Posts tagged alzheimer's disease
Articles and news from the latest research reports.
Alzheimer’s missing link found: Is a promising target for new drugs
Yale School of Medicine researchers have discovered a protein that is the missing link in the complicated chain of events that lead to Alzheimer’s disease, they report in the Sept. 4 issue of the journal Neuron. Researchers also found that blocking the protein with an existing drug can restore memory in mice with brain damage that mimics the disease.
“What is very exciting is that of all the links in this molecular chain, this is the protein that may be most easily targeted by drugs,” said Stephen Strittmatter, the Vincent Coates Professor of Neurology and senior author of the study. “This gives us strong hope that we can find a drug that will work to lessen the burden of Alzheimer’s.”
Scientists have already provided a partial molecular map of how Alzheimer’s disease destroys brain cells. In earlier work, Strittmatter’s lab showed that the amyloid-beta peptides, which are a hallmark of Alzheimer’s, couple with prion proteins on the surface of neurons. By an unknown process, the coupling activates a molecular messenger within the cell called Fyn.
In the Neuron paper, the Yale team reveals the missing link in the chain, a protein within the cell membrane called metabotropic glutamate receptor 5 or mGluR5. When the protein is blocked by a drug similar to one being developed for Fragile X syndrome, the deficits in memory, learning, and synapse density were restored in a mouse model of Alzheimer’s.
Strittmatter stressed that new drugs may have to be designed to precisely target the amyloid-prion disruption of mGluR5 in human cases of Alzheimer’s and said his lab is exploring new ways to achieve this.
Scientists use latest stem cell and gene-editing techniques to generate neurons in a dish, and reveal new clues behind deadly diseases of the brain
There is no easy way to study diseases of the brain. Extracting neurons from a living patient is both difficult and risky, while examining a patient’s brain post-mortem usually only reveals the disease’s final stages. And animal models, while incredibly informative, have frequently fallen short during the crucial drug-development stage of research. The result: we are woefully unprepared to fight—and win—the war against this class of diseases.
But scientists at the Gladstone Institutes and the University of California, San Francisco (UCSF) are taking a potentially more powerful approach: an advanced stem-cell technique that creates a human model of degenerative disease in a dish.
Using this model, the team uncovered a molecular process that causes neurons to degenerate, a hallmark sign of conditions such as Alzheimer’s disease and frontotemporal dementia (FTD). The results, published in the latest issue of Stem Cell Reports, offer fresh ammunition in the continued battle against these and other deadly neurodegenerative disorders.
The research team, led by Gladstone Investigator Yadong Huang, MD, PhD, identified an important mechanism behind tauopathies. A group of disorders that includes both Alzheimer’s and FTD, tauopathies are characterized by the abnormal accumulation of the protein Tau in neurons. This buildup is thought to contribute to the degeneration of these neurons over time, leading to debilitating symptoms such as dementia and memory loss. But while this notion has been around for a long time, the underlying processes have largely remained unclear.
“So much about the mechanisms that cause tauopathies is a mystery, in part because traditional approaches—such as post-mortem brain analysis and animal models—give an incomplete picture,” explained Dr. Huang. “But by using the latest stem-cell technology, we generated human neurons in a dish that exhibited the same pattern of cell degeneration and death that occurs inside a patient’s brain. Studying these models allowed us to see for the first time how a specific genetic mutation may kick start the tauopathy process.”
Other scientists recently discovered that the Tau mutation in question could increase a person’s risk of developing different tauopathies, including Alzheimer’s or FTD. So the research team, in collaboration with Bruce Miller, MD, who directs the UCSF Memory and Aging Center and who provided skin cells from a patient with this mutation, transformed these cells into induced pluripotent stem cells, or iPS cells. This technique, pioneered by Gladstone Investigator and 2012 Nobel Laureate Shinya Yamanaka, MD, PhD, allows scientists to reprogram adult skin cells into cells that are virtually identical to stem cells. These stem cells can then develop into almost any cell in the body.
The team combined this method with a cutting-edge gene-editing technique that essentially eliminated the Tau mutation in some of the iPS cells. The result was a system that allowed the team to compare neurons that had the mutation to those that did not.
“Our approach allowed us to grow human neurons in a dish that contained the exact same mutation as the neurons in the brain of the patient,” explained first author Helen Fong, PhD, who is also a California Institute for Regenerative Medicine postdoctoral scholar. “By comparing these diseased neurons with the ‘genetically corrected’ healthy neurons, we could see—cell by cell—how the Tau mutation leads to the abnormal build up of Tau and, over time, neuronal degeneration and death.”
“Tau’s main functions include keeping the skeletal structure of individual neurons intact and regulating neuronal activity,” said Dr. Huang. “But our research showed that the Tau produced by neurons from people with the Tau mutation is different; so it is red-flagged by the cell and targeted for destruction. However, instead of being flushed out, Tau gets chopped into pieces. These potentially toxic fragments accumulate over time and may in fact cause the neuron to degenerate and die.”
But by correcting the Tau mutation, the team effectively removed Tau’s red flag. The protein remained in one piece, the abnormal buildup ceased and the neurons remained healthy. Ongoing studies aim to determine whether the abnormal fragmentation and buildup of mutant tau is really the main cause of the neuronal death and, if so, how to block it.
Finding a way to block this toxic buildup of tau fragments has been a key focus of drug development—but has thus far been unsuccessful. But Dr. Huang and his colleagues are optimistic that their approach could be exactly what researchers need to fight back against deadly tauopathies.
“These findings not only offer a glimpse into how these powerful new models can shed light on mechanisms of disease” said Dr. Miller, “They may also prove invaluable for screening potential drugs that could be developed into better treatments for Alzheimer’s disease, FTD and related conditions.”
Toward an early diagnostic tool for Alzheimer’s disease
Despite all the research done on Alzheimer’s, there is still no early diagnostic tool for the disease. By looking at the brain wave components of individuals with the disease, Professor Tiago H. Falk of INRS’s Centre Énergie Matériaux Télécommunications has identified a promising avenue of research that may not only help diagnose the disease, but also assess its severity. This non-invasive, objective method is the subject of an article in the journal PLOS ONE.
Patients with Alzheimer’s disease currently undergo neuropsychological testing to detect signs of the disease. The test results are difficult to interpret and are insufficient for making a definitive diagnosis. But as scientists have already discovered, activity in certain areas of the cerebral cortex is affected even in the early stages of the disease. Professor Falk, who specialises in biological signal acquisition, examined this phenomenon and compared the electroencephalograms (EEGs) of healthy individuals (27), individuals with mild Alzheimer’s (27), and individuals with moderate cases of the disease (22). He found statistically significant differences across the three groups.
In collaboration with neurologists and Francisco J. Fraga, an INRS visiting professor specializing in biological signals, Professor Falk used an algorithm that dissects brain waves of varying frequencies. “What makes this algorithm innovative is that it characterizes the changes in temporal dynamics of the patients’ brain waves,” explains Professor Falk. “The findings show that healthy individuals have different patterns than those with mild Alzheimer’s disease. We also found a difference between patients with mild levels of the disease and those with moderate Alzheimer’s.”
To validate the model in order to eventually develop an early diagnostic tool for Alzheimer’s disease, Professor Falk’s team is sharing their algorithm on the NeuroAccelerator.org online data analysis portal. It is the first open source algorithm posted on the portal and may be used by researchers around the world to produce additional research findings.
Alzheimer’s disease accounts for 60% to 80% of all dementia cases in North America and is skyrocketing. This step toward the development of an early diagnostic tool that is non-invasive, objective, and relatively inexpensive is therefore welcome news for the research community.
A Major Cause of Age-Related Memory Loss Identified
Study points to possible treatments and confirms distinction between memory loss due to aging and that of Alzheimer’s
A team of Columbia University Medical Center (CUMC) researchers, led by Nobel laureate Eric R. Kandel, MD, has found that deficiency of a protein called RbAp48 in the hippocampus is a significant contributor to age-related memory loss and that this form of memory loss is reversible. The study, conducted in postmortem human brain cells and in mice, also offers the strongest causal evidence that age-related memory loss and Alzheimer’s disease are distinct conditions. The findings were published today in the online edition of Science Translational Medicine.
