Researchers at the University of Montreal Hospital Research Centre (CRCHUM) have identified a promising solution to improving treatments offered to patients with cystic fibrosis.
This advancement, published in Frontiers in Cellular and Infection Microbiology, could lead to the development of new personalized therapies in the near future.
“Adding molecules called quorum-sensing inhibitors to current drugs reduces bacterial production of certain harmful residues and restores the efficacy of existing treatments on the cells of cystic fibrosis patients,” explained Emmanuelle Brochiero, a researcher at the CRCHUM and a professor at Université de Montréal.
Cystic fibrosis is a fatal genetic disease affecting children and adults. It is characterized by excessive mucus production in several organs, recurrent bacterial infections and progressive lung damage. To date, no cure has been found. When the disease is too far advanced, the only option is to perform a lung transplant.
One of the difficulties encountered in cystic fibrosis research is the disease’s variability from one patient to another. In fact, there are more than 2,000 possible gene mutations. Over the past decade, two prescription medications have been offered to eligible patients: Kalydeco for those with rare mutations (fewer than 4 per cent of patients), and Orkambi for the more frequent mutation (79 per cent of patients). Unfortunately, these two drugs have only limited efficacy.
Brochiero’s team is trying to understand why. With the consent of patients, she collects nasal cells and also reuses the lungs removed from patients with cystic fibrosis at the time of transplant. To study the disease and test therapeutic approaches, the scientists then manage to recreate airway epithelial tissue, via tissue engineering.
“Patients with cystic fibrosis present genetic defects that cause the abnormal production of a protein called CFTR in cells and an excess of mucus in organs,” said Brochiero. “Current drugs act to correct the defect in the CFTR protein. In a sterile in vitro environment, Kalydeco and Orkambi treatments work well. But in real life, the lungs of sick patients are colonized by bacteria, Pseudomonas aeruginosa in particular. Much evidence has indicated that the bacteria could interfere with the treatment. Thanks to this study, we have been able to determine which substances released by the bacteria could reduce the efficacy of the treatments.”
Some of these harmful particles are controlled by the bacterial quorum-sensing gene lasR. “During the disease, this bacterial gene mutates and the production of harmful products varies,” said Émilie Maille, a research assistant in Brochiero’s laboratory and the study’s lead author. “Our work confirms that different bacterial strains, depending on whether they come from acute infections – especially in young patients – or chronic infections – especially in older patients – affect treatment efficacy in different ways.”
The researchers then tested, in vitro, the effect of adding a quorum-sensing inhibitor from the furanone family. “We showed that this molecule, by reducing the bacterial production of harmful residues, maintains treatment efficacy in the cells of patients with cystic fibrosis,” Brochiero said.
Other research has to be conducted to confirm the efficacy and safety of quorum-sensing inhibitors, which may eventually be offered as a supplement to current drugs.
But this study has already opened a new personalized-medicine approach to cystic fibrosis. “By using cells collected from patients, we think that it will be possible to test and predict the efficacy of treatments such as Kalydeco and Orkambi, based on the bacteria taken from each patient,” concluded Brochiero. “We’ll evaluate the ability of the treatments to repair damaged lung tissue. And lastly, we’ll work on identifying the most effective molecules, such as bacterial quorum-sensing inhibitors, that can counteract the harmful effect of infections. The ultimate goal is to improