Mutation in Brain’s Immune Cells Linked to Alzheimer’s Risk

Summary: A genetic mutation affecting microglia, the brain’s immune cells, can increase the risk of Alzheimer’s disease up to threefold.

The mutation, known as TREM2 R47H/+, impairs microglia function and contributes to Alzheimer’s pathology. It causes inflammation, reduces debris clearance, impairs response to neuronal injury, and leads to excessive synapse pruning.

The study highlights the complex impact of this mutation, offering insights for potential therapeutic interventions in Alzheimer’s disease.

Key Facts:

  1. TREM2 R47H/+ mutation increases the risk of Alzheimer’s disease by affecting microglia function.
  2. Mutant microglia exhibit increased inflammation, reduced debris clearance, and impaired response to neuronal injury.
  3. The study provides new insights into the molecular mechanisms underlying microglial dysfunction and potential therapeutic targets.

Source: MIT

A rare but potent genetic mutation that alters a protein in the brain’s immune cells, known as microglia, can give people as much as a three-fold greater risk of developing Alzheimer’s disease.

A new study by researchers in The Picower Institute for Learning and Memory at MIT details how the mutation undermines microglia function, explaining how it seems to generate that higher risk.

The study is not the first to ask how the TREM2 R47H/+ mutation contributes to Alzheimer’s, but it may advance scientists’ emerging understanding, Penney said. Credit: Neuroscience News

“This TREM2 R47H/+ mutation is a pretty important risk factor for Alzheimer’s disease,” said study lead author Jay Penney, a former postdoc in the MIT lab of Picower Professor Li-Huei Tsai. Penney is now an incoming assistant professor at the University of Prince Edward Island.

“This study adds clear evidence that microglia dysfunction contributes to Alzheimer’s disease risk.”

In the study in the journal GLIA, Tsai and Penney’s team shows that human microglia with the R47H/+ mutation in the TREM2 protein exhibit several deficits related to Alzheimer’s pathology. Mutant microglia are prone to inflammation yet are worse at responding to neuron injury and less able to clear harmful debris including the Alzheimer’s hallmark protein amyloid beta.

When the scientists transferred TREM2 mutant human microglia into the brains of mice, the mice suffered a significant decline in the number of synapses, or connections between their neurons, which can impair the circuits that enable brain functions such as memory.

The study is not the first to ask how the TREM2 R47H/+ mutation contributes to Alzheimer’s, but it may advance scientists’ emerging understanding, Penney said. Early studies suggested that the mutation simply robbed the protein of its function, but the new evidence paints a deeper and more nuanced picture.

While the microglia do exhibit reduced debris clearance and injury response, they become overactive in other ways, such as their overzealous inflammation and synapse pruning.

“There is a partial loss of function but also a gain of function for certain things,” Penney said.

Misbehaving microglia

Rather than rely on mouse models of TREM2 R47H/+ mutation, Penney, Tsai and their co-authors focused their work on human microglia cell cultures. To do this they used a stem cell line derived from skin cells donated by a healthy 75-year-old woman.

In some of the stem cells they then used CRISPR gene editing to insert the R47H/+ mutation and then cultured both edited and unedited stem cells to become microglia. This strategy gave them a supply of mutated microglia and healthy microglia, to act as experimental controls, that were otherwise genetically identical.

The team then looked to see how harboring the mutation affected each cell line’s expression of its genes. The scientists measured more than 1,000 differences but an especially noticeable finding was that microglia with the mutation increased their expression of genes associated with inflammation and immune responses.

Then, when they exposed microglia in culture to chemicals that simulate infection, the mutant microglia demonstrated a significantly more pronounced response than normal microglia, suggesting that the mutation makes microglia much more inflammation-prone.

In further experiments with the cells, the team exposed them to three kinds of the debris microglia typically clear away in the brain: myelin, synaptic proteins and amyloid beta. The mutant microglia cleared less than the healthy ones.

Another job of microglia is to respond when cells, such as neurons, are injured. Penney and Tsai’s team co-cultured microglia and neurons and then zapped the neurons with a laser.

For the next 90 minutes after the injury the team tracked the movement of surrounding microglia. Compared to normal microglia, those with the mutation proved less likely to head toward the injured cell.

Finally, to test how the mutant microglia act in a living brain, the scientists transplanted mutant or healthy control microglia into mice in a memory-focused region of the brain called the hippocampus. The scientists then stained that region to highlight various proteins of interest.

Having mutant or normal human microglia didn’t matter for some measures, but proteins associated with synapses were greatly reduced in mice where the mutated microglia were implanted.

By combining evidence from the gene expression measurements and the evidence from microglia function experiments, the researchers were able to formulate new ideas about what drives at least some of the microglial misbehavior. For instance, Penney and Tsai’s team noticed a decline in the expression of a “purinergic” receptor protein involving sensing neuronal injury perhaps explaining why mutant microglia struggled with that task.

They also noted that mice with the mutation overexpressed “complement” proteins used to tag synapses for removal. That might explain why mutant microglia were overzealous about clearing away synapses in the mice, Penney said, though increased inflammation might also cause that by harming neurons overall.

As the molecular mechanisms underlying microglial dysfunction become clearer, Penney said, drug developers will gain critical insights into ways to target the higher disease risk associated with the TREM2 R47H/+ mutation.

“Our findings highlight multiple effects of the TREM2 R47H/+ mutation likely to underlie its association with Alzheimer’s disease risk and suggest new nodes that could be exploited for therapeutic intervention,” the authors conclude.

In addition to Penney and Tsai, the paper’s other authors are William Ralvenius, Anjanet Loon, Oyku Cerit, Vishnu Dileep, Blerta Milo, Ping-Chieh Pao, and Hannah Woolf.

Funding: The Robert A. and Renee Belfer Family Foundation, The Cure Alzheimer’s Fund, the National Institutes of Health, The JPB Foundation, The Picower Institute for Learning and Memory and the Human Frontier Science Program provided funding for the study.

About this genetics and Alzheimer’s disease research news

Author: David Orenstein
Source: MIT
Contact: David Orenstein – MIT
Image: The image is credited to Neuroscience News

Original Research: Open access.
iPSC-derived microglia carrying the TREM2 R47H/+ mutation are proinflammatory and promote synapse loss” by Jay Penney et al. Glia


Abstract

iPSC-derived microglia carrying the TREM2 R47H/+ mutation are proinflammatory and promote synapse loss

Genetic findings have highlighted key roles for microglia in the pathology of neurodegenerative conditions such as Alzheimer’s disease (AD). A number of mutations in the microglial protein triggering receptor expressed on myeloid cells 2 (TREM2) have been associated with increased risk for developing AD, most notably the R47H/+ substitution.

We employed gene editing and stem cell models to gain insight into the effects of the TREM2 R47H/+ mutation on human-induced pluripotent stem cell-derived microglia. We found transcriptional changes affecting numerous cellular processes, with R47H/+ cells exhibiting a proinflammatory gene expression signature.

TREM2 R47H/+ also caused impairments in microglial movement and the uptake of multiple substrates, as well as rendering microglia hyperresponsive to inflammatory stimuli. We developed an in vitro laser-induced injury model in neuron–microglia cocultures, finding an impaired injury response by TREM2 R47H/+ microglia.

Furthermore, mouse brains transplanted with TREM2 R47H/+ microglia exhibited reduced synaptic density, with upregulation of multiple complement cascade components in TREM2 R47H/+ microglia suggesting inappropriate synaptic pruning as one potential mechanism.

These findings identify a number of potentially detrimental effects of the TREM2 R47H/+ mutation on microglial gene expression and function likely to underlie its association with AD.

Reference

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