Skip to main content

September 1, 2023

Immune Cells Shape Their Own Path

Scientists at ISTA show how immune cells migrate along self-generated gradients

When fighting disease, our immune cells need to reach their target quickly. Researchers at the Institute of Science and Technology Austria (ISTA) now discovered that immune cells actively generate their own guidance system to navigate through complex environments. Their findings, published in the journal Science Immunology, enhance our knowledge of the immune system and offer potential new approaches to improve human immune response.  

Migrating immune cells. During the experiment,trajectories of dendritic cells (blue) were projected over several hours, highlighting their robust directional migration. © Jonna Alanko/Science Immunology

Immunologic threats like germs or toxins can arise everywhere inside the human body. Luckily, the immune system—our very own protective shield—has its intricate ways of coping with these threats. For example, a crucial aspect of our immune response involves the coordinated collective movement of immune cells during infection and inflammation. But how do our immune cells know which way to go?

A group of scientists from the Sixt group and the Hannezo group at the Institute of Science and Technology Austria (ISTA) addressed this question. In their study, published today in Science Immunology, the researchers shed light on the immune cells’ ability to collectively migrate through complex environments. 

Dendritic cells — the messengers

Dendritic cells (DCs) are one of the key players in our immune response. They function as a messenger between the innate response—the body’s first reaction to an invader, and the adaptive response—a delayed reaction that targets very specific germs and creates memories to fight off future infections. Like detectives, DCs scan tissues for intruders. Once they locate an infection site, they are activated and immediately migrate to the lymph nodes where they hand over the battle plan and initiate the next steps in the cascade.

Their migration towards the lymph nodes is guided by chemokines—small signaling proteins released from lymph nodes—that establish a gradient. In the past, it was believed that DCs and other immune cells react to this external gradient moving along towards a higher concentration. However, novel research conducted at ISTA now challenges this notion.

One receptor — two functions

The scientists took a close look at a receptor—a surface structure found on activated DCs called “CCR7”. CCR7’s essential function is to bind to a lymph node-specific molecule (CCL19), which triggers the next steps of the immune response. ”We found that CCR7 not only senses CCL19 but also actively contributes to shaping the distribution of chemokine concentrations,” Jonna Alanko, a former postdoc from the lab of Michael Sixt, explains.

Experimental agarose assay. The video shows the collective migration of dendritic cells (magenta) over several hours. By consuming the chemokine CCL19, cells generate a dynamic gradient that guides them to move away from the source at the bottom. © Sixt group/Science Immunology

Using different experimental techniques, they demonstrated that as DCs migrate, they take up and internalize chemokines via the CCR7 receptor, resulting in local depletion of chemokine concentration. With less signaling molecules around, they move further into higher chemokine concentrations. This dual function allows immune cells to generate their own guidance cues to orchestrate their collective migration more effectively.

Movement depends on cell population

To understand this mechanism quantitatively at the multicellular scale, Alanko and colleagues teamed up with theoretical physicists Edouard Hannezo and Mehmet Can Ucar, also at ISTA. With their expertise in cell movement and dynamics, they established computer simulations that were able to reproduce Alanko’s experiments. With these simulations, the scientists predicted that the dendritic cells’ movement not only depends on their individual responses to the chemokine but also on the density of the cell population. ”This was a simple but nontrivial prediction; the more cells there are the sharper the gradient they generate—it really highlights the collective nature of this phenomenon!” says Can Ucar.

Experiments vs. simulations. Trajectories of dendritic cells over time as obtained from experiments (left) and simulations (right). Their directional bias to move as a unified front results from the collective action of individual cells locally internalizing chemokines. © Hannezo group/ Science Immunology

Additionally, the researchers found that T-cells—specific immune cells that destroy harmful germs—also benefit from this dynamic interplay to enhance their own directional movement. “We are eager to find out more about this novel interaction principle between cell populations with ongoing projects,” the physicist continues.

Enhancing the immune response

The discoveries are a step in a new direction for how cells move inside our bodies. In contradiction to what was previously believed, immune cells not only respond to chemokines, but they also play an active role in shaping their own environment by consuming these chemical signals. This dynamic regulation of signaling cues provides an elegant strategy to guide their own movement and that of other immune cells. 

This research has significant implications for our understanding of how immune responses are coordinated within the body. By uncovering these mechanisms, scientists could potentially design new strategies to enhance immune cell recruitment to specific sites, such as tumor cells or areas of infection.

Publication:       

J. Alanko, M. C. Ucar, N. Canigova, J. Stopp, J. Schwarz, J. Merrin, E. Hannezo & M. Sixt. 2023. CCR7 acts as both a sensor and a sink for CCL19 to coordinate collective leukocyte migration. Science Immunology. DOI: 10.1126/sciimmunol.adc9584

Funding information:

This project was supported by grants from the European Research Council under the European Union’s Horizon 2020 research to M.S. (grant agreement no. 724373) and to E.H. (grant agreement no. 851288), and a grant by the Austrian Science Fund (DK Nanocell W1250-B20) to M.S. J.A was supported by the Jenny and Antti Wihuri Foundation and Research Council of Finland’s Flagship Programme InFLAMES (decision number: 357910.). M.C.U. was supported by the European Union’s Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement no. 754411.

Information on animal studies:

In order to better understand fundamental processes, for example, in the fields of neuroscience, immunology, or genetics, the use of animals in research is indispensable. No other methods, such as in silico models, can serve as an alternative. The animals are raised, kept, and treated according to the strict regulations of Austrian law. All animal procedures are approved by the Federal Ministry of Education, Science and Research.



Share

facebook share icon
twitter share icon
back-to-top icon
Back to Top