August 4, 2020

Science Daily/Tokyo University of Science

The agglomeration of proteins into structures called amyloid plaques is a common feature of many neurodegenerative diseases, including Alzheimer's. Now, scientists reveal, through experiments and simulations, how resonance with an infrared laser, when it is tuned to a specific frequency, causes amyloid fibrils to disintegrate from the inside out. Their findings open doors to novel therapeutic possibilities for amyloid plaque-related neurodegenerative diseases that have thus far been incurable.

A notable characteristic of several neurodegenerative diseases, such as Alzheimer's and Parkinson's, is the formation of harmful plaques that contain aggregates -- also known as fibrils -- of amyloid proteins. Unfortunately, even after decades of research, getting rid of these plaques has remained a herculean challenge. Thus, the treatment options available to patients with these disorders are limited and not very effective.

In recent years, instead of going down the chemical route using drugs, some scientists have turned to alternative approaches, such as ultrasound, to destroy amyloid fibrils and halt the progression of Alzheimer's disease. Now, a research team led by Dr Takayasu Kawasaki (IR-FEL Research Center, Tokyo University of Science, Japan) and Dr Phuong H. Nguyen (Centre National de la Recherche Scientifique, France), including other researchers from the Aichi Synchrotron Radiation Center and the Synchrotron Radiation Research Center, Nagoya University, Japan, has used novel methods to show how infrared-laser irradiation can destroy amyloid fibrils.

In their study, published in Journal of Physical Chemistry B, the scientists present the results of laser experiments and molecular dynamics simulations. This two-pronged attack on the problem was necessary because of the inherent limitations of each approach, as Dr Kawasaki explains, "While laser experiments coupled with various microscopy methods can provide information about the morphology and structural evolution of amyloid fibrils after laser irradiation, these experiments have limited spatial and temporal resolutions, thus preventing a full understanding of the underlying molecular mechanisms. On the other hand, though this information can be obtained from molecular simulations, the laser intensity and irradiation time used in simulations are very different from those used in actual experiments. It is therefore important to determine whether the process of laser-induced fibril dissociation obtained through experiments and simulations is similar."

The scientists used a portion of a yeast protein that is known to form amyloid fibrils on its own. In their laser experiments, they tuned the frequency of an infrared laser beam to that of the "amide I band" of the fibril, creating resonance. Scanning electron microscopy images confirmed that the amyloid fibrils disassembled upon laser irradiation at the resonance frequency, and a combination of spectroscopy techniques revealed details about the final structure after fibril dissociation.

For the simulations, the researchers employed a technique that a few members of the current team had previously developed, called "nonequilibrium molecular dynamics (NEMD) simulations." Its results corroborated those of the experiment and additionally clarified the entire amyloid dissociation process down to very specific details. Through the simulations, the scientists observed that the process begins at the core of the fibril where the resonance breaks intermolecular hydrogen bonds and thus separates the proteins in the aggregate. The disruption to this structure then spreads outward to the extremities of the fibril.

Together, the experiment and simulation make a good case for a novel treatment possibility for neurodegenerative disorders. Dr Kawasaki remarks, "In view of the inability of existing drugs to slow or reverse the cognitive impairment in Alzheimer's disease, developing non-pharmaceutical approaches is very desirable. The ability to use infrared lasers to dissociate amyloid fibrils opens up a promising approach."

The team's long-term goal is to establish a framework combining laser experiments with NEMD simulations to study the process of fibril dissociation in even more detail, and new works are already underway. All these efforts will hopefully light a beacon of hope for those dealing with Alzheimer's or other neurodegenerative diseases.

https://www.sciencedaily.com/releases/2020/08/200804111501.htm

Researchers' findings show that may be the case

January 25, 2020

Science Daily/McGill University

In a new study, a team of researchers has shown that, when given in a formulation that facilitates passage to the brain, lithium in doses up to 400 times lower than what is currently being prescribed for mood disorders is capable of both halting signs of advanced Alzheimer's pathology and of recovering lost cognitive abilities.

There remains a controversy in scientific circles today regarding the value of lithium therapy in treating Alzheimer's disease. Much of this stems from the fact that because the information gathered to date has been obtained using a multitude of differential approaches, conditions, formulations, timing and dosages of treatment, results are difficult to compare. In addition, continued treatments with high dosage of lithium render a number of serious adverse effects making this approach impracticable for long term treatments especially in the elderly.

