Researchers have known for many years that Alzheimer’s disease involves two proteins called amyloid-beta and tau, and that interaction drives the spread of neurodegeneration. What hasn’t been clear is where and how those interactions occur over time as the disease progresses.
In a study published in the journal Neuron, neurologist William Seeley, MD, and his colleagues at UC San Francisco and in South Korea identified two key moments in the natural history of the disease.
The new findings may point to a window of opportunity for treatment with amyloid-lowering drugs like the controversial Adulhelm and similar medications currently in the pipeline. Seeley took some time to tell us about the importance of the recent discovery.
What do we generally know about amyloid-beta and tau play in Alzheimer’s disease?
We know from human neuropathological studies that the tau tangles that cause so much trouble in Alzheimer’s disease are commonly observed in small numbers in the brains of adults by around age 40. This tau, which accumulates in-memory structures initially, exists in a dormant state. Without amyloid-beta, the tau doesn’t spread widely throughout the brain.
If and when amyloid does start to appear, it first accumulates in the neocortex, the parts of the brain that handle cognitive functions like language and visuospatial skills. These regions are some distance from the memory structures where the tau lies dormant. We know that these two proteins interact somehow because the amyloid seems to draw out the tau and encourage its spread. A central mystery is how that interaction happens because it occurs over such a long distance, and it’s arguably one of the most fundamental questions in the field.
What did you learn about this interaction that helps explain how Alzheimer’s unfolds?
We were able to identify two key interactions between amyloid-beta and tau during the course of Alzheimer’s progression based on large, publicly available datasets, which include PET scans for detecting pathological amyloid-beta and tau. Our goal was to determine how the normal architecture of brain connections might facilitate these interactions between tau and amyloid and influence tau spreading.
First, we looked at interactions between amyloid-beta and tau across a distance. Based on what we know about connections between brain parts, we could model the pathways through which these interactions might occur. We found that the earliest of these remote interactions takes place in the entorhinal cortex, the area where tau first appears in the cerebral cortex.
Second, we looked at what happened when the two proteins got close enough to actually co-mingle within a brain region. This type of interaction occurs first in the inferior temporal gyrus, or ITG, which is an essential area for conveying visual information to other parts of the brain.
The ITG appears to act like a big city train station, a transportation hub with dozens of tracks leaving it for other brain regions. Once the two proteins interact locally within this hub, the amyloid seems to catalyze an acceleration phase. The tau leaves the station bound for other areas in the neocortex where amyloid is already accumulating.
Importantly, we were able to replicate all of these key findings in a second, independent dataset, drawn from older persons living in South Korea.
What does this information mean for the future of amyloid-lowering drugs?
Our findings suggest that we need to prescribe amyloid-lowering drugs for people before the two proteins meet at the ITG train station. We hypothesize that if we wait until the trains have left the hub, it will be too late to influence the overall course of the disease. This is the idea we hope to pursue in the next stage of our research.
This work may also help to explain why drugs like aducanumab (Aduhelm) have shown limited benefit in clinical trials. There’s no question that aducanumab and other experimental drugs in its class are lowering amyloid, but benefits have been modest and inconsistent so far. This could be because many patients enrolled in these trials are already past the stage in which tau is explosively propagating. The two key timepoints we identified could serve as a framework for deciding which patients are best for a given clinical trial. If we get better at selecting, we’ll get clearer readouts on efficacy.
What we need now are studies of people in a presymptomatic stage who have amyloid accumulating in the brain to see if treatment during that window is beneficial. The end goal here is secondary prevention. Just like we screen for hypertension and then treat it before it causes heart attacks and strokes, we want to screen for early Alzheimer’s disease and treat it before it causes dementia.
Source: UCSF
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