The lead cell is tethered by E-caderin to other cells in the cluster and pulls them in the proper direction in the same way the lead sled dog guides its team. (Credit: kris krüg/Flickr)

Groups of cells travel a lot like sled dogs

New research shows cell clusters, like sled dogs, travel in groups and need a leader to make sure they all follow in the same direction.

Denise Montell, professor of molecular cellular and developmental biology, and colleagues worked on three independent projects involving E-cadherin, a protein found in epithelial cells throughout the body.

The researchers used fruit-fly ovaries to uncover the role played by E-cadherin in collective cell migration. Their findings appear in the journal Cell.

According to traditional scientific dogma, E-cadherin acts like the mortar between bricks, holding cells together and preventing motility. Montell’s team found the opposite: cadherin is actually promoting the ability of cells to move and migrate.

“It’s doing it in three different ways in three different parts of the cell,” Montell says. “In each spot in the cell, cadherin is doing something different and all of those function together to orchestrate the movement of cells.”

Tethered together

Montell’s team sought to understand the E-cadherin-mediated migration of these cells with three separate approaches that converged on one idea: the guidance of cell movement. “This kind of motility is similar to what tumor cells do when they metastasize,” Montell says, “and it’s part of the normal development of different tissues.”

One researcher studied the interaction between the lead cell and the following cells—hence the sled dog comparison. The lead cell is tethered by E-caderin to other cells in the cluster and pulls them in the proper direction in the same way the lead sled dog guides its team.

While E-cadherin is distributed throughout the cell cluster, the lead cell—determined by the strong force of E-cadherin that causes the cell to protrude in the direction of the movement—can communicate with the side and rear cells and prohibit them from protruding. This creates a front and back to the entire cluster of cells.

Lead author Danfeng Cai, a graduate student in Montell’s lab, suppressed cadherin in different cell types and analyzed the visible guidance defects by making movies of the migrating cells. When cells lacked E-cadherin, they were unable to migrate as an organized group, and the direction of their movement was random and irregular.

New tools to probe living tissue

Another member of the research team designed an optical sensor of mechanical tension—a kind of microscopic spring—and inserted it into the cadherin protein. This enabled the measurement of force on the E-cadherin molecules. The results show that even though the distribution of the protein was uniform, the force per molecule was stronger at the front. “It’s kind of amazing that you can make that measurement in living cells,” Montell says.

An optical sensor of mechanical tension (blue) inserted between E-cadherin (green). (Credit: Illustration by Peter Allen/UC Santa Barbara)
An optical sensor of mechanical tension (blue) inserted between E-cadherin (green). (Credit: Illustration by Peter Allen/UC Santa Barbara)

In addition to highlighting E-cadherin’s role in cell migration, the paper introduces new experimental tools the team used to probe and analyze E-cadherin in living tissue, the first being the optical sensor of mechanical tension.

The researchers found that E-cadherin molecules implanted with the sensor were fully functional. This allowed them to generate transgenic flies containing only E-cadherin molecules with optical sensors.

“This in vivo tension sensor could revolutionize the area of research that strives to elucidate the interplay between biochemical signals and mechanical forces during morphogenesis,” Montell says. “In contrast to other approaches that attempt to measure forces in tissues, such as laser cutting, this one is nonperturbing.”

A second tool Montell’s team developed and reported for the first time is morphodynamic profiling. This quantitative approach allowed the researchers to compare changing cell morphologies over time between different genotypes.

Data from the cell movement imaging were mathematically translated into graphs showing cell protrusion and retraction velocities at different points in time.

“E-cadherin is serving multiple purposes,” Montell concludes, “all of which function together to coordinate the collective ability of these cells to sense direction. Our work demonstrates three completely different approaches that all show the same result.”

While E-cadherin serves different functions in different subcellular locations, it appears to drive cohesive cell migration, an entirely new role for this much-studied molecule.

Source: UC Santa Barbara

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