In a new study, however, a team of researchers at McGill University led by Dr. Claudio Cuello of the Department of Pharmacology and Therapeutics, has shown that, when given in a formulation that facilitates passage to the brain, lithium in doses up to 400 times lower than what is currently being prescribed for mood disorders is capable of both halting signs of advanced Alzheimer's pathology such as amyloid plaques and of recovering lost cognitive abilities. The findings are published in the most recent edition of the Journal of Alzheimer's Disease.

Building on their previous work

"The recruitment of Edward Wilson, a graduate student with a solid background in psychology, made all the difference," explains Dr. Cuello, the study's senior author, reflecting on the origins of this work. With Wilson, they first investigated the conventional lithium formulation and applied it initially in rats at a dosage similar to that used in clinical practice for mood disorders. The results of the initial tentative studies with conventional lithium formulations and dosage were disappointing however, as the rats rapidly displayed a number of adverse effects. The research avenue was interrupted but renewed when an encapsulated lithium formulation was identified that was reported to have some beneficial effects in a Huntington disease mouse model.

The new lithium formulation was then applied to a rat transgenic model expressing human mutated proteins causative of Alzheimer's, an animal model they had created and characterized. This rat develops features of the human Alzheimer's disease, including a progressive accumulation of amyloid plaques in the brain and concurrent cognitive deficits.

"Microdoses of lithium at concentrations hundreds of times lower than applied in the clinic for mood disorders were administered at early amyloid pathology stages in the Alzheimer's-like transgenic rat. These results were remarkably positive and were published in 2017 in Translational Psychiatry and they stimulated us to continue working with this approach on a more advanced pathology," notes Dr. Cuello.

Encouraged by these earlier results, the researchers set out to apply the same lithium formulation at later stages of the disease to their transgenic rat modelling neuropathological aspects of Alzheimer's disease. This study found that beneficial outcomes in diminishing pathology and improving cognition can also be achieved at more advanced stages, akin to late preclinical stages of the disease, when amyloid plaques are already present in the brain and when cognition starts to decline.

"From a practical point of view our findings show that microdoses of lithium in formulations such as the one we used, which facilitates passage to the brain through the brain-blood barrier while minimizing levels of lithium in the blood, sparing individuals from adverse effects, should find immediate therapeutic applications," says Dr. Cuello. "While it is unlikely that any medication will revert the irreversible brain damage at the clinical stages of Alzheimer's it is very likely that a treatment with microdoses of encapsulated lithium should have tangible beneficial effects at early, preclinical stages of the disease."

Moving forward

Dr. Cuello sees two avenues to build further on these most recent findings. The first involves investigating combination therapies using this lithium formulation in concert with other interesting drug candidates. To that end he is pursuing opportunities working with Dr. Sonia Do Carmo, the Charles E. Frosst-Merck Research Associate in his lab.

He also believes that there is an excellent opportunity to launch initial clinical trials of this formulation with populations with detectable preclinical Alzheimer's pathology or with populations genetically predisposed to Alzheimer's, such as adult individuals with Down Syndrome. While many pharmaceutical companies have moved away from these types of trials, Dr. Cuello is hopeful of finding industrial or financial partners to make this happen, and, ultimately, provide a glimmer of hope for an effective treatment for those suffering from Alzheimer's disease.

https://www.sciencedaily.com/releases/2020/01/200125090727.htm

Tau PET brain imaging could launch precision medicine era for Alzheimer's disease

January 1, 2020

Science Daily/University of California - San Francisco

The results support researchers' growing recognition that tau drives brain degeneration in Alzheimer's disease more directly than amyloid protein, and at the same time demonstrates the potential of recently developed tau-based PET (positron emission tomography) brain imaging technology to accelerate Alzheimer's clinical trials and improve individualized patient care.

Brain imaging of pathological tau-protein "tangles" reliably predicts the location of future brain atrophy in Alzheimer's patients a year or more in advance, according to a new study by scientists at the UC San Francisco Memory and Aging Center. In contrast, the location of amyloid "plaques," which have been the focus of Alzheimer's research and drug development for decades, was found to be of little utility in predicting how damage would unfold as the disease progressed.

The results, published January 1, 2020 in Science Translational Medicine, support researchers' growing recognition that tau drives brain degeneration in Alzheimer's disease more directly than amyloid protein, and at the same time demonstrates the potential of recently developed tau-based PET (positron emission tomography) brain imaging technology to accelerate Alzheimer's clinical trials and improve individualized patient care.

