Posts tagged synapses
Articles and news from the latest research reports.
Tiny chip mimics brain, delivers supercomputer speed
Researchers Thursday unveiled a powerful new postage-stamp size chip delivering supercomputer performance using a process that mimics the human brain.
The so-called “neurosynaptic” chip is a breakthrough that opens a wide new range of computing possibilities from self-driving cars to artificial intelligence systems that can installed on a smartphone, the scientists say.
The researchers from IBM, Cornell Tech and collaborators from around the world said they took an entirely new approach in design compared with previous computer architecture, moving toward a system called “cognitive computing.”
"We have taken inspiration from the cerebral cortex to design this chip," said IBM chief scientist for brain-inspired computing, Dharmendra Modha, referring to the command center of the brain.
Study Suggests Disruptive Effects of Anesthesia on Brain Cell Connections Are Temporary
A study of juvenile rat brain cells suggests that the effects of a commonly used anesthetic drug on the connections between brain cells are temporary.
The study, published in this week’s issue of the journal PLOS ONE, was conducted by biologists at the University of California, San Diego and Weill Cornell Medical College in New York in response to concerns, arising from multiple studies on humans over the past decade, that exposing children to general anesthetics may increase their susceptibility to long-term cognitive and behavioral deficits, such as learning disabilities.
An estimated six million children, including 1.5 million infants, undergo surgery in the United States requiring general anesthesia each year and a least two large-scale clinical studies are now underway to determine the potential risks to children and adults.
“Since these procedures are unavoidable in most cases, it’s important to understand the mechanisms associated with the potentially toxic effects of anesthetics on the developing brain, and on the adult brain as well,” said Shelley Halpain, a professor of biology at UC San Diego and the Sanford Consortium for Regenerative Medicine, who co-headed the investigation. “Because the clinical studies haven’t been completed, preclinical studies, such as ours, are needed to define the effects of various anesthetics on brain structure and function.”
“There is concern now about cognitive dysfunction from surgery and anesthesia—how much these effects are either permanent or slowly reversible is very controversial,” said Hugh Hemmings, Jr., chair of anesthesiology at Weill Cornell and the study’s other senior author. “It has been suggested recently that some of the effects of anesthesia may be more lasting than previously thought. It is not clear whether the residual effects after an operation are due to the surgery itself, or the hospitalization and attendant trauma, medications and stress—or a combination of these issues.”
However, he added, “There is evidence that some of the delayed or persistent cognitive effects after surgery are not primarily due to anesthesia itself, but more importantly to brain inflammation resulting from the surgery. But this is not yet clear.”
The team of biologists examined one of the most commonly used general anesthetics, a derivative of ether called “isoflurane” used to maintain anesthesia during surgery.
“Previous studies in cultured neurons and in the intact brains of rodents provided evidence suggesting that exposure to anesthetics might render neurons more susceptible to cell death through a process called ‘apoptosis’,” said Halpain. “While overt cell death could certainly be one way to explain any long-lasting neurocognitive consequences of general anesthesia, we hypothesized that there could be other cellular mechanisms that disrupt neural circuits without inducing cell death per se.”
One such mechanism, she added, is known as “synaptotoxicity.” In this mechanism of neural-circuit disruption, the “synapses,” or junctions between neurons, become weakened or shrink away due to some factor that injures the neurons locally along their axons (the long processes of neurons that transmit signals) and dendrites (the threadlike extensions of neurons that receive nerve signals) without inducing the neurons themselves to die.
In the experiments at UC San Diego headed by Jimcy Platholi, a postdoctoral researcher in Halpain’s lab who is now at Weill Cornell, the scientists used neurons from embryonic rats taken from the hippocampus, a part of the mammalian forebrain essential for encoding newly acquired memories and ensuring that short-term memories are converted into long-term memories. The researchers cultured these brain cells in a laboratory dish for three weeks, allowing the neurons time to mature and to develop a dense network of synaptic connections and “dendritic spines”—specialized structures that protrude from the dendrites and are essential mediators of activity throughout neural networks.
