Percée d’Alzheimer : une nouvelle cible thérapeutique trouvée

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La maladie d’Alzheimer est un trouble cérébral progressif qui affecte la mémoire, la pensée et le comportement. C’est la cause la plus fréquente de démence chez les personnes âgées et se caractérise par la perte de cellules cérébrales et le rétrécissement du tissu cérébral. Selon l’Organisation mondiale de la santé, la maladie d’Alzheimer touche environ 50 millions de personnes dans le monde, et ce nombre devrait tripler d’ici 2050.

Des chercheurs du Centre allemand pour les maladies neurodégénératives (DZNE) ont découvert que la protéine médine co-agrégée avec l’amyloïde-β dans les vaisseaux sanguins du cerveau de

La maladie d’Alzheimer est une maladie qui attaque le cerveau, provoquant une diminution et une détérioration de la capacité mentale avec le temps. Il s’agit de la forme de démence la plus courante et représente 60 à 80 % des cas de démence. Il n’existe actuellement aucun remède contre la maladie d’Alzheimer, mais il existe des médicaments qui peuvent soulager les symptômes.

 » data-gt-translate-attributes= »[{ » attribute= » »>Alzheimer’s patients. Their findings were recently published in the prestigious journal Nature.

“Medin has been known for over 20 years, but its influence on diseases was previously underestimated. We were able to show that pathological changes in the blood vessels of Alzheimer’s patients are significantly enhanced by medin,” says Dr. Jonas Neher from the Tübingen site of the DZNE, who led the study.

The Hertie Institute for Clinical Brain Research in Tübingen, the University of Tübingen, and various international institutions and partners were also involved in this long-term project.

Medin belongs to the group of amyloids. Of these proteins, amyloid-β is best known because it clumps together in the brains of Alzheimer’s patients. These aggregates then deposit both as so-called plaques directly in the brain tissue, but also in its blood vessels, thereby damaging the nerve cells and the blood vessels, respectively. But while many studies have focused on amyloid-β, medin has not been a focus of interest. “There was little evidence of pathology, that is, of a clinically striking finding associated with medin – and that is often the prerequisite for a more in-depth study of an amyloid,” Jonas Neher explains.

However, medin is actually found in the blood vessels of almost everybody over 50 years of age, making it the most common amyloid known. With his team, Jonas Neher originally found that medin even develops in aging mice, and reported this discovery two years ago in the scientific journal PNAS. The older the mice get, the more medin accumulates in the blood vessels of their brains, was the finding at the time. What’s more, when the brain becomes active and triggers an increase in blood supply, vessels with medin deposits expand more slowly than those without medin. This ability of blood vessels to expand, however, is important to optimally supply the brain with oxygen and nutrients.

For their latest results, the researchers built on this foundation and looked specifically at Alzheimer’s disease. First, they were able to show in Alzheimer’s mouse models that medin accumulates even more strongly in the brain’s blood vessels if amyloid-β deposits are also present. Importantly, these findings were confirmed when brain tissue from organ donors with Alzheimer’s dementia was analyzed. However, when mice were genetically modified to prevent medin formation, significantly fewer amyloid-β deposits developed, and as a result, less damage to blood vessels occurred.

“There are only a handful of research groups worldwide working on medin at all,” says Jonas Neher. Most recently, a study from the U.S. reported that medin levels may increase in Alzheimer’s patients. However, it remained unclear whether this increase is merely a consequence of the disease or whether it is one of the causes.

“We have now been able to show through many experiments that medin actually promotes vascular pathology in Alzheimer’s models,” Neher said. So medin deposits are indeed a cause of blood vessel damage. “And this indicates that medin is one of the causes of the disease,” Neher said.

In their studies, the researchers stained tissue sections from both mice and Alzheimer’s patients in such a way that specific proteins become visible. This allowed them to show that medin and amyloid-β are deposited together in blood vessels of the brain – co-localization is the technical term for this. In the next step, they were able to prove that these two amyloids also co-aggregate – that is, form mixed deposits.

“Amazingly, medin interacts directly with amyloid-β and promotes its aggregation – this was completely unknown,” Jonas Neher summarizes the results.

It is precisely from this insight that the researchers draw hope for the development of a new treatment. “Medin could be a therapeutic target to prevent vascular damage and cognitive decline resulting from amyloid accumulation in the blood vessels of the brain,” they conclude. It is undisputed among experts that in addition to amyloid-β aggregates in brain tissue, the development of Alzheimer’s disease is also promoted by vascular alterations – that is, reduced function or damage to blood vessels. Therefore, treatments that target not only plaques but also affected blood vessels could help patients.

Next, it will now be necessary to determine if medin aggregates can be removed therapeutically and whether this intervention actually has an effect on cognitive performance. The scientists first want to test this in mouse models, because these reflect the pathological changes in Alzheimer’s patients very well.

Reference: “Medin co-aggregates with vascular amyloid-β in Alzheimer’s disease” by Jessica Wagner, Karoline Degenhardt, Marleen Veit, Nikolaos Louros, Katerina Konstantoulea, Angelos Skodras, Katleen Wild, Ping Liu, Ulrike Obermüller, Vikas Bansal, Anupriya Dalmia, Lisa M. Häsler, Marius Lambert, Matthias De Vleeschouwer, Hannah A. Davies, Jillian Madine, Deborah Kronenberg-Versteeg, Regina Feederle, Domenico Del Turco, K. Peter R. Nilsson, Tammaryn Lashley, Thomas Deller, Marla Gearing, Lary C. Walker, Peter Heutink, Frederic Rousseau, Joost Schymkowitz, Mathias Jucker and Jonas J. Neher, 16 November 2022, Nature.
DOI: 10.1038/s41586-022-05440-3

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