"The match between the spread of tau and what happened to the brain in the following year was really striking," said neurologist Gil Rabinovici, MD, the Edward Fein and Pearl Landrith Distinguished Professor in Memory and Aging and leader of the PET imaging program at the UCSF Memory and Aging Center. "Tau PET imaging predicted not only how much atrophy we would see, but also where it would happen. These predictions were much more powerful than anything we've been able to do with other imaging tools, and add to evidence that tau is a major driver of the disease."

Interest in Tau Growing as Amyloid-Based Therapies Stumble

Alzheimer's researchers have long debated the relative importance of amyloid plaques and tau tangles -- two kinds of misfolded protein clusters seen in postmortem studies of patients' brains, both first identified by Alois Alzheimer in the early 20th century. For decades, the "amyloid camp" has dominated, leading to multiple high-profile efforts to slow Alzheimer's with amyloid-targeting drugs, all with disappointing or mixed results.

Many researchers are now taking a second look at tau protein, once dismissed as simply a "tombstone" marking dying cells, and investigating whether tau may in fact be an important biological driver of the disease. In contrast to amyloid, which accumulates widely across the brain, sometimes even in people with no symptoms, autopsies of Alzheimer's patients have revealed that tau is concentrated precisely where brain atrophy is most severe, and in locations that help explain differences in patients' symptoms (in language-related areas vs. memory-related regions, for example).

"No one doubts that amyloid plays a role in Alzheimer's disease, but more and more tau findings are beginning to shift how people think about what is actually driving the disease," explained Renaud La Joie, PhD, a postdoctoral researcher in Rabinovici's In Vivo Molecular Neuroimaging Lab, and lead author of the new study. "Still, just looking at postmortem brain tissue, it has been hard to prove that tau tangles cause brain degeneration and not the other way around. One of our group's key goals has been to develop non-invasive brain imaging tools that would let us see whether the location of tau buildup early in the disease predicts later brain degeneration."

Tau PET Scans Predict Locations of Future Brain Atrophy in Individual Patients

Despite early misgivings that tau might be impossible to measure in the living brain, scientists recently developed an injectable molecule called flortaucipir -- currently under review by the FDA -- which binds to misfolded tau in the brain and emits a mild radioactive signal that can be picked up by PET scans.

Rabinovici and collaborator William Jagust, MD, of UC Berkeley and Lawrence Berkeley National Laboratory, have been among the first to adopt tau PET imaging to study the distribution of tau tangles in the normally aging brain and in a smaller cross-sectional study of Alzheimer's patients. Their new study represents the first attempt to test whether tau levels in Alzheimer's patients can predict future brain degeneration.

La Joie recruited 32 participants with early clinical stage Alzheimer's disease through the UCSF Memory and Aging Center, all of whom received PET scans using two different tracers to measure levels of amyloid protein and tau protein in their brains. The participants also received MRI scans to measure their brain's structural integrity, both at the start of the study, and again in follow-up visits one to two years later.

The researchers found that overall tau levels in participants' brains at the start of the study predicted how much degeneration would occur by the time of their follow up visit (on average 15 months later). Moreover, local patterns of tau buildup predicted subsequent atrophy in the same locations with more than 40 percent accuracy. In contrast, baseline amyloid-PET scans correctly predicted only 3 percent of future brain degeneration.

"Seeing that tau buildup predicts where degeneration will occur supports our hypothesis that tau is a key driver of neurodegeneration in Alzheimer's disease," La Joie said.

Notably, PET scans revealed that younger study participants had higher overall levels of tau in their brains, as well as a stronger link between baseline tau and subsequent brain atrophy, compared to older participants. This suggests that other factors -- likely other abnormal proteins or vascular injuries -- may play a larger role in late-onset Alzheimer's, the researchers say.

Ability to Predict Brain Atrophy a 'Valuable Precision Medicine Tool'

The results add to hopes that tau-targeting drugs currently under study at the UCSF Memory and Aging Center and elsewhere may provide clinical benefits to patients by blocking this key driver of neurodegeneration in the disease. At the same time, the ability to use tau PET to predict later brain degeneration could enable more personalized dementia care and speed ongoing clinical trials, the authors say.

