its symptoms.
In research reported in Human Molecular Genetics, they created a more sensitive test which detected neurological changes before degeneration of the nervous system became apparent.
In laboratory tests using fruit flies, the researchers discovered that a human genetic mutation that causes Parkinson’s amplified visual signals in young flies dramatically. This resulted in loss of vision in later life.
Working with researchers from the Danish pharmaceutical company, H.Lundbeck A/S, they tested a new drug that targets the Parkinson’s mutation in flies. This drug prevented the abnormal changes in the flies’ visual function.
It is the first time that the compound has been used in vivo and its effectiveness was analysed using the new, sensitive technique devised by Dr Wade. This was originally used for measuring vision in people with eye disease and epilepsy.
Dr Elliott, who is part-funded by Parkinson’s UK, said: “If this kind of drug proves to be successful in clinical trials, it would have the potential to bring long-lasting relief from PD symptoms and fewer side effects than existing levadopa therapy.”
Dr Wade added: “This technique forms a remarkable bridge between human clinical science and animal research. If it proves successful in the future, it could open the door to a new way of studying a whole range of neurological diseases.”
Senior Vice President, Research at Lundbeck, Kim Andersen, said: “This new research may prove to be groundbreaking in the understanding and treatment of Parkinson’s disease. Science does not currently have answers for what happens in the brain before and during the disease, but these discoveries may bring us closer to this understanding. This may also give us the opportunity to revolutionize the diagnosis and treatment of Parkinson’s disease, for the benefit of patients and their families.”
(Source: york.ac.uk)
New hope for treating ALS
Patient stem cells help identify common problem, leading to clinical trials
Harvard stem cell scientists have discovered that a recently approved medication for epilepsy might be a meaningful treatment for amyotrophic lateral sclerosis (ALS), also known as Lou Gehrig’s disease, a uniformly fatal neurodegenerative disorder. The researchers are now collaborating with Massachusetts General Hospital (MGH) to design an initial clinical trial testing the safety of the treatment in ALS patients.
The investigators all caution that a great deal of work needs to be done to assure the safety and efficacy of the treatment in ALS patients before physicians should start offering it.
The work, laid out in two related advance online publications in April by Cell Stem Cell and Cell Reports, is the long-term fruit of studies by Harvard Stem Cell Institute (HSCI) principal faculty member Kevin Eggan, who in a 2008 Science paper first raised the possibility of using ALS patient-derived stem cells to better understand the disease and identify therapeutic targets for new drugs.
Scientists find potential target for treating mitochondrial disorders
Mitochondria, long known as “cellular power plants” for their generation of the key energy source adenosine triphosphate (ATP), are essential for proper cellular functions. Mitochondrial defects are often observed in a variety of diseases, including cancer, Alzheimer’s disease, and Parkinson’s disease, and are the hallmarks of a number of genetic mitochondrial disorders whose manifestations range from muscle weakness to organ failure. Despite a fairly strong understanding of the pathology of such genetic mitochondrial disorders, efforts to treat them have been largely ineffective.
But now, graduate student Walter Chen and postdoctoral researcher Kivanc Birsoy, both part of Whitehead Institute Member David Sabatini’s lab, have unraveled how to rescue cells suffering from mitochondrial dysfunction, a finding that may lead to new therapies for this condition.
To find genetic mutations that would rescue the cells, Chen and Birsoy mimicked mitochondrial dysfunction in a haploid genetic system developed by former Whitehead Fellow Thijn Brummelkamp. After suppressing mitochondrial function using the drug antimycin, Chen and Birsoy saw that cells with mutations inactivating the gene ATPIF1 were protected against loss of mitochondrial function.
The protein ATPIF1 is part of a backup system to save starving cells. When cells are deprived of oxygen and sugars, a mitochondrial complex that usually produces ATP, called ATP synthase, switches to consuming it, a state that can be harmful to an already starving cell. ATPIF1 interacts with ATP synthase to shut it down and prevent it from consuming the mitochondrion’s dwindling ATP supply but, in the process, also worsens the mitochondrion’s membrane potential.
“In these diseases of mitochondrial dysfunction, in a sense, it’s a false starvation situation for the cell—there are plenty of nutrients, but because there’s a block in the mitochondria’s normal function, the mitochondria behave as if there’s not enough oxygen,” says Chen, who with Birsoy, authored a paper in the journal Cell Reports describing this work. “So in these situations, activation of ATPIF1 is not good, because there are still many nutrients around to provide ATP. Instead, blocking ATPIF1 is therapeutic because it allows for maintenance of the membrane potential.”
