Interleukin-1alpha causes people to choke on air
Osaka University Research News Jan 30, 2017
Researchers have pinpointed specific molecular events that could explain allergic reactions to air pollution.
Photos of cities darkened by pollution are becoming evermore common. These same cities are seeing a rise in cases of asthma and other respiratory ailments, marking a relationship between pollution and health costs. Nanoscopic particulates polluting the air enter the lungs to cause the allergic reactions. Which immune–related events in the lung lead to this response, however, are unclear.
"We found that particulates kill macrophages, which then go on to release interleukin–1alpha (IL–1alpha)", explains Etsushi Kuroda, who first–authored a new study in Immunity that indicates IL–1alpha triggers a series of events that causes respiratory illnesses. The release of IL–1alpha in mice primed the lungs for inflammation when the mice were later exposed to an allergen. Kuroda added, "Particulates that did not kill macrophages did not cause an allergic reaction."
However, the vulnerability of macrophages to particulates remains unclear, which is why understanding the events following IL–1alpha secretion may be key to prevention and treatment.
"IL–1alpha secretion was followed by the formation of iBALTs. iBALTs are frequently found in infected or inflamed lungs and in patients with asthma," said Osaka University Professor Ken J. Ishii, who led the study. The increase in iBALTs led to an increase in IgE antibodies, which intensified the immune response. On the other hand, mutant mice that were insensitive to IL–1alpha did not produce iBALTs and reduced IgE responses.
The presence of iBALTs would suggest that a human population could remain susceptible to high levels of asthma attacks even on clear days, as the iBALTs could form on days of high pollution, but the patient could then be exposed to the allergen much later.
This finding suggested that iBALTs could prime the lungs to an allergic reaction, which is why Ishii believes that iBALTs could make a promising therapeutic target to combat the rise of respiratory illnesses associated with air pollution. But first, he said, "we must identify the molecular signals and key chemicals that form these iBALTs."
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Photos of cities darkened by pollution are becoming evermore common. These same cities are seeing a rise in cases of asthma and other respiratory ailments, marking a relationship between pollution and health costs. Nanoscopic particulates polluting the air enter the lungs to cause the allergic reactions. Which immune–related events in the lung lead to this response, however, are unclear.
"We found that particulates kill macrophages, which then go on to release interleukin–1alpha (IL–1alpha)", explains Etsushi Kuroda, who first–authored a new study in Immunity that indicates IL–1alpha triggers a series of events that causes respiratory illnesses. The release of IL–1alpha in mice primed the lungs for inflammation when the mice were later exposed to an allergen. Kuroda added, "Particulates that did not kill macrophages did not cause an allergic reaction."
However, the vulnerability of macrophages to particulates remains unclear, which is why understanding the events following IL–1alpha secretion may be key to prevention and treatment.
"IL–1alpha secretion was followed by the formation of iBALTs. iBALTs are frequently found in infected or inflamed lungs and in patients with asthma," said Osaka University Professor Ken J. Ishii, who led the study. The increase in iBALTs led to an increase in IgE antibodies, which intensified the immune response. On the other hand, mutant mice that were insensitive to IL–1alpha did not produce iBALTs and reduced IgE responses.
The presence of iBALTs would suggest that a human population could remain susceptible to high levels of asthma attacks even on clear days, as the iBALTs could form on days of high pollution, but the patient could then be exposed to the allergen much later.
This finding suggested that iBALTs could prime the lungs to an allergic reaction, which is why Ishii believes that iBALTs could make a promising therapeutic target to combat the rise of respiratory illnesses associated with air pollution. But first, he said, "we must identify the molecular signals and key chemicals that form these iBALTs."
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