"One of the first things people want to know when they hear a diagnosis of Alzheimer's disease is simply what the future holds for themselves or their loved ones. Will it be a long fading of memory, or a quick decline into dementia? How long will the patient be able to live independently? Will they lose the ability to speak or get around on their own? These are questions we can't currently answer, except in the most general terms," Rabinovici said. "Now, for the first time, this tool could let us give patients a sense of what to expect by revealing the biological process underlying their disease."

Rabinovici and his team also anticipate that the ability to predict future brain atrophy based on tau PET imaging will allow Alzheimer's clinical trials to quickly assess whether an experimental treatment can alter the specific trajectory predicted for an individual patient, which is currently impossible due to the wide variability in how the disease progresses from individual to individual. Such insights could make it possible to adjust dosage or switch to a different experimental compound if the first treatment is not affecting tau levels or altering a patient's predicted trajectory of brain atrophy.

"Tau PET could be an extremely valuable precision medicine tool for future clinical trials," Rabinovici said. "The ability to sensitively track tau accumulation in living patients would for the first time let clinical researchers seek out treatments that can slow down or even prevent the specific pattern of brain atrophy predicted for each patient."

https://www.sciencedaily.com/releases/2020/01/200101144012.htm

October 4, 2019

Science Daily/Picower Institute at MIT

By scanning whole brains of Alzheimer's model mice from an early age, researchers were able to precisely trace the terrible march of amyloid plaques from deep brain structures outward along specific circuits. They also showed that plaque density in a key region in humans scales with disease stage.

Long before symptoms like memory loss even emerge, the underlying pathology of Alzheimer's disease, such as an accumulation of amyloid protein plaques, is well underway in the brain. A longtime goal of the field has been to understand where it starts so that future interventions could begin there. A new study by MIT neuroscientists at The Picower Institute for Learning and Memory could help those efforts by pinpointing the regions with the earliest emergence of amyloid in the brain of a prominent mouse model of the disease. Notably, the study also shows that the degree of amyloid accumulation in one of those same regions of the human brain correlates strongly with the progression of the disease.

"Alzheimer's is a neurodegenerative disease so in the end you can see a lot of neuron loss," said Wen-Chin "Brian" Huang, co-lead author of the study and a postdoc in the lab of co-senior author Li-Huei Tsai, Picower Professor of Neuroscience and director of the Picower Institute. "At that point it would be hard to cure the symptoms. It's really critical to understand what circuits and regions show neuronal dysfunction early in the disease. This will in turn facilitate the development of effective therapeutics."

In addition to Huang, the study's co-lead authors are Rebecca Canter, a former member of the Tsai lab, and Heejin Choi, a former member of the lab of co-senior author Kwanghun Chung, associate professor of chemical engineering and a member of the Picower Institute and the Institute for Medical Engineering and Science.

Tracking plaques

Many research groups have made progress in recent years by tracing amyloid's path in the brain using technologies such as positron emission tomography and by looking at brains post-mortem, but the new study adds substantial new evidence from the 5XFAD mouse model because it presents an unbiased look at the entire brain as early as one month of age. The study reveals that amyloid begins its terrible march in deep brain regions such as the mammillary body, the lateral septum and the subiculum before making its way along specific brain circuits that ultimately lead it to the hippocampus, a key region for memory, and the cortex, a key region for cognition.

The team used SWITCH, a technology developed by Chung, to label amyloid plaques and to clarify the whole brains of 5XFAD mice so that they could be imaged in fine detail at different ages. The team was consistently able to see that plaques first emerged in the deep brain structures and then tracked along circuits such as the Papez memory circuit to spread throughout the brain by 6-12 months (a mouse's lifespan is up to three years).

The findings help to cement an understanding that has been harder to obtain from human brains, Huang said, because post-mortem dissection cannot easily account for how the disease developed over time and PET scans don't offer the kind of resolution the new study provides from the mice.

Key validations

Importantly, the team directly validated a key prediction of their mouse findings in human tissue: If the mammillary body is indeed a very early place that amyloid plaques emerge, then the density of those plaques should increase in proportion with how far advanced the disease is. Sure enough, when the team used SWITCH to examine the mammillary bodies of post-mortem human brains at different stages of the disease, they saw exactly that relationship: The later the stage, the more densely plaque-packed the mammillary body was.