Liver cells are frequently affected in patients with severe mitochondrial disease, so Chen and Birsoy tested the effects of mitochondrial dysfunction in the liver cells of control mice and mice with ATPIF1 genetically knocked out. Again, the liver cells with suppressed ATPIF1 function dealt better with mitochondrial dysfunction than liver cells with normal ATPIF1 activity.
“It’s very simple—if you get rid of ATPIF1, you survive in the presence of mitochondrial dysfunction,” says Birsoy. “From what we see so far, there are no major side effects from blocking ATPIF1 in mice.”
For Chen and Birsoy, the next step in this line of research is to test the effects of ATPIF1 suppression in mouse models of mitochondrial dysfunction. Then they will try to identify therapeutics that effectively block ATPIF1 function.
New genetic mutations shed light on schizophrenia
Researchers from the Broad Institute and several partnering institutions have taken a closer look at the human genome to learn more about the genetic underpinnings of schizophrenia. In two studies published this week in Nature (1, 2), scientists analyzed the exomes, or protein-coding regions, of people with schizophrenia and their healthy counterparts, pinpointing the sites of mutations and identifying patterns that reveal clues about the biology underlying the disorder.
2 genetic wrongs make a biochemical right
In a biological quirk that promises to provide researchers with a new approach for studying and potentially treating Fragile X syndrome, scientists at the University of Massachusetts Medical School (UMMS) have shown that knocking out a gene important for messenger RNA (mRNA) translation in neurons restores memory deficits and reduces behavioral symptoms in a mouse model of a prevalent human neurological disease. These results, published today in Nature Medicine, suggest that the prime cause of the Fragile X syndrome may be a translational imbalance that results in elevated protein production in the brain. Restoration of this balance may be necessary for normal neurological function.
"Biology works in strange ways," said Joel Richter, PhD, professor of molecular medicine at UMMS and senior author on the study. "We corrected one genetic mutation with another, which in effect showed that two wrongs make a right. Mutations in each gene result in impaired brain function, but in our studies, we found that mutations in both genes result in normal brain function. This sounds counter-intuitive, but in this case that seems to be what has happened."
Fragile X syndrome, the most common form of inherited mental retardation and the most frequent single-gene cause of autism, is a genetic condition resulting from a CGG repeat expansion in the DNA sequence of the Fragile X (Fmr1) gene required for normal neurological development. People with Fragile X suffer from intellectual disability as well as behavioral and learning challenges. Depending on the length of the CGG repeat, intellectual disabilities can range from mild to severe.
While scientists have identified the genetic mutation that causes Fragile X, on a molecular level they still don’t know much about how the disease works or what precisely goes wrong in the brain as a result. What is known is that the Fmr1 gene codes for the Fragile X protein (FMRP). This protein probably has several functions throughout the neuron but its main activity is to repress the translation of as many as 1,000 different mRNAs. By doing this, FMRP controls synaptic plasticity and higher brain function. Mice without the Fragile X gene, for instance, have a 15 to 20 percent overall elevation in neural protein production. It is thought that the inability to repress mRNA translation and the resulting increase in neural proteins may somehow hamper normal synaptic function in patients with Fragile X. But because FMRP binds so many mRNAs, and some proteins become more elevated than others, parsing which mRNA or combination of mRNAs is responsible for Fragile X pathology is a daunting task.
From Frog Egg to Fragile X
For years, Dr. Richter had been studying how translation, the process in which cellular ribosomes create proteins, went from dormant to active in frog eggs. He discovered the key gene controlling this process, the RNA binding protein CPEB. In 1998, Richter found the CPEB protein in the rodent brain where it played an important role in regulating how synapses talk to each other. At this point, his work began to move from exploring the role of CPEB in the developmental biology of the frog to how the CPEB protein impacted learning and memory. A serendipitous research symposium with colleagues at Cold Spring Harbor got him thinking about CPEB and Fragile X syndrome.
"Here I was, an outsider, a molecular biologist who had worked for years with frog eggs, in the same room with neurobiologists and neurologists, when they started talking about Fragile X syndrome and translational activity," said Richter. "It got me thinking that the CPEB protein might be a path to restoring the translational imbalance they were discussing."
