Posts tagged muscle cells
Articles and news from the latest research reports.
Researchers Identify New Rare Neuromuscular Disease
An international team of researchers has identified a new inherited neuromuscular disorder. The rare condition is the result of a genetic mutation that interferes with the communication between nerves and muscles, resulting in impaired muscle control.
The new disease was diagnosed in two families – one in the U.S. and the other in Great Britain – and afflicts multiple generations. The discovery was published in the American Journal of Human Genetics.
“This discovery gives us new insight into the mechanisms of diseases that are caused by a breakdown in neuromuscular signal transmission,” said David Herrmann, M.B.B.Ch., a professor in the Department of Neurology at the University of Rochester School of Medicine and Dentistry and co-lead author of the study. “It is our hope that these findings will help identify new targets for therapies that can eventually be used to treat these diseases.”
The focus of the research is the neuromuscular junction, the point at which the axon fibers that extend from peripheral nerves meet the muscle cells. The chemical signals that pass across the junction are essential for motor function.
There are a number of disorders – both acquired and inherited – that interfere with the communication that occurs at the neuromuscular junction. For example, in Lambert-Eaton myasthenic syndrome, which is most commonly triggered by certain cancers, the body’s own immune system attacks the neuromuscular junction, interrupting signal transmission. These diseases, which are rare, result in muscle weakness and fatigue, primarily in the limbs.
While the families in the study had at one point been diagnosed with other neuromuscular conditions, the researchers identified them as unique, due to their particular motor abnormalities, including problems resembling Lambert-Eaton, and because the disease was passed from one generation to the next.
The researchers compiled a genetic profile of the family members. Specifically, they analyzed the section of DNA code responsible for creating proteins using a technique called whole exome sequencing.
They discovered that the two different families had mutations in the code that creates the protein synaptotagmin 2 (SYT2). Scientists have long understood the function of this protein, but it had never before been associated with a disease in humans.
SYT2 is present at the pre-synaptic terminal, the end of the nerve cell that sits at the neuromuscular junction and helps the cells sense fluctuations in calcium levels. Calcium plays an important role in the electrical function of cells and, in the case of the neuromuscular junction, helps dictate the release of acetylcholine, a chemical responsible for passing communication between the nerve and muscle cells.
In the two families, the mutation disrupted the ability of the nerve cells to sense the changes in calcium levels that would normally trigger the release of acetylcholine. As a result, communication was disrupted and muscle control was impaired.
The authors have used the mutation in SYT2 to create a fruit fly (drosophila) model of the disease. Fruit flies are an important research tool and the study of their neurobiology has contributed greatly to our understanding of neurological development and diseases and the researchers see this as a first step to the development of potential new therapies to treat the condition.
(Source: urmc.rochester.edu)
Functioning of aged brains and muscles in mice made younger
Harvard Stem Cell Institute (HSCI) researchers have shown that a protein they previously demonstrated can make the failing hearts in aging mice appear more like those of young health mice, similarly improves brain and skeletal muscle function in aging mice.
In two separate papers given early online release today by the journal Science—which is publishing the papers this coming Friday, Professors Amy Wagers, PhD, and Lee Rubin, PhD, of Harvard’s Department of Stem Cell and Regenerative Biology (HSCRB), report that injections of a protein known as GDF11, which is found in humans as well as mice, improved the exercise capability of mice equivalent in age to that of about a 70-year-old human, and also improved the function of the olfactory region of the brains of the older mice—they could detect smell as younger mice do.
Rubin, and Wagers, who also has a laboratory at the Joslin Diabetes Center, each said that, baring unexpected developments, they expect to have GDF11 in initial human clinical trials within three to five years.
Postdoctoral fellow Lida Katsimpardi, PhD, is the lead author on the Rubin group’s paper, and postdocs Manisha Sinha, PhD, and Young Jang, PhD, are the lead authors on the paper from the Wagers group.
Both studies examined the effect of GDF11 in two ways. First, by using what is called a parabiotic system, in which two mice are surgically joined and the blood of the younger mouse circulates through the older mouse. And second, by injecting the older mice with GDF11, which in an earlier study by Wagers and Richard Lee, MD, of Brigham and Women’s Hospital who is also an author on the two papers released today, was shown to be sufficient to reverse characteristics of aging in the heart.
