Scientists at the Scripps Research Institute (TSRI) have mapped key elements of a severe immune overreaction—a “cytokine storm”—that can both sicken and kill patients who are infected with certain strains of flu virus.
Their findings, published in this week’s online Early Edition of the Proceedings of the National Academy of Sciences, also clarify the workings of a potent new class of anti-inflammatory compounds that prevent this immune overreaction in animal models.
“We show that with this type of drug, we can quiet the storm enough to interfere with the virus-induced disease and lung injury, while still allowing the infected host to mount a sufficient immune response to eliminate the virus,” says John R. Teijaro, an assistant professor in TSRI’s Department of Immunology and Microbial Science and first author of the study.
“This study provides insights into mechanisms that are chemically tractable and can modulate these cytokine storms,” says Hugh Rosen, professor in TSRI’s Department of Chemical Physiology and senior author of the study with Michael B. A. Oldstone, professor in TSRI’s Department of Immunology and Microbial Science.
A cytokine storm is an overproduction of immune cells and their activating compounds (cytokines), which, in a flu infection, is often associated with a surge of activated immune cells into the lungs. The resulting lung inflammation and fluid buildup can lead to respiratory distress and can be contaminated by a secondary bacterial pneumonia—often enhancing the mortality in patients.
This little-understood phenomenon is thought to occur in at least several types of infections and autoimmune conditions, but it appears to be particularly relevant in outbreaks of new flu variants. Cytokine storm is now seen as a likely major cause of mortality in the 1918-20 “Spanish flu”—which killed more than 50 million people worldwide—and the H1N1 “swine flu” and H5N1 “bird flu” of recent years. In these epidemics, the patients most likely to die were relatively young adults with apparently strong immune reactions to the infection—whereas ordinary seasonal flu epidemics disproportionately affect the very young and the elderly.
For the past eight years, Rosen’s and Oldstone’s laboratories have collaborated in analyzing the cytokine storm and finding treatments for it. In 2011, led by Teijaro, who was then a research associate in the Oldstone Lab, the TSRI team identified endothelial cells lining blood vessels in the lungs as the central orchestrators of the cytokine storm and immune cell infiltration during H1N1 flu infection.
In a separate study, the TSRI researchers found that they could quiet this harmful reaction in flu-infected mice and ferrets by using a candidate drug compound to activate immune-damping receptors (S1P1 receptors) on the same endothelial cells. This prevented most of the usual mortality from H1N1 infection—and did so much more effectively than the existing antiviral drug oseltamivir, although the combination of both therapies worked even better. “That was really the first demonstration that inhibiting the cytokine storm is protective,” says Teijaro.
For the new study, Teijaro and his colleagues set out to map the major elements of the cytokine storm in H1N1 infection. To do so, they used gene knock-out techniques to breed mice that lack one or more molecular sensors of influenza virus infection and then observed the response to infection by H1N1 influenza virus.
The experiments showed that knocking out any one infection-sensing pathway has relatively modest effects on damping the cytokine and immune cell lung-infiltration response. In each case, an experimental drug compound (CYM5442) that activates S1P1 receptors knocked it down much more.
“What this shows is that our drug is working not through one selective pathway but much more broadly,” says Teijaro. “Many different cytokines are induced in this reaction, so just blocking one is surely not enough to reduce the lung disease.”
While CYM5442’s effect is broad, its action is selective on cells that bear the sphingosine-1-phosphate 1 receptor (S1P1R). Teijaro points out that it is also milder than those of steroids, which act indiscriminately on all lymphoid cells, and other strong immunosuppressant drugs, which may block the immune response so completely that an infecting virus ends up replicating out of control.
An optimized version of CYM5442, initially developed by Rosen and fellow TSRI chemist Ed Roberts, has been licensed to the pharmaceutical company Receptos. It is now in Phase 3 clinical trials for treating relapsing-remitting multiple sclerosis and Phase 2 trials for ulcerative colitis. Other S1P1 receptor agonists are in development for inflammatory conditions. A less-specific S1P receptor agonist—which hits S1P1, but also hits S1P3, S1P4 and S1P5, with potential off-target effects—is already approved for treating multiple sclerosis.
“We’d like to understand all the pathways through which S1P1 agonists work and, by pinpointing specific stop/start points, figure out how best to target those pathways with future drugs,” says Teijaro, who plans further studies with his colleagues to determine what other cell types are involved in orchestrating and possibly quieting the cytokine storm. “I’m hoping our work can further contribute to TSRI’s long track record of success in employing small molecule probes coupled to genetic and biochemical tools to provide biological insight into pathological disease processes.”
In addition to Teijaro, Rosen and Oldstone, the co-authors of the study, “Mapping the innate signaling cascade essential for cytokine storm during influenza virus infection,” were Kevin B. Walsh and Stephanie Rice, both of the Oldstone laboratory during the study.
Funding was provided in part by National Institutes of Health grants AI057160 (MBAO), AI055509 and MH084512 (HR) and American Heart Association Fellowship 11POST7430106 (JRT).
Source: Scripps Research Institute
Scripps Research Institute Scientists Describe Deadly Immune 'Storm' Caused by Emergent Flu Infections
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