Today, researchers describe major advances in the understanding of the development of the neocortex —layer-by-layer and cell-by-cell—thanks to a pioneering database developed at the University of Maryland School of Medicine (UMSOM) that combines multiomic data from 188 different studies. The revolutionary and publicly accessible database—called the Neuroscience Multi-Omic Analytics ( NeMO Analytics )—is helping scientists make groundbreaking discoveries about the brain and disease development by using vast amounts of human, non-human primate, mouse, and organoid data.
The study is part of a collection of papers on human brain development published in Nature and Nature Neuroscience by an international consortium of researchers in the National Institutes's of Health BRAIN Initiative Cell Atlas Network (BICAN) . NeMO Analytics—housed at the Institute for Genome Sciences (IGS) at UMSOM—is a critical part of BICAN. Scientists from IGS and UMSOM—along with colleagues at Johns Hopkins University (JHU), NIH, Yale University, and the University of Toronto—published their findings in Nature Neuroscience.
The neocortex is a part of the brain that processes sensory information, language, memory, and consciousness. Changes in neocortical development impact risk for many brain disorders, including autism spectrum disorders (ASD) and schizophrenia. The neocortex also has undergone dramatic changes in size and organization in the lineage leading to humans, compared to non-human primates and other mammals.
"We faced two major challenges in doing this research," said the study's senior author Carlo Colantuoni, PhD, a Research Associate at IGS and UMSOM's Department of Neurology, as well as an Adjunct at JHU's School of Medicine. "First, existing individual databases only cover portions of a brain region, developmental stage, or specific species. Secondly, most existing analysis pipelines cannot identify common molecular mechanisms across diverse datasets."
The research team analyzed vast amounts of data, including gene-level data from 30-million single-cell transcriptomes, spatial transcriptomes, and RNA sequencing from sorted cells and bulk tissue to identify shared patterns of gene activity. In all mammals neurons develop into specialized cells within the six layers of the neocortex. In this study, they discovered, that while mouse cortical development is complete within months, neurons in humans take many years to reach full molecular maturity. Further, they showed that in brain organoids, which mimic early brain development, neurons do not develop fully into cells specific to the individual layers of the neocortex.
"One of the key discoveries in this study is that brain disorders aren't just caused by missing or faulty genes—they can also result from how genes are turned on or off during brain development," said UMSOM Dean Mark Gladwin, MD, who is also the Vice President for Medical Affairs at the University of Maryland, Baltimore, and the John Z. and Akiko K. Bowers Distinguished Professor. "For example, the team discovered that a gene called FOXN3 is turned on in neural progenitors in mice, potentially limiting growth, but it was turned off in human progenitors, allowing for more growth."
"The ability to integrate and analyze so many types of data at once within NeMO Analytics allows scientists to map patterns, discover features unique to human brain development, and track how disruptions, such as inflammation or epigenetic changes, could cause brain diseases," added Seth Ament, PhD, a co-author on the study, IGS faculty member, and Associate Professor of Psychiatry at UMSOM. "By making this resource user-friendly and available to all scientists, we are enabling faster discoveries that will lead to earlier detection, targeted treatments, and even preventive approaches for human brain disorders."
About the Institute for Genome Sciences
The Institute for Genome Sciences' (IGS) has been part of the University of Maryland School of Medicine (UMSOM) since 2007. IGS scientists work in diverse areas, applying genomics and systems biology approaches to better understand health issues to create a healthier Maryland and world. Our research spans multiple areas including cancer and precision medicine; parasitic, fungal, and bacterial diseases; sexual and reproductive health; the underpinnings of aging; and neuroscience areas including brain development, addiction, and mental health IGS also remains at the forefront of high-throughput genomic technologies and bioinformatics analyses through its core facility, Maryland Genomics which provides researchers around the world with cutting-edge, collaborative, and cost-effective sequencing and analysis.
About the University of Maryland School of Medicine