“Our study provides compelling evidence that age-related memory loss is a syndrome in its own right, apart from Alzheimer’s. In addition to the implications for the study, diagnosis, and treatment of memory disorders, these results have public health consequences,” said Dr. Kandel, who is University Professor & Kavli Professor of Brain Science, co-director of Columbia’s Mortimer B. Zuckerman Mind Brain Behavior Institute, director of the Kavli Institute for Brain Science, and senior investigator, Howard Hughes Medical Institute, at CUMC. Dr. Kandel received a share of the 2000 Nobel Prize in Physiology or Medicine for his discoveries related to the molecular basis of memory.
The hippocampus, a brain region that consists of several interconnected subregions, each with a distinct neuron population, plays a vital role in memory. Studies have shown that Alzheimer’s disease hampers memory by first acting on the entorhinal cortex (EC), a brain region that provides the major input pathways to the hippocampus. It was initially thought that age-related memory loss is an early manifestation of Alzheimer’s, but mounting evidence suggests that it is a distinct process that affects the dentate gyrus (DG), a subregion of the hippocampus that receives direct input from the EC.
“Until now, however, no one has been able to identify specific molecular defects involved in age-related memory loss in humans,” said co-senior author Scott A. Small, MD, the Boris and Rose Katz Professor of Neurology and director of the Alzheimer’s Research Center at CUMC.
The current study was designed to look for more direct evidence that age-related memory loss differs from Alzheimer’s disease. The researchers began by performing microarray (gene expression) analyses of postmortem brain cells from the DG of eight people, ages 33 to 88, all of whom were free of brain disease. The team also analyzed cells from their EC, which served as controls since that brain structure is unaffected by aging. The analyses identified 17 candidate genes that might be related to aging in the DG. The most significant changes occurred in a gene called RbAp48, whoseexpressiondeclined steadily with aging across the study subjects.
To determine whether RbAp48plays an active role in age-related memory loss, the researchers turned to mouse studies. “The first question was whether RbAp48is downregulated in aged mice,” said lead author Elias Pavlopoulos, PhD, associate research scientist in neuroscience at CUMC. “And indeed, that turned out to be the case—there was a reduction of RbAp48 protein in the DG.”
When the researchers genetically inhibited RbAp48inthe brains ofhealthy young mice, they found the same memory loss as in aged mice, as measured by novel object recognition and water maze memory tests. When RbAp48inhibition was turned off, the mice’s memory returned to normal.
The researchers also did functional MRI (fMRI) studies of the mice with inhibited RbAp48 and found a selective effect in the DG, similar to that seen in fMRI studies of aged mice, monkeys, and humans. This effect of RbAp48 inhibition on the DG was accompanied by defects in molecular mechanisms similar to those found in aged mice. The fMRI profile and mechanistic defects of the mice with inhibited RbAp48 returned to normal when the inhibition was turned off.
In another experiment, the researchers used viral gene transfer and increased RbAp48expression inthe DG of aged mice. “We were astonished that not only did this improve the mice’s performance on the memory tests, but their performance was comparable to that of young mice,” said Dr. Pavlopoulos.
“The fact that we were able to reverse age-related memory loss in mice is very encouraging,” said Dr. Kandel. “Of course, it’s possible that other changes in the DG contribute to this form of memory loss. But at the very least, it shows that this protein is a major factor, and it speaks to the fact that age-related memory loss is due to a functional change in neurons of some sort. Unlike with Alzheimer’s, there is no significant loss of neurons.”
Finally, the study data suggest that RbAp48 protein mediates its effects, at least in part, through the PKA-CREB1-CBP pathway, which the team had found in earlier studies to be important for age-related memory loss in the mouse. According to the researchers, RbAp48 and the PKA-CREB1-CBP pathway are valid targets for therapeutic intervention. Agents that enhance this pathway have already been shown to improve age-related hippocampal dysfunction in rodents.
“Whether these compounds will work in humans is not known,” said Dr. Small. “But the broader point is that to develop effective interventions, you first have to find the right target. Now we have a good target, and with the mouse we’ve developed, we have a way to screen therapies that might be effective, be they pharmaceuticals, nutraceuticals, or physical and cognitive exercises.”
