Posts tagged amyloid beta
Articles and news from the latest research reports.
Drugs targeting blood vessels may be candidates for treating Alzheimer’s
University of British Columbia researchers have successfully normalized the production of blood vessels in the brain of mice with Alzheimer’s disease (AD) by immunizing them with amyloid beta, a protein widely associated with the disease.
While AD is typically characterized by a build-up of plaques in the brain, recent research by the UBC team showed a near doubling of blood vessels in the brain of mice and humans with AD.
The new study, published online last week in Scientific Reports, a Nature journal, shows a reduction of brain capillaries in mice immunized with amyloid beta – a phenomenon subsequently corroborated by human clinical data – as well as a reduction of plaque build-up.
“The discovery provides further evidence of the role that an overabundance of brain blood vessels plays in AD, as well as the potential efficacy of amyloid beta as basis for an AD vaccine,” says lead investigator Wilfred Jefferies, a professor in UBC’s Michael Smith Laboratories.
“Now that we know blood vessel growth is a factor in AD, if follows that drugs targeting blood vessels may be good candidates as an AD treatment.”
AD accounts for two-thirds of all cases of dementia. The number of Canadians living with dementia is expected to reach 1.4 million by 2013, according to the Alzheimer’s Society of Canada.
New model could lead to improved treatment for early stage Alzheimer’s
Researchers at the University of Florida and The Johns Hopkins University have developed a line of genetically altered mice that model the earliest stages of Alzheimer’s disease. This model may help scientists identify new therapies to provide relief to patients who are beginning to experience symptoms.
The researchers report their findings in the current issue of The Journal of Neuroscience.
“The development of this model could help scientists identify new ways to enhance brain function in patients in the early stages of the disease,” said David Borchelt, UF professor of neuroscience in the Evelyn F. and William L. McKnight Brain Institute and director of the SantaFe HealthCare Alzheimer’s Disease Research Center. “Such therapies could preserve brain function longer and delay the appearance of more severe symptoms that leave patients unable to care for themselves.”
In the early stages of Alzheimer’s disease, people struggle with and fail to learn new games, rules or technologies because their cognitive flexibility decreases. The degenerative disease continues with memory loss and the decline of other brain functions.
The researchers worked with mice that had specially designed gene fragments derived from bacteria and from humans that allowed the investigators to control the production of a small peptide. The peptide, called amyloid beta peptide, is a short chain of amino acids. Accumulations of this particular peptide in the brain as lesions called plaques occur early in the progression of Alzheimer’s disease and seem to trigger the early memory problems.
The team regulated the expression of the peptide using antibiotics — when the animals stopped taking the antibiotic, the peptide-producing gene turned on and caused the mice to develop the plaques found in Alzheimer’s patients. After the mice had developed the Alzheimer pathology, the researchers turned the gene back off and observed that the mice showed persistent memory problems that resemble the early stages of the disease.
“This model may be useful to researchers to test drugs that could help with symptoms of early stage Alzheimer’s disease,” Borchelt said.This research is funded by the National Institute of Neurological Disease and Stroke of the National Institutes of Health, and the SantaFe HealthCare Alzheimer’s Disease Research Center of the University of Florida.
Working with a group from Nagasaki University, a research group at the Center for iPS Cell Research and Application (CiRA) has successfully modeled Alzheimer’s disease (AD) using both familial and sporadic patient-derived induced pluripotent stem cells (iPSCs), and revealed stress phenotypes and differential drug responsiveness associated with intracellular amyloid β oligomers in AD neurons and astrocytes.
In a study published online in Cell Stem Cell, Associate Professor Haruhisa Inoue and his team at CiRA and a research group led by Professor Nobuhisa Iwata of Nagasaki University generated cortical neurons and astrocytes from iPSCs derived from two familial AD patients with mutations in amyloid precursor protein (APP), and two sporadic AD patients. The neural cells from one of the familial and one of the sporadic patients showed endoplasmic reticulum (ER)-stress and oxidative-stress phenotypes associated with intracellular Aβ oligomers. The team also found that these stress phenotypes were attenuated with docosahexaenoic acid (DHA) treatment. These findings may help explain the variable clinical results obtained using DHA treatment, and suggest that DHA may in fact be effective only for a subset of patients.
