Posts tagged microRNA
Articles and news from the latest research reports.
Human skin cells reprogrammed directly into brain cells
Scientists have described a way to convert human skin cells directly into a specific type of brain cell affected by Huntington’s disease, an ultimately fatal neurodegenerative disorder. Unlike other techniques that turn one cell type into another, this new process does not pass through a stem cell phase, avoiding the production of multiple cell types, the study’s authors report.
(Image caption: Human skin cells (top) can be converted into medium spiny neurons (bottom) with exposure to the right combination of microRNAs and transcription factors, according to work by Andrew Yoo and his research team)
The researchers, at Washington University School of Medicine in St. Louis, demonstrated that these converted cells survived at least six months after injection into the brains of mice and behaved similarly to native cells in the brain.
“Not only did these transplanted cells survive in the mouse brain, they showed functional properties similar to those of native cells,” said senior author Andrew S. Yoo, PhD, assistant professor of developmental biology. “These cells are known to extend projections into certain brain regions. And we found the human transplanted cells also connected to these distant targets in the mouse brain. That’s a landmark point about this paper.”
The work appears Oct. 22 in the journal Neuron.
The investigators produced a specific type of brain cell called medium spiny neurons, which are important for controlling movement. They are the primary cells affected in Huntington’s disease, an inherited genetic disorder that causes involuntary muscle movements and cognitive decline usually beginning in middle-adulthood. Patients with the condition live about 20 years following the onset of symptoms, which steadily worsen over time.
The research involved adult human skin cells, rather than more commonly studied mouse cells or even human cells at an earlier stage of development. In regard to potential future therapies, the ability to convert adult human cells presents the possibility of using a patient’s own skin cells, which are easily accessible and won’t be rejected by the immune system.
To reprogram these cells, Yoo and his colleagues put the skin cells in an environment that closely mimics the environment of brain cells. They knew from past work that exposure to two small molecules of RNA, a close chemical cousin of DNA, could turn skin cells into a mix of different types of neurons.
In a skin cell, the DNA instructions for how to be a brain cell, or any other type of cell, is neatly packed away, unused. In past research published in Nature, Yoo and his colleagues showed that exposure to two microRNAs called miR-9 and miR-124 altered the machinery that governs packaging of DNA. Though the investigators still are unraveling the details of this complex process, these microRNAs appear to be opening up the tightly packaged sections of DNA important for brain cells, allowing expression of genes governing development and function of neurons.
Knowing exposure to these microRNAs alone could change skin cells into a mix of neurons, the researchers then started to fine tune the chemical signals, exposing the cells to additional molecules called transcription factors that they knew were present in the part of the brain where medium spiny neurons are common.
“We think that the microRNAs are really doing the heavy lifting,” said co-first author Matheus B. Victor, a graduate student in neuroscience. “They are priming the skin cells to become neurons. The transcription factors we add then guide the skin cells to become a specific subtype, in this case medium spiny neurons. We think we could produce different types of neurons by switching out different transcription factors.”
Yoo also explained that the microRNAs, but not the transcription factors, are important components for the general reprogramming of human skin cells directly to neurons. His team, including co-first author Michelle C. Richner, senior research technician, showed that when the skin cells were exposed to the transcription factors alone, without the microRNAs, the conversion into neurons wasn’t successful.
The researchers performed extensive tests to demonstrate that these newly converted brain cells did indeed look and behave like native medium spiny neurons. The converted cells expressed genes specific to native human medium spiny neurons and did not express genes for other types of neurons. When transplanted into the mouse brain, the converted cells showed morphological and functional properties similar to native neurons.
To study the cellular properties associated with the disease, the investigators now are taking skin cells from patients with Huntington’s disease and reprogramming them into medium spiny neurons using the approach described in the new paper. They also plan to inject healthy reprogrammed human cells into mice with a model of Huntington’s disease to see if this has any effect on the symptoms.
(Source: news.wustl.edu)
Researchers Identify Key Factor in Transition from Moderate to Problem Drinking
A team of UC San Francisco researchers has found that a tiny segment of genetic material known as a microRNA plays a central role in the transition from moderate drinking to binge drinking and other alcohol use disorders.
Previous research in the UCSF laboratory of Dorit Ron, PhD, Endowed Chair of Cell Biology of Addiction in Neurology, has demonstrated that the level of a protein known as brain-derived neurotrophic factor, or BDNF, is increased in the brain when alcohol consumed in moderation. In turn, experiments in Ron’s lab have shown, BDNF prevents the development of alcohol use disorders.
