Summary: While aging is the primary risk factor for neurodegenerative diseases like Alzheimer’s and Parkinson’s, the exact molecular shifts that occur over time have remained elusive. Now, researchers have created the most comprehensive single-cell atlas of the aging brain to date.
By profiling over 1 million cells in the mouse brain, the team mapped epigenetic changes—the chemical “tags” that turn genes on or off—across 36 distinct cell types. The atlas reveals that aging isn’t uniform; different brain regions and cell types age at different speeds. The study also identified “jumping genes” that lose methylation and become active with age, potentially driving cellular dysfunction.
Key Facts
- Massive Scale: The atlas profiles nearly 900,000 cells using spatial transcriptomics and over 200,000 via methylation and chromatin conformation assays across eight brain regions.
- Non-Neuronal Vulnerability: Surprisingly, age-related epigenetic changes were more pronounced in non-neuronal cells (like glia) than in neurons.
- “Jumping Genes” Activated: The study found that transposable elements (repetitive DNA sequences) lose their chemical “silencers” (methylation) as the brain ages, which may contribute to cognitive decline.
- Spatial Variance: The same cell type ages differently based on its location; for example, non-neuronal cells in the back of the brain show more inflammation than those in the front.
- New Biomarker: Researchers identified TAD boundary strengthening (changes in how the genome is 3D-organized) as a high-precision biomarker for brain aging.
Source: Salk Institute
Neurodegenerative diseases affect more than 57 million people globally. The incidence of these diseases, from Alzheimer’s to Parkinson’s to ALS and beyond, is expected to double every 20 years. Though scientists know aging is a major risk factor for neurodegenerative diseases, the full mechanisms behind aging’s impact remain unclear.
One major mechanistic influence on aging is epigenetic change: the way small chemical tags on top of our base genetic code shift over time to alter gene expression. Salk researchers created the most comprehensive single-cell atlas to date of epigenetic changes in the aging mouse brain, revealing how DNA methylation, genome structure, and gene activity change across brain regions and cell types.
The new atlas represents eight brain regions and 36 distinct brain cell types, with over 200,000 single cells profiled across methylation and chromatin conformation assays, plus nearly 900,000 cells captured with spatial transcriptomics.
The atlas’ contents have already revealed clear epigenetic differences between different age groups, as well as allowed the researchers to develop novel deep-learning models that predict age-related gene expression changes. Published in Cell on March 11, 2026, the atlas is now publicly available on Amazon Web Services (AWS) and Gene Expression Omnibus (GEO), where it will serve as a critical reference framework for interpreting human brain datasets, including those generated by the National Institute of Health’s Brain Research Through Advancing Innovative Neurotechnologies (BRAIN) Initiative.
“Age-related brain changes, particularly in regions critical for attention, memory, emotion, and motor functions, severely impact life quality,” says co-corresponding author Joseph Ecker, PhD, professor and holder of the Salk International Council Chair in Genetics at Salk and a Howard Hughes Medical Institute Investigator.
“By mapping how the epigenome changes across individual brain cell types as animals age, we now have a framework for understanding how aging reshapes the brain at the molecular level. This resource should help researchers pinpoint mechanisms that contribute to neurodegenerative disease.”
What do we know about the aging brain?
With age comes four molecular hallmarks: chronic inflammation, mitochondrial dysfunction, genome instability, and epigenetic changes. Recent findings have pinpointed the epigenome as a major driver of physiological aging. And one type of epigenetic change called methylation has been associated with neuronal function, behavior, and disease. If scientists could connect the dots between methylation changes and adverse age-related outcomes, they could begin to engineer solutions that reverse those changes and rescue health.
But generating useful methylation data isn’t as simple as sampling a few brain cells and drawing generalized conclusions. The brain has many different regions and cell types, which each must be considered to get a full picture of what’s going on.
“The brain is so interconnected, with different regions controlling different functions and aging at different speeds at the cell type level,” says co-corresponding author Margarita Behrens, PhD, a research professor at Salk.
