New live-imaging technique reveals cellular repair crew plugging leaky biological barrier

February 14, 2019
Contact: Jim Erickson ericksn@umich.edu
Sheets of cells in our bodies called epithelial tissues coat our organs, creating wall-like barriers that protect us from disease. When potentially harmful gaps between these cells emerge, a molecular switch gets flipped to call a repair crew to fix the leaks, like patching cracked mortar between bricks in a wall. The microscope image on the left shows epithelial cells from a frog embryo. The junctions between the cells are highlighted in white, and cell nuclei are blue. Microscope image credit: Rachel Stephenson.

Sheets of cells in our bodies called epithelial tissues coat our organs, creating wall-like barriers that protect us from disease. When potentially harmful gaps between these cells emerge, a molecular switch gets flipped to call a repair crew to fix the leaks, like patching cracked mortar between bricks in a wall. The microscope image on the left shows epithelial cells from a frog embryo. The junctions between the cells are highlighted in white, and cell nuclei are blue. Microscope image credit: Rachel Stephenson.

ANN ARBOR—Suppose you live in a brick house and notice cracks in the mortar that let in cold air, rain and insect pests. You might call a brick mason to repair those leaks and to restore the barrier that keeps the great outdoors from getting inside.

In much the same way, sheets of cells in our bodies called epithelial tissues coat our organs, creating wall-like barriers that protect us from bacteria, viruses and other disease-causing invaders. And when potentially harmful gaps between these cells emerge, a molecular switch gets flipped to call the repair crew and fix the leaks.

An important unanswered question about epithelial tissues is: How are the junctions between cells able to maintain the biological barrier function even as cells change shape?
Ann Miller

Using a novel live-imaging technique they developed, University of Michigan researchers have achieved the first direct detection of short-lived leaks in epithelial tissues as they occur. Their new microscopy barrier assay also allowed them to discover that the repair mechanism involves local activation of a protein called Rho.

As epithelial cells move and change shape, the junctions between these cells can develop gaps, resulting in a leaky barrier. Bursts of Rho activity (called Rho flares, white arrows) occur at the sites of breakage and are used to signal for the repair of leaky junctions. The movie on the right is an enlargement of a Rho flare from the movie on the left. Green: a fluorescent reporter for active Rho. Magenta: fluorescently tagged ZO-1, a junction protein. Animation credit: Rachel Stephenson

As epithelial cells move and change shape, the junctions between these cells can develop gaps, resulting in a leaky barrier. Bursts of Rho activity (called Rho flares, white arrows) occur at the sites of breakage and are used to signal for the repair of leaky junctions. The movie on the right is an enlargement of a Rho flare from the movie on the left. Green: a fluorescent reporter for active Rho. Magenta: fluorescently tagged ZO-1, a junction protein. Animation credit: Rachel Stephenson

The new assay could help provide insights into the mechanisms of diseases that target the epithelial barrier—ailments caused by microbes and allergens, as well as various inflammatory states, immune disorders, diabetes and even cancers. And the assay could potentially be used to screen drugs to treat those afflictions, according to the researchers.

The team’s findings were published online Feb. 14 in the journal Developmental Cell. Ann Miller, an associate professor in the U-M Department of Molecular, Cellular, and Developmental Biology, is senior author of the paper. The first author is Rachel Stephenson, a research scientist in Miller’s lab who carried out the project for her doctoral dissertation.

Ann Miller

Ann Miller

“An important unanswered question about epithelial tissues is: How are the junctions between cells able to maintain the biological barrier function even as cells change shape?” Miller said.

In the study, Miller’s team used epithelial cells in live frog embryos, which have cell-cell junctions similar in structure and protein composition to those in human epithelial tissues.

During embryonic development, many epithelial cells work together to bend and fold tissues. Using their new microscopy assay—which is known as ZnUMBA for Zinc-based Ultrasensitive Microscopic Barrier Assay—the researchers studied what happens at the cellular level when epithelial cell-cell junctions are stretched.

They showed that leaks in barrier function happened when cell-cell junctions elongate. But the leaks are short-lived, suggesting there is an active repair mechanism.

On further investigation, the researchers discovered that the repair mechanism involves local activation of the protein Rho, in a sudden burst of activity they dubbed a Rho flare. Rho then activates proteins that contract the junction, repairing it.

We discovered that cells are normally very proactive when it comes to maintaining the barrier. This repair mechanism happens quickly and is carried out very locally, affecting only a small part of the cell junction, rather than multiple cells or the whole tissue.
Rachel Stephenson

Rachel Stephenson

Rachel Stephenson

“We discovered that cells are normally very proactive when it comes to maintaining the barrier,” Stephenson said. “This repair mechanism happens quickly and is carried out very locally, affecting only a small part of the cell junction, rather than multiple cells or the whole tissue.

“We think that this proactive approach is what gives our cells the flexibility to move and change shape without compromising the barrier function of the tissue. Diseases involving a leaky barrier might be due to a faulty repair mechanism or the cells’ inability to detect leaks and flip the switch.”

Stephenson and other members of the Miller Lab are now working to determine how the switch gets flipped to turn on Rho at the right time and place and to identify other proteins that are part of the cellular repair crew to plug leaky biological barriers.

The Miller Lab is part of a larger group of researchers at U-M studying biological barriers. An Exploratory Funding Initiative entitled “The Role of Tissue Barriers in Health and Disease”—led by Miller, David Antonetti, Asma Nusrat and Anuska Andjelkovic-Zochowska—was recently funded by the U-M Biosciences Initiative.

The Developmental Cell paper is titled “Rho flares repair local tight junction leaks” (DOI: 10.1016/j.devcel.2019.01.016). Other authors are Tomohito Higashi and Torey Arnold of the U-M Department of Molecular, Cellular and Developmental Biology and Ivan Erofeev, Marcin Leda and Andrew Goryachev of the University of Edinburgh.

The research in the Miller Lab was funded by the National Institutes of Health, National Science Foundation Graduate Research Fellowships and a postdoctoral fellowship from the Japan Society for the Promotion of Science.

 

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