In the new study, Ron and first author Emmanuel Darcq, PhD, a former postdoctoral fellow now at McGill University in Canada, found that when mice consumed excessive amounts of alcohol for a prolonged period, there was a marked decrease in the amount of BDNF in the medial prefrontal cortex (mPFC), a brain region important for decision making. As reported in the October 21, 2014 online edition of Molecular Psychiatry, this decline was associated with a corresponding increase in the level of a microRNA called miR-30a-5p.
MicroRNAs lower the levels of proteins such as BDNF by binding to messenger RNA, the molecular middleman that carries instructions from genes to the protein-making machinery of the cell, and tagging it for destruction.
Ron and colleagues then showed that if they increased the levels of miR-30a-5p in the mPFC, BDNF was reduced, and the mice consumed large amounts of alcohol. When mice were treated with an inhibitor of miR-30a-5p, however, the level of BDNF in the mPFC was restored to normal and alcohol consumption was restored to normal, moderate levels.
“Our results suggest BDNF protects against the transition from moderate to uncontrolled drinking and alcohol use disorders,” said Ron, senior author of the study and a professor in UCSF’s Department of Neurology. “When there is a breakdown in this protective pathway, however, uncontrolled excessive drinking develops, and microRNAs are a possible mechanism in this breakdown. This mechanism may be one possible explanation as to why 10 percent of the population develop alcohol use disorders and this study may be helpful for the development of future medications to treat this devastating disease.”
One reason many potential therapies for alcohol abuse have been unsuccessful is because they inhibit the brain’s reward pathways, causing an overall decline in the experience of pleasure. But in the new study, these pathways continued to function in mice in which the actions of miR-30a-5p had been tamped down—the mice retained the preference for a sweetened solution over plain water that is seen in normal mice.
This result has significant implications for future treatments, Ron said. “In searching for potential therapies for alcohol abuse, it is important that we look for future medications that target drinking without affecting the reward system in general. One problem with current alcohol abuse medications is that patients tend to stop taking them because they interfere with the sense of pleasure.”
Tiny Molecule Could Help Diagnose and Treat Mental Disorders
Scientists “fingerprint” a culprit in depression, anxiety and other mood disorders
According to the World Health Organization, such mood disorders as depression affect some 10% of the world’s population and are associated with a heavy burden of disease. That is why numerous scientists around the world have invested a great deal of effort in understanding these diseases. Yet the molecular and cellular mechanisms that underlie these problems are still only partly understood.
The existing anti-depressants are not good enough: Some 60-70% of patients get no relief from them. For the other 30-40%, that relief is often incomplete, and they must take the drugs for a long period before feeling any effects. In addition, there are many side effects associated with the drugs. New and better drugs are clearly needed, an undertaking that requires, first and foremost, a better understanding of the processes and causes underlying the disorders.
The Weizmann Institute’s Prof. Alon Chen, together with his then PhD student Dr. Orna Issler, investigated the molecular mechanisms of the brain’s serotonin system, which, when misregulated, is involved in depression and anxiety disorders. Chen and his colleagues researched the role of microRNA molecules (small, non-coding RNA molecules that regulate various cellular activities) in the nerve cells that produce serotonin. They succeeded in identifying, for the first time, the unique “fingerprints” of a microRNA molecule that acts on the serotonin-producing nerve cells. Combining bioinformatics methods with experiments, the researchers found a connection between this particular microRNA, (miR135), and two proteins that play a key role in serotonin production and the regulation of its activities. The findings appeared today in Neuron.
The scientists noted that in the area of the brain containing the serotonin-producing nerve cells, miR135 levels increased when antidepressant compounds were introduced. Mice that were genetically engineered to produce higher-than-average amounts of the microRNA were more resistant to constant stress: They did not develop any of the behaviors associated with chronic stress, such as anxiety or depression, which would normally appear. In contrast, mice that expressed low levels of miR135 exhibited more of these behaviors; in addition, their response to antidepressants was weaker. In other words, the brain needs the proper miR135 levels – low enough to enable a healthy stress response and high enough to avoid depression or anxiety disorders and to respond to serotonin-boosting antidepressants. When this idea was tested on human blood samples, the researchers found that subjects who suffered from depression had unusually low miR135 levels in their blood. On closer inspection, the scientists discovered that the three genes involved in producing miR135 are located in areas of the genome that are known to be associated with risk factors for bipolar mood disorders.
These findings suggest that miR135 could be a useful therapeutic molecule – both as a blood test for depression and related disorders, and as a target whose levels might be raised in patients. Yeda Research and Development Co. Ltd., the technology transfer arm of the Weizmann Institute, has applied for a patent connected to these findings and recently licensed the rights to miCure Therapeutics to develop a drug and diagnostic method. After completing preclinical trials, the company hopes to begin clinical trials in humans.
New study links inflammation in those with PTSD to changes in microRNA
With a new generation of military veterans returning home from Iraq and Afghanistan, post-traumatic stress disorder (PTSD) has become a prominent concern in American medical institutions and the culture at-large. Estimates indicate that as many as 35 percent of personnel deployed to Iraq and Afghanistan suffer from PTSD. New research from the University of South Carolina School of Medicine is shedding light on how PTSD is linked to other diseases in fundamental and surprising ways.
The rise in PTSD has implications beyond the impact of the psychiatric disorder and its immediate consequences, which include elevated suicide risk and inability to lead a normal life, that result in approximately $3 billion in lost productivity every year. Over time, these PTSD patients will continue to experience increased risks of a myriad of medical conditions like cardiovascular disease, diabetes, gastrointestinal disease, fibromyalgia, musculoskeletal disorders and others, all of which share chronic inflammation as a common underlying cause.
The mechanisms that trigger PTSD, and that cause PTSD patients to suffer from higher rates of chronic-inflammation-related medical conditions remain unknown. Additionally, PTSD is incurable, and though there are available treatments, they are often not completely effective. In an effort to get to the root of PTSD, and begin to understand the links between PTSD and the secondary diseases that often come with it, a team at the University of South Carolina School of Medicine is investigating PTSD through the lens of inflammation. They have recently published findings of a new study, “Dysregulation in microRNA Expression is Associated with Alterations in Immune Functions in Combat Veterans with Post-traumatic Stress Disorder,” in the journal PLOS ONE.
In this study, led by Drs. Prakash Nagarkatti and Mitzi Nagarkatti, the authors investigated microRNA profiles and tried to establish a link between the microRNA and inflammation in combat veterans of the Persian Gulf, Iraq and Afghanistan wars who are PTSD patients at the Dorn VA Medical Center. MicroRNA are small, noncoding RNA that can switch human genes on and off, effectively controlling gene expression. Some specific types of microRNA are known to regulate genes involved in inflammation, making them a kind of marker that can indicate when inflammation is present.
The microRNA role in PTSD has not been investigated previous to this study, which found that the PTSD patients had significant alterations in microRNA expression. The study analyzed 1163 microRNA and found that the expression of microRNA that regulate genes involved in inflammation were altered in PTSD patients. The alterations were found to be linked to heightened inflammation in these patients.
Dr. Mitzi Nagarkatti sums up the significance of this study as follows: “We are very excited about these results. Thus far, no one had looked at the role of microRNA in the blood of PTSD patients. Thus, our finding that the alterations in these small molecules are connected to higher inflammation seen in these patients is very interesting and helps establish the connection between war trauma and microRNA changes.”
In addition to the alterations in microRNA expression, the study also found that PTSD patients had higher levels of inflammation caused by certain types of immune cells called T cells. These T cells produced higher levels of inflammatory mediators called cytokines, specifically interferon-gamma and interleukin-17. This finding was especially interesting because one of the inflammation-associated microRNAs, miR-125a, which specifically targets increased production of interferon-gamma, was found to have decreased expression in the PTSD patients studied. Overall, these results suggested that trauma may cause alterations in the expression of microRNA which promote inflammation in PTSD patients.
Commenting on this, Dr. Prakash Nagarkatti said, “These studies form the foundation to further analyze the role of microRNA in PTSD. Trauma experienced during war may trigger changes in microRNA which may in turn cause various clinical disorders seen in PTSD patients. Our long-term goal is to identify whether PTSD patients express a unique signature profile of microRNA which can be used towards early detection, prevention and treatment of PTSD.”
(Source: eurekalert.org)
The phenomenon has long been known in psychology: traumatic experiences can induce behavioural disorders that are passed down from one generation to the next. It is only recently that scientists have begun to understand the physiological processes underlying hereditary trauma. ”There are diseases such as bipolar disorder, that run in families but can’t be traced back to a particular gene”, explains Isabelle Mansuy, professor at ETH Zurich and the University of Zurich. With her research group at the Brain Research Institute of the University of Zurich, she has been studying the molecular processes involved in non-genetic inheritance of behavioural symptoms induced by traumatic experiences in early life.
