by The Scripps Research Institute
Researchers monitored the gene expression of more than 100,000 individual cells from the prefrontal cortices of mice—shown here clustered and colored by cell type. Excessive alcohol exposure changed the patterns of gene expression in the brains of mice genetically predisposed to Alzheimer's, and these changes were associated with accelerated cognitive decline. Credit: Pietro P. Sanna (Scripps Research) and Federico M. Giorgi (University of Bologna)
Alcohol use disorder (AUD) quickens the pace of Alzheimer's disease progression when paired with genetic susceptibility. Scripps Research and University of Bologna scientists have reported in the journal eNeuro that repeated alcohol intoxication is associated with changes to gene expression indicative of disease progression in the brains of mice that are genetically predisposed to Alzheimer's. When repeatedly exposed to intoxicating amounts of alcohol, these mice showed signs of cognitive decline approximately two months sooner than they usually would.
"Adding ethanol to an Alzheimer's genetic background pushes Alzheimer's forward by a few months or a few years," says co-lead author Federico Manuel Giorgi, Ph.D., a professor of Computational Genomics at the University of Bologna.
Though few studies have explored the potential for alcohol to exacerbate Alzheimer's disease, epidemiological studies have hinted that AUD could lead to a higher risk of developing dementia in general.
To explore the potential for alcohol to affect Alzheimer's disease, the researchers exposed mice to alcohol repeatedly over the course of several months in a model that mimics levels of alcohol exposure for people with AUD. They compared control mice to mice that carry three genes that make them susceptible to Alzheimer's.
The team found that compared to control mice, alcohol-exposed mice became progressively worse at learning and remembering spatial patterns, and they showed these signs of cognitive decline at an earlier age than usual.
"We started seeing cognitive impairments in the alcohol-treated mice approximately two months before they would normally develop these impairments," says co-lead author Pietro Paolo Sanna, MD, a professor of Immunology and Microbiology at Scripps Research.
The researchers characterized and compared the gene expression of more than 100,000 individual cells from the brains of alcohol-exposed and unexposed mice to pinpoint exactly what was happening in these cells during AUD.
They found that alcohol exposure was associated with widespread changes in gene expression in the prefrontal cortex. Specifically, alcohol-exposed mice had higher expression of genes associated with neuronal excitability, neurodegeneration, and inflammation. These changes occurred not only in neurons, but also in supporting cells such as astrocytes, microglia, and endothelial cells.
"This is interesting because it used to be thought that neurons were the ones carrying out all the responses associated with Alzheimer's disease, and only recently have these cell types been recognized as having a role in Alzheimer's pathogenesis," says Giorgi.
When the researchers compared the gene transcription profiles of the alcohol-exposed mice to unexposed mice of different ages and stages of Alzheimer's with the same genetic background, they found that the gene transcription profiles of the alcohol-exposed mice more closely resembled those of older mice with more severe cognitive decline than mice their own age.
"When we compared the alcohol-exposed mice to the same type of mice with early or late progression of the disease—so mice that are not yet impaired in any way and mice that are really compromised—we found that the effect of alcohol is to move gene expression towards the advanced disease," says Sanna.
Understanding how gene expression changes in different populations of cells during Alzheimer's is an important step toward understanding the molecular mechanisms behind memory loss and developing therapies. The researchers speculate that the gene transcription pathways involved in Alzheimer's progression with AUD may also help explain disease progression in the absence of alcohol consumption.
"The mechanisms of progression that this dataset will uncover may apply to Alzheimer's in general, even without alcohol," says Sanna. "Ultimately, this gene expression analysis will identify key regulatory genes that drive Alzheimer's progression."
Though this study focused on familial Alzheimer's, in future the team plans to explore whether alcohol consumption also impacts the onset and progression of sporadic Alzheimer's in people who are not genetically predisposed to the disease.
In addition to Sanna and Giorgi, authors of the study include Amanda Roberts, Tomoya Kawamura, and Vez Repunte-Canonigo of Scripps Research; Chiara Cabrelle, Daniele Mercatelli of University of Bologna; and Nathan O'Connor of MBF Bioscience.
More information: Pietro Paolo Sanna et al, A history of repeated alcohol intoxication promotes cognitive impairment and gene expression signatures of disease progression in the 3xTg mouse model of Alzheimer's disease, eNeuro (2023). DOI: 10.1523/ENEURO.0456-22.2023
Journal information: eNeuro
Provided by The Scripps Research Institute
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