Posts tagged MECP2

When young mice with the rodent equivalent of a rare autism spectrum disorder (ASD), called Rett syndrome, were fed a diet supplemented with the synthetic oil triheptanoin, they lived longer than mice on regular diets. Importantly, their physical and behavioral symptoms were also less severe after being on the diet, according to results of new research from The Johns Hopkins University.

(Image caption: Mitochondria (arrows) in muscle cells from mice with Rett syndrome improved in appearance after the mice were given triheptanoin oil. Top: Muscle from mice given regular food. Bottom: Muscle from mice given food supplemented with triheptanoin. Left: Healthy mice. Right: Mice with a genetic mutation that mimics Rett syndrome.)

Researchers involved in the study think that triheptanoin improved the functioning of mitochondria, energy factories common to all cells. Since mitochondrial defects are seen in other ASDs, the researchers say, the experimental results offer hope that the oil could help not just people with Rett syndrome, but also patients with other, more common ASDs.

A description of the research was published on Oct. 9 in the journal PLOS ONE.

ASDs affect an estimated one in 68 children under 8 years of age in the United States. Rett syndrome is a rare ASD caused by mutations in the MECP2 gene, which codes for methyl-CpG-binding-protein 2 (MeCP2). Rett syndrome includes autismlike signs, such as difficulty communicating, socializing and relating to others. Other hallmarks are seizures, decreased muscle tone, repetitive involuntary movements, and gastrointestinal and breathing problems. These other signs are also seen in some patients with other ASDs, suggesting underlying similarities in their causes. While the causes of most ASDs are unknown and thought to be complex, Rett syndrome is unique — and could be a source of insight for the others — because it is caused by an error in a single gene.

The research team used mice lacking the MeCP2 protein, which left them with severe Rett syndrome. In examining those mice, what stood out, according to Gabriele Ronnett, M.D., Ph.D., who led the research project at the Johns Hopkins University School of Medicine, was that they weighed the same as healthy mice but had large fat deposits accompanied by lower amounts of nonfat tissue, such as muscle. This suggested that calories were not being used to support normal tissue function but instead were being stored as fat.

This possibility led Ronnett and her research team to consider the role of mitochondria, which transform the building blocks of nutrients into a high-energy molecule, ATP. This molecule drives processes such as the building of muscle and the growth of nerve cells. Mitochondria use a series of biochemical reactions, collectively called the TCA cycle, to make this transformation possible. According to Susan Aja, Ph.D., a research associate and lead member of the research team, “If the components of the TCA cycle are low, nutrient building blocks are not processed well to create ATP. They are instead stored as fat.”

Ronnett suspected, she says, that some of Rett syndrome’s neurological symptoms could stem from metabolic deficiencies caused by faulty mitochondria and reduced energy for brain cells. “Rett syndrome becomes apparent in humans 6 to 18 months old, when the energy needs of the brain are particularly high, because a lot of new neural connections are being made,” says Ronnett. “If the mitochondria are already defective, stressed or damaged, the increased demand would be too much for them.”

Previous small clinical trials in people with a different metabolic disorder suggested that dietary intervention with triheptanoin could help. Triheptanoin is odorless, tasteless and a little thinner than olive oil. It is easily processed to produce one of the components of the TCA cycle.

When Rett syndrome mice were weaned at 4 weeks of age, they were fed a diet in which 30 percent of their calories came from triheptanoin, mixed in with their normal pelleted food. Though far from a cure, the results of the triheptanoin treatment were impressive, the researchers say. Treated mice had healthier mitochondria, improved motor function, increased social interest in other mice and lived four weeks — or 30 percent — longer than mice who did not receive the oil. The team also found that the diet normalized their body fat, glucose and fat metabolism.

“You can think of the mitochondria of the Rett syndrome model mice as damaged buckets with holes in them that allow TCA cycle components to leak out,” says Aja. “We haven’t figured out how to plug the holes, but we can keep the buckets full by providing triheptanoin to replenish the TCA cycle.”