Mansuy and her team have succeeded in identifying a key component of these processes: short RNA molecules. These RNAs are synthetized from genetic information (DNA) by enzymes that read specific sections of the DNA (genes) and use them as template to produce corresponding RNAs. Other enzymes then trim these RNAs into mature forms. Cells naturally contain a large number of different short RNA molecules called microRNAs. They have regulatory functions, such as controlling how many copies of a particular protein are made.
Small RNAs with a huge impact
The researchers studied the number and kind of microRNAs expressed by adult mice exposed to traumatic conditions in early life and compared them with non-traumatized mice. They discovered that traumatic stress alters the amount of several microRNAs in the blood, brain and sperm – while some microRNAs were produced in excess, others were lower than in the corresponding tissues or cells of control animals. These alterations resulted in misregulation of cellular processes normally controlled by these microRNAs.
After traumatic experiences, the mice behaved markedly differently: they partly lost their natural aversion to open spaces and bright light and had depressive-like behaviours. These behavioural symptoms were also transferred to the next generation via sperm, even though the offspring were not exposed to any traumatic stress themselves.
Even passed on to the third generation
The metabolism of the offspring of stressed mice was also impaired: their insulin and blood-sugar levels were lower than in the offspring of non-traumatized parents. “We were able to demonstrate for the first time that traumatic experiences affect metabolism in the long-term and that these changes are hereditary”, says Mansuy. The effects on metabolism and behaviour even persisted in the third generation.
“With the imbalance in microRNAs in sperm, we have discovered a key factor through which trauma can be passed on,” explains Mansuy. However, certain questions remain open, such as how the dysregulation in short RNAs comes about. “Most likely, it is part of a chain of events that begins with the body producing too much stress hormones.”
Importantly, acquired traits other than those induced by trauma could also be inherited through similar mechanisms, the researcher suspects. “The environment leaves traces on the brain, on organs and also on gametes. Through gametes, these traces can be passed to the next generation.”
Mansuy and her team are currently studying the role of short RNAs in trauma inheritance in humans. As they were also able to demonstrate the microRNAs imbalance in the blood of traumatized mice and their offspring, the scientists hope that their results may be useful to develop a blood test for diagnostics.
Untangling Alzheimer’s Disease
TAU researchers identify specific molecules that could be targeted to treat the disorder
Plaques and tangles made of proteins are believed to contribute to the debilitating progression of Alzheimer’s disease. But proteins also play a positive role in important brain functions, like cell-to-cell communication and immunological response. Molecules called microRNAs regulate both good and bad protein levels in the brain, binding to messenger RNAs to prevent them from developing into proteins.
Now, Dr. Boaz Barak and a team of researchers in the lab of Prof. Uri Ashery of Tel Aviv University’s Department of Neurobiology at the George S. Wise Faculty of Life Sciences and the Sagol School of Neuroscience have identified a specific set of microRNAs that detrimentally regulate protein levels in the brains of mice with Alzheimer’s disease and beneficially regulate protein levels in the brains of other mice living in a stimulating environment.
"We were able to create two lists of microRNAs — those that contribute to brain performance and those that detract — depending on their levels in the brain," says Dr. Barak. "By targeting these molecules, we hope to move closer toward earlier detection and better treatment of Alzheimer’s disease."
Prof. Daniel Michaelson of TAU’s Department of Neurobiology in the George S. Wise Faculty of Life Sciences and the Sagol School of Neuroscience, Dr. Noam Shomron of TAU’s Department of Cell and Developmental Biology and Sagol School of Neuroscience, Dr. Eitan Okun of Bar-Ilan University, and Dr. Mark Mattson of the National Institute on Aging collaborated on the study, published in Translational Psychiatry.
A double-edged sword
Alzheimer’s disease is the most common form of dementia. Currently incurable, it increasingly impairs brain function over time, ultimately leading to death. The TAU researchers became interested in the disease while studying the brains of mice living in an “enriched environment” — an enlarged cage with running wheels, bedding and nesting material, a house, and frequently changing toys. Such environments have been shown to improve and maintain brain function in animals much as intellectual activity and physical fitness do in people.
