News Release

PHILADELPHIA—Asthma is an enormous public health problem that continues to grow larger, in part because scientists don’t fully understand how it is caused. Existing therapies don’t cure the disease and often don’t even significantly alleviate the symptoms. Now, scientists from the Perelman School of Medicine at the University of Pennsylvania and Rutgers University have identified a biological pathway that potentially explains why current asthma therapies don’t work well in many cases—and might be targeted to help those patients.


Increased neuropeptide Y expression in the epithelium of Foxp1/4 double knockout mouse lung tissue (arrowheads) compared to control mouse lung tissue.
Ai = airway.

Credit: The lab of Edward E. Morrisey, PhD, Perelman School of Medicine, University of Pennsylvania, Journal of Clinical Investigation

Asthma is a chronic condition that affects more than 25 million people in the United States alone, including more than 7 million children. It accounts for nearly 2 million ER visits annually and about 1.5 million patient-days of hospital inpatient care.

“Only 60 percent of asthma patients have an inflammatory or allergic component to their asthma and 40 percent of asthma patients wheeze in part due to intrinsic abnormalities of epithelial and smooth muscle cells,” said co-senior author Edward E. Morrisey, PhD, a professor of Cell and Developmental Biology and director of the Penn Center for Pulmonary Biology at Penn.

“Curiously, these patients are refractory to current therapies,” said co-senior author Reynold A. Panettieri, Jr., MD, Vice Chancellor of Translational Medicine and Science at Rutgers. “There’s a real need to understand the non-inflammatory aspects of asthma, and with this study we’re getting closer to that understanding.”

The study, which appears in the current issue of the Journal of Clinical Investigation, is a collaboration between the Morrisey laboratory and the laboratory of Panettieri, an asthma specialist who moved from Penn Medicine to Rutgers Biomedical and Health Sciences last summer.

Clues from Goblet Cells

The discovery of the possible new asthma pathway emerged from basic research by Morrisey and colleagues on the developmental biology of the epithelial layer of cells that line the lung and its airways. In experiments published in 2012, they found that the transcription factors Foxp1 and Foxp4—which can switch certain gene programs on or off—normally repress the production of mucus-secreting goblet cells in the lung epithelia of mice. Genetic inactivation of these two transcription factors caused goblet cells to differentiate abnormally.

Increased goblet cell differentiation in the airways is a hallmark of asthma. From this, the Morrisey lab investigated whether loss of the Foxp1/4 genes, specifically in the airway epithelium of the lung, also causes an asthma-like condition in mice.

In an initial set of experiments, the team, including first author Shanru Li, a staff scientist in the Morrisey lab, studied the physiological function of airways lacking the Foxp1/4 genes in adult mice. “We found that the airways of these mice did indeed behave like asthmatic human airways,” Morrisey said.

A classic sign of asthma is airway hyper-responsiveness (AHR)—an abnormally strong tendency for the smooth muscle cells underlying the airway epithelium to contract and cause a partial closure of the airway. The team found that the mice lacking airway Foxp1/4 showed significantly greater signs of AHR, compared to control mice, especially when experimentally challenged with airway irritants. “At the high doses of the challenge the Foxp1/4-knockout mice basically started to die because their airways closed off,” Morrisey said.

Intriguingly, the airway lining in the Foxp1/4-knockout mice did not show signs of the type of inflammation that is typically associated with asthma and targeted with standard asthma drugs.

Neuropeptide Y – The Key to Non-inflammatory Asthma?

To find out the principal cause of the hyper-responsiveness in the airways of these mice, the researchers looked at the gene expression patterns of the affected airway epithelial cells, comparing them to the patterns seen in control mice that have normal levels of Foxp1/4 expression.

“Because only Foxp1/4 genes were missing from the airway epithelium of these mutant mice, we hypothesized that epithelial cells in the mutants were secreting a factor that was causing the underlying smooth muscle cells to contract. Therefore, we looked specifically for expression changes in genes encoding molecules that could be secreted from the epithelial cells and be received by the airway smooth muscle cells,” Morrisey said.