“There’s been a lot of handwringing over the failures of drug trials based on findings from mouse models of Alzheimer’s,” Dr. Small said. “But this is different. Alzheimer’s does not occur naturally in the mouse. Here, we’ve caused age-related memory loss in the mouse, and we’ve shown it to be relevant to human aging.”
Study suggests iron is at core of Alzheimer’s disease
Alzheimer’s disease has proven to be a difficult enemy to defeat. After all, aging is the No. 1 risk factor for the disorder, and there’s no stopping that.
Most researchers believe the disease is caused by one of two proteins, one called tau, the other beta-amyloid. As we age, most scientists say, these proteins either disrupt signaling between neurons or simply kill them.
Now, a new UCLA study suggests a third possible cause: iron accumulation.
Dr. George Bartzokis, a professor of psychiatry at the Semel Institute for Neuroscience and Human Behavior at UCLA and senior author of the study, and his colleagues looked at two areas of the brain in patients with Alzheimer’s. They compared the hippocampus, which is known to be damaged early in the disease, and the thalamus, an area that is generally not affected until the late stages. Using sophisticated brain-imaging techniques, they found that iron is increased in the hippocampus and is associated with tissue damage in that area. But increased iron was not found in the thalamus.
The research appears in the August edition of the Journal of Alzheimer’s Disease.
While most Alzheimer’s researchers focus on the buildup of tau or beta-amyloid that results in the signature plaques associated with the disease, Bartzokis has long argued that the breakdown begins much further “upstream.” The destruction of myelin, the fatty tissue that coats nerve fibers in the brain, he says, disrupts communication between neurons and promotes the buildup of the plaques. These amyloid plaques in turn destroy more and more myelin, disrupting brain signaling and leading to cell death and the classic clinical signs of Alzheimer’s.
Myelin is produced by cells called oligodendrocytes. These cells, along with myelin, have the highest levels of iron of any cells in the brain, Bartzokis says, and circumstantial evidence has long supported the possibility that brain iron levels might be a risk factor for age-related diseases like Alzheimer’s. Although iron is essential for cell function, too much of it can promote oxidative damage, to which the brain is especially vulnerable.
In the current study, Bartzokis and his colleagues tested their hypothesis that elevated tissue iron caused the tissue breakdown associated with Alzheimer’s disease. They targeted the vulnerable hippocampus, a key area of the brain involved in the formation of memories, and compared it to the thalamus, which is relatively spared by Alzheimer’s until the very late stages of disease.
The researchers used an MRI technique that can measure the amount of brain iron in ferritin, a protein that stores iron, in 31 patients with Alzheimer’s and 68 healthy control subjects.
In the presence of diseases like Alzheimer’s, as the structure of cells breaks down, the amount of water increases in the brain, which can mask the detection of iron, according to Bartzokis.
"It is difficult to measure iron in tissue when the tissue is already damaged," he said. "But the MRI technology we used in this study allowed us to determine that the increase in iron is occurring together with the tissue damage. We found that the amount of iron is increased in the hippocampus and is associated with tissue damage in patients with Alzheimer’s but not in the healthy older individuals — or in the thalamus. So the results suggest that iron accumulation may indeed contribute to the cause of Alzheimer’s disease."
But it’s not all bad news from this study, Bartzokis noted.
"The accumulation of iron in the brain may be influenced by modifying environmental factors, such as how much red meat and iron dietary supplements we consume and, in women, having hysterectomies before menopause," he said.
In addition, he noted, medications that chelate and remove iron from tissue are being developed by several pharmaceutical companies as treatments for the disorder. This MRI technology may allow doctors to determine who is most in need of such treatments.
(Source: newsroom.ucla.edu)
Brain network decay detected in early Alzheimer’s
In patients with early Alzheimer’s disease, disruptions in brain networks emerge about the same time as chemical markers of the disease appear in the spinal fluid, researchers at Washington University School of Medicine in St. Louis have shown.