The researchers ran a series of tests on a part of the mice’s brains called the hippocampus, which plays a major role in memory and spatial navigation and is one of the earliest targets of Alzheimer’s disease in humans. They found that, compared to mice in normal cages, the mice from the enriched environment developed higher levels of good proteins and lower levels of bad proteins. Then, for the first time, they identified the microRNAs responsible for regulating the expression of both good and bad proteins.
Armed with this new information, the researchers analyzed changes in the levels of microRNAs in the hippocampi of young, middle-aged, and old mice with an Alzheimer’s-disease-like condition. They found that some of the microRNAs were expressed in exactly inverse amounts in mice with Alzheimer’s disease as they were in mice from the enriched environment. The results were higher levels of bad proteins and lower levels of good proteins in the hippocampi of old mice with Alzheimer’s disease. The microRNAs the researchers identified had already been shown or predicted to regulate the expression of proteins in ways that contributed to Alzheimer’s disease. Their finding that the microRNAs are inversely regulated in mice from the enriched environment is important, because it suggests the molecules can be targeted by activities or drugs to preserve brain function.
Brain-busting potential
Two findings appear to have particular potential for treating people with Alzheimer’s disease. In the brains of old mice with the disease, microRNA-325 was diminished, leading to higher levels of tomosyn, a protein that is well known to inhibit cellular communication in the brain. The researchers hope that eventually microRNA-325 can be used to create a drug to help Alzheimer’s patients maintain low levels of tomosyn and preserve brain function. Additionally, the researchers found several important microRNAs at low levels starting in the brains of young mice. If the same can be found in humans, these microRNAs could be used as biomarker to detect Alzheimer’s disease at a much earlier age than is now possible — at 30 years of age, for example, instead of 60.
"Our biggest hope is to be able to one day use microRNAs to detect Alzheimer’s disease in people at a young age and begin a tailor-made treatment based on our findings, right away," says Dr. Barak.
(Source: aftau.org)
![Memory-Boosting Chemical Is Identified in Mice
Memory improved in mice injected with a small, drug-like molecule discovered by UCSF San Francisco researchers studying how cells respond to biological stress.
The same biochemical pathway the molecule acts on might one day be targeted in humans to improve memory, according to the senior author of the study, Peter Walter, PhD, UCSF professor of biochemistry and biophysics and a Howard Hughes Investigator.
The discovery of the molecule and the results of the subsequent memory tests in mice were published in eLife, an online scientific open-access journal, on May 28, 2013.
In one memory test included in the study, normal mice were able to relocate a submerged platform about three times faster after receiving injections of the potent chemical than mice that received sham injections.
The mice that received the chemical also better remembered cues associated with unpleasant stimuli – the sort of fear conditioning that could help a mouse avoid being preyed upon.
Notably, the findings suggest that despite what would seem to be the importance of having the best biochemical mechanisms to maximize the power of memory, evolution does not seem to have provided them, Walter said.
“It appears that the process of evolution has not optimized memory consolidation; otherwise I don’t think we could have improved upon it the way we did in our study with normal, healthy mice,” Walter said.
The memory-boosting chemical was singled out from among 100,000 chemicals screened at the Small Molecule Discovery Center at UCSF for their potential to perturb a protective biochemical pathway within cells that is activated when cells are unable to keep up with the need to fold proteins into their working forms.
However, UCSF postdoctoral fellow Carmela Sidrauski, PhD, discovered that the chemical acts within the cell beyond the biochemical pathway that activates this unfolded protein response, to more broadly impact what’s known as the integrated stress response. In this response, several biochemical pathways converge on a single molecular lynchpin, a protein called eIF2 alpha.
Scientists have known that in organisms ranging in complexity from yeast to humans different kinds of cellular stress — a backlog of unfolded proteins, DNA-damaging UV light, a shortage of the amino acid building blocks needed to make protein, viral infection, iron deficiency — trigger different enzymes to act downstream to switch off eIF2 alpha.
“Among other things, the inactivation of eIF2 alpha is a brake on memory consolidation,” Walter said, perhaps an evolutionary consequence of a cell or organism becoming better able to adapt in other ways.
Turning off eIF2 alpha dials down production of most proteins, some of which may be needed for memory formation, Walter said. But eIF2 alpha inactivation also ramps up production of a few key proteins that help cells cope with stress.
Study co-author Nahum Sonenberg, PhD, of McGill University previously linked memory and eIF2 alpha in genetic studies of mice, and his lab group also conducted the memory tests for the current study.
The chemical identified by the UCSF researchers is called ISRIB, which stands for integrated stress response inhibitor. ISRIB counters the effects of eIF2 alpha inactivation inside cells, the researchers found.
“ISRIB shows good pharmacokinetic properties [how a drug is absorbed, distributed and eliminated], readily crosses the blood-brain barrier, and exhibits no overt toxicity in mice, which makes it very useful for studies in mice,” Walter said. These properties also indicate that ISRIB might serve as a good starting point for human drug development, according to Walter.
Walter said he is looking for scientists to collaborate with in new studies of cognition and memory in mouse models of neurodegenerative diseases and aging, using ISRIB or related molecules.
In addition, chemicals such as ISRIB could play a role in fighting cancers, which take advantage of stress responses to fuel their own growth, Walter said. Walter already is exploring ways to manipulate the unfolded protein response to inhibit tumor growth, based on his earlier discoveries.
At a more basic level, Walter said, he and other scientists can now use ISRIB to learn more about the role of the unfolded protein response and the integrated stress response in disease and normal physiology.](http://41.media.tumblr.com/11ebbfd04cfa4f78a2b3f00de596c905/tumblr_mofkpwCqOn1rog5d1o1_500.jpg)
Memory-Boosting Chemical Is Identified in Mice
Memory improved in mice injected with a small, drug-like molecule discovered by UCSF San Francisco researchers studying how cells respond to biological stress.
The same biochemical pathway the molecule acts on might one day be targeted in humans to improve memory, according to the senior author of the study, Peter Walter, PhD, UCSF professor of biochemistry and biophysics and a Howard Hughes Investigator.
The discovery of the molecule and the results of the subsequent memory tests in mice were published in eLife, an online scientific open-access journal, on May 28, 2013.
In one memory test included in the study, normal mice were able to relocate a submerged platform about three times faster after receiving injections of the potent chemical than mice that received sham injections.
The mice that received the chemical also better remembered cues associated with unpleasant stimuli – the sort of fear conditioning that could help a mouse avoid being preyed upon.
Notably, the findings suggest that despite what would seem to be the importance of having the best biochemical mechanisms to maximize the power of memory, evolution does not seem to have provided them, Walter said.
“It appears that the process of evolution has not optimized memory consolidation; otherwise I don’t think we could have improved upon it the way we did in our study with normal, healthy mice,” Walter said.
The memory-boosting chemical was singled out from among 100,000 chemicals screened at the Small Molecule Discovery Center at UCSF for their potential to perturb a protective biochemical pathway within cells that is activated when cells are unable to keep up with the need to fold proteins into their working forms.
However, UCSF postdoctoral fellow Carmela Sidrauski, PhD, discovered that the chemical acts within the cell beyond the biochemical pathway that activates this unfolded protein response, to more broadly impact what’s known as the integrated stress response. In this response, several biochemical pathways converge on a single molecular lynchpin, a protein called eIF2 alpha.
Scientists have known that in organisms ranging in complexity from yeast to humans different kinds of cellular stress — a backlog of unfolded proteins, DNA-damaging UV light, a shortage of the amino acid building blocks needed to make protein, viral infection, iron deficiency — trigger different enzymes to act downstream to switch off eIF2 alpha.
“Among other things, the inactivation of eIF2 alpha is a brake on memory consolidation,” Walter said, perhaps an evolutionary consequence of a cell or organism becoming better able to adapt in other ways.
Turning off eIF2 alpha dials down production of most proteins, some of which may be needed for memory formation, Walter said. But eIF2 alpha inactivation also ramps up production of a few key proteins that help cells cope with stress.
Study co-author Nahum Sonenberg, PhD, of McGill University previously linked memory and eIF2 alpha in genetic studies of mice, and his lab group also conducted the memory tests for the current study.
The chemical identified by the UCSF researchers is called ISRIB, which stands for integrated stress response inhibitor. ISRIB counters the effects of eIF2 alpha inactivation inside cells, the researchers found.
“ISRIB shows good pharmacokinetic properties [how a drug is absorbed, distributed and eliminated], readily crosses the blood-brain barrier, and exhibits no overt toxicity in mice, which makes it very useful for studies in mice,” Walter said. These properties also indicate that ISRIB might serve as a good starting point for human drug development, according to Walter.
Walter said he is looking for scientists to collaborate with in new studies of cognition and memory in mouse models of neurodegenerative diseases and aging, using ISRIB or related molecules.
In addition, chemicals such as ISRIB could play a role in fighting cancers, which take advantage of stress responses to fuel their own growth, Walter said. Walter already is exploring ways to manipulate the unfolded protein response to inhibit tumor growth, based on his earlier discoveries.
At a more basic level, Walter said, he and other scientists can now use ISRIB to learn more about the role of the unfolded protein response and the integrated stress response in disease and normal physiology.
New Molecular-Level Understanding of Brain’s Recovery After Stroke
A specific MicroRNA, a short set of RNA (ribonuclease) sequences, naturally packaged into minute (50 nanometers) lipid containers called exosomes, are released by stem cells after a stroke and contribute to better neurological recovery according to a new animal study by Henry Ford Hospital researchers.
The important role of a specific microRNA transferred from stem cells to brain cells via the exosomes to enhance functional recovery after a stroke was shown in lab rats. This study provides fundamental new insight into how stem cells affect injured tissue and also offers hope for developing novel treatments for stroke and neurological diseases, the leading cause of long-term disability in adult humans.
The study was published in the journal Stem Cells.
Although most stroke victims recover some ability to voluntarily use their hands and other body parts, nearly half are left with weakness on one side of their body, while a substantial number are permanently disabled.
Currently no treatment exists for improving or restoring this lost motor function in stroke patients, mainly because of mysteries about how the brain and nerves repair themselves.
“This study may have solved one of those mysteries by showing how certain stem cells play a role in the brain’s ability to heal itself to differing degrees after stroke or other trauma,” says study author Michael Chopp, Ph.D., scientific director of the Henry Ford Neuroscience Institute and vice chairman of the department of Neurology at Henry Ford Hospital.
The researchers noted that Henry Ford’s Institutional Animal Care and Use Committee approved all the experimental procedures used in the new study.
The experiment began by isolating mesenchymal stem cells (MSCs) from the bone marrow of lab rats. These MSCs are then genetically altered to release exosomes that contain specific microRNA molecules. The MSCs then become “factories” producing exosomes containing specific microRNAs. These microRNAs act as master switches that regulate biological function.
The new study showed for the first time that a specific microRNA, miR-133b, carried by these exosomes contributes to functional recovery after a stroke.
The researchers genetically raised or lowered the amount of miR-133b in MSCs and, respectively, treated the rats. When these MSCs are injected into the bloodstream 24 hours after stroke, they enter the brain and release their exosomes. When the exosomes were enriched with the miR-133b, they amplified neurological recovery, and when the exosomes were deprived of the miR-133b, the neurological recovery was substantially reduced.
Stroke was induced under anesthesia by inserting a nylon thread up the carotid artery to occlude a major artery in the brain, the middle cerebral artery. MSCs were then injected 24 hours after the induction of stroke in these animals and neurological recovery was measured.
As a measure on neurological recovery, rats were given two types of behavioral tests to measure the normal function of their front legs and paws – a “foot-fault test,” to see how well they could walk on an unevenly spaced grid; and an “adhesive removal test” to measure how long it took them to remove a piece of tape stuck to their front paws.
Researchers then separated the disabled rats into several groups and injected each group with a specific dosage of saline, MSCs and MSCs with increased or decreased miR-133b, respectively. The two behavioral tests were again given to the rats three, seven and 14 days after treatment.
The data demonstrated that the enriched miR-133b exosome package greatly promoted neurological recovery and enhanced axonal plasticity, an aspect of brain rewiring, and the diminished miR-133b exosome package failed to enhance neurological recovery
While the research team was careful to note that this was an animal study, its findings offer hope for new ways to address the single biggest concern of stroke victims as well as those with neural injury such as traumatic brain injury and spinal cord damage – regaining neurological function for a better quality of life.
(Source: henryford.com)
Sniffing Out Schizophrenia
Neurons in the nose could be the key to early, fast, and accurate diagnosis, says a TAU researcher
A debilitating mental illness, schizophrenia can be difficult to diagnose. Because physiological evidence confirming the disease can only be gathered from the brain during an autopsy, mental health professionals have had to rely on a battery of psychological evaluations to diagnose their patients.