One such molecule, neuropeptide Y (NPY), stood out well above the rest—it was not expressed in control airway epithelial cells but was expressed at high levels in the airway epithelia of the knockout mice.

NPY is a signaling molecule and neurotransmitter found abundantly in the nervous system and some other parts of the body. Its many biological actions include stimulating the constriction of blood vessels. Previous research has linked variants of its gene to increased asthma risk, but NPY hasn’t been known to have a direct role in asthma.

Morrisey’s team showed that NPY has a significant role in asthma by deleting the NPY gene while at the same time deleting the Foxp1/4 genes. This resulted in the airway hyper-responsiveness that is observed in Foxp1/4-mutant mice to return to almost normal levels. Importantly, since changes in NPY expression have been linked to asthma in humans, the investigators tested whether NPY could directly cause airway hyper-responsiveness in human lung tissue. These experiments showed that when normal human lung airways are exposed to NPY, they exhibit a marked increase in hyper-responsiveness to methacholine challenge. In all of these experiments, the inflammatory response remained unchanged, indicating that NPY did not cause alterations in the immune response that could cause asthmatic symptoms.

“These data strongly suggest that NPY can cause airway hyper-responsiveness in human lungs and could be a causative mechanism in human asthma,” Morrisey said.

“Further, the molecular mechanisms mediating airway hyper-responsiveness occur at the level of smooth muscle where NPY amplifies smooth muscle contraction at all mediators by activating Rho Kinase, a pivotal signaling molecule in the bronchoconstriction pathway," Panettieri said. It also suggests that inhibiting NPY activity in people with asthma, perhaps with an inhaled medication, might help the millions of patients who get little or no benefit from current asthma therapies.

Pharmaceutical companies have already developed compounds that block NPY signaling for other applications such as obesity and hypertension. “Testing whether these NPY inhibitors would help human asthma patients would be worthwhile given the results of our studies” Morrisey said.

In addition to setting up tests of NPY-blocking drugs, he and his team hope to replicate their mouse-model findings in a larger animal model of asthma, which better simulates the human disease.

Other co-authors of the study included Cynthia Koziol-White, Joseph Jude, Meiqi Jiang, Hengjiang Zhao, Gaoyuan Cao, Edwin Yoo, William Jester from Rutgers and Michael P. Morley, Su Zhou, Yi Wang, and Min Min Lu from Penn.

Funding was provided by the National Institutes of Health (HL071589, HL110942, HL110942).

Penn Medicine is one of the world’s leading academic medical centers, dedicated to the related missions of medical education, biomedical research, excellence in patient care, and community service. The organization consists of the University of Pennsylvania Health System and Penn’s Raymond and Ruth Perelman School of Medicine, founded in 1765 as the nation’s first medical school.

The Perelman School of Medicine is consistently among the nation's top recipients of funding from the National Institutes of Health, with $550 million awarded in the 2022 fiscal year. Home to a proud history of “firsts” in medicine, Penn Medicine teams have pioneered discoveries and innovations that have shaped modern medicine, including recent breakthroughs such as CAR T cell therapy for cancer and the mRNA technology used in COVID-19 vaccines.

The University of Pennsylvania Health System’s patient care facilities stretch from the Susquehanna River in Pennsylvania to the New Jersey shore. These include the Hospital of the University of Pennsylvania, Penn Presbyterian Medical Center, Chester County Hospital, Lancaster General Health, Penn Medicine Princeton Health, and Pennsylvania Hospital—the nation’s first hospital, founded in 1751. Additional facilities and enterprises include Good Shepherd Penn Partners, Penn Medicine at Home, Lancaster Behavioral Health Hospital, and Princeton House Behavioral Health, among others.

Penn Medicine is an $11.1 billion enterprise powered by more than 49,000 talented faculty and staff.

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