Doug Melton, PhD, co-chair of HSCRB and co-director of HSCI, reacted to the two papers by saying that he couldn’t “recall a more exciting finding to come from stem cell science and clever experiments. This should give us all hope for a healthier future. We all wonder why we were stronger and mentally more agile when young, and these two unusually exciting papers actually point to a possible answer: the higher levels of the protein GDF11 we have when young. There seems to be little question that, at least in animals, GDF11 has an amazing capacity to restore aging muscle and brain function,” he said.
Melton, Harvard’s Xander University Professor, continued, saying that the ongoing collaboration between Wagers, a stem cell biologist whose focus has been on muscle, Rubin, whose focus is on neurodegenerative diseases and using patient generated stem cells as targets for drug discovery, and Lee, a practicing cardiologist and researcher, “is a perfect example of the power of the Harvard Stem Cell Institute as an engine of truly collaborative efforts and discovery, bringing together people with big, unique ideas and expertise in different biological areas.”
As Melton noted, GDF11 is naturally found in much higher concentrations in young mice than in older mice, and raising its levels in the older mice has improved the function of every organ system thus far studied.
Wagers first began using the parabiotic system in mice 14 years ago as a postdoctoral fellow at Stanford University, when she and colleagues Thomas Rando, MD, PhD, of Stanford, Irina Conboy, PhD, of the University of California, Berkley, and Irving Weissman, MD, of Stanford, observed that the blood of young mice circulating in old mice seemed to have some rejuvenating effects on muscle repair after injury.
Last year, she and Richard Lee published a paper in which they reported that when exposed to the blood of young mice, the enlarged, weakened hearts of older mice returned to a more youthful size, and their function improved. And then working with a Colorado firm, the pair reported that GDF11 was the factor in the blood apparently responsible for the rejuvenating effect. That finding has raised hopes that GDF11 may prove, in some form, to be a possible treatment for diastolic heart failure, a fatal condition in the elderly that now is irreversible, and fatal.
“From the previous work it could have seemed that GD11 was heart specific,” said Wagers, “but this shows that it is active in multiple organs and cell types. Prior studies of skeletal muscle and the parabiotic effect really focused on regenerative biology. Muscle was damaged and assayed on how well it could recover,” Wagers explained.
She continued: “The additional piece is that while prior studies of young blood factors have shown that we achieve restoration of muscle stem cell function and they repair the muscle better, in this study, we also saw repair of DNA damage associated with aging, and we got it in association with recovery of function, and we saw improvements in unmanipulated muscle. Based on other studies, we think that the accumulation of DNA damage in muscle stem cells might reflect an inability of the cells to properly differentiate to make mature muscle cells, which is needed for adequate muscle repair.”
Wagers noted that there is still a great deal to be learned about the mechanics of aging in muscle, and its repair. “I don’t think we fully understand how this happening or why. We might say that the damage is modification to the genetic material; the genome does have breaks in it. But whether it’s damaging, or a necessary part of repair, we don’t know yet.”
Rubin, whose primary research focus is on developing treatment for neurodegenerative diseases, particularly in children, said that when his group began its GDF11 experiments, “we knew that in the old mouse things were bad in the brain, there is a reduced amount of neurogenesis (the development of neurons), and it’s well known that cognition goes down. It wasn’t obvious to me that those things that can be repaired in peripheral tissue could be fixed in the brain.”
Rubin said that postdoctoral fellow Lida Katsimpardi, the lead author on his group’s paper, was taught the parabiotic experimental technique by Wagers, but conducted the Rubin group’s experiments independently of the Wagers group, and “she saw an increase in neural stem cells, and increased development of blood vessels in the brain.” Rubin said that 3D reconstruction of the brain, and magnetic resonance imaging (MRI) of the mouse brain showed “more new blood vessels and more blood flow,” both of which are normally associated with younger, healthier brain tissue.”
Younger mice, Rubin said, “have a keen sense of olfactory discrimination,” they can sense fine differences in odor. “When we tested the young mice, they avoided the smell of mint; the old mice didn’t. But the old mice exposed to the blood of the young mice, and those treated with GDF11 did.”