While two chemical markers in the spinal fluid are regarded as reliable indicators of early disease, the new study, published in JAMA Neurology, is among the first to show that scans of brain networks may be an equally effective and less invasive way to detect early disease.
“Tracking damage to these brain networks may also help us formulate a more detailed understanding of what happens to the brain before the onset of dementia,” said senior author Beau Ances, MD, PhD, associate professor of neurology and of biomedical engineering.
Diagnosing Alzheimer’s early is a top priority for physicians, many of whom believe that treating patients long before dementia starts greatly improves the chances of success.
Ances and his colleagues studied 207 older but cognitively normal research volunteers at the Charles F. and Joanne Knight Alzheimer’s Disease Research Center at Washington University. Over several years, spinal fluids from the volunteers were sampled multiple times and analyzed for two markers of early Alzheimer’s: changes in amyloid beta, the principal ingredient of Alzheimer’s brain plaques, and in tau protein, a structural component of nerve cells.
The volunteers were also scanned repeatedly using a technique called resting state functional magnetic resonance imaging (fMRI). This scan tracks the rise and fall of blood flow in different brain regions as patients rest in the scanner. Scientists use the resulting data to assess the integrity of the default mode network, a set of connections between different brain regions that becomes active when the mind is at rest.
Earlier studies by Ances and other researchers have shown that Alzheimer’s damages connections in the default mode network and other brain networks.
The new study revealed that this damage became detectable at about the same time that amyloid beta levels began to fall and tau levels started to rise in spinal fluid. The part of the default mode network most harmed by the onset of Alzheimer’s disease was the connection between two brain areas associated with memory, the posterior cingulate and medial temporal regions.
The researchers are continuing to study the connections between brain network damage and the progress of early Alzheimer’s disease in normal volunteers and in patients in the early stages of Alzheimer’s-associated dementia.
(Source: news.wustl.edu)
Copper Identified as Culprit in Alzheimer’s Disease
Copper appears to be one of the main environmental factors that trigger the onset and enhance the progression of Alzheimer’s disease by preventing the clearance and accelerating the accumulation of toxic proteins in the brain. That is the conclusion of a study appearing today in the journal Proceedings of the National Academy of Sciences.
“It is clear that, over time, copper’s cumulative effect is to impair the systems by which amyloid beta is removed from the brain,” said Rashid Deane, Ph.D., a research professor in the University of Rochester Medical Center (URMC) Department of Neurosurgery, member of the Center for Translational Neuromedicine, and the lead author of the study. “This impairment is one of the key factors that cause the protein to accumulate in the brain and form the plaques that are the hallmark of Alzheimer’s disease.”
Copper’s presence in the food supply is ubiquitous. It is found in drinking water carried by copper pipes, nutritional supplements, and in certain foods such as red meats, shellfish, nuts, and many fruits and vegetables. The mineral plays an important and beneficial role in nerve conduction, bone growth, the formation of connective tissue, and hormone secretion.
However, the new study shows that copper can also accumulate in the brain and cause the blood brain barrier – the system that controls what enters and exits the brain – to break down, resulting in the toxic accumulation of the protein amyloid beta, a by-product of cellular activity. Using both mice and human brain cells Deane and his colleagues conducted a series of experiments that have pinpointed the molecular mechanisms by which copper accelerates the pathology of Alzheimer’s disease.
Under normal circumstances, amyloid beta is removed from the brain by a protein called lipoprotein receptor-related protein 1 (LRP1). These proteins – which line the capillaries that supply the brain with blood – bind with the amyloid beta found in the brain tissue and escort them into the blood vessels where they are removed from the brain.
The research team“dosed” normal mice with copper over a three month period. The exposure consisted of trace amounts of the metal in drinking water and was one-tenth of the water quality standards for copper established by the Environmental Protection Agency.
“These are very low levels of copper, equivalent to what people would consume in a normal diet.” said Deane.
The researchers found that the copper made its way into the blood system and accumulated in the vessels that feed blood to the brain, specifically in the cellular “walls” of the capillaries. These cells are a critical part of the brain’s defense system and help regulate the passage of molecules to and from brain tissue. In this instance, the capillary cells prevent the copper from entering the brain. However, over time the metal can accumulate in these cells with toxic effect.
The researchers observed that the copper disrupted the function of LRP1 through a process called oxidation which, in turn, inhibited the removal of amyloid beta from the brain. They observed this phenomenon in both mouse and human brain cells.
The researchers then looked at the impact of copper exposure on mouse models of Alzheimer’s disease. In these mice, the cells that form the blood brain barrier have broken down and become “leaky” – a likely combination of aging and the cumulative effect of toxic assaults – allowing elements such as copper to pass unimpeded into the brain tissue. They observed that the copper stimulated activity in neurons that increased the production of amyloid beta. The copper also interacted with amyloid beta in a manner that caused the proteins to bind together in larger complexes creating logjams of the protein that the brain’s waste disposal system cannot clear.
This one-two punch, inhibiting the clearance and stimulating the production of amyloid beta, provides strong evidence that copper is a key player in Alzheimer’s disease. In addition, the researchers observed that copper provoked inflammation of brain tissue which may further promote the breakdown of the blood brain barrier and the accumulation of Alzheimer’s-related toxins.
However, because metal is essential to so many other functions in the body, the researchers say that these results must be interpreted with caution.
“Copper is an essential metal and it is clear that these effects are due to exposure over a long period of time,” said Deane. “The key will be striking the right balance between too little and too much copper consumption. Right now we cannot say what the right level will be, but diet may ultimately play an important role in regulating this process.”
(Source: urmc.rochester.edu)
A Genetic Answer to the Alzheimer’s Riddle?
What if we could pinpoint a hereditary cause for Alzheimer’s, and intervene to reduce the risk of the disease? We may be closer to that goal, thanks to a team at the University of Kentucky. Researchers affiliated with the UK Sanders-Brown Center on Aging have completed new work in Alzheimer’s genetics; the research is detailed in a paper published today in the Journal of Neuroscience.
Emerging evidence indicates that, much like in the case of high cholesterol, some Alzheimer’s disease risk is inherited while the remainder is environmental. Family and twin studies suggest that about 70 percent of total Alzheimer’s risk is hereditary.
Recently published studies identified several variations in DNA sequence that each modify Alzheimer’s risk. In their work, the UK researchers investigated how one of these sequence variations may act. They found that a “protective” genetic variation near a gene called CD33 correlated strongly with how the CD33 mRNA was assembled in the human brain. The authors found that a form of CD33 that lacked a critical functional domain correlates with reduced risk of Alzheimers disease. CD33 is thought to inhibit clearance of amyloid beta, a hallmark of Alzheimers disease.
The results obtained by the UK scientists indicate that inhibiting CD33 may reduce Alzheimer’s risk. A drug tested for acute myeloid leukemia targets CD33, suggesting the potential for treatments based on CD33 to mitigate the risk for Alzheimer’s disease. Additional studies must be conducted before this treatment approach could be tested in humans.
Study identifies new culprit that may make aging brains susceptible to neurodegenerative diseases
The steady accumulation of a protein in healthy, aging brains may explain seniors’ vulnerability to neurodegenerative disorders, a new study by researchers at the Stanford University School of Medicine reports.
The study’s unexpected findings could fundamentally change the way scientists think about neurodegenerative disease.
The pharmaceutical industry has spent billions of dollars on futile clinical trials directed at treating Alzheimer’s disease by ridding brains of a substance called amyloid plaque. But the new findings have identified another mechanism, involving an entirely different substance, that may lie at the root not only of Alzheimer’s but of many other neurodegenerative disorders — and, perhaps, even the more subtle decline that accompanies normal aging.
The study, published Aug. 14 in the Journal of Neuroscience, reveals that with advancing age, a protein called C1q, well-known as a key initiator of immune response, increasingly lodges at contact points connecting nerve cells in the brain to one another. Elevated C1q concentrations at these contact points, or synapses, may render them prone to catastrophic destruction by brain-dwelling immune cells, triggered when a catalytic event such as brain injury, systemic infection or a series of small strokes unleashes a second set of substances on the synapses.
