Posts tagged nerve cells

Humans may be endowed with the ability to perform complex forms of learning, attention and function but the evolutionary process that led to this has put us at risk of mental illness.

Data from new research, published today in the journal Nature Neuroscience, was analysed by Dr Richard Emes, a bioinformatics expert from the School of Veterinary Medicine and Science at The University of Nottingham. The results showed that disease-causing mutations occur in the genes that evolved to make us smarter than our fellow animals.

Dr Emes, Director of The University of Nottingham’s Advanced Data Analysis Centre, conducted an analysis of the evolutionary history of the Discs Large homolog (Dlg) family of genes which make some of the essential building blocks of the synapse — the connection between nerve cells in the brain. He said: “This study highlights the importance of the synapse proteome — the proteins involved in the brains signalling processes — in the understanding of cognition and the power of comparative studies to investigate human disease.”

The study involved scientists from The University of Edinburgh, The Wellcome Trust Sanger Institute, the University of Aberdeen, The University of Nottingham and the University of Cambridge.

This cross-disciplinary team of experts carried out what they believe to be the first genetic dissection of the vertebrate’s ability to perform complex forms of learning, attention and function. They focussed on Dlg — a family of genes that humans shared with the ancestor of all backboned animals some 550 million years ago. Gene families like the Dlgs arose by duplication of DNA, changed by mutation over millions of years and now contribute to the complex cognitive processes we have today. However, this redundancy and subsequent accumulation of changes in the DNA may have led to increased susceptibility to some diseases.

Components of the human cognitive repertoire are routinely assessed by using computerised touch-screen methods. By using the same technique with mice researchers were able to probe the cognitive mechanisms conserved since humans and mice shared a common ancestor — around 100 million years ago. By comparing the effect of DNA changes on behavioural test outcomes this research showed a common cause of mutation and effect of learning changes in both mice and humans.

Dr Emes said: “This research shows the importance of discerning information from data and how the power of computational research combined with behavioural and cognitive studies can provide such novel insight into the basis of clinical disorders. This research provides continued support that discovery occurs at the boundary of disciplines by the integration of data.”

(Source: nottingham.ac.uk)

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)

Scientists at the Gladstone Institutes have defined for the first time a key underlying process implicated in multiple sclerosis (MS)—a disease that causes progressive and irreversible damage to nerve cells in the brain and spinal cord. This discovery offers new hope for the millions who suffer from this debilitating disease for which there is no cure.

Researchers in the laboratory of Gladstone Investigator Katerina Akassoglou, PhD, have identified in animal models precisely how a protein that seeps from the blood into the brain sets off a response that, over time, causes the nerve cell damage that is a key indicator of MS. These findings, which are reported in the latest issue of Nature Communications, lay the groundwork for much-needed therapies to treat this disease.

(Source: gladstoneinstitutes.org)

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Scientists at NYU Langone Medical Center have identified two genes involved in establishing the neuronal circuits required for breathing. They report their findings in a study published in the December issue of Nature Neuroscience. The discovery, featured on the journal’s cover, could help advance treatments for spinal cord injuries and neurodegenerative diseases such as amyotrophic lateral sclerosis (ALS), which gradually kill neurons that control the movement of muscles needed to breathe, move, and eat.

The study identifies a molecular code that distinguishes a group of muscle-controlling nerve cells collectively known as the phrenic motor column (PMC). These cells lie about halfway up the back of the neck, just above the fourth cervical vertebra, and are “probably the most important motor neurons in your body,” says Jeremy Dasen, PhD, assistant professor of physiology and neuroscience and a member of the Howard Hughes Medical Institute, who led the three-year study with Polyxeni Philippidou, PhD, a postdoctoral fellow.

Harming the part of the spinal cord where the PMC resides can instantly shut down breathing. But relatively little is known about what distinguishes PMC neurons from neighboring neurons, and how PMC neurons develop and wire themselves to the diaphragm in the fetus.

The PMC cells relay a constant flow of electrochemical signals down their bundled axons and onto the diaphragm muscles, allowing the lungs to expand and relax in the natural rhythm of breathing. “We now have a set of molecular markers that distinguish those cells from other populations of motor neurons, so that we can study them in detail and look for ways to selectively enhance their survival,” Dr. Dasen says. Degeneration of PMC neurons is the primary cause of death in patients with ALS and spinal cord injuries.

To find out what distinguishes PMC neurons from their spinal neighbors in mice, Dr. Philippidou injected a retrograde fluorescent tracer into the phrenic nerve, which wires the PMC to the diaphragm, and then looked for the spinal neurons that lit up as the tracer worked its way back to the PMC. He used transgenic mice that express green fluorescent protein (GFP) in motor neurons and their axons in order to see the phrenic nerve. After noting the characteristic gene expression pattern of these PMC neurons, Dr. Philippidou began to determine their specific roles. Ultimately, a complicated strain of transgenic mice, based partly on mice supplied by collaborator Lucie Jeannotte, PhD, at the University of Laval in Quebec, revealed two genes, Hoxa5 and Hoxc5, as the prime controllers of proper PMC development. Hox genes (39 are expressed in humans) are well known as master gene regulators of animal development.

When Hoxa5 and Hoxc5 are silenced in embryonic motor neurons in mice, the scientists reported, the PMC fails to form its usual, tightly columnar organization and doesn’t connect correctly to the diaphragm, leaving a newborn animal unable to breathe. “Even if you delete these genes late in fetal development, the PMC neuron population drops and the phrenic nerve doesn’t form enough branches on diaphragm muscles,” Dr. Dasen says.

