Shining New Light on How Cytokines Manage Immune Response

Green fluorescent tags delivered by the new CyCLoPs tool reveal cells that responded to a specific cytokine (IL-17A) in a mouse model.
Image Credit: Huh Lab

Scientific Frontline: "At a Glance" Summary

• Main Discovery: A new toolkit named CyCLoPs (cytokine cellular locating platforms) enables the precise tagging and visualization of cells that receive cytokine signals, illuminating previously invisible immune communication pathways.
• Methodology: Researchers engineered a system that functions as a biological highlighter; when a cytokine binds to a cell receptor, a fluorescent marker is released and travels to the cell nucleus, creating a durable tag that persists through cell division and allows for long-term tracking.
• Key Data: Validation in preclinical mouse models successfully identified cells responding to interleukin-17A in the small intestine and interferon gamma in tumors, with the latter experiment revealing that the cytokine unexpectedly weakened killer T cells.
• Significance: This technology addresses a critical gap in immunology by identifying exactly which cells receive immune signals and how they react, moving beyond the historical capability limited to observing only the cells that send these signals.
• Future Application: The platform supports the development of targeted therapies for infectious diseases, cancer, and autoimmune conditions by allowing scientists to observe immune responses over extended periods and in specific tissues.
• Branch of Science: Immunology and Molecular Biology
• Additional Detail: Current limitations exist regarding non-dividing cells such as neurons due to nuclear architecture or cell size, prompting the immediate development of a second-generation version to expand compatibility.

Scientists in the Blavatnik Institute at Harvard Medical School and MIT have created a new family of tools that, for the first time, illuminates the missing half of how the immune system uses molecules called cytokines to communicate with the rest of the body.

The work, described in Cell and supported with funding from the U.S. federal government, could provide a transformative view of immune response and disease, which in turn could lead to new drugs for infectious diseases, cancer, allergies, and autoimmune diseases.

Immune cells use cytokines to communicate with other cell types. These messages play many important roles in protecting the body and maintaining a stable, steady internal environment, including initiating, coordinating, and terminating immune responses such as fever and inflammation.

Scientists know a lot about how, when, and why immune cells create and send out cytokines and have used this information to create important medicines to fight infectious diseases, cancers, and autoimmune diseases. However, scientists have had a hard time identifying which cells receive specific cytokine signals as well as when and how they respond when called upon.

“Imagine you’re watching a baseball game, and all you can see is the hitters,” said study co-senior and lead author Jun Huh, associate professor of immunology at HMS. “It’s very difficult to understand what’s happening if you don’t know anything about who the players are in the field, where they are, or what they do if they catch the ball.”

The new tools, called cytokine cellular locating platforms (CyCLoPs), at last allow researchers to tag the cells that respond to specific cytokines in particular situations.

“We have a tool that gives us a better view of the whole game,” Huh said. “This way we can follow all of the players on the field over an extended time.”

New tool to visualize cytokine receptor activity

Huh became interested in solving the problem of tracking cytokine responses because it stood in the way of his desire to understand how the immune system moderates its responses, especially in the context of immune disease and neurological disorders, and to capitalize on that knowledge to make better drugs.

CyCLoPs works like a biological highlighter: When a cytokine binds to its receptor on a cell, the tool tags the cell with a fluorescent marker.

For this study, tests in cell cultures showed that CyCLoPs produced a strong, clear signal and could be adapted to detect many different cytokines.

The researchers also developed two preclinical mouse models that allowed them to test CyCLoPs in organs and tumors. With one mouse type, they tagged cells that responded to the cytokine interleukin-17A (IL-17A) in the lining of the lower small intestine after exposure to a particular gut bacterial species. With the other mouse type, they found that the cytokine interferon gamma (IFN-γ), which is thought to protect against tumors, in this case actually weakened a group of immune “killer” T cells, when tagged cells showed signs of being less effective at killing the cancer cells.

Because the fluorescent markers that CyCLoPs delivers make their way to cell nuclei, each tagged cell — and its descendants — can be found and studied later.

This means the durable, genetically traceable tags will make it possible to, for example, see how cells that have responded to cytokines react if they are later re-exposed to the same immune stimuli that triggered the original cytokine release.

Next steps

The new technology still has limitations. The strength of the cytokine reception signal varies in different cell types, which means it’s not an effective tool for comparing the relative strength of response in different cell types, Huh said.

CyCLoPs had a particularly hard time labelling cell types that don’t proliferate, including neurons, which is ironic, since the researchers originally set out to build the tool to explore how cytokines help the immune system interact with the nervous system.

Huh hypothesizes that this may be due either to the large size and elongated shape of neurons, or to the architecture of the nucleus of nondividing cells being less compatible with the tagging system.

“We’re very excited about what this new system can do, but we’re also going to keep expanding its capabilities,” he said. “We’re already working on CyCLoPs 2.0.”

Additional information: The Biopolymers Facility Next-Gen Sequencing Core at HMS provided expertise and instrument availability for bulk RNA-seq. The Dana-Farber/Harvard Cancer Center (DF/HCC) Rodent Histopathology Core at HMS performed frozen sample sections.

Disclaimer: Huh and Choi consult for CJ CheilJedang, hy, and Interon Laboratories. Huh is an advisor on the Samsung Biologics Advisory Board. Lu and Huh filed a provisional patent application related to this work.

Funding: This study was supported by the Burroughs Wellcome Fund and National Institutes of Health (grants 5R01DK110559, 5R01MH119459, and 1RF1AG080738).

Published in journal: Cell

Title: In vivo detection of immune responses via cytokine activity labeling

Authors: Guangqing Lu, Shanshan Zhang, Mengyang Feng, Eunha Kim, Daniel Cho, Jae Hyun Kim, Hannah Caris, Lev Silberstein, Gloria B. Choi, and Jun R. Huh

Source/Credit: Harvard Medical School | Jake Miller

Reference Number: imgy021126_01

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