“No other protein has ever been shown to increase nearly so profoundly with normal brain aging,” said Ben Barres, MD, PhD, professor and chair of neurobiology and senior author of the study. Examinations of mouse and human brain tissue showed as much as a 300-fold age-related buildup of C1q.
The finding was made possible by the diligence and ingenuity of the study’s lead author, Alexander Stephan, PhD, a postdoctoral scholar in Barres’ lab. Stephan screened about 1,000 antibodies before finding one that binds to C1q and nothing else. (Antibodies are proteins, generated by the immune system, that adhere to specific “biochemical shapes,” such as surface features of invading pathogens.)
Comparing brain tissue from mice of varying ages, as well as postmortem samples from a 2-month-old infant and an older person, the researchers showed that these C1q deposits weren’t randomly distributed along nerve cells but, rather, were heavily concentrated at synapses. Analyses of brain slices from mice across a range of ages showed that as the animals age, the deposits spread throughout the brain.
“The first regions of the brain to show a dramatic increase in C1q are places like the hippocampus and substantia nigra, the precise brain regions most vulnerable to neurodegenerative diseases like Alzheimer’s and Parkinson’s disease, respectively,” said Barres. Another region affected early on, the piriform cortex, is associated with the sense of smell, whose loss often heralds the onset of neurodegenerative disease.
Other scientists have observed moderate, age-associated increases (on the order of three- or four-fold) in brain levels of the messenger-RNA molecule responsible for transmitting the genetic instructions for manufacturing C1q to the protein-making machinery in cells. Testing for messenger-RNA levels — typically considered reasonable proxies for how much of a particular protein is being produced — is fast, easy and cheap compared with analyzing proteins.
But in this study, Barres and his colleagues used biochemical measures of the protein itself. “The 300-fold rise in C1q levels we saw in 2-year-old mice — equivalent to 70- or 80-year-old humans — knocked my socks off,” Barres said. “I was not expecting that at all.”
C1q is the first batter on a 20-member team of immune-response-triggering proteins, collectively called the complement system. C1q is capable of clinging to the surface of foreign bodies such as bacteria or to bits of our own dead or dying cells. This initiates a molecular chain reaction known as the complement cascade. One by one, the system’s other proteins glom on, coating the offending cell or piece of debris. This in turn draws the attention of omnivorous immune cells that gobble up the target.
The brain has its own set of immune cells, called microglia, which can secrete C1q. Still other brain cells, called astrocytes, secrete all of C1q’s complement-system “teammates.” The two cell types work analogously to the two tubes of an Epoxy kit, in which one tube contains the resin, the other a catalyst.
Previous work in Barres’ lab has shown that the complement cascade plays a critical role in the developing brain. A young brain generates an excess of synapses, creating a huge range of options for the potential formation of new neural circuits. These synapses strengthen or weaken over time, in response to their heavy use or neglect. The presence of feckless connections contributes noise to the system, so the efficiency of the maturing brain’s architecture is improved if these underused synapses are pruned away.
In a 2007 paper in Cell, Barres’ group reported that the complement system is essential to synaptic pruning in normal, developing brains. Then in 2012, in Neuron, in a collaboration with the lab of Harvard neuroscientist Beth Stevens, PhD, they showed that it is specifically microglia — the brain’s in-house immune cells — that attack and ingest complement-coated synapses.
Barres now believes something similar is happening in the normal, aging brain. C1q, but not the other protein components of the complement system, gradually becomes highly prevalent at synapses. By itself, this C1q buildup doesn’t trigger wholesale synapse loss, the researchers found — although it does seem to impair their performance. Old mice whose capacity to produce C1q had been eliminated performed subtly better on memory and learning tests than normal older mice did.
Still, this leaves the aging brain’s synapses precariously perched on the brink of catastrophe. A subsequent event such as brain trauma, a bad case of pneumonia or perhaps a series of tiny strokes that some older people experience could incite astrocytes — the second tube in the Epoxy kit — to start secreting the other complement-system proteins required for synapse destruction.
Most cells in the body have their own complement-inhibiting agents. This prevents the wholesale loss of healthy tissue during an immune attack on invading pathogens or debris from dead tissue during wound healing. But nerve cells lack their own supply of complement inhibitors. So, when astrocytes get activated, their ensuing release of C1q’s teammates may set off a synapse-destroying rampage that spreads “like a fire burning through the brain,” Barres said.