Using both familial and sporadic AD iPSCs, the researchers discovered that pathogenesis differed between individual AD patients. For example, secreted Aβ42 levels were depressed in familial AD with APP E693Δ mutation, elevated in familial AD with APP V717L mutation, but normal in sporadic AD.
"This shows that patient classification by iPSC technology may contribute to a preemptive therapeutic approach toward AD," said Inoue, a principal investigator at CiRA who is also a research director for the CREST research program funded by the Japan Science and Technology Agency. "Further advances in iPSC technology will be required before large-scale analysis of AD patient-specific iPSCs is possible."
Cigarette smoke damages the lungs, but it also wreaks havoc in the brain, a study in mice suggests. Signs of Alzheimer’s disease increased in the brains of animals that breathed cigarette smoke for four months, scientists report February 19 in Nature Communications.
The relationship between smoking and Alzheimer’s in people is murky. Some evidence from the 1990s suggested that smoking actually protected people against Alzheimer’s, presumably by stimulating nicotine-detecting brain cells. More recent studies have found that smoking ups the odds of the disease.
To see what cigarettes do to the brain, scientists led by Claudio Soto of the University of Texas Medical School at Houston turned to mice. In animals bred to show signs of Alzheimer’s, cigarette smoke (one cigarette’s worth in air the mouse breathed for an hour, five days a week) worsened aspects of the disease. Compared with mice that weren’t exposed, mice exposed to smoke had several signs of Alzheimer’s: they had more amyloid beta plaques, a higher load of abnormal tau protein and more severe inflammation in their brains.
The scientists don’t know yet how cigarette smoke causes these changes, or whether a similar process happens in people.
Type II diabetes and the Alzheimer’s connection
A research team in Israel has devised a novel approach to identifying the molecular basis for designing a drug that might one day decrease the risk diabetes patients face of developing Alzheimer’s disease. The team will present its work at the 57th Annual Meeting of the Biophysical Society (BPS), held Feb. 2-6, 2013, in Philadelphia, Pa.
A recent study suggests that people who suffer from type 2 diabetes face twice the risk of developing Alzheimer’s disease later in life compared to those who do not have diabetes. The link these diseases share relates to the formation of two types of peptide deposits that aggregate, or clump together. Peptides are chains of amino acids; longer chains form proteins. One type of peptide, called amyloid beta, is found in Alzheimer plaques in neurons of the brain. The other type, amylin, is found in the pancreas and the brain. Two years ago, researchers found both molecules in the pancreas of diabetic patients, and in both diseases their presence has been linked to the progression of the disease state.
To explore the hypothesis that interactions between the two molecules might play a critical role in the self-assembly of peptides that leads to protein aggregation, Yifat Miller, assistant professor from Ben-Gurion University of the Negev, Beer-Sheva, Israel, characterized the way the two protein molecules interact with each other through an examination of their structure. It was the first analysis of its kind.
"By identifying the specific ‘hot regions’ of these peptides that strongly interact with each other, our study may provide insight into the link between type 2 diabetes and Alzheimer’s disease," Miller says. "We believe that preventing these interactions by developing a drug will decrease the risk that type 2 diabetes patients face of developing Alzheimer’s disease later life."
(Source: eurekalert.org)
Major step toward an Alzheimer’s vaccine
A team of researchers from Université Laval, CHU de Québec, and pharmaceutical firm GlaxoSmithKline (GSK) has discovered a way to stimulate the brain’s natural defense mechanisms in people with Alzheimer’s disease. This major breakthrough, details of which are presented today in an early online edition of the Proceedings of the National Academy of Sciences (PNAS), opens the door to the development of a treatment for Alzheimer’s disease and a vaccine to prevent the illness.
One of the main characteristics of Alzheimer’s disease is the production in the brain of a toxic molecule known as amyloid beta. Microglial cells, the nervous system’s defenders, are unable to eliminate this substance, which forms deposits called senile plaques.