Richter knew that CPEB stimulated translation and that FMRP repressed it. He also knew that animal models lacking the CPEB protein had memory deficits and that both proteins bound to many of the same mRNAs – the overlap may be as higher as 33 percent. The thought was that by taking away a protein that stimulated translation might counterbalance the loss of the repressor FMRP protein, thereby restoring translational homeostasis in the brain and normal neurological function.
"It was one of those kind of goofy ‘what if’ sort of things," said Richter.
To test his hypothesis, Richter developed a double knockout mouse model that lacked both the FMRP gene that caused Fragile X and the CPEB gene. When they began measuring for Fragile X pathologies what they found was almost too good to be true.
"We measured a host of factors, biochemical, morphological, electrophysiological and behavioral phenotypes," said Richter. "And we kept finding the same thing. By knocking out both the FMRP and CPEB genes we were able to restore levels of protein synthesis to normal and corrected the disease characteristics of the Fragile X mice, making them almost indistinguishable from wild type mice."
Most importantly, tests to evaluate short-term memory in the double knockout mice also showed normal results with no indications of Fragile X pathology. This suggested an experiment to test whether CPEB might be a potential therapeutic target for Fragile X to benefit patients. Richter and colleagues took adult Fragile X mice and injected a lentivirus that expresses a small RNA to knock down CPEB in the hippocampus, which is a brain region that is important for short-term memory. Subsequent tests showed improved short-term memory in these mice, indicating that at least this one characteristic of Fragile X syndrome, which is generally thought to be a developmental disorder, can be reversed in adults.
"People with Fragile X make too much protein," said Richter. "By using CPEB to recalibrate the cellular machinery that makes protein we’ve shown that tamping down this process has a profoundly good impact on mouse models with Fragile X. It may be that a similar approach could be beneficial for kids with this disease."
The next step for Richter and colleagues is to determine which, of the more than 300 mRNAs that both CPEB and FMRP bind to, contribute to Fragile X syndrome and how. They’ll also begin looking at small molecules and other avenues that, like the ablation of the CPEB protein, might be able to slow down the synthesis of protein. “There are several small molecules that we know affect the translational apparatus,” Richter said. “Some cross the blood/brain barrier, some are toxic, and some are not. We’d like to investigate those.”
"This is another, great example of how basic science translates to human disease," said Richter. "If we had started out looking at the human brain, not knowing about the CPEB protein and its role in translational activity, we wouldn’t have had any idea where to start or what to look for. But because we started out in the frog, where things are much easier to see, and because more often than not these processes are conserved, we’ve learned something new and totally unexpected that may have a profound impact on human disease."
(Source: eurekalert.org)
Two genes linked to increased risk for eating disorders
Eating disorders like anorexia nervosa and bulimia often run in families, but identifying specific genes that increase a person’s risk for these complex disorders has proved difficult.
Now scientists from the University of Iowa and University of Texas Southwestern Medical Center have discovered—by studying the genetics of two families severely affected by eating disorders—two gene mutations, one in each family, that are associated with increased risk of developing eating disorders.
Moreover, the new study shows that the two genes interact in the same signaling pathway in the brain, and that the two mutations produce the same biological effect. The findings suggest that this pathway might represent a new target for understanding and potentially treating eating disorders.
"If you’re considering two randomly discovered genes, the chance that they will interact is small. But, what really sealed the deal for us that the association was real was that the mutations have the same effect," says Michael Lutter, UI assistant professor of psychiatry and senior author of the study.
Overall, the study, published Oct. 8 in the Journal of Clinical Investigation, suggests that mutations that decrease the activity of a transcription factor—a protein that turns on the expression of other genes—called estrogen-related receptor alpha (ESRRA) increase the risk of eating disorders.
The challenge of finding genes for complex diseases
Anorexia nervosa and bulimia nervosa are fairly common, especially among women. They affect between 1 and 3 percent of women. They also are among the most lethal of all psychiatric diseases; about 1 in 1,000 women will die from anorexia.
Finding genes associated with complex diseases like eating disorders is challenging. Scientists can analyze the genetics of thousands of people and use statistics to find common, low-risk gene variations, the accumulation of which causes complex disorders from psychiatric conditions like eating disorders to conditions like heart disease or obesity.
On the other end of the spectrum are very rare gene variants, which confer an almost 100 percent risk of getting the disease. To track down these variants, researchers turn to large families that are severely affected by an illness.