“It is still too early to assume that this oil will work in humans with ASDs, but these results give us hope,” says Ronnett. “It’s exciting to think that we might be able to improve many ASDs without having to identify each and every contributing gene.”

According to Aja, additional mouse studies are needed to learn if female mice respond to the treatment, to perform a wider range of physiology and behavior tests, and, importantly, to assess the effects of triheptanoin treatment on the brain, which is considered the main driver of many Rett symptoms. The team would also like to provide triheptanoin at earlier ages, perhaps via the mothers’ milk, to mimic developmental ages at which most children are diagnosed with Rett syndrome.

Triheptanoin is currently made for research purposes only and is not available as a medicine or dietary supplement for humans.

(Source: hopkinsmedicine.org)

The concept behind gene therapy is simple: deliver a healthy gene to compensate for one that is mutated. New research published today in the Journal of Neuroscience suggests this approach may eventually be a feasible option to treat Rett Syndrome, the most disabling of the autism spectrum disorders. Gail Mandel, Ph.D., a Howard Hughes Investigator at Oregon Health and Sciences University, led the study. The Rett Syndrome Research Trust, with generous support from the Rett Syndrome Research Trust UK and Rett Syndrome Research & Treatment Foundation, funded this work through the MECP2 Consortium.

In 2007, co-author Adrian Bird, Ph.D., at the University of Edinburgh astonished the scientific community with proof-of-concept that Rett is curable, by reversing symptoms in adult mice. His unexpected results catalyzed labs around the world to pursue a multitude of strategies to extend the pre-clinical findings to people.

Today’s study is the first to show reversal of symptoms in fully symptomatic mice using techniques of gene therapy that have potential for clinical application.

Rett Syndrome is an X-linked neurological disorder primarily affecting girls; in the US, about 1 in 10,000 children a year are born with Rett.  In most cases symptoms begin to manifest between 6 and 18 months of age, as developmental milestones are missed or lost. The regression that follows is characterized by loss of speech, mobility, and functional hand use, which is often replaced by Rett’s signature gesture: hand-wringing, sometimes so intense that it is a constant during every waking hour. Other symptoms include seizures, tremors, orthopedic and digestive problems, disordered breathing and other autonomic impairments, sensory issues and anxiety. Most children live into adulthood and require round-the-clock care.

The cause of Rett Syndrome’s terrible constellation of symptoms lies in mutations of an X-linked gene called MECP2 (methyl CpG-binding protein). MECP2 is a master gene that regulates the activity of many other genes, switching them on or off.

“Gene therapy is well suited for this disorder,” Dr. Mandel explains. “Because MECP2 binds to DNA throughout the genome, there is no single gene currently that we can point to and target with a drug. Therefore the best chance of having a major impact on the disorder is to correct the underlying defect in as many cells throughout the body as possible. Gene therapy allows us to do that.”

Healthy genes can be delivered into cells aboard a virus, which acts as a Trojan horse. Many different types of these Trojan horses exist. Dr. Mandel used adeno-associated virus serotype 9 (AAV9), which has the unusual and attractive ability to cross the blood-brain barrier. This allows the virus and its cargo to be administered intravenously, instead of employing more invasive direct brain delivery systems that require drilling burr holes into the skull.

Because the virus has limited cargo space, it cannot carry the entire MECP2 gene. Co-author Brian Kaspar of Nationwide Children’s Hospital collaborated with the Mandel lab to package only the gene’s most critical segments. After being injected into the Rett mice, the virus made its way to cells throughout the body and brain, distributing the modified gene, which then started to produce the MeCP2 protein.

As in human females with Rett Syndrome, only approximately 50% of the mouse cells have a healthy copy of MECP2. After the gene therapy treatment 65% of cells now had a functioning MECP2 gene.

The treated mice showed profound improvements in motor function, tremors, seizures and hind limb clasping. At the cellular level the smaller body size of neurons seen in mutant cells was restored to normal. Biochemical experiments proved that the gene had found its way into the nuclei of cells and was functioning as expected, binding to DNA.