“Evidence from animal studies indicates that new dendritic spines emerge and existing spines expand in size during learning and memory,” explained Halpain. “Therefore, the overall numbers and size of dendritic spines can profoundly impact the strength of neural networks. Since neural network activity underlies all brain function, changes in dendritic spine number and shape can influence cognition and behavior.”
Using neurons in culture, rather than intact animal brains, allowed the biologists to take images of the synapses at high spatial resolution using techniques called fluorescence light microscopy and confocal imaging. They also used time-lapse microscopy to observe structural changes in individual dendritic spines during exposure to isoflurane. Karl Herold, a research associate in the Hemmings laboratory and a co-author of the study, performed some of the image analysis.
“Imaging of human brain synapses at this level of detail is impossible with today’s technology and it remains very challenging even in laboratory rodents,” said Halpain. “It was important that we performed our study using rodent neurons in a culture dish, so that we could really drill down into the subcellular and molecular details of how anesthetics work.”
The researchers wondered whether brief exposure to isoflurane would alter the numbers and size of dendritic spines, so they applied the anesthetic to the cultured rat cells at concentrations and durations (up to 60 minutes) that are frequently used during surgery.
“We observed detectable decreases in dendritic spine numbers and shape within as little as 10 minutes,” said Halpain. “However this spine loss and shrinkage was reversible after the anesthetic was washed out of the culture.”
“Our study was reassuring in the sense that the effects are not irreversible and this fits in with known clinical effects,” said Hemmings. “For the most part, we find that the effects are reversible.”
“We clearly see an effect—a very marked effect on the dendritic spines—from use of this drug that was reversible, suggesting that it is not a toxic effect, but something more relevant to the pharmacological actions of the drug,” he added. “Connecting what we found to the cognitive effects of isoflurane will require much more detailed analysis.”
The team plans to follow up its study with future experiments to probe the molecular mechanisms and long-lasting consequences of isoflurane’s effects on neuron synapses and examine other commonly-used anesthetics for surgery.
Rigid connections: Molecular basis of age-related memory loss explained
From telephone numbers to foreign vocabulary, our brains hold a seemingly endless supply of information. However, as we are getting older, our ability to learn and remember new things declines. A team of scientists around Associate Prof Dr Antonio Del Sol Mesa from the Luxembourg Centre for Systems Biomedicine of the University of Luxembourg and Dr Ronald van Kesteren of the VU University Amsterdam have identified the molecular mechanisms of this cognitive decline using latest high-throughput proteomics and statistical methods.
The results were published this week in the prestigious scientific journal “Molecular and Cellular Proteomics”.
Brain cells undergo chemical and structural changes, when information is written into our memory or recalled afterwards. Particularly, the number and the strength of connections between nerve cells, the so-called synapses, changes. To investigate why learning becomes more difficult even during healthy ageing, the scientists looked at the molecular composition of brain connections in healthy mice of 20 to 100 weeks of age. This corresponds to a period from puberty until retirement in humans. “Amazingly, there was only one group of four proteins of the so-called extracellular matrix which increased strongly with age. The rest stayed more or less the same,” says Prof Dr Antonio del Sol Mesa from the Luxembourg Centre for Systems Biomedicine.
The extracellular matrix is a mesh right at the connections between brain cells. A healthy amount of these proteins ensures a balance between stability and flexibility of synapses and is vital for learning and memory. “An increase of these proteins with age makes the connections between brain cells more rigid which lowers their ability to adapt to new situations. Learning gets difficult, memory slows down,” Dr Ronald van Kesteren of the VU University Amsterdam elaborates.
In addition, the researchers not only looked at the individual molecules but also analysed the whole picture using a systems biology approach. Here they described the interplay between molecules as networks that together tightly control the amount of individual molecules and their interactions. “A healthy network keeps all molecules in the right level for proper functioning. In older mice we found, however, that the overall molecular composition is more variable compared to younger animals. This shows that the network is losing its control and can be more easily disturbed when we age,” Prof Dr Antonio del Sol Mesa explains. According to the researchers this makes the brain more susceptible to diseases.
Hence, this insight into the normal aging process could also help in the future to better understand complex neurodegenerative diseases such as Alzheimer’s and Parkinson’s disease. Chemical compounds that modulate the extracellular matrix might be promising new treatments for learning disorders and memory loss.