“We can see how interconnected the brain is in conditions like Parkinson’s, where the death of one group of neurons spirals into an entire circuit malfunctioning and then the tremors and cognitive effects we see in patients. So, the importance of having a cell type-specific understanding of aging will bring more granular knowledge that will expand therapeutic possibilities.”
What is an epigenetic atlas?
Bulk analysis of brain cells loses cell type specificity, making single-cell analyses a powerful tool. So, the Salk researchers set out to create the most comprehensive single-cell, multi-omic brain imaging data set to date. On top of methylation, they surveyed another genome-regulating mechanism called chromatin conformation—the 3D shape of the genome. They also used cutting-edge spatial transcriptomics technology to map gene expression while preserving spatial context within the sampled brain tissue.
“What makes this work innovative is, above all, its spatial dimension,” explains first author Qiurui Zeng, a graduate student in Ecker’s lab.
“Spatial resolution reveals which regions and local microenvironments are most vulnerable to aging, how cell-type composition shifts across brain areas over time, and how neighboring cells may influence one another’s aging trajectories. The scale of the spatial dataset—nearly 900,000 spatial transcriptome cells—is itself unprecedented for a longitudinal aging study.”
Using a mouse model of aging, the team collected methylation data on 132,551 single brain cells and joint methylation-chromatin conformation data on 72,666 brain cells. Together, 36 major cell types were represented. This dataset was published in full on AWS and GEO in December 2025.
Hosting this massive dataset of nearly 900,000 spatially resolved cells on AWS ensures both accessibility and immediacy. Typically, such massive amounts of data require significant computational power to access, but cloud hosting tears down those infrastructure barriers.
“The AWS Open Data program covers storage costs and places this dataset alongside other major neuroscience resources like the Allen Brain Atlas and the Seattle Alzheimer’s Disease Brain Cell Atlas, making it part of an interconnected ecosystem of publicly accessible brain data,” adds Zeng.
“Researchers in aging, neurodegeneration, and spatial genomics can build on this resource immediately, accelerating the pace of discovery well beyond what a single lab could achieve.”
What can an epigenetic atlas teach us?
First, the methylation data revealed that age-related methylation changes were more pronounced in non-neuronal cells. The team found that transposable elements—sometimes called ‘jumping genes’—lose DNA methylation as cells age, suggesting that normally silenced genomic elements become more active in the aging brain.
Jumping genes are repetitive DNA sequences that make up around half of the human genome, and their expression can lead to dysfunction and age-related decline. This finding is consistent with the idea that epigenetic changes may contribute to aging-related cellular dysfunction.
The chromatin confirmation data revealed further changes during aging. Notably, the researchers were able to identify a new biomarker for brain aging: increased strength at topologically associating domain (TAD) boundaries and greater accessibility at related CTCF binding sites. The massive amount of information contained in a genome is organized using TADs, which are simply smaller stretches of DNA that work together. CTCF is a protein that binds to boundaries on either end of TADs, assisting in their organization.
Then came the time to fold in the spatial transcriptomics insights. Nearly 900,000 cells were used to trace differences between aging in different brain regions and cell types.
“The same cell type ages differently depending on its location; for instance, non-neuronal cells in the back of the brain show more inflammation than those in the front parts,” says Zeng. “This data really underscores the variability in aging even among the same cell type, emphasizing the importance of cell and brain region-level specificity in unraveling the complexities of aging.”
How will this atlas help scientists and patients?
The team has already gleaned impressive insight from the dataset. For example, they developed deep learning methods to predict gene expression using future multi-omic epigenetic data, thereby laying the groundwork for the future development of a virtual brain aging model. And more exciting insights are on the way.
The atlas is available online now for anyone to use. By making these sorts of resources accessible to all, the scientists hope to see their findings accelerated by the power of global collaboration.
