Columbia-led team harnesses two powerful technologies to identify promising targets for diagnosing and treating neurodegenerative diseases

February 6, 2020

Science Daily/The Zuckerman Institute at Columbia University

The protein tau has long been implicated in Alzheimer's and a host of other debilitating brain diseases. But scientists have struggled to understand exactly how tau converts from its normal, functional form into a misfolded, harmful one. Now, researchers at Columbia University's Zuckerman Institute and Mayo Clinic in Florida have used cutting-edge technologies to see tau in unprecedented detail. By analyzing brain tissue from patients, this research team has revealed that modifications to the tau protein may influence the different ways it can misfold in a person's brain cells. These differences are closely linked to the type of neurodegenerative disease that will develop -- and how quickly that disease will spread throughout the brain.

The study, published today in Cell, employed two complementary techniques to map the structure of tau and decipher the effects of additional molecules, called post-translational modifications (PTMs), on its surface. These new structural insights could accelerate the fight against neurodegenerative diseases, by helping researchers identify new biomarkers that detect these disorders before symptoms arise and design new drugs that target specific PTMs, preventing the onset of disease before it wreaks havoc on the brain.

"Tau has long been a protein of significant interest due to its prevalence in disease," said Anthony Fitzpatrick, PhD, a Principal Investigator at Columbia's Mortimer B. Zuckerman Mind Brain Behavior Institute who led the study. "In today's publication, we lay out compelling evidence that PTMs play an important structural role in tauopathies, the collection of neurodegenerative diseases characterized by toxic buildup of misfolded tau."

No two tauopathies are exactly alike. Each affects different parts of the brain -- even different cell types -- which can lead to different symptoms. Alzheimer's, for example, arises in the hippocampus, and so affects memory. Chronic traumatic encephalopathy, a disorder most often seen in survivors of traumatic brain injury, can lead to problems with movement, memory or emotion, depending on which areas of the brain are affected.

Scientists have used traditional imaging techniques to find clues to how tangles of tau, comprised of individual fibers, or filaments, are implicated in these diseases. But painting a complete picture has proven difficult.

"The brains of patients with neurodegenerative diseases are easy to identify: entire sections have been eaten away, replaced by large clumps and tangles of misfolded proteins like tau," said Tamta Arakhamia, an undergraduate at Columbia's School of General Studies, a research assistant in the Fitzpatrick lab and the paper's co-first author. "However, tau filaments are 10,000 times thinner than the width of a human hair, making them extraordinarily difficult to study in detail."

To address this challenge, Dr. Fitzpatrick recently pioneered the use of cryo-electron microscopy, or cryo-EM, to visualize individual tau filaments from diseased human brain tissue. Cryo-EM is a Nobel Prize-winning technology developed, in part, by researchers at Columbia University. Cryo-EM images samples using a beam of electrons and has proven indispensable for investigations into extremely small biological structures. Using cryo-EM, Dr. Fitzpatrick's team has reconstructed the structures of tau filaments, providing new insights into how they form, grow, and spread throughout the brain.

For all its ability to provide highly detailed snapshots of proteins, cryo-EM has limits. To overcome these limits, Dr. Fitzpatrick and his team to paired it with a second technology: mass spectrometry.

"Cryo-EM does not provide a complete picture because it cannot fully recognize the microscopic PTMs on tau's surface," said Christina Lee, an undergraduate student at Columbia College, a research assistant in the Fitzpatrick lab and the paper's co-first author. "But mass spectrometry can pinpoint the chemical composition of PTMs on the surface of tau."

Working with co-corresponding author Leonard Petrucelli, PhD, Ralph B. and Ruth K. Abrams Professor of Neuroscience at Mayo Clinic in Florida, and Nicholas Seyfried, PhD, professor of biochemistry at Emory University School of Medicine, the researchers used cryo-EM and mass spectrometry to analyze the brain tissue from patients diagnosed with two tauopathies: Alzheimer's disease and corticobasal degeneration, or CBD. CBD is a rare but extremely aggressive tauopathy, affecting only one in every 10,000 people. Unlike Alzheimer's, which is thought to arise due to a number of factors including tau, CBD is primarily associated with misbehaving tau proteins.

"Studying a primary tauopathy like CBD helps us to figure out how tau becomes toxic to brain cells," said Dr. Petrucelli. "We hope to extrapolate that knowledge to secondary tauopathies, such as Alzheimer's disease."

The scientists' analysis of brain tissue samples revealed several key insights. Most notably, the researchers found that cross-talk between PTMs on the surface of tau influences the structure of the tau filaments, contributing to differences in tau filaments observed across the various tauopathies -- and even variations from patient to patient.

"Collectively, these results suggest that PTMs may not only be serving as markers on the proteins' surface, but are actually influencing the behavior of tau," said Dr. Fitzpatrick, who is also an assistant professor of biochemistry and molecular biophysics at Columbia's Vagelos College of Physicians and Surgeons.

Moving forward, Dr. Fitzpatrick and his team plan to expand this work to other tauopathies. Today's findings on Alzheimer's and CBD hold immense promise for the field, particularly in the development of new disease models -- such as lab-grown organoids, or mini-brains -- that may serve to accurately recapitulate what is actually happening in the brains of patients.