How the brain stabilizes its connections in order to learn better
Throughout our lives, our brains adapt to what we learn and memorise. The brain is indeed made up of complex networks of neurons and synapses that are constantly re-configured. However, in order for learning to leave a trace, connections must be stabilized. A team at the University of Geneva (UNIGE) discovered a new cellular mechanism involved in the long-term stabilization of neuron connections, in which non-neuronal cells, called astrocytes, play a role unidentified until now. These results, published in Current Biology, will lead to a better understanding of neurodegenerative and neurodevelopmental diseases.
The central nervous system excitatory synapses – points of contact between neurons that allow them to transmit signals – are highly dynamic structures, which are continuously forming and dissolving. They are surrounded by non-neuronal cells, or glial cells, which include the distinctively star-shaped astrocytes. These cells form complex structures around synapses, and play a role in the transmission of cerebral information which was widely unknown before.
Plasticity and Stability
By increasing neuronal activity through whiskers stimulation of adult mice, the scientists were able to observe, in both the somatosensory cortex and the hippocampus, that this increased neuronal activity provokes an increase in astrocytes movements around synapses. The synapses, surrounded by astrocytes, re-organise their architecture, which protects them and increases their longevity. The team of researchers led by Dominique Muller, Professor in the Department of Fundamental Neuroscience of the Faculty of Medicine at UNIGE, developed new techniques that allowed them to specifically “control” the different synaptic structures, and to show that the phenomenon took place exclusively in the connections between neurons involved in learning. “In summary, the more the astrocytes surround the synapses, the longer the synapses last, thus allowing learning to leave a mark on memory,” explained Yann Bernardinelli, the lead author on this study.
This study identifies a new, two-way interaction between neurons and astrocytes, in which the learning process regulates the structural plasticity of astrocytes, who in turn determine the fate of the synapses. This mechanism indicates that astrocytes apparently play an important role in the processes of learning and memory, which present abnormally in various neurodegenerative and neurodevelopmental diseases, among which Alzheimer’s, autism, or Fragile X syndrome.
This discovery highlights the until now underestimated importance of cells which, despite being non-neuronal, participate in a crucial way in the cerebral mechanisms that allow us to learn and retain memories of what we have learned.
In the brains of all vertebrates, information is transmitted through synapses, a mechanism that allows an electric or chemical signal to be passed from one brain cell to another. Chemical synapses, which are the most abundant type of synapse, can be either excitatory or inhibitory. Synapse formation is crucial for learning, memory, perception and cognition, and the balance between excitatory and inhibitory synapses critical for brain function. For instance, every time we learn something, the new information is transformed into memory through synaptic plasticity, a process in which synapses are strengthened and become more responsive to different stimuli or environmental cues. Synapses may change their shape or function in a matter of seconds or over an entire lifetime. In humans, a number of disorders are associated with dysfunctional synapses, including autism, epilepsy, substance abuse and depression.
Astrocytes, named for their star-like shape, are ubiquitous brain cells known for regulating excitatory synapse formation through cells. Recent studies have shown that astrocytes also play a role in forming inhibitory synapses, but the key players and underlying mechanisms have remained unknown until now.
A new study just published in the journal Glia and available online on July 11th, details the newly discovered mechanism by which astrocytes are involved in inhibitory synapse formation and presents strong evidence that Transforming Growth Factor Beta 1 (TGF β1), a protein produced by many cell types (including astrocytes) is a key player in this process. The team led by Flávia Gomes of the Rio de Janeiro Institute of Biomedical Sciences at the Federal University of Rio de Janeiro investigated the process in both mouse and human tissues, first in test tubes, then in living brain cells.
Previous evidence has shown that TGF β1, a molecule associated with essential functions in nervous system development and repair, modulates other components responsible for normal brain function. In this study, the authors were able to show that TGF β1 triggers N-methyl-D-aspartate receptor (NMDA), a molecule controlling memory formation and maintenance through synaptic plasticity. In the study, the group also shows that TGF β1-induction of inhibitory synapses depends on activation of another molecule - Ca2+/calmodulin-dependent protein kinase II (CaMK2)-, which works as a mediator for learning and memory. “Our study is the first to associate this complex pathway of molecules, of which TGF β1 seems to be a key player, to astrocytes’ ability to modulate inhibitory synapses”, says Flávia Gomes.
