3D Gene Regulation Map Sheds Light on Brain Development

Summary: Researchers have developed the first 3D map of gene regulation in the human brain, offering insights into how early brain development influences lifelong mental health. This map, focusing on regions tied to memory and emotional regulation, reveals how chromatin structure controls gene activity, especially during key developmental stages.

These findings may help identify when and where genetic variants linked to autism and schizophrenia disrupt normal development. By understanding these early influences, scientists hope to improve neurodevelopmental disorder research and stem-cell models, potentially paving the way for earlier intervention strategies.

Key Facts

  • New 3D brain map shows gene regulation in memory and emotional regions.
  • Chromatin structure influences gene expression during critical brain development.
  • Findings may guide research on autism, schizophrenia, and improved brain models.

Source: UCLA

A UCLA-led study has provided an unprecedented look at how gene regulation evolves during human brain development, showing how the 3D structure of chromatin — DNA and proteins — plays a critical role. This work offers new insights into how early brain development shapes lifelong mental health.

The study, published in Nature, was led by Dr. Chongyuan Luo at UCLA and Dr. Mercedes Paredes at UC San Francisco, in collaboration with researchers from the Salk Institute, UC San Diego and Seoul National University.

It created the first map of DNA modification in the hippocampus and prefrontal cortex — two regions of the brain critical to learning, memory and emotional regulation. These areas are also frequently involved in disorders like autism and schizophrenia.

This shows the hippocampus.
Fluorescent image of a developing human hippocampus. Credit: Oier Pastor-Alonso/UCSF

The researchers hope the data resource, which they’ve made publicly available through an online platform, will be a valuable tool scientists can use to connect genetic variants associated with these conditions to the genes, cells and developmental periods that are most sensitive to their effects.

“Neuropsychiatric disorders, even those emerging in adulthood, often stem from genetic factors disrupting early brain development,” said Luo, a member of the Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research at UCLA.

“Our map offers a baseline to compare against genetic studies of diseased-affected brains and pinpoint when and where molecular changes occur.”

To produce the map, the research team used a cutting-edge sequencing approach Luo developed and scaled with support from the UCLA Broad Stem Cell Research Center Flow Cytometry Core called single nucleus methyl-seq and chromatin conformation capture, or snm3C-seq.

This technique enables researchers to simultaneously analyze two epigenetic mechanisms that control gene expression on a single-cell basis: chemical changes to DNA known as methylation and chromatin conformation, the 3D structure of how chromosomes are tightly folded to fit into nuclei.

Figuring out how these two regulatory elements act on genes that affect development is a critical step to understanding how errors in this process lead to neuropsychiatric conditions.

“The vast majority of disease-causing variants we’ve identified are located between genes on the chromosome, so it’s challenging to know which genes they regulate,” said Luo, who is also an assistant professor of human genetics at the David Geffen School of Medicine at UCLA.

“By studying how DNA is folded inside of individual cells, we can see where genetic variants connect with certain genes, which can help us pinpoint the cell types and developmental periods most vulnerable to these conditions.” 

For example, autism spectrum disorder is commonly diagnosed in children aged 2 and over. However, if researchers can gain a better understanding of the genetic risk of autism and how it impacts development, they can potentially develop intervention strategies to help alleviate the symptoms of autism, like communication challenges, while the brain is developing.

The research team analyzed more than 53,000 brain cells from donors spanning mid-gestation to adulthood, revealing significant changes in gene regulation during critical developmental windows.

In capturing such a broad spectrum of developmental phases, the researchers were able to assemble a remarkably comprehensive picture of the massive genetic rewiring that occurs during critical timepoints in human brain development.

One of the most dynamic periods comes around the midpoint of pregnancy. At this time, neural stem cells called radial glia, which have produced billions of neurons during the first and second trimesters, stop producing neurons and begin generating glial cells, which support and protect neurons.

