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Mathematicians use machine intelligence to map gene interactions

Mathematicians use machine intelligence to map gene interactions
UCI scientists have developed a machine-intelligence technique to map communications between individual genes and cells. The method could be useful in understanding interactions between infected and immune lung cells that are being attacked by the virus responsible for COVID-19. Credit: Qing Nie / UCI

Researchers at the University of California, Irvine have developed a new mathematical machine-intelligence-based technique that spatially delineates highly complicated cell-to-cell and gene-gene interactions. The powerful method could help with the diagnosis and treatment of diseases ranging from cancer to COVID-19 through quantifying crosstalks between “good” cells and “bad” cells.

By combining the mathematical concept known as “optimal transport” with machine learning and information theory, the scientists were able to equip unconnected single cells with spatial information, thereby highlighting communication links between cells or genes. The work is the subject of a new study published today in Nature Communications.

“With this tool, we can identify cross-talk between virus-infected cells and immune cells,” said co-author Qing Nie, UCI professor of mathematics and the director of the National Science Foundation-Simons Center for Multiscale Cell Fate Research, which supported the project. “This novel approach may have an immediate application in finding critical cell-to-cell communication links in the lung when the COVID-19 virus attacks.”

Nie said that accurate disease diagnosis and treatment requires both gene screening and tissue imaging. High-throughput gene profiling at single-cell resolution often requires dissociation of tissues into individual cells, leading to a loss of spatial information. But imaging intact tissues only allows the measurement of a small number of genes.

“This new mathematical machine-intelligence method greatly enriches our capability in integrating multiple biomedical datasets,” said Nie. “For the very first time, we can reveal how one gene in one cell—for example, in a particular cancer cell—may influence another gene in an immune cell, for instance.”

He said that he was partly inspired to look into the use of optimal transport, a tool with broad applications, including deep learning, after the 2018 Fields Medal (the mathematics equivalent to the Nobel Prize) was awarded on the topic.

Provided by University of California, Irvine

Source: phys.org

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