"Our findings will inspire new approaches for developing diagnostic tools and designing drugs, such as targeting PTM vulnerabilities to slow disease progression," said Dr. Fitzpatrick, who is also a member of Columbia's Taub Institute for Research on Alzheimer's Disease and the Aging Brain. "Neurodegenerative diseases are among the most complex and distressing class of illnesses, but through our work and that of our colleagues and collaborators, we are building a roadmap toward successful diagnostics and therapeutics."

https://www.sciencedaily.com/releases/2020/02/200206144841.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

Study suggests Tau tangles, not amyloid plaques, drive daytime napping that precedes dementia

August 12, 2019

Science Daily/University of California - San Francisco

Researchers and caregivers have noted that excessive daytime napping can develop long before the memory problems associated with Alzheimer's disease begin to unfold. Prior studies have considered this excessive daytime napping to be compensation for poor nighttime sleep caused by Alzheimer's-related disruptions in sleep-promoting brain regions, while others have argued that the sleep problems themselves contribute to the progression of the disease. But now UC San Francisco scientists have provided a striking new biological explanation for this phenomenon, showing instead that Alzheimer's disease directly attacks brain regions responsible for wakefulness during the day.

The new research demonstrates that these brain regions (including the part of the brain impacted by narcolepsy) are among the first casualties of neurodegeneration in Alzheimer's disease, and therefore that excessive daytime napping -- particularly when it occurs in the absence of significant nighttime sleep problems -- could serve as an early warning sign of the disease. In addition, by associating this damage with a protein known as tau, the study adds to evidence that tau contributes more directly to the brain degeneration that drives Alzheimer's symptoms than the more extensively studied amyloid protein.

"Our work shows definitive evidence that the brain areas promoting wakefulness degenerate due to accumulation of tau -- not amyloid protein -- from the very earliest stages of the disease," said study senior author Lea T. Grinberg, MD, PhD, an associate professor of neurology and pathology at the UCSF Memory and Aging Center and a member of the Global Brain Health Institute and UCSF Weill Institute for Neurosciences.

Wakefulness Centers Degenerate in Alzheimer's Brains

In the new study, published August 12, 2019 in Alzheimer's and Dementia, lead author Jun Oh, a Grinberg lab research associate, and colleagues precisely measured Alzheimer's pathology, tau protein levels and neuron numbers in three brain regions involved in promoting wakefuless from 13 deceased Alzheimer's patients and seven healthy control subjects, which were obtained from the UCSF Neurodegenerative Disease Brain Bank.

Compared to healthy brains, Oh and colleagues found that the brains of Alzheimer's patients had significant tau buildup in all three wakefulness-promoting brain centers they studied -- the locus coeruleus (LC), lateral hypothalamic area (LHA), and tuberomammillary nucleus (TMN) -- and that these regions had lost as many as 75 percent of their neurons.

"It's remarkable because it's not just a single brain nucleus that's degenerating, but the whole wakefulness-promoting network," Oh said. "Crucially this means that the brain has no way to compensate because all of these functionally related cell types are being destroyed at the same time."

Oh and colleagues also studied brain samples from seven patients with progressive supranuclear palsy (PSP) and corticobasal disease (CBD), two distinct forms of neurodegenerative dementia caused by tau accumulation. In contrast to the Alzheimer's disease brains, wakefulness-promoting neurons appeared to be spared in the PSP and CBD brains, despite comparable levels of tau buildup in these tissue samples.

"It seems that the wakefulness-promoting network is particularly vulnerable in Alzheimer's disease," Oh said. "Understanding why this is the case is something we need to follow up in future research."

Studies point to role of tau protein in Alzheimer's symptoms

The new results are in line with an earlier study by Grinberg's group which showed that people who died with elevated levels of tau protein in their brainstem -- corresponding to the earliest stages of Alzheimer's disease -- had already begun to experience changes in mood, such as anxiety and depression, as well as increased sleep disturbances.

"Our new evidence for tau-linked degeneration of the brain's wakefulness centers provides a compelling neurobiological explanation for those findings," Grinberg said. "It suggests we need to be much more focused on understanding the early stages of tau accumulation in these brain areas in our ongoing search for Alzheimer's treatments."

These studies add to a growing recognition among some researchers that tau buildup is more closely linked to the actual symptoms of Alzheimer's than the more widely studied amyloid protein, which has so far failed to yield effective Alzheimer's therapies.

For instance, another recent study by the Grinberg lab measured tau buildup in the brains of patients who died with different clinical manifestations of Alzheimer's disease, including variants that involved language impairment or visual problems instead of more typical memory loss. They found that differences in local tau burden in these patients' brains closely matched their symptoms: patients with language impairments had more tau accumulation in language related brain areas than in memory regions, while patients with visual problems had higher tau levels in visual brain areas.

"This research adds to a growing body of work showing that tau burden is likely a direct driver of cognitive decline," Grinberg said.

Increased focus on the role of tau in Alzheimer's suggests that treatments currently in development at UCSF's Memory and Aging Center and elsewhere that directly tackle tau pathology have the potential to improve sleep and other early symptoms of Alzheimer's disease, in addition to holding a key to slowing the progress of the disease overall, the authors say.

https://www.sciencedaily.com/releases/2019/08/190812075523.htm