Lutter and his colleagues were able to work with two such families to identify the two new genes associated with eating disorders.
"It’s basically a matter of finding out what the people with the disorder share in common that people without the disease don’t have," Lutter explains. "From a theoretical perspective, it’s straightforward. But the difficulty comes in having a large enough group to find these rare genes. You have to have large families to get the statistical power."
In the new study, 20 members from three generations of one family (10 affected individuals and 10 unaffected), and eight members of a second family (six affected and two unaffected) were analyzed.
Two genes, one pathway
The gene discovered in the larger family was ESRRA, a transcription factor that turns on the expression of other genes. The mutation associated with eating disorders decreases ESSRA activity.
The gene found in the second family is a transcriptional repressor called histone deacetylase 4 (HDAC4), which turns off transcription factors, including ESRRA. This mutation is unusual in the sense that it increases the gene’s activity—most mutations decrease or destroy a gene’s activity.
Importantly, the team also found that the two affected proteins interacted with one another; HDAC4 binds to ESRRA and inhibits it.
"The fact that the HDAC4 mutation happens to increase the gene activity and happens to increase its ability to repress the ESSRA protein we found in the other family was just beyond coincidence," Lutter says.
The two genes are already known to be involved in metabolic pathways in muscle and fat tissue. They also are both regulated by exercise.
In the brain, HDAC4 is very important for regulating genes that form connections between neurons. However, there’s almost nothing known about ESRRA in the brain, although it is expressed in many brain regions that are disrupted in anorexia.
Lutter and his colleagues plan to study the role of these genes in mice and in cultured neurons to find out exactly what they are doing in the brain. They will also look for ways to modify the genes’ activity, with the long-term goal of finding small molecules that might be developed into therapies for eating disorders.
They also plan to study patients with eating disorders and see if other genes associated with the ESSRA/HDAC4 brain pathway are affected in humans.
(Source: medicine.uiowa.edu)
Genes Involved in Birth Defects May Also Lead to Mental Illness
Gene mutations that lead to major birth defects may also cause subtle disruptions in the brain that contribute to psychiatric disorders such as schizophrenia, autism, and bipolar disorder, according to new research by UC San Francisco scientists.
Over the past several years, researchers in the laboratory of psychiatrist Benjamin Cheyette, MD, PhD, have shown that mutations in a gene called Dact1 cause cell signaling networks to go awry during embryonic development. Researchers observed that mice with Dact1 mutations were born with a range of severe malformations, including some reminiscent of spina bifida in humans.
This new study was designed to explore whether Dact1 mutations exert more nuanced effects in the brain that may lead to mental illness. In doing so, Cheyette, John Rubenstein, MD, PhD, and colleagues in UCSF’s Nina Ireland Laboratory of Developmental Neurobiology used a genetic technique in adult mice to selectively delete the Dact1 protein only in interneurons, a group of brain cells that regulates activity in the cerebral cortex, including cognitive and sensory processes. Poor function of interneurons has been implicated in a range of psychiatric conditions.
As reported in the June 24 online issue of PLOS ONE, researchers found that the genetically altered interneurons appeared relatively normal and had managed to find their proper position in the brain’s circuitry during development. But the cells had significantly fewer synapses, the sites where communication with neighboring neurons takes place. In additional observations not included in the new paper, the team also noted that the cells’ dendrites – fine extensions that normally form bushy arbors studded with synapses – were poorly developed and sparsely branched.
“When you delete this gene function after initial, early development – just eliminating it in neurons after they’ve formed – they migrate to the right place and their numbers are correct, but their morphology is a little off,” Cheyette said. “And that’s very much in line with the kinds of pathology that people have been able to identify in psychiatric illness.
"Neurological illnesses tend to be focal, with lesions that you can identify or pathology you can see on an imaging study," Cheyette explained. "Psychiatric illnesses? Not so much. The differences are really subtle and hard to see.”
Key Gene’s Role in Development of Human Nervous System
The Dact1 protein is part of a fundamental biological system known as the Wnt (pronounced “wint”) signaling pathway. Interactions among proteins in the Wnt pathway orchestrate many processes essential to life in animals as diverse as fruit flies, mice and humans, including the proper development of the immensely complex human nervous system from a single fertilized egg cell.