"This suggests that human brain alterations in Alzheimer's disease look similar to what we observe in mouse," the authors wrote. "Thus we propose that amyloid-beta deposits start in susceptible subcortical structures and spread to increasingly complex memory and cognitive networks with age."

The team also performed experiments to determine whether the accumulation of plaques they observed were of real disease-related consequence for neurons in affected regions. One of the hallmarks of Alzheimer's disease is a vicious cycle in which amyloid makes neurons too easily excited and overexcitement causes neurons to produce more amyloid. The team measured the excitability of neurons in the mammillary body of 5XFAD mice and found they were more excitable than otherwise similar mice that did not harbor the 5XFAD set of genetic alterations.

In a preview of a potential future therapeutic strategy, when the researchers used a genetic approach to silence the neurons in the mammillary body of some 5XFAD mice but left neurons in others unaffected, the mice with silenced neurons produced less amyloid.

While the study findings help explain much about how amyloid spreads in the brain over space and time, they also raise new questions, Huang said. How might the mammillary body affect memory and what types of cells are most affected there?

"This study sets a stage for further investigation of how dysfunction in these brain regions and circuits contributes to the symptoms of Alzheimer's disease," he said.

https://www.sciencedaily.com/releases/2019/10/191004074850.htm

Study reveals crucial mechanisms contributing to the disease

July 31, 2019

Science Daily/University of California - Irvine

University of California, Irvine researchers have made it possible to learn how key human brain cells respond to Alzheimer's, vaulting a major obstacle in the quest to understand and one day vanquish it. By developing a way for human brain immune cells known as microglia to grow and function in mice, scientists now have an unprecedented view of crucial mechanisms contributing to the disease.

The team, led by Mathew Blurton-Jones, associate professor of neurobiology & behavior, said the breakthrough also holds promise for investigating many other neurological conditions such as Parkinson's, traumatic brain injury, and stroke. The details of their study have just been published in the journal Neuron.

The scientists dedicated four years to devising the new rodent model, which is considered "chimeric." The word, stemming from the mythical Greek monster Chimera that was part goat, lion and serpent, describes an organism containing at least two different sets of DNA.

To create the specialized mouse, the team generated induced pluripotent stem cells, or iPSCs, using cells donated by adult patients. Once created, iPSCs can be turned into any other type of cell. In this case, the researchers coaxed the iPSCs into becoming young microglia and implanted them into genetically-modified mice. Examining the rodents several months later, the scientists found about 80-percent of the microglia in their brains was human, opening the door for an array of new research.

"Microglia are now seen as having a crucial role in the development and progression of Alzheimer's," said Blurton-Jones. "The functions of our cells are influenced by which genes are turned on or off. Recent research has identified over 40 different genes with links to Alzheimer's and the majority of these are switched on in microglia. However, so far we've only been able to study human microglia at the end stage of Alzheimer's in post-mortem tissues or in petri dishes."

In verifying the chimeric model's effectiveness for these investigations, the team checked how its human microglia reacted to amyloid plaques, protein fragments in the brain that accumulate in people with Alzheimer's. They indeed imitated the expected response by migrating toward the amyloid plaques and surrounding them.

"The human microglia also showed significant genetic differences from the rodent version in their response to the plaques, demonstrating how important it is to study the human form of these cells," Blurton-Jones said.

"This specialized mouse will allow researchers to better mimic the human condition during different phases of Alzheimer's while performing properly-controlled experiments," said Jonathan Hasselmann, one of the two neurobiology & behavior graduate students involved in the study. Understanding the stages of the disease, which according to the Alzheimer's Association can last from two to 20 years, has been among the challenges facing researchers.

Neurobiology & behavior graduate student and study co-author Morgan Coburn said: "In addition to yielding vital information about Alzheimer's, this new chimeric rodent model can show us the role of these important immune cells in brain development and a wide range of neurological disorders."

https://www.sciencedaily.com/releases/2019/07/190731125448.htm

Analysis of genes altered by the disease could provide targets for new treatments

May 1, 2019

Science Daily/Massachusetts Institute of Technology

MIT researchers have performed the first comprehensive analysis of the genes that are expressed in individual brain cells of patients with Alzheimer's disease. The results allowed the team to identify distinctive cellular pathways that are affected in neurons and other types of brain cells.

This analysis could offer many potential new drug targets for Alzheimer's, which afflicts more than 5 million people in the United States.