The idea that the balance between excitatory and inhibitory inputs depends on astrocyte signals gains strong support with this new study and suggests a pivotal role for astrocytes in the development of neurological disorders involving impaired inhibitory synapse transmission. Knowing the players and mechanisms underlying inhibitory synapses may improve our understanding of synaptic plasticity and cognitive processes and may help develop new drugs for treating these diseases.
Huntington’s Disease Protein Helps Wire the Young Brain
The protein that is mutated in Huntington’s disease is critical for wiring the brain in early life, according to a new Duke University study.
(Image caption: The protein associated with Huntington’s disease, Htt, is critical in early brain development. Brains of 5-week-old mice whose Htt was deleted show signs of cellular stress — reactive astrocytes (green) and microglia (white and red) and faulty connections — in brain circuits that have already been linked to the disease. Credit: Spencer McKinstry)
Huntington’s disease is a progressive neurodegenerative disorder that causes a wide variety of symptoms, such as uncontrolled movements, inability to focus or remember, depression and aggression. By the time these symptoms appear, usually in middle age, the disease has already ravaged the brain.
The new findings, published July 9 in the Journal of Neuroscience, add to growing evidence that Huntington’s and other neurodegenerative disorders, such as Alzheimer’s disease, may take root during development, said lead author Cagla Eroglu, an assistant professor of cell biology in the Duke University Medical School, and member of the Duke Institute for Brain Sciences.
“The study is exciting because it means that, if we understand what these developmental errors are, we may be able to interfere with the first stage of the disease, before it shows itself,” Eroglu said.
Several years ago, Eroglu and her team were looking for molecular players involved in the formation of new connections, or synapses, in early brain development in mice when their studies unexpectedly hit on the huntingtin (Htt) protein, which is present throughout the body and which forms clumps in the brain cells of people with Huntington’s disease.
“(Htt) had been implicated in certain cellular functions and synaptic dysfunction in Huntington’s, but the possibility that Htt is playing a direct role in synapse formation was not explored,” Eroglu said.
To understand the protein’s role as synapses form, the scientists created mice in which Htt is deleted only in the cortex, a part of the brain that is implicated in the disease and that controls perception, memory and thought.
At three weeks of age (roughly similar to the first two years of human life), a time when a mouse begins to take in its surroundings through its eyes and ears, the synapses of the mutant mice formed more rapidly compared with those of healthy mice, the scientists found.
But by five weeks, when some synapses typically strengthen while others weaken in a normal process called pruning, the synapses had completely deteriorated in the mutant mice. In collaboration with another Duke researcher, Henry Yin, an assistant professor in psychology & neuroscience, the team also investigated the changes in synaptic function in these mutant mice and found severe alterations of the synaptic physiology.
Not only did the researchers see faulty circuits in the mice missing cortical Htt, they also saw signs of cellular stress in the brain, in the exact spot within the cortex that projects to the striatum, another brain area targeted by Huntington’s disease in people. “There’s something about that particular circuit that is vulnerable to changes in Htt,” Eroglu said.
The researchers also examined what happens in early brain development in a mouse model of Huntington’s disease. Similar to people with the disease, these animals have one normal copy of the Htt gene, and one mutated copy, which produces a protein that is present in cells but in expanded form.
The researchers found the same pattern: the Huntington’s disease model animals have synapses that initially mature much faster than normal in the cortex and then die off.
The new results also suggest that missing Htt for a prolonged period may not only affect the development but also the maintenance of healthy synapses, Eroglu said.
That’s especially relevant to a current strategy for treating Huntington’s disease: dialing down Htt levels in the brain using gene therapy or small-molecule inhibitors. But it has been a challenge to target the mutated copy of the gene, not the normal copy. Interested in the implications of lowering overall Htt levels, the group plans to delete Htt in the mouse brain later in life and measure the number of its synapses.
Other mouse models of the disease are also likely to have these faulty circuits. “We think this is probably a common thing, but that’s something we’re working on: whether we can detect early signs of faulty connections, correct it before the disease starts, and make these mice better,” Eroglu said.