One Rett symptom that was not ameliorated was abnormal respiration. Researchers hypothesize that correcting this may require targeting a greater number of cells than the 15% that had been achieved in the brainstem.

“We learned a critical and encouraging point with these experiments – that we don’t have to correct every cell in order to reverse symptoms. Going from 50% to 65% of the cells having a functioning gene resulted in significant improvements,” said co-author Saurabh Garg.

One of the potential challenges of gene therapy in Rett is the possibility of delivering multiple copies of the gene to a cell. We know from the MECP2 Duplication Syndrome that too much of this protein is detrimental. “Our results show that after gene therapy treatment the correct amount of MeCP2 protein was being expressed. At least in our hands, with these methods, overexpression of MeCP2 was not an issue,” said co-author Daniel Lioy.

Dr. Mandel cautioned that key steps remain before clinical trials can begin. “Our study is an important first step in highlighting the potential for AAV9 to treating the neurological symptoms in Rett. We are now working on improving the packaging of MeCP2 in the virus to see if we can target a larger percentage of cells and therefore improve symptoms even further,” said Mandel. Collaborators Hélène Cheval and Adrian Bird see this as a promising follow up to the 2007 work showing symptom reversal in Rett mice. “That study used genetic tricks that could not be directly applicable to humans, but the AAV9 vector used here could in principle deliver a gene therapeutically. This is an important step forward, but there is a way to go yet.”

“Gene therapy has had a tumultuous road in the past few decades but is undergoing a renaissance due to recent technological advances. Europe and Asia have gene therapy treatments already in the clinic and it’s likely that the US will follow suit. Our goal now is to prioritize the next key experiments and facilitate their execution as quickly as possible. Gene therapy, especially to the brain, is a tricky undertaking but I’m cautiously optimistic that with the right team we can lay out a plan for clinical development. I congratulate the Mandel and Bird labs on today’s publication, which is the third to be generated from the MECP2 Consortium in a short period of time,” said Monica Coenraads, Executive Director of the Rett Syndrome Research Trust and mother of a teenaged daughter with the disorder.

(Source: rsrt.org)

Statins, a class of cholesterol-lowering drugs found in millions of medicine cabinets, may help treat Rett Syndrome, according to a study published today in Nature Genetics. The Rett Syndrome Research Trust (RSRT) funded this work with generous support from the Rett Syndrome Research Trust UK and Rett Syndrome Research & Treatment Foundation.

Rett Syndrome is a neurological disorder that affects girls. A seemingly typical toddler begins to miss developmental milestones. A regression follows as young girls lose speech, mobility, and hand use. Many girls have seizures, orthopedic and severe digestive problems, as well as breathing and other autonomic impairments. Most live into adulthood and require total, round-the-clock care. Rett Syndrome affects about 1 in 10,000 girls born in the U.S. each year.

The new study screened for randomly induced mutations in genes that modify the effect of the Rett gene, MECP2 (methyl-CpG-binding protein 2), in a mouse model. MECP2 turns other genes on or off by disrupting chromatin, the DNA-protein mix that makes up chromosomes.

The challenge of treating Rett Syndrome is what drove senior author Monica Justice, Ph.D., Professor in the Departments of Molecular and Human Genetics and Molecular Physiology and Biophysics at the Baylor College of Medicine, to look beyond MECP2, hoping to find new drug targets that might improve symptoms or even reverse the course of the disease. In 2007, Adrian Bird, Ph.D., Buchanan Professor of Genetics at the Wellcome Trust Centre for Cell Biology at the University of Edinburgh, showed that symptoms in mice are reversible regardless of the age of the animal.

Exploring cholesterol metabolism in neurological diseases is an emerging area, with statin drugs being tested in fragile X syndrome, neurofibromatosis, amyotrophic lateral sclerosis, and other conditions. But it hadn’t been on the radar for Rett Syndrome. “Our screen was to see if we could suppress the symptoms to reveal alternative pathways to treatment. The cholesterol hit was a big one,” Dr. Justice said. The screen was unbiased – the researchers were looking for any gene that would interact with MECP2 in a useful way, rather than employing a candidate gene approach based on hypotheses.