"This study provides, in my view, the very first map for going after all of the molecular processes that are altered in Alzheimer's disease in every single cell type that we can now reliably characterize," says Manolis Kellis, a professor of computer science and a member of MIT's Computer Science and Artificial Intelligence Laboratory and of the Broad Institute of MIT and Harvard. "It opens up a completely new era for understanding Alzheimer's."

The study revealed that a process called axon myelination is significantly disrupted in patients with Alzheimer's. The researchers also found that the brain cells of men and women vary significantly in how their genes respond to the disease.

Kellis and Li-Huei Tsai, director of MIT's Picower Institute for Learning and Memory, are the senior authors of the study, which appears in the May 1 online edition of Nature. MIT postdocs Hansruedi Mathys and Jose Davila-Velderrain are the lead authors of the paper.

Single-cell analysis

The researchers analyzed postmortem brain samples from 24 people who exhibited high levels of Alzheimer's disease pathology and 24 people of similar age who did not have these signs of disease. All of the subjects were part of the Religious Orders Study, a longitudinal study of aging and Alzheimer's disease. The researchers also had data on the subjects' performance on cognitive tests.

The MIT team performed single-cell RNA sequencing on about 80,000 cells from these subjects. Previous studies of gene expression in Alzheimer's patients have measured overall RNA levels from a section of brain tissue, but these studies don't distinguish between cell types, which can mask changes that occur in less abundant cell types, Tsai says.

"We wanted to know if we could distinguish whether each cell type has differential gene expression patterns between healthy and diseased brain tissue," she says. "This is the power of single-cell-level analysis: You have the resolution to really see the differences among all the different cell types in the brain."

Using the single-cell sequencing approach, the researchers were able to analyze not only the most abundant cell types, which include excitatory and inhibitory neurons, but also rarer, non-neuronal brain cells such as oligodendrocytes, astrocytes, and microglia. The researchers found that each of these cell types showed distinct gene expression differences in Alzheimer's patients.

Some of the most significant changes occurred in genes related to axon regeneration and myelination. Myelin is a fatty sheath that insulates axons, helping them to transmit electrical signals. The researchers found that in the individuals with Alzheimer's, genes related to myelination were affected in both neurons and oligodendrocytes, the cells that produce myelin.

Most of these cell-type-specific changes in gene expression occurred early in the development of the disease. In later stages, the researchers found that most cell types had very similar patterns of gene expression change. Specifically, most brain cells turned up genes related to stress response, programmed cell death, and the cellular machinery required to maintain protein integrity.

Sex differences

The researchers also discovered correlations between gene expression patterns and other measures of Alzheimer's severity such as the level of amyloid plaques and neurofibrillary tangles, as well as cognitive impairments. This allowed them to identify "modules" of genes that appear to be linked to different aspects of the disease.

"To identify these modules, we devised a novel strategy that involves the use of an artificial neural network and which allowed us to learn the sets of genes that are linked to the different aspects of Alzheimer's disease in a completely unbiased, data-driven fashion," Mathys says. "We anticipate that this strategy will be valuable to also identify gene modules associated with other brain disorders."

The most surprising finding, the researchers say, was the discovery of a dramatic difference between brain cells from male and female Alzheimer's patients. They found that excitatory neurons and other brain cells from male patients showed less pronounced gene expression changes in Alzheimer's than cells from female individuals, even though those patients did show similar symptoms, including amyloid plaques and cognitive impairments. By contrast, brain cells from female patients showed dramatically more severe gene-expression changes in Alzheimer's disease, and an expanded set of altered pathways.

"That's when we realized there's something very interesting going on. We were just shocked," Tsai says.

So far, it is unclear why this discrepancy exists. The sex difference was particularly stark in oligodendrocytes, which produce myelin, so the researchers performed an analysis of patients' white matter, which is mainly made up of myelinated axons. Using a set of MRI scans from 500 additional subjects from the Religious Orders Study group, the researchers found that female subjects with severe memory deficits had much more white matter damage than matched male subjects.

More study is needed to determine why men and women respond so differently to Alzheimer's disease, the researchers say, and the findings could have implications for developing and choosing treatments.

"There is mounting clinical and preclinical evidence of a sexual dimorphism in Alzheimer's predisposition, but no underlying mechanisms are known. Our work points to differential cellular processes involving non-neuronal myelinating cells as potentially having a role. It will be key to figure out whether these discrepancies protect or damage the brain cells only in one of the sexes -- and how to balance the response in the desired direction on the other," Davila-Velderrain says.

