Scripps Research scientists have developed a new class of drug compounds that reduce harmful inflammation while leaving the body’s ability to fight infections intact—a long-sought goal in treating autoimmune diseases. The compounds, called ENDOtollins, work by interrupting a “molecular handshake” between two proteins inside immune cells. The research, published in Nature Chemical Biology, could lead to more targeted treatments for conditions like lupus, rheumatoid arthritis and juvenile arthritis, which together affect more than 15 million Americans.
“A key component of our approach is to begin by understanding the biological mechanisms at play,” says Sergio D. Catz, professor at Scripps Research and senior author. “By accomplishing this first, we can more easily target the pathway driving inflammation without affecting other important processes.”
Limits of current autoimmune therapies
Current autoimmune disease treatments like hydroxychloroquine work by broadly blocking endosomes, the compartments inside cells where incoming materials are sorted and processed, including molecules that trigger immune responses. While effective, this approach can lead to significant side effects—including gastrointestinal problems, and—less commonly—vision damage, causing a significant number of patients to stop treatment.
Catz and his team took a different approach: They focused on two proteins, Munc13-4 and syntaxin 7, that must bind together for immune sensors called Toll-like receptors (TLRs) to activate inside endosomes. This “molecular handshake” plays a key role in detecting the foreign DNA and RNA from invaders like viruses and bacteria. However, in autoimmune diseases, TLRs become overactive, detecting self-nucleic acids, for example, from neutrophil-extracellular traps, and trigger chronic, damaging inflammation even without a real threat.
Zeroing in on a protein handshake
In collaboration with co-author Hugh Rosen, a professor at Scripps Research and the Pearson Family Chair, the team screened roughly 32,000 compounds with the support of the institute’s Molecular Screening Center. The researchers identified molecules that specifically block the Munc13-4–syntaxin 7 interaction without disrupting other cellular functions. Because Munc13-4 is found mainly in immune cells, the compounds offer a targeted way to calm inflammation.
“Most treatments for autoimmune diseases manage symptoms; they don’t change the underlying course of the disease,” says Rosen. “What’s exciting about this approach is its potential to be disease-modifying: targeting the specific molecular machinery that drives inflammation, rather than broadly suppressing the immune system.”
A key innovation was screening compounds in an intact cellular environment. Unlike many drug screening approaches, which extract proteins from the cell, Catz and his team developed an approach that keeps cellular compartments intact.
“By maintaining the proteins in their natural environment, we increase the likelihood that compounds we find will actually work in living cells,” says Jennifer Johnson, first author and senior staff scientist at Scripps Research.
ENDO12 shows targeted anti-inflammatory effects
The most potent compound, ENDO12, reduced inflammation in animal models that were also given a TLR-activating molecule. Blood levels of inflammatory markers—including immune system activators IL-6 and IFN-γ, and the enzyme myeloperoxidase—dropped significantly in those that were treated.
Crucially, ENDO12 did not impair the animal models’ ability to fight a real viral infection: They showed a normal antiviral immune response when exposed to a virus. This selectivity addresses a major concern with immunosuppressive drugs: that dampening inflammation might leave patients vulnerable to infections.
What comes next for ENDOtollins
The team’s next steps include testing ENDOtollins in models that more closely mimic human autoimmune diseases, as well as further optimizing the compounds’ chemistry for potential clinical use.
Beyond autoimmune conditions, the researchers suggest ENDOtollins might help treat cytokine storms—the dangerous immune overreactions seen in patients with severe COVID-19 and as a side effect of CAR-T cancer therapy. Both involve excessive IL-6 and runaway inflammation.
While translating these findings into treatments for patients remains a long-term goal, Catz emphasizes that the mechanistic insights are valuable in their own right. ENDOtollins can serve as precision tools to probe other cellular processes regulated by endosomes and lysosomes—including pathways implicated in neurodegeneration and immune dysfunction. Understanding the basis of how these compartments become stressed or dysfunctional could have broad implications for understanding and treating human disease.