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How do cells coordinate their behavior with other cells to create tissue-scale behaviors?

A collaboration between computational researchers from Ben-Gurion University of the Negev and experimental researchers from University of British Columbia discovered a new mode of cell-cell communication in cellular communities that lead to collective synchronization during tissue development.

Cells communicate with one another during development, but what are the steps that enable them to transition from local cell-cell communication to a globally synchronized tissue-scale behavior?

Prof. Assaf Zaritsky | Photo: Dani Machlis

Ben-Gurion University of the Negev's Prof. Assaf Zaritsky and his international colleagues have identified a new mode of communication that involves recurring “communities” of cells that are associated with the fruit fly (Drosophila) lymph gland developmental process. These findings may begin to explain how collective tissue behavior emerges from single cell interactions.

Their findings were published in the Proceedings of the National Academy of Sciences (PNAS) .

The team found communities of three to ten cells each which both communicated extensively amongst themselves and received and transmitted information to the surrounding cells. Cells that participated in multiple communities merged to form larger communication hubs, called “hotspots” that repeatedly spread and retrieved information throughout the lymph gland to synchronize the tissue. These “hotspots” resemble beating pacemaker heart cells that coordinate other individual cells to guide collective decisions in the heart. These communities and “hotspots” emerged in advanced stages of the lymph gland development, and required the existence of tiny channels, called “gap junctions”, that connect adjacent cells and allow them to communicate with each other by direct passing of molecules and ions between them.

“We pinpointed an intermediate spatial scale between single-cell and tissue function involving cell communities working together to coordinate the collective. These results highlight how diversity in local cell-cell communication can contribute to collective decision making,” explains Prof. Zaritsky.

Prof. Zaritsky is a member of the Department of Software and Information Systems Engineering.

Additional researchers included: Saar Ben David from the same department at Ben-Gurion University and Kevin Ho and Guy Tanentzapf from the Department of Cellular and Physiological Sciences at the University of British Columbia.

Research in the Zaritsky lab is supported by the GIF, the German-Israeli Foundation for Scientific Research and Development; the Israel Council for Higher Education via the Data Science Research Center, Ben-Gurion University of the Negev; the Israel Science Foundation (Grant No. 2516/21); the Israel Ministry of Science and Technology; the Wellcome Leap Delta Tissue program, and by the Rosetrees Trust. Research in the Tanentzapf lab is supported by the Canadian Institutes of Health Research.

Cells communicate with one another during development, but what are the steps that enable them to transition from local cell-cell communication to a globally synchronized tissue-scale behavior? Prof. Assaf Zaritsky | Photo: Dani Machlis Ben-Gurion University of the Negev's Prof. Assaf Zaritsky and his international colleagues have identified a new mode of communication that involves recurring “communities” of cells that are associated with the fruit fly (Drosophila) lymph gland developmental process. These findings may begin to explain how collective tissue behavior emerges from single cell interactions. Their findings were published in the Proceedings of the National Academy of Sciences (PNAS) . The team found communities of three to ten cells each which both communicated extensively amongst themselves and received and transmitted information to the surrounding cells. Cells that participated in multiple communities merged to form larger communication hubs, called “hotspots” that repeatedly spread and retrieved information throughout the lymph gland to synchronize the tissue.
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