“We think an effect of GDF11 is the improved vascularity and blood flow, which is associated with increased neurogenesis,” Rubin said. “However, the increased blood flow should have more widespread effects on brain function. We do think that, at least in principle, there will be a way to reverse some of the cognitive decline that takes place during aging, perhaps even with a single protein. It could be that a molecule like GDF11, or GDF11 itself, could” reverse the damage of aging.
“It isn’t out of question that GDF11,” or a drug developed from it, “might be capable of slowing some of the cognitive defects associated with Alzheimer’s disease, a disorder whose main risk factor is aging itself,” Rubin said. It is even possible that this could occur without directly changing the “plaque and tangle burden” that are the pathological hallmarks of Alzheimer’s. Thus, a future treatment for this disease might be a combination of a therapeutic that reduces plaques and tangles, such as an antibody directed against the β-amyloid peptide, with a potential cognition enhancer like GDF11.
Wagers said that the two research groups are in discussions with a venture capital group to obtain funding to “be able to do the additional preclinical work” necessary before moving GDF11 into human trials.
“I would wager that the results of this work, together with the other work, will translate into a clinical trial and a treatment,” said the stem cell biologist. “But of course that’s just a wager.”
Researchers Find Dying Cells Essential to Muscle Development and Repair
Dying cells play an unexpected and vital role in the creation of muscle fibers, researchers at the University of Virginia School of Medicine have determined. The finding could lead to new ways to battle conditions such as muscular dystrophy, facilitate healing after surgery and benefit athletes in their efforts to recover more quickly.
“These dead cells aren’t just a nuisance, which we’ve always considered them to be,” U.Va.’s Kodi S. Ravichandran said. “They have other, important roles before they leave this world.”
Dying cells have long been considered debris that must be removed from the body to avoid causing tissue inflammation. However, the U.Va. research shows that a small number of myoblasts – precursor cells that develop into muscle tissue – must die to allow muscle formation.
The finding suggests that programmed cell death, known as apoptosis, can also influence differentiation of other healthy cells within a tissue. The dying cells express a marker on their surface that signals their death and spurs the body to remove them; that same marker on these dying cells, the U.Va. researchers discovered, cues surrounding cells to develop into muscle fibers. The U.Va. researchers have identified both the membrane marker on the dying cells (a lipid normally hidden on live cells) and a corresponding receptor in the healthy myoblasts that are induced to fuse, said Ravichandran, chairman of the School of Medicine’s Department of Microbiology, Immunology and Cancer Biology.
“It’s been known for a while that there are a few muscle cells that die during exercise, and that building muscle mass depends on a few of those cells dying,” Ravichandran said. “This work puts an interesting spin on that.”
The discovery opens up many intriguing avenues for researchers to explore, including the possibility of producing muscle growth either through the direct application of apoptotic cells or by otherwise stimulating the cellular signaling pathways on the healthy cells. The genes encoding the receptor protein (called BAI1) and some of the components of the signaling pathway are found to be altered in patients with muscular dystrophy and other forms of muscle disorders.
“Because this pathway seems to be involved in muscle repair after injury, this could be relevant for recovery after surgeries, combat injuries in soldiers or any condition that could lead to muscle injury or muscle atrophy,” Ravichandran said. “Take Duchenne muscular dystrophy, for example. One in 3,500 boys that are born have this disease. If we can help alleviate the distress of even a few of these individuals, we would have made significant progress.”
The findings have been published online by the journal Nature and will appear in a forthcoming print edition (along with a News and Views highlighting the impact of the work).
(Source: news.virginia.edu)
Riding the exosome shuttle from neuron to muscle
Novel intercellular transportation system may have potential for delivering RNAi and other gene-based therapeutics
Important new research from UMass Medical School demonstrates how exosomes shuttle proteins from neurons to muscle cells where they take part in critical signaling mechanisms, an exciting discovery that means these tiny vehicles could one day be loaded with therapeutic agents, such as RNA interference (RNAi), and directly target disease-carrying cells. The study, published this month in the journal Neuron, is the first evidence that exosomes can transfer membrane proteins that play an important role in cell-to-cell signaling in the nervous system.
“There has been a long-held belief that certain cellular materials, such as integral membrane proteins, are unable to pass from one cell to another, essentially trapping them in the cell where they are made,” said Vivian Budnik, PhD, professor of neurobiology and lead author of the study. “What we’ve shown in this study is that these cellular materials can actually move between different cell types by riding in the membrane of exosomes.
“What is so exciting about this discovery is that these exosomes can deliver materials from one cell, over a distance, to a very specific and different cell,” said Dr. Budnik. “Once inside the recipient cell, the materials contained in the exosome can influence or perform processes in the new cell. This raises the enticing possibility that exosomes can be packed with gene therapies, such as RNAi, and delivered to diseased cells where they could have a therapeutic effect for people.”
Discovered in the mid-80s, exosomes have only recently attracted the attention of scientists at large, according to Budnik. Exosomes are small vesicles containing cellular materials such as microRNA, messenger RNAs (mRNAs) and proteins, packaged inside larger, membrane-bound bodies called multivesicular bodies (MVBs) inside cells. When MVBs containing exosomes fuse with the cell plasma membrane, they release these exosome vesicles into the extracellular space. Once outside the cell, exosomes can then travel to other cells, where they are taken up. The recipient cells can then use the materials contained within exosomes, influencing cellular function and allowing the recipient cell to carry out certain processes that it might not be able to complete otherwise.
Budnik and colleagues made this startling discovery while investigating how the synapses at the end of neurons and nearby muscle cells communicate in the developing Drosophila fruit fly to form the neuromuscular junction (NMJ). The NMJ is essential for transmitting electrical signals between neurons and muscles, allowing the organism to move and control important physiological processes. Alterations of the NMJ can lead to devastating diseases, such as muscular dystrophy and Amyotrophic lateral sclerosis (ALS). Understanding how the NMJ develops and is maintained is important for human health.
As organisms develop, the synapse and muscle cell need to grow in concert. If one or the other grows too quickly or not quickly enough, it could have dire consequences for the ability of the organism to move and survive. To coordinate development, signals are sent from the neuron to the muscle cell (anterograde signals) and from the muscle cell to the neuron (retrograde signals). However, the identity of these signals and how their release is coordinated is poorly understood.
Normally, the vesicle protein Synaptotagmin 4 (Syt4) is found in both the synapse and the muscle cells. Previous knockout experiments eliminating the Syt4 protein from Drosophila have resulted in stunted NMJs. Suspecting that Syt4 played an important role in retrograde signaling at the developing NMJ, Budnik and colleagues used knockdown experiments to decrease Syt4 protein levels in either the neurons or the muscle cells. Surprisingly, when RNAi was used to knockdown Syt4 in the neurons alone, Syt4 protein was eliminated in both neurons and muscles. The opposite was not the case. When Syt4 was knocked down in muscle cells only, there was no change in the levels of Syt4 in either muscles or neurons.
To confirm this, Budnik and colleagues inserted a Syt4 gene into the neurons of a Drosophila mutant completely lacking the normal protein. This restored Syt4 in both neurons and muscle cells. Further experiments suggested that the only source of Syt4 is the neuron. These observations were consistent with the model that Syt4 is actually transferred from neurons to muscle cells. As a transmembrane protein, however, Syt4 was thought to be unable to move from one cell to another through traditional avenues. How the Syt4 protein was moving from neuron to muscle cell was unclear.
Knowing that exosomes had been observed to carry transmembrane proteins in other systems and from their own work on the Drosophila NMJ, Budnik and colleagues began testing to see if exosomes could be the vehicle responsible for carrying Syt4 form neurons to muscles. “We had previously observed that it was possible to transfer transmembrane proteins across the NMJ through exosomes, a process also observed in the immune system,” said Budnik. “We suspect this was how Syt4 was making its way from the neuron to the muscle.”
When exosomes were purified from cultured cells containing Syt4, they found that exosomes indeed contained Syt4. In addition, when these purified exosomes were applied to cultured muscle cells from fly embryos, these cells were able to take up the purified Syt4 exosomes. Taken together, these findings indicate that Syt4 plays a critical role in the signaling process between synapse and muscle cell that allows for coordinated development of the NMJ. While Syt4 is required to release a retrograde signal from muscle to neuron, a component of this retrograde signal must be supplied from the neuron to the muscle. This establishes a positive feedback loop that ensures coordinated growth of the NMJ. Equally important is the finding that this feedback mechanism is enabled by the use of exosomes, which can shuttle transmembrane proteins across cells.
“While this discovery greatly enhances our understanding of how the neural muscular junction develops and works, it also has tremendous promise as a potential vector for targeted genetic therapies,” said Budnik. “More work needs to be done, but this study significantly supports the possibility that exosomes could be loaded with therapeutic agents and delivered to specific cells in patients.”
(Source: umassmed.edu)
Another Muscular Dystrophy Mystery Solved; MU Scientists Inch Closer to a Therapy for Patients
Approximately 250,000 people in the United States suffer from muscular dystrophy, which occurs when damaged muscle tissue is replaced with fibrous, bony or fatty tissue and loses function. Three years ago, University of Missouri scientists found a molecular compound that is vital to curing the disease, but they didn’t know how to make the compound bind to the muscle cells. In a new study, published in the Proceedings of the National Academies of Science, MU School of Medicine scientists Yi Lai and Dongsheng Duan have discovered the missing pieces to this puzzle that could ultimately lead to a therapy and, potentially, a longer lifespan for patients suffering from the disease.
Duchenne muscular dystrophy (DMD), predominantly affecting males, is the most common type of muscular dystrophy. Patients with Duchenne muscular dystrophy have a gene mutation that disrupts the production of dystrophin, a protein essential for muscle cell survival and function. Absence of dystrophin starts a chain reaction that eventually leads to muscle cell degeneration and death. While dystrophin is vital for muscle development, the protein also needs several “helpers” to maintain the muscle tissue. One of these “helper” molecular compounds is nNOS, which produces nitric oxide that can keep muscle cells healthy after exercise.
“Dystrophin not only helps build muscle cells, it’s also a key factor to attracting nNOS to the muscles cells and helping nNOS bind to the cell and help repair it following activity,” said Lai, a research assistant professor in the Department of Molecular Microbiology and Immunology. “Prior to this discovery, we didn’t know how dystrophin made nNOS bind to the cells. What we found was that dystrophin has a special ‘claw’ that is used to grab nNOS and bring it close to the muscle cell. Now that we have that key, we hope to begin the process of developing a therapy for patients.”
Made to order: printing of live cells
Surgeons may soon be able to regrow patients’ nerves, such as those in damaged spinal cords, using technology adapted from the type of inkjet printer most of us have connected to our computer at home.
Researchers at the ARC Centre of Excellence for Electromaterials Science (ACES), University of Wollongong (UOW) node in NSW, have spent the past three years developing the technology to print living human cells—nerve cells and muscle cells onto tiny biodegradable polymer scaffolds. They’ve also developed a special “ink” that carries the cells.
The ink has to keep the cells in suspension, as well as having the right chemical composition to keep them alive. It also protects them as they are shot out of the printer at amazing speeds.
The scaffolds act as the base upon which the cells thrive, and contain substances such as growth factor molecules and electrical conduits to enable stimulation to promote cell growth. The aim is to produce structures up to 4 cm long, which can be “patched” into broken or damaged nerves or muscles.
“There’s great interest from the medical world, and we are working closely with clinicians at St Vincents Hospital in Melbourne,” says Prof Gordon Wallace, director of the Materials node of ANFF and ACES. “They’re very interested in the possibilities it raises, and the collaboration is resulting in new ideas almost every week.”
“The support from ANFF and the collaborative, interdisciplinary approach that our facilities bring has attracted the best people in the world to join our teams,” he adds.
(Source: scienceinpublic.com.au)
The MIT and University of Pennsylvania team decided that mimicking animal behaviour in robotics was not enough — by mimicking the genetic materials that allow those behaviours, they could make a giant leap towards feasible biorobots. It is the first time skeletal muscle has ever been manipulated to react to light, with past studies focusing only on cardiac muscle cells.
"With bio-inspired designs, biology is a metaphor, and robotics is the tool to make it happen," said MIT engineering professor Harry Asada, who has co-authored a paper on the study, due to appear in the journal Lab on a Chip. “With bio-integrated designs, biology provides the materials, not just the metaphor. This is a new direction we’re pushing in biorobotics.”