Dr. Justice and her team injected healthy male mice with a chemical called ENU (a form of nitrosourea) that mutates sperm stem cells randomly, then mated the males to Rett females. The researchers then looked for offspring that should have developed the syndrome (according to their genes), but didn’t (according to their good health).

Key to the investigation was being able to tell sick mice from healthy ones. Fortunately this turned out to be easy. The rescued mice didn’t develop the characteristic tremor, trouble breathing, poor limb-clasping, and general scruffiness of their affected cage-mates. They moved around more, performed better on mobility tests and lived longer.

Once the rescued mice had been identified the random gene mutations from the 24,000 genes that make up the mouse genome had to be pinpointed. “With next generation DNA sequencing, we are finding mutations so easily and quickly. It’s amazing,” said Dr. Justice, compared to the old days of setting up many more generations of crosses to narrow down a part of the genome harboring a gene of interest.

“We are only15% of the way through the screen, and so far we have identified 5 modifiers. The most drug-targetable is a gene called squalene epoxidase (Sqle), which encodes a rate-limiting enzyme in the cholesterol biosynthetic pathway. Frankly, this discovery was a surprise,” Dr. Justice said.  It’s important to note that this enzyme is different from the rate-limiting enzyme (HMG CoA reductase) influenced by statin drugs.

Cholesterol is of course best known for its negative effects on the cardiovascular system, but the lipid has multiple roles in the brain: it helps to form the myelin insulation on neurons and takes part in membrane trafficking, dendrite remodeling, synapse formation, signal transduction, and neuropeptide synthesis.

The next step was to test several statins (fluvastatin and lovastatin) on Rett mice. Like the Sqle mutation, the drugs improved symptoms. Treated mice performed well on mobility and gross motor tests, had better overall health scores and lived longer. The drugs didn’t, however, improve breathing.

“When we saw the mutation in a cholesterol pathway enzyme, we immediately thought of statin drugs. Now that our eyes have opened to what is going on, we have a multitude of drugs that modulate lipid metabolism that we can try in addition to statins,” said first author Christie Buchovecky, graduate student in the Justice lab.

With additional RSRT funding, pediatric neurologist and Director of the Tri-State Rett Syndrome Center in the Bronx Dr. Sasha Djukic undertook a detailed review of lipid data in girls with Rett Syndrome. She found that a subset have elevated cholesterol levels which normalize as they age. These data are not included in the Nature Genetics publication but will be part of a subsequent paper. Dr. Djukic is now planning a clinical trial.

Drs. Justice and Djukic caution that carefully designed and rigorously executed clinical trials are essential to test whether what works in mice will also work in girls with Rett Syndrome. Clinical trials should also determine the most effective timeframe for treatment, ways to identify which girls are most likely to respond, (for example, will statins help girls with Rett who do not have elevated cholesterol?), which drugs to trial and what dosages are effective but not toxic.

“Although statins are blockbuster drugs taken by a large percentage of the population they are not without risks and side-effects, and data on statins in the general pediatric population are quite limited. One of the key objectives of the clinical trial will be to determine correct dosages for Rett symptoms. It’s important to note that the mice in Dr. Justice’s study received very low doses of statins. I urge parents to resist any temptation to medicate their children with off-label statins,” cautions Dr Djukic. “The only way to know if this class of drugs will be efficacious in Rett is through controlled trials. Working with Dr. Justice and RSRT we will be bringing families additional information as soon as possible.”

“The biggest finding is the discovery that this pathway is so important to the pathology of the disorder; it suggests new directions for trying to learn more about Rett Syndrome,” Dr. Justice explains. “Emerging evidence from both mice and humans suggest that Rett Syndrome may have a component of disease that is metabolic. Certainly, this study will further clarify our data, and may suggest avenues for treatment that were previously unexplored.”

(Source: rsrt.org)