One way the Wnt pathway manages this task is by maintaining the “polarity” of cells during development, said Cheyette, “a process of sequestering, increasing the concentration of one set of proteins on one side of the cell and a different set of proteins on the other side of the cell.” Polarity is particularly important as precursor cells transform into nerve cells, Cheyette said, because neurons are “the most polarized cells in the body,” with specialized input and output zones that must wind up in the proper spots if the cells are to function normally.
Cheyette said his group is now conducting behavioral experiments with the mice analyzed in the new PLOS ONE paper and with genetically related mouse lines to test whether these mice have behavioral abnormalities in sociability, sensory perception, anxiety or motivation that resemble symptoms in major psychiatric disorders.
He also hopes to collaborate with UCSF colleagues on follow-up experiments to determine whether the activity of neurons lacking Dact1 is impaired in addition to the structural flaws identified in the new study and prior published work from his lab.
Meanwhile, as-yet-unpublished findings from human genetics research conducted by Cheyette’s group suggest that individuals with autism are significantly more likely than healthy comparison subjects to carry mutations in a Wnt pathway gene called WNT1.
“Just because a gene plays an important role in the embryo doesn’t mean it isn’t also important in the brain later, and might be involved in psychiatric pathology,” said Cheyette. “When these genes are mutated, someone may look fine, develop fine and have no obvious medical problems at birth, but they may also develop autism in childhood or have a psychotic break in adulthood and develop schizophrenia.”
A pan-European study: signs of motor disorders can appear years before disease manifestation
It is known that signs of neurological disorders such as Alzheimer’s and Huntington’s disease can appear years before the disease becomes manifest; these signs take the form of subtle changes in the brain and behavior of individuals affected. For the first time, an international group of researchers led by the DZNE and the Bonn University Hospital has proven the existence of such signatures for motor disorders belonging to the group of “spinocerebellar ataxias”. The scientists report these findings in the current online edition of “The Lancet Neurology”. This pan-European study could open up new possibilities of early diagnosis and smooth the way for treatments which tackle diseases before the patient’s nervous system is irreparably damaged.
“Spinocerebellar ataxias” comprise a group of genetic diseases of the cerebellum and other parts of the brain. Persons affected only have limited control of their muscles. They also suffer from balance disorders and impaired speech. The symptoms originate from mutations in the patient’s genetic make-up. These cause nerve cells to become damaged and to die off. Such genetic defects are comparatively rare: it is estimated that about 3,000 people in Germany are affected.
It is known that there are various subtypes of these neurodegenerative diseases. The age at which the symptoms manifest consequently fluctuates between about 30 and 50. “Our aim was to find out whether specific signs can be recognized before a disease becomes obvious,” says project leader Prof. Thomas Klockgether, Director for Clinical Research at the DZNE and Director of the Clinic for Neurology at Bonn University Hospital.
Pan-European cooperation
The study, which involved 14 research centers in all, focused on the four most common forms of spinocerebellar ataxia. These account for more than half of all cases. More than 250 siblings and children of patients throughout Europe declared their willingness to participate in appropriate tests. These individuals had no obvious symptoms of ataxia. However, about half of them had inherited the genetic defects which invariably cause the disease to manifest in the long term.
With the aid of a mathematical model that considered the genetic mutations and their effects, the scientists were able to estimate the time remaining until the disease could be expected to manifest. In the test group, this “time to onset” varied from 2 to 24 years. These and all other test results remained anonymous: the data was not known to the test subjects, neither could the researchers assign it to specific participants. The same applied to individuals whose DNA turned out to be inconspicuous. “People in families with cases of ataxia usually have not taken a genetic test and they don’t want to know any results. This kind of information has to be treated very carefully for ethical reasons,” emphasizes Klockgether.
Extensive tests
The study participants made themselves available for various examinations including standardized tests of muscular coordination. These included measuring the time needed by the subjects to walk a specific distance. Another series of experiments involved inserting small pins into the holes of a board and taking them back out as quickly as possible. Yet another test measured how often the participants could repeat a certain sequence of syllables in ten seconds. “The tests were designed in such a way that they would provide significant information but still be easy to perform,” says Klockgether. “Tests like these can be performed anywhere without need for special technology.”
Technically complex methods were also used: all study participants were tested for the genetic defects relevant to ataxia. At some of the research centers involved in the study, it was also possible to examine the subjects with the aid of magnetic resonance imaging (MRI). This enabled researchers to measure the total brain volume as well as the dimensions of individual parts of the brain in about a third of the subjects.