(Source: today.duke.edu)
Cocoa Extract May Counter Specific Mechanisms of Alzheimer’s Disease
A specific preparation of cocoa-extract called Lavado may reduce damage to nerve pathways seen in Alzheimer’s disease patients’ brains long before they develop symptoms, according to a study conducted at the Icahn School of Medicine at Mount Sinai and published June 20 in the Journal of Alzheimer’s Disease (JAD).
Specifically, the study results, using mice genetically engineered to mimic Alzheimer’s disease, suggest that Lavado cocoa extract prevents the protein β-amyloid- (Aβ) from gradually forming sticky clumps in the brain, which are known to damage nerve cells as Alzheimer’s disease progresses.
Lavado cocoa is primarily composed of polyphenols, antioxidants also found in fruits and vegetables, with past studies suggesting that they prevent degenerative diseases of the brain.
The Mount Sinai study results revolve around synapses, the gaps between nerve cells. Within healthy nerve pathways, each nerve cell sends an electric pulse down itself until it reaches a synapse where it triggers the release of chemicals called neurotransmitters that float across the gap and cause the downstream nerve cell to “fire” and pass on the message.
The disease-causing formation of Aβ oligomers – groups of molecules loosely attracted to each other –build up around synapses. The theory is that these sticky clumps physically interfere with synaptic structures and disrupt mechanisms that maintain memory circuits’ fitness. In addition, Aβ triggers immune inflammatory responses, like an infection, bringing an on a rush of chemicals and cells meant to destroy invaders but that damage our own cells instead.
“Our data suggest that Lavado cocoa extract prevents the abnormal formation of Aβ into clumped oligomeric structures, to prevent synaptic insult and eventually cognitive decline,” says lead investigator Giulio Maria Pasinetti, MD, PhD, Saunders Family Chair and Professor of Neurology at the Icahn School of Medicine at Mount Sinai. “Given that cognitive decline in Alzheimer’s disease is thought to start decades before symptoms appear, we believe our results have broad implications for the prevention of Alzheimer’s disease and dementia.
Evidence in the current study is the first to suggest that adequate quantities of specific cocoa polyphenols in the diet over time may prevent the glomming together of Aβ into oligomers that damage the brain, as a means to prevent Alzheimer’s disease.
The research team led by Dr. Pasinetti tested the effects of extracts from Dutched, Natural, and Lavado cocoa, which contain different levels of polyphenols. Each cocoa type was evaluated for its ability to reduce the formation of Aβ oligomers and to rescue synaptic function. Lavado extract, which has the highest polyphenol content and anti-inflammatory activity among the three, was also the most effective in both reducing formation of Aβ oligomers and reversing damage to synapses in the study mice.
“There have been some inconsistencies in medical literature regarding the potential benefit of cocoa polyphenols on cognitive function,” says Dr. Pasinetti. “Our finding of protection against synaptic deficits by Lavado cocoa extract, but not Dutched cocoa extract, strongly suggests that polyphenols are the active component that rescue synaptic transmission, since much of the polyphenol content is lost by the high alkalinity in the Dutching process.”
Because loss of synaptic function may have a greater role in memory loss than the loss of nerve cells, rescue of synaptic function may serve as a more reliable target for an effective Alzheimer’s disease drug, said Dr. Pasinetti.
The new study provides experimental evidence that Lavado cocoa extract may influence Alzheimer’s disease mechanisms by modifying the physical structure of Aβ oligomers. It also strongly supports further studies to identify the metabolites of Lavado cocoa extract that are active in the brain and identify potential drug targets.
In addition, turning cocoa-based Lavado into a dietary supplement may provide a safe, inexpensive and easily accessible means to prevent Alzheimer’s disease, even in its earliest, asymptomatic stages.
(Source: mountsinai.org)
Neuroscientists explain how mutated X-linked mental retardation protein impairs neuronal function
There are new clues about malfunctions in brain cells that contribute to intellectual disability and possibly other developmental brain disorders.