The researchers are now using mouse and human induced pluripotent stem cell models to further study some of the key cellular pathways that they identified as associated with Alzheimer's in this study, including those involved in myelination. They also plan to perform similar gene expression analyses for other forms of dementia that are related to Alzheimer's, as well as other brain disorders such as schizophrenia, bipolar disorder, psychosis, and diverse dementias. 

https://www.sciencedaily.com/releases/2019/05/190501131400.htm

April 23, 2019

Science Daily/Florida Atlantic University

Worldwide, 50 million people are living with Alzheimer's disease and other dementias. According to the Alzheimer's Association, every 65 seconds someone in the United States develops this disease, which causes problems with memory, thinking and behavior.

It has been more than 100 years since Alois Alzheimer, M.D., a German psychiatrist and neuropathologist, first reported the presence of senile plaques in an Alzheimer's disease patient brain. It led to the discovery of amyloid precursor protein that produces deposits or plaques of amyloid fragments in the brain, the suspected culprit of Alzheimer's disease. Since then, amyloid precursor protein has been extensively studied because of its association with Alzheimer's disease. However, amyloid precursor protein distribution within and on neurons and its function in these cells remain unclear.

A team of neuroscientists led by Florida Atlantic University's Brain Institute sought to answer a fundamental question in their quest to combat Alzheimer's disease -- "Is amyloid precursor protein the mastermind behind Alzheimer's disease or is it just an accomplice?"

Mutations found in amyloid precursor protein have been linked to rare cases of familial Alzheimer's disease. Although scientists have gained a lot knowledge about how this protein turns into amyloid plaques, little is known about its native function in neurons. In the case of more common sporadic Alzheimer's disease, the highest genetic risk factor is a protein that is involved in cholesterol transportation and not this amyloid precursor protein. Moreover, various clinical trials designed to address Alzheimer's disease by minimizing amyloid plaque formation have failed, including one from Biogen announced last month.

In a study published in the journal Neurobiology of Disease, Qi Zhang, Ph.D., senior author, an investigator at the FAU Brain Institute, and an assistant research professor in FAU's Schmidt College of Medicine, along with collaborators from Vanderbilt University, tackle this Alzheimer's disease mystery by devising a multi-functional reporter for amyloid precursor protein and tracking the protein's localization and mobility using quantitative imaging with unprecedented accuracy.

For the study, Zhang and collaborators genetically disrupted the interaction between cholesterol and amyloid precursor protein. Surprisingly, by disengaging the two, they discovered that this manipulation not only disrupts the trafficking of amyloid precursor protein but also messes up cholesterol distribution at the neuronal surface. Neurons with an altered distribution of cholesterol exhibited swollen synapses and fragmented axons and other early signs of neurodegeneration.

"Our study is intriguing because we noticed a peculiar association between amyloid precursor protein and cholesterol that resides in the cell membrane of synapses, which are points of contact among neurons and the biological basis for learning and memory," said Zhang. "Amyloid precursor protein may just be one of the many accomplices partially contributing to cholesterol deficiency. Strangely, the heart and brain seem to meet again in the fight against bad cholesterol."

Given the broad involvement of cholesterol in almost all aspects of neurons' life, Zhang and collaborators have proposed a new theory about the amyloid precursor protein connection in Alzheimer's disease, especially in the surface of those tiny synapses, which triggers neurodegeneration.

"Although still in early stages, this cutting-edge research by Dr. Zhang and his collaborators at Vanderbilt University may have implications for the millions of people at risk for or suffering with Alzheimer's disease," said Randy D. Blakely, Ph.D., executive director of the FAU Brain Institute and a professor of biomedical science in FAU's Schmidt College of Medicine. "The number of people in Florida alone who are age 65 and older with Alzheimer's disease is expected to increase 41.2 percent by 2025 to a projected 720,000, highlighting the urgency of finding a medical breakthrough."

Locally, Alzheimer's disease affects 11.5 percent of Medicare beneficiaries in Palm Beach County and 12.7 percent of Medicare beneficiaries in Broward County (a nearly 18 percent increase over national average).

According to the Alzheimer's Association, Florida is number one in per capita cases of Alzheimer's disease in the U.S.

https://www.sciencedaily.com/releases/2019/04/190423113951.htm