Immune cells identified as key players in brain health

Using novel genetic and genomic tools, researchers at the Icahn School of Medicine at Mount Sinai have shed light on the role of immune cells called macrophages in lipid-rich tissues like the brain, advancing our understanding of Alzheimer's and other diseases. The study, published in Nature Communications, represents a step forward in understanding immune cell regulation and its impact on disease progression.

The researchers initially studied genes controlling macrophages, also referred to as microglia, when they are in the brain, particularly in response to damage to fatty tissues like the brain. Disease-associated microglia/macrophages are thought to be protective, as they participate in removing lipid-rich waste derived from tissue damage. Therefore, researchers wanted to find factors that promote the "garbage removal" activity of these cells.

They identified two influential genes, BHLHE40 and BHLHE41, and used advanced gene editing technology (CRISPR-Cas9) to deactivate them in lab-grown cells. These cells were then transformed into microglia. The resulting microglia lacking BHLHE40 and BHLHE41 resembled disease-associated microglia observed in Alzheimer's disease, showing improved ability to clear cholesterol-rich waste.

Confirmation came from experiments on cultured human peripheral macrophages and microglia from mice lacking these genes.

"Through our analysis of single-cell datasets from multiple organs, we've uncovered pivotal regulators of immune cell function essential for tissue health," says senior study author Alison M. Goate, DPhil, the Jean C. and James W. Crystal Professor and Chair of Genetics and Genomic Sciences at Icahn Mount Sinai.

"Our use of advanced models has further validated the critical role played by transcription factors BHLHE40 and BHLHE41, proteins that regulate gene expression by binding to specific DNA sequences, in controlling immune cell responses, presenting potential targets for therapeutic intervention."

Next, the researchers will investigate whether microglia without BHLHE40 and BHLHE41 can help clear away harmful amyloid proteins. In one experiment, the investigators will grow brain cells such as neurons and astrocytes that have harmful Alzheimer's mutations in a dish and test whether immune cells without BHLHE40 and 41 influence beta-amyloid levels, neurodegeneration, and cytokine response (neuroinflammation).

In another, they will inject the immune cells with and without BHLHE40 and 41 into a mouse model of Alzheimer's to see how they affect the development of Alzheimer's-like plaques.

"We want to see how these cells, particularly those without the two genes, impact Alzheimer 's-related phenotypes in both dish and mouse models. We predict that in mice, microglia without BHLHE40 and 41 will clear away beta-amyloid plaques more effectively than control microglia that have normal levels of BHLHE40 and 41. Also, we're exploring how lack of these genes in the brain immune cells affect other types of cells in the brain such as neurons and astrocytes," says Dr. Goate.