(Image caption: False color image of a mouse hippocampal neuron (cell
body is at lower right) with branchlike dendrites that provide surfaces at which projections from other neurons can connect, by forming synapses. Van Aelst and colleagues have shown that when the OPHN1 protein is mutated, interfering with its ability to interact with another protein called Homer1b/c, AMPA receptors don’t recycle to the surface at synapses at the rate they normally do. This adversely impacts synaptic plasticity, the process by which neurons adjust the strength of their connections. Such pathology may play a role in X-linked mental retardation.)
Professor Linda Van Aelst of Cold Spring Harbor Laboratory (CSHL) has been scrutinizing how the normal version of a protein called OPHN1 helps enable excitatory nerve transmission in the brain, particularly at nerve-cell docking ports containing AMPA receptors (AMPARs). Her team’s new work, published June 24 in the Journal of Neuroscience, provides new mechanistic insight into how OPHN1 defects can lead to impairments in the maturation and adjustment of synaptic strength of AMPAR-expressing neurons, which are ubiquitous in the brain and respond to the excitatory neurotransmitter glutamate.
Mutations in a gene called oligophrenin-1 (OPHN1) – located on the X chromosome – have previously been linked to X-linked intellectual disability (also known as X-linked mental retardation), a condition that affects boys disproportionately and could account for as much as one-fifth of all intellectual disability among males.
Several different mutations in the OPHN1 gene have been identified to date, all of which perturb nerve cells’ manufacture of OPHN1 protein. Previously, Van Aelst and colleagues demonstrated that OPHN1 has a vital role in synaptic plasticity, the process through which adjacent nerve cells adjust the strength of their connections. Cells in the brain are constantly adjusting connection strength as they respond to streams of stimuli.
The new discovery shows how OPHN1 is involved in the trafficking of AMPARs, an essential feature of plasticity in neurons. Neurons move receptors away from synapses into their interior and then back to the surface of synapses to control connection strength. At the synaptic surface, receptors provide an opportunity for the docking of neurotransmitters, in this case glutamate molecules. After a cell has fired, surface receptors are typically brought back into the interior, where they are recycled for future use.
When OPHN1 is misshapen or missing due to genetic mutation, the CSHL team demonstrated, it can no longer properly perform its role in receptor recycling, thus also impairing neurons’ ability to maintain strong long-term connections with their neighbors, called long-term potentiation.
Van Aelst’s new experiments explain how OPHN1 in complex with another protein called Homer1b/c should normally interact with an area called the endocytic zone (EZ) to provide a pool of AMPARs to be brought to the synapse at a location called the post-synaptic density (PSD). When OPHN1 is mutated, the pool does not form and receptors needed for strengthening synapses are not available. Long-term potentiation is impaired.
“This suggests a previously unknown way in which genetic defects in OPHN1 can lead to dysfunctions in the glutamate system,” says Dr. Van Aelst. “Our earlier studies had already shown that OPHN1 is essential in stabilizing AMPA receptors at the synapse. Together, these two essential roles suggest how defective OPHN1 protein may contribute to pathology that underlies X-linked intellectual disability.”
(Source: cshl.edu)
Stress hormone linked to short-term memory loss as we age
A new study at the University of Iowa reports a potential link between stress hormones and short-term memory loss in older adults.
The study, published in the Journal of Neuroscience, reveals that having high levels of cortisol—a natural hormone in our body whose levels surge when we are stressed—can lead to memory lapses as we age.
Short-term increases in cortisol are critical for survival. They promote coping and help us respond to life’s challenges by making us more alert and able to think on our feet. But abnormally high or prolonged spikes in cortisol—like what happens when we are dealing with long-term stress—can lead to negative consequences that numerous bodies of research have shown to include digestion problems, anxiety, weight gain, and high blood pressure.
In this study, the UI researchers linked elevated amounts of cortisol to the gradual loss of synapses in the prefrontal cortex, the region of the brain that houses short-term memory. Synapses are the connections that help us process, store, and recall information. And when we get older, repeated and long-term exposure to cortisol can cause them to shrink and disappear.
“Stress hormones are one mechanism that we believe leads to weathering of the brain,” says Jason Radley, assistant professor in psychology at the UI and corresponding author on the paper. Like a rock on the shoreline, after years and years it will eventually break down and disappear.
