Microglial lysosomes immune activation and protein turnover.

In addition to its role in protein and organelle homeostasis, lysosomes are also involved in nutrient sensing, cell metabolism, immune response, and programmed cell death.

Lysosomes are heterogeneous subpopulations and their dysfunction has been associated with the pathogenesis of several neurodegenerative diseases.

Although lysosomal biogenesis, transport, and heterogeneity are well studied in neurons, the researchers in this review discuss microglial lysosome biology its regulation, composition, and function, and how these properties are linked to immune activation, aging, and certain disease pathologies. sciencenewshighlights Science Mission https://sciencemission.com/microglial-lysosomes

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Npj Dementia — “Micro-managing” immune activation and protein turnover: microglial lysosomes in the context of health and disease. npj Dement. 2, 35 (2026). https://doi.org/10.1038/s44400-026-00086-8

One possible explanation is that resilient brains are better at repairing themselves during Alzheimer’s. “Perhaps they can add new brain cells to a network that is degenerating”, the author says.

This idea is linked to a process called adult neurogenesis, which refers to the birth of new brain cells (neurons) in the adult brain. It has been well-established in other animals, but its existence in humans has been debated for years.

To study this, the team used human brain tissue from the Netherlands Brain Bank, which collects and stores donated brain samples for research. They included brains from control donors with no brain pathology, Alzheimer’s patients, and individuals with Alzheimer’s pathology who remained resilient to developing dementia.

The team focused on a small part of the brain’s memory center, likely one of the few areas where these new brain cells could form. “These cells are extremely rare, so we had to develop new ways to find them,” the author says. “We really zoomed in on the exact spot where we expected them to be.”

The team found what they were looking for: so-called “immature” neurons. These cells resemble young, not fully developed neurons. “Even at an average age of over 80, we still found these immature neurons in all groups,” the author says.

But the biggest surprise came next. While the team had expected to find much more of these cells in the resilient group than in the Alzheimer’s patients, the difference was not as big as expected.

Surprisingly, the team found that the key difference lies in how the immature neurons behave. “In resilient individuals, these cells seem to activate programs that help them survive and cope with damage,” the author says. “We also see lower signals related to inflammation and cell death.”