At the same time, the newly formed neurons mature, gaining the characteristics they need to fulfill specific functions and forming the synaptic connections that enable them to communicate. 

This stage of development has been overlooked in previous studies, the researchers say, due to the limited availability of brain tissue from this period.

“Our study tackles the complex relationship between DNA organization and gene expression in developing human brain at ages typically not interrogated: the third trimester and infancy,” said Paredes, an associate professor of neurology at UCSF.

“The connections we’ve identified across different cell types through this work could untangle the current challenges in identifying meaningful genetic risk factors for neurodevelopmental and neuropsychiatric conditions.”

The findings also have implications for improving stem cell-based models, such as brain organoids, which are used to study brain development and diseases. The new map offers a benchmark for scientists to ensure these models accurately replicate human brain development.

“Growing a healthy human brain is a tremendous feat,” says co-author Dr. Joseph Ecker, professor at the Salk Institute and Howard Hughes Medical Institute investigator.

“Our study establishes an important database that captures key epigenetic changes that occur during brain development, in turn bringing us closer to understanding where and when failures arise in this development that can lead to neurodevelopmental disorders like autism.”

The group’s efforts were supported by the National Institutes of Health’s BRAIN Initiative Cell Atlas Network, or BICAN, which aims to build reference brain cell atlases that will provide a foundational framework for studying brain function and disorders.

Funding: Funding was also provided by the National Institute of Mental Health, the National Human Genome Research Institute, the Simons Foundation, the Roberta and Oscar Gregory Endowment in Stroke and Brain Research, the Chan Zuckerberg Biohub, the National Research Foundation of Korea, the Shurl and Kay Curci Foundation, National Institute on Drug Abuse and the California Institute for Regenerative Medicine.

Additional authors are: Jingtian Zhou, Yi Zhang, Dong-Sung Lee, Kangcheng Hou, Oier Pastor Alonso, Kevin D Abuhanna, Joseph Galasso, Colin Kern, Chu-Yi Tai, Carlos Garcia Padilla, Mahsa Nafisi, Yi Zhou, Anthony D. Schmitt, Terence Li, Maximilian Haeussler, Brittney Wick, Martin Jinye Zhang, Fangming Xie, Ryan S. Ziffra, Eran A. Mukamel, Eleazar Eskin, Tomasz J. Nowakowski, Jesse R. Dixon, Bogdan Pasaniuc, Joseph R. Ecker, Quan Zhu and Bogdan Bintu.

About this gene mapping and neurodevelopment research news

Author: Ani Vahradyan
Source: UCLA
Contact: Ani Vahradyan – UCLA
Image: The image is credited to Oier Pastor-Alonso/UCSF

Original Research: Open access.
Temporally distinct 3D multi-omic dynamics in the developing human brain” by Chongyuan Luo et al. Nature


Abstract

Temporally distinct 3D multi-omic dynamics in the developing human brain

The human hippocampus and prefrontal cortex play critical roles in learning and cognition, yet the dynamic molecular characteristics of their development remain enigmatic.

Here we investigated the epigenomic and three-dimensional chromatin conformational reorganization during the development of the hippocampus and prefrontal cortex, using more than 53,000 joint single-nucleus profiles of chromatin conformation and DNA methylation generated by single-nucleus methyl-3C sequencing (snm3C-seq3).

The remodelling of DNA methylation is temporally separated from chromatin conformation dynamics.

Using single-cell profiling and multimodal single-molecule imaging approaches, we have found that short-range chromatin interactions are enriched in neurons, whereas long-range interactions are enriched in glial cells and non-brain tissues.

We reconstructed the regulatory programs of cell-type development and differentiation, finding putatively causal common variants for schizophrenia strongly overlapping with chromatin loop-connected, cell-type-specific regulatory regions.

Our data provide multimodal resources for studying gene regulatory dynamics in brain development and demonstrate that single-cell three-dimensional multi-omics is a powerful approach for dissecting neuropsychiatric risk loci.

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