The team led by Dr. Serge Rivest, professor at Université Laval’s Faculty of Medicine and researcher at the CHU de Québec research center, identified a molecule that stimulates the activity of the brain’s immune cells. The molecule, known as MPL (monophosphoryl lipid A), has been used extensively as a vaccine adjuvant by GSK for many years, and its safety is well established.
In mice with Alzheimer’s symptoms, weekly injections of MPL over a twelve-week period eliminated up to 80% of senile plaques. In addition, tests measuring the mice’s ability to learn new tasks showed significant improvement in cognitive function over the same period.
The researchers see two potential uses for MPL. It could be administered by intramuscular injection to people with Alzheimer’s disease to slow the progression of the illness. It could also be incorporated into a vaccine designed to stimulate the production of antibodies against amyloid beta. “The vaccine could be given to people who already have the disease to stimulate their natural immunity,” said Serge Rivest. “It could also be administered as a preventive measure to people with risk factors for Alzheimer’s disease.”
"When our team started working on Alzheimer’s disease a decade ago, our goal was to develop better treatment for Alzheimer’s patients," explained Professor Rivest. "With the discovery announced today, I think we’re close to our objective."
(Photo: ALAMY)
Clue to Alzheimer’s cause found in brain samples
Researchers at Washington University School of Medicine in St. Louis have found a key difference in the brains of people with Alzheimer’s disease and those who are cognitively normal but still have brain plaques that characterize this type of dementia.
“There is a very interesting group of people whose thinking and memory are normal, even late in life, yet their brains are full of amyloid beta plaques that appear to be identical to what’s seen in Alzheimer’s disease,” says David L. Brody, MD, PhD, associate professor of neurology. “How this can occur is a tantalizing clinical question. It makes it clear that we don’t understand exactly what causes dementia.”
Hard plaques made of a protein called amyloid beta are always present in the brain of a person diagnosed with Alzheimer’s disease, according to Brody. But the simple presence of plaques does not always result in impaired thinking and memory. In other words, the plaques are necessary – but not sufficient – to cause Alzheimer’s dementia.
The new study, available online in Annals of Neurology, still implicates amyloid beta in causing Alzheimer’s dementia, but not necessarily in the form of plaques. Instead, smaller molecules of amyloid beta dissolved in the brain fluid appear more closely correlated with whether a person develops symptoms of dementia. Called amyloid beta “oligomers,” they contain more than a single molecule of amyloid beta but not so many that they form a plaque.
Oligomers floating in brain fluid have long been suspected to have a role in Alzheimer’s disease. But they are difficult to measure. Most methods only detect their presence or absence, or very large quantities. Brody and his colleagues developed a sensitive method to count even small numbers of oligomers in brain fluid and used it to compare amounts in their samples.
The researchers examined samples of brain tissue and fluid from 33 deceased elderly subjects (ages 74 to 107). Ten subjects were normal – no plaques and no dementia. Fourteen had plaques, but no dementia. And nine had a diagnosis of Alzheimer’s disease – both plaques and dementia.
They found that cognitively normal patients with plaques and Alzheimer’s patients both had the same amount of plaque, but the Alzheimer’s patients had much higher oligomer levels.
But even oligomer levels did not completely distinguish the two groups. For example, some people with plaques but without dementia still had oligomers, even in similar quantity to some patients with Alzheimer’s disease. Where the two groups differed completely, according to Brody and his colleagues, was the ratio of oligomers to plaques. They measured more oligomers per plaque in patients with dementia, and fewer oligomers per plaque in the samples from cognitively normal people.
In people with plaques but no dementia, Brody speculates that the plaques could serve as a buffer, binding with free oligomers and keeping them tied down. And in dementia, perhaps the plaques have exceeded their capacity to capture the oligomers, leaving them free to float in the brain’s fluid, where they can damage or interfere with neurons.
Brody cautions that, due to the difficulty in getting samples, oligomer levels have never been measured in living people. Therefore, it’s possible these floating clumps of amyloid beta only form after death. Even so, he says, there is still a clear difference between the two groups.
“The plaques and oligomers appear to be in some kind of equilibrium,” Brody says. “What happens to shift the relationship between the oligomers and plaques? Like much Alzheimer’s research, this study raises more questions than it answers. But it’s an important next piece of the puzzle.”
(Source: news.wustl.edu)