“Our findings may well explain the long-mysterious vulnerability specifically of the aging brain to neurodegenerative disease,” he said. “Kids don’t get Alzheimer’s or Parkinson’s. Profound activation of the complement cascade, associated with massive synapse loss, is the cardinal feature of Alzheimer’s disease and many other neurodegenerative disorders. People have thought this was because synapse loss triggers inflammation. But our findings here suggest that activation of the complement cascade is driving synapse loss, not the other way around.”
(Source: med.stanford.edu)
Neuroscientists identify protein linked to Alzheimer’s-like afflictions
A team of neuroscientists has identified a modification to a protein in laboratory mice linked to conditions associated with Alzheimer’s Disease. Their findings, which appear in the journal Nature Neuroscience, also point to a potential therapeutic intervention for alleviating memory-related disorders.
The research centered on eukaryotic initiation factor 2 alpha (eIF2alpha) and two enzymes that modify it with a phosphate group; this type of modification is termed phosphorylation. The phosphorylation of eIF2alpha, which decreases protein synthesis, was previously found at elevated levels in both humans diagnosed with Alzheimer’s and in Alzheimer’s Disease (AD) model mice.
"These results implicate the improper regulation of this protein in Alzheimer’s-like afflictions and offer new guidance in developing remedies to address the disease," said Eric Klann, a professor in New York University’s Center for Neural Science and the study’s senior author.
The study’s co-authors also included: Douglas Cavener, a professor of biology at Pennsylvania State University; Clarisse Bourbon, Evelina Gatti, and Philippe Pierre of Université de la Méditerranée in Marseille, France; and NYU researchers Tao Ma, Mimi A. Trinh, and Alyse J. Wexler.
It has been known for decades that triggering new protein synthesis is vital to the formation of long-term memories as well as for long-lasting synaptic plasticity — the ability of the neurons to change the collective strength of their connections with other neurons. Learning and memory are widely believed to result from changes in synaptic strength.
In recent years, researchers have found that both humans with Alzheimer’s Disease and AD model mice have relatively high levels of eIF2alpha phosphorylation. But the relationship between this characteristic and AD-related afflictions was unknown.
Klann and his colleagues hypothesized that abnormally high levels of eIF2alpha phosphorylation could become detrimental because, ultimately, protein synthesis would diminish, thereby undermining the ability to form long-term memories.
To explore this question, the researchers examined the neurological impact of two enzymes that phosphorylate eIF2alpha, kinases termed PERK and GCN2, in different populations of AD model mice — all of which expressed genetic mutations akin to those carried by humans with AD. These were: AD model mice; AD model mice that lacked PERK; and AD model mice that lacked GCN2.
Specifically, they looked at eIF2alpha phosphorylation and the regulation of protein synthesis in the mice’s hippocampus region — the part of the brain responsible for the retrieval of old memories and the encoding of new ones. They then compared these levels with those of postmortem human AD patients.
Here, they found both increased levels of phosphorylated eIF2alpha in the hippocampus of both AD patients and the AD model mice. Moreover, in conjunction with these results, they found decreased protein synthesis, known to be required for long-term potentiation — a form of long-lasting synaptic plasticity—and for long-term memory.
To test potential remedies, the researchers examined phosphorylation of eIF2alpha in mice lacking PERK, hypothesizing that removal of this kinase would return protein synthesis to normal levels. As predicted, mice lacking PERK had levels of phosphorylated eIF2alpha and protein synthesis similar to those of normal mice.
They then conducted spatial memory tests in which the mice needed to navigate a series of mazes. Here, the AD model mice lacking PERK were able to successfully maneuver through the mazes at rates achieved by normal mice. By contrast, the other AD model mice lagged significantly in performing these tasks.
The researchers replicated these procedures on AD model mice lacking GCN2. The results here were consistent with those of the AD model mice lacking PERK, demonstrating that removal of both kinases diminished memory deficits associated with Alzheimer’s Disease.
(Source: eurekalert.org)