While previous studies have shown cortisol to produce similar effects in other regions of the aging brain, this was the first study to examine its impact on the prefrontal cortex.
And although preliminary, the findings raise the possibility that short-memory decline in aging adults may be slowed or prevented by treatments that decrease levels of cortisol in susceptible individuals, says Radley. That could mean treating people who have naturally high levels of cortisol—such as those who are depressed—or those who experience repeated, long-term stress due to traumatic life events like the death of a loved one.
According to Radley and Rachel Anderson, the paper’s lead author and a second year-graduate student in psychology at the UI, short-term memory lapses related to cortisol start around age 65. That’s about the equivalent of 21 month-old rats, which the pair studied to make their discovery.
The UI scientists compared the elderly rats to four-month old rats, which are roughly the same age as a 20 year-old person. The young and elderly groups were then separated further according to whether the rats had naturally high or naturally low levels of corticosterone—the hormone comparable to cortisol in humans.
The researchers subsequently placed the rats in a T-shaped maze that required them to use their short-term memory. In order to receive a treat, they needed to recall which direction they had turned at the top of the T just 30, 60, or 120 seconds ago and then turn the opposite way each time they ran the maze.
Though memory declined across all groups as the time rats waited before running the maze again increased, older rats with high corticosterone levels consistently performed the worst. They chose the correct direction only 58 percent of the time, compared to their older peers with low corticosterone levels who chose it 80 percent of the time.
When researchers took tissue samples from the rats’ prefrontal cortexes and examined them under a microscope, they found the poor performers had smaller and 20 percent fewer synapses than all other groups, indicating memory loss.
In contrast, older rats with low corticosterone levels showed little memory loss and ran the maze nearly as well as the younger rats, who were not affected by any level of corticosterone—low or high.
Still, researchers say it’s important to remember that stress hormones are only one of a host of factors when it comes to mental decline and memory loss as we age.
How to Erase a Memory – And Restore It
Researchers at the University of California, San Diego School of Medicine have erased and reactivated memories in rats, profoundly altering the animals’ reaction to past events.
The study, published in the June 1 advanced online issue of the journal Nature, is the first to show the ability to selectively remove a memory and predictably reactivate it by stimulating nerves in the brain at frequencies that are known to weaken and strengthen the connections between nerve cells, called synapses.
“We can form a memory, erase that memory and we can reactivate it, at will, by applying a stimulus that selectively strengthens or weakens synaptic connections,” said Roberto Malinow, MD, PhD, professor of neurosciences and senior author of the study.
Scientists optically stimulated a group of nerves in a rat’s brain that had been genetically modified to make them sensitive to light, and simultaneously delivered an electrical shock to the animal’s foot. The rats soon learned to associate the optical nerve stimulation with pain and displayed fear behaviors when these nerves were stimulated.
Analyses showed chemical changes within the optically stimulated nerve synapses, indicative of synaptic strengthening.
In the next stage of the experiment, the research team demonstrated the ability to weaken this circuitry by stimulating the same nerves with a memory-erasing, low-frequency train of optical pulses. These rats subsequently no longer responded to the original nerve stimulation with fear, suggesting the pain-association memory had been erased.
In what may be the study’s most startlingly discovery, scientists found they could re-activate the lost memory by re-stimulating the same nerves with a memory-forming, high-frequency train of optical pulses. These re-conditioned rats once again responded to the original stimulation with fear, even though they had not had their feet re-shocked.
“We can cause an animal to have fear and then not have fear and then to have fear again by stimulating the nerves at frequencies that strengthen or weaken the synapses,” said Sadegh Nabavi, a postdoctoral researcher in the Malinow lab and the study’s lead author.
In terms of potential clinical applications, Malinow, who holds the Shiley Endowed Chair in Alzheimer’s Disease Research in Honor of Dr. Leon Thal, noted that the beta amyloid peptide that accumulates in the brains of people with Alzheimer’s disease weakens synaptic connections in much the same way that low-frequency stimulation erased memories in the rats. “Since our work shows we can reverse the processes that weaken synapses, we could potentially counteract some of the beta amyloid’s effects in Alzheimer’s patients,” he said.