Notable findings
In two of the four types of ataxia investigated, the scientists found signs of impending disease. “We found a loss in brain volume, particularly shrinkage in the area of the cerebellum and brain stem. These subjects also had subtle difficulties with coordination,” Klockgether summarizes the results. “This means that manifestations of this kind can be measured years before the disease is likely to become obvious.”
The findings for the other two types of ataxia were less conclusive. “I assume that there are indications also for these types of the disease. However, this subgroup of participants was relatively small. It is therefore difficult to make statistically reliable statements about these subjects,” says the Bonn-based researcher.
In his view, the study results testify to the modern-day view of neurodegenerative processes: “Neurodegeneration doesn’t begin when the symptoms surface. Rather, it is a stealthy disease which starts developing years or even decades beforehand.”
Klockgether believes that this gradual development offers certain opportunities: “If we intervened in this process by appropriate treatments and at a sufficiently early stage, it might be possible to slow down or even stop the disease process.”
More investigations planned
The current results will be the basis for long-term investigations. A new series of tests with the same group of individuals has already started; further tests are scheduled every two years. The scientists intend to monitor the study participants for as long as possible.
(Source: dzne.de)
Common Food Supplement Fights Degenerative Brain Disorders
Nutritional supplement delays advancement of Parkinson’s and Familial Dysautonomia, TAU researchers discover
Widely available in pharmacies and health stores, phosphatidylserine is a natural food supplement produced from beef, oysters, and soy. Proven to improve cognition and slow memory loss, it’s a popular treatment for older people experiencing memory impairment. Now a team headed by Prof. Gil Ast and Dr. Ron Bochner of Tel Aviv University’s Department of Human Molecular Genetics has discovered that the same supplement improves the functioning of genes involved in degenerative brain disorders, including Parkinson’s disease and Familial Dysautonomia (FD).
In FD, a rare genetic disorder that impacts the nervous system and appears almost exclusively in the Ashkenazi Jewish population, a genetic mutation prevents the brain from manufacturing healthy IKAP proteins — which likely have a hand in cell migration and aiding connections between nerves — leading to the early degeneration of neurons. When the supplement was applied to cells taken from FD patients, the gene function improved and an elevation in the level of IKAP protein was observed, reports Prof. Ast. These results were replicated in a second experiment which involved administering the supplement orally to mouse populations with FD.
The findings, which have been published in the journal Human Molecular Genetics, are very encouraging, says Prof. Ast. “That we see such an effect on the brain — the most important organ in relation to this disease — shows that the supplement can pass through the blood-brain barrier even when administered orally, and accumulate in sufficient amounts in the brain.”
Slowing the death of nerve cells
Already approved for use as a supplement by the FDA, phosphatidylserine contains a molecule essential for transmitting signals between nerve cells in the brain. Prof. Ast and his fellow researchers decided to test whether the same chemical, which is naturally synthesized in the body and known to boost memory capability, could impact the genetic mutation which leads to FD.
Researchers applied a supplement derived from oysters, provided by the Israeli company Enzymotec, to cells collected from FD patients. Noticing a robust effect on the gene, including a jump in the production of healthy IKAP proteins, they then tested the same supplement on mouse models of FD, engineered with the same genetic mutation that causes the disease in humans.
The mice received the supplement orally, every two days for a period of three months. Researchers then conducted extensive genetic testing to assess the results of the treatment. “We found a significant increase of the protein in all the tissues of the body,” reports Prof. Ast, including an eight-fold increase in the liver and 1.5-fold increase in the brain. “While the food supplement does not manufacture new nerve cells, it probably delays the death of existing ones,” he adds.
Therapeutic potential for Parkinson’s
That the supplement is able to improve conditions in the brain, even when given orally, is a significant finding, notes Prof. Ast. Most medications enter the body through the blood stream, but are incapable of breaking through the barrier between the blood and the brain.
In addition, the researchers say the supplement’s positive effects extend beyond the production of IKAP. Not only did phosphatidylserine impact the gene associated with FD, but it also altered the level of a total of 2400 other genes — hundreds of which have been connected to Parkinson’s disease in previous studies.
The researchers believe that the supplement may have a beneficial impact on a number of degenerative diseases of the brain, concludes Prof. Ast, including a major potential for the development of new medications which would help tens of millions of people worldwide suffering from these devastating diseases.
(Source: aftau.org)