Other authors and funding
Other authors include Wei Tian, Anna Bartlett, Joseph Nery, Rosa Castanon, Julia Osteen, Nicholas Johnson, Wenliang Wang, Wubin Ding, Huaming Chen, Jordan Altshul, Mia Kenworthy, Cynthia Valadon, William Owens, Cindy Tatiana Báez-Becerra, Silvia Cho, Chumo Chen, Jackson Willier, Stella Cao, Jonathan Rink, Jasper Lee, Ariana Barcoma, Jessica Arzavala, and Nora Emerson of Salk; Qiurui Zeng and Amit Klein of Salk and UC San Diego; Hanqing Liu of Salk and Harvard; Zhanghao Wu of UC Berkeley; Maria Luisa Amaral, Yuru Song, and Nathan Zemke of UC San Diego; and Yuancheng Ryan Lu of Whitehead Institute.
Funding: The work was supported by the National Institutes of Health (5R01AG066018-05, RRID: SCR_014839, CCSG P30 CA014195, S10-OD023689, S10 OD034268) and Howard Hughes Medical Institute.
Key Questions Answered:
A: Not even close! This atlas shows that aging is highly localized. You might have microglia in one part of your brain that look “young,” while the exact same cell type in a different region is showing signs of advanced “molecular aging.” It’s a patchwork, not a steady decline across the board.
A: About half of our genome is made of these repetitive sequences called transposable elements. Normally, the brain keeps them “locked down” with chemical tags (methylation). As we age, we lose those tags, and these genes can start “jumping” or becoming active, which creates genomic instability and inflammation—key drivers of diseases like ALS and Alzheimer’s.
A: We’re getting there. By identifying the specific chemical tags that change with age, scientists can now start testing ways to “reset” the epigenome. If we can re-silence those jumping genes or restore the 3D structure of the genome, we might be able to rescue failing neural circuits before permanent damage occurs.
Editorial Notes:
- This article was edited by a Neuroscience News editor.
- Journal paper reviewed in full.
- Additional context added by our staff.
About this aging and genetics research news
Author: Salk Comms
Source: Salk Institute
Contact: Salk Comms – Salk Institute
Image: The image is credited to Neuroscience News
Original Research: Open access.
“Cell-type-specific transposon demethylation and TAD remodeling in aging mouse brain” by Qiurui Zeng, Wenliang Wang, Wei Tian, Amit Klein, Anna Bartlett, Hanqing Liu, Joseph R. Nery, Rosa G. Castanon, Julia Osteen, Nicholas D. Johnson, Wubin Ding, Huaming Chen, Jordan Altshul, Mia Kenworthy, Cynthia Valadon, William Owens, Zhanghao Wu, Maria Luisa Amaral, Nathan R. Zemke, Yuru Song, Cindy Tatiana Báez-Becerra, Silvia Cho, Chumo Chen, Jackson Willier, Stella Cao, Jonathan Rink, Jasper Lee, Ariana Barcoma, Jessica Arzavala, Nora Emerson, Yuancheng Ryan Lu, Bing Ren, M. Margarita Behrens, and Joseph R. Ecker. Cell
DOI:10.1016/j.cell.2026.02.015
Abstract
Cell-type-specific transposon demethylation and TAD remodeling in aging mouse brain
Aging is a major risk factor for neurodegenerative diseases, yet the underlying epigenetic mechanisms remain unclear.
Here, we generated a comprehensive single-nucleus cell atlas of brain aging across multiple brain regions, comprising 132,551 single-cell methylomes and 72,666 joint chromatin conformation-methylome nuclei. Integration with companion transcriptomic and chromatin accessibility data yielded a cross-modality taxonomy of 36 major cell types.
We observed that transposable element (TE) methylation alone distinguished age groups, showing cell-type-specific genome-wide demethylation. Chromatin conformation analysis demonstrated age-related increases in topologically associated domain (TAD) boundary strength with enhanced accessibility at CCCTC-binding factor (CTCF) binding sites.
Spatial transcriptomics across 895,296 cells revealed regional heterogeneity during aging within identical cell types. Finally, we developed deep-learning models that reliably predict age-related gene expression changes using multi-modal epigenetic features, providing mechanistic insights into gene regulation.
Age-related comparisons use a 2-month baseline reflecting the late-adolescent/early-young adult stage. This dataset advances our understanding of brain aging and offers potential translational applications.