Now, Dr. Noam Shomron and Prof. Ruth Navon of Tel Aviv University’s Sackler Faculty of Medicine, together with PhD student Eyal Mor from Dr. Shomron’s lab and Prof. Akira Sawa of Johns Hopkins Hospital in Baltimore, Maryland, have discovered a method for physical diagnosis — by collecting tissue from the nose through a simple biopsy. Surprisingly, collecting and sequencing neurons from the nose may lead to “more sure-fire” diagnostic capabilities than ever before, Dr. Shomron says.
This finding, which was reported in the journal Neurobiology of Disease, could not only lead to a more accurate diagnosis, it may also permit the crucial, early detection of the disease, giving rise to vastly improved treatment overall.
From the nose to diagnosis
Until now, biomarkers for schizophrenia had only been found in the neuron cells of the brain, which can’t be collected before death. By that point it’s obviously too late to do the patient any good, says Dr. Shomron. Instead, psychiatrists depend on psychological evaluations for diagnosis, including interviews with the patient and reports by family and friends.
For a solution to this diagnostic dilemma, the researchers turned to the olfactory system, which includes neurons located on the upper part of the inner nose. Researchers at Johns Hopkins University collected samples of olfactory neurons from patients diagnosed with schizophrenia and a control group of non-affected individuals, then sent them to Dr. Shomron’s TAU lab.
Dr. Shomron and his fellow researchers applied a high-throughput technology to these samples, studying the microRNA of the olfactory neurons. Within these molecules, which help to regulate our genetic code, they were able to identify a microRNA which is highly elevated in those with schizophrenia, compared to individuals who do not have the disease.
"We were able to narrow down the microRNA to a differentially expressed set, and from there down to a specific microRNA which is elevated in individuals with the disease compared to healthy individuals," explains Dr. Shomron. Further research revealed that this particular microRNA controls genes associated with the generation of neurons.
In practice, material for biopsy could be collected through a quick and easy outpatient procedure, using a local anesthetic, says Dr. Shomron. And with microRNA profiling results ready in a matter of hours, this method could evolve into a relatively simple and accurate test to diagnose a very complicated illness.
Early detection, early intervention
Though there is much more to investigate, Dr. Shomron has high hopes for this diagnostic method. It’s important to determine whether this alteration in microRNA expression begins before schizophrenic symptoms begin to exhibit themselves, or only after the disease fully develops, he says. If this change comes near the beginning of the timeline, it could be invaluable for early diagnostics. This would mean early intervention, better treatment, and possibly even the postponement of symptoms.
If, for example, a person has a family history of schizophrenia, this test could reveal whether they too suffer from the disease. And while such advanced warning doesn’t mean a cure is on the horizon, it will help both patient and doctor identify and prepare for the challenges ahead.
(Source: aftau.org)
New epilepsy gene identified; possible new treatment option
ScienceDaily (July 23, 2012) — New research conducted by neuroscientists from the Royal College of Surgeons in Ireland (RCSI) published in Nature Medicine has identified a new gene involved in epilepsy and could potentially provide a new treatment option for patients with epilepsy.
The research focussed on a new class of gene called a ‘microRNA’ which controls protein production inside cells. The research looked in detail at one particular microRNA called ‘microRNA-134’ and found that levels of microRNA-134 are much higher in the part of the brain that causes seizures in patients with epilepsy.
By using a new type of drug-like molecule called an antagomir which locks onto the ‘microRNA-134’ and removes it from the brain cell, the researchers found they could prevent epileptic seizures from occurring.
Professor David Henshall, Department of Physiology & Medical Physics, RCSI and senior author on the paper said ‘We have been looking to find what goes wrong inside brain cells to trigger epilepsy. Our research has discovered a completely new gene linked to epilepsy and it shows how we can target this gene using drug-like molecules to reduce the brain’s susceptibility to seizures and the frequency in which they occur.”
Dr Eva Jimenez-Mateos, Department of Physiology & Medical Physics, RCSI and first author on the paper said “Our research found that the antagomir drug protects the brain cells from toxic effects of prolonged seizures and the effects of the treatment can last up to one month.”
Epilepsy affects 37,000 in Ireland alone. For every two out of three people with epilepsy their seizures are controlled by medication, but one in three patients continues to have seizures despite being prescribed medication. This study could potentially offer new treatment methods for patients.
The research was supported by a grant from Science Foundation Ireland (SFI). Researchers in the Department of Physiology & Medical Physics and Molecular & Cellular Therapeutics, RCSI, clinicians at Beaumont Hospital and experts in brain structure from the Cajal Institute in Madrid were involved in the study.
Source: Science Daily