Dr. Dasen plans to use the findings to help understand the wider circuitry of breathing—including rhythm-generating neurons in the brain stem, which are in turn responsive to carbon dioxide levels, stress, and other environmental factors. “Now that we know something about PMC cells, we can work our way through the broader circuit, to try to figure out how all those connections are established,” he says.

"Once we understand how the respiratory network is wired we can begin to develop novel treatment options for breathing disorders such as sleep apneas," adds Dr. Philippidou.

In late October Dr. Dasen lost many of his transgenic mice when Hurricane Sandy flooded the basement of the Smilow building at NYU Langone Medical Center. But just before the hurricane hit, he sent an important group of these mice back to Dr. Jeannotte in Quebec, “so we didn’t lose everything,” he says.

(Source: eurekalert.org)

Reduced production of myelin, a type of protective nerve fiber that is lost in diseases like multiple sclerosis, may also play a role in the development of mental illness, according to researchers at the Graduate School of Biomedical Sciences at Mount Sinai School of Medicine. The study is published in the journal Nature Neuroscience.

Myelin is an insulating material that wraps around the axon, the threadlike part of a nerve cell through which the cell sends impulses to other nerve cells. New myelin is produced by nerve cells called oligodendrocytes both during development and in adulthood to repair damage in the brain of people with diseases such as multiple sclerosis (MS).

A new study led by Patrizia Casaccia, MD, PhD, Professor of Neuroscience, Genetics and Genomics; and Neurology at Mount Sinai, determined that depriving mice of social contact reduced myelin production, demonstrating that the formation of new oligodendrocytes is affected by environmental changes. This research provides further support to earlier evidence of abnormal myelin in a wide range of psychiatric disorders, including autism, anxiety, schizophrenia and depression.

“We knew that a lack of social interaction early in life impacted myelination in young animals but were unsure if these changes would persist in adulthood,” said Dr. Casaccia, who is also Chief of the Center of Excellence for Myelin Repair at the Friedman Brain Institute at Mount Sinai School of Medicine. “Social isolation of adult mice causes behavioral and structural changes in neurons, but this is the first study to show that it causes myelin dysfunction as well.”

Dr. Casaccia’s team isolated adult mice to determine whether new myelin formation was compromised. After eight weeks, they found that the isolated mice showed signs of social withdrawal. Subsequent brain tissue analyses indicated that the socially isolated mice had lower-than-normal levels of myelin-forming oligodendrocytes in the prefrontal cortex, but not in other areas of the brain. The prefrontal cortex controls complex emotional and cognitive behavior.

The researchers also found changes in chromatin, the packing material for DNA. As a result, the DNA from the new oligodendrocytes was unavailable for gene expression.

After observing the reduction in myelin production in socially-isolated mice, Dr. Casaccia’s team then re-introduced these mice into a social group. After four weeks, the social withdrawal symptoms and the gene expression changes were reversed.

“Our study demonstrates that oligodendrocytes generate new myelin as a way to respond to environmental stimuli, and that myelin production is significantly reduced in social isolation,” said Dr. Casaccia. “Abnormalities occur in people with psychiatric conditions characterized by social withdrawal. Other disorders characterized by myelin loss, such as MS, often are associated with depression. Our research emphasizes the importance of maintaining a socially stimulating environment in these instances.”

At Mount Sinai, Dr. Casaccia’s laboratory is studying oligodendrocyte formation to identify therapeutic targets for myelin repair. They are screening newly-developed pharmacological compounds in brain cells from rodents and humans for their ability to form new myelin.

(Source: newswise.com)

Researchers at Yale University have found that neural receptors in a fly’s antenna are able to communicate with one another despite a lack of synaptic connections. They suggest in their paper published in the journal Nature that the communication between the neurons occurs via electrical signals transported by shared fluids.

Suspecting that the fluid filled hairs in the antennas of the fly, Drosophila melanogaster, called sensilla, might possess a property known as ephaptic coupling, where nerve cells communicate without a direct link, the researchers tested the abilities of several fly specimens in their lab. The first focused on two receptors located in the sensilla responsible for detecting fruity methyl hexanoate and banana-scented 2-heptanone, respectively. When exposed to methyl hexonate, they found that only the first receptor fired. If heptanone were suddenly introduced however, the first receptor ceased firing immediately as the second commenced indicating that some form of communication between the two was occurring. They found that the reverse worked as well. To rule out possible modes of communication, the researchers conducted the same experiment with flies that had their synapses disabled via drugs and with others that had had their antennas physically cut off. Both showed the same results indicating that the communication was not direct but was localized.

In another experiment the researchers blocked a neuron in a sensilla responsible for detecting vinegar which was situated next to a neuron responsible for detecting carbon dioxide (for avoidance). When placed in a maze with two arms that smelled of carbon dioxide and one of vinegar, the fly headed for the vinegar scented arm, showing that the vinegar disabled neuron was still able to communicate with its carbon dioxide detecting partner.

The researchers suggest such an ability in flies might help in figuring out which path to take when encountering an environment filled with many different options. They also suggest that neuron pairs in the sensilla might be communicating with one another via electrical signals. When one detects what it’s supposed to detect, it sends a small charge into the fluid in which it and other neurons reside. That charge may then cause other neurons in the vicinity to go silent.

(Source: medicalxpress.com)