‘Chronic Lung-transplant Rejection Has Been a Black Box’
New Northwestern Medicine study provides answers and drug targets
More than 50% of lung-transplant recipients experience a rejection of their new lung within five years of receiving it, yet the reason why this is such a prevalent complication has remained a medical mystery.
Now, a new Northwestern Medicine study has found that, following transplant and in chronic disease states, abnormal cells emerge and “conversations” between them drives the development of lung damage and transplant rejection.
These findings not only help answer why rejection occurs, but they also have spurred immediate exploration of new drugs to treat transplant rejection and other lung-scarring diseases.
“Chronic lung-transplant rejection has been a ‘black box.’ We knew it happened but did not exactly know why,” said corresponding author Dr Ankit Bharat, professor of thoracic surgery at Northwestern University Feinberg School of Medicine and executive director of the Northwestern Medicine Canning Thoracic Institute. “Our study provides the first comprehensive cellular and molecular roadmap of the disease.”
The study was published in JCI Insight.
Leading cause of death after the first year of transplantation
Surgeons perform approximately 3000 to 3500 lung transplants each year in the U.S., and more than 69 000 have been performed worldwide to date. Chronic lung allograft dysfunction (CLAD), which encompasses several manifestations of chronic lung rejection, remains the leading cause of death after the first year of transplantation. There currently are no effective treatments for CLAD once it develops, leaving patients with only one option: re-transplantation.
In the new study, after evaluating almost 1.6 million cells, scientists distinguished between abnormal cells from the donor lung versus cells from the recipient’s own immune system. They discovered the donor-derived structural cells and recipient’s immune cells talk to each other in harmful ways that perpetuate lung damage. The findings could lead to new drug targets and provide insights that could help patients with various lung-scarring diseases, not just transplant recipients.
Comparing rejection to other scarring lung diseases
The scientists discovered a rogue cell type (KRT17 and KRT5 cells) that drives lung scarring across multiple diseases, including idiopathic pulmonary fibrosis, interstitial lung disease, COPD, COVID-19 lung damage and transplant rejection. By integrating data from this array of scarring lung diseases, the scientists created the first comprehensive reference map showing which molecular features are shared across conditions and which are unique to each disease.
“By comparing chronic rejection to other scarring lung diseases, we identified both shared and unique features,” said Bharat, who also is a member of the Robert H. Lurie Comprehensive Cancer Center of Northwestern University. “This means treatments developed for one condition might help others. The benefits extend far beyond transplant patients.”
The scientists also identified previously unrecognised cell populations in rejected lungs. These include “exhausted” T cells that remain activated but dysfunctional, and “super-activated” macrophages that promote inflammation and scarring.
Lastly, the scientists developed new computational methods to analyse data from multiple studies together, overcoming technical barriers that previously prevented this kind of comprehensive analysis, Bharat said.
New drug targets identified
The scientists pinpointed specific genes and signaling pathways (like PDGF, GDF15 and TWEAK) that drive scarring, which allows them to identify potential targets for new drugs, Bharat said. Some existing medications, such as nintedanib, and pirfenidone, which are approved (in the US) for other lung diseases, might be repurposed for transplant rejection, he said.
“The findings have immediate translational potential,” Bharat said. “We’re already exploring therapeutic strategies based on these discoveries.”
Broad impact on pulmonary fibrosis
While addressing CLAD was the main focus of the paper, this research has major implications for understanding and treating all forms of pulmonary fibrosis, Bharat said.
“The molecular pathways and cell types we identified are relevant to conditions affecting hundreds of thousands of patients with various lung-scarring diseases, not just transplant recipients,” Bharat said. “This work essentially provides a ‘Rosetta Stone’ for understanding lung scarring regardless of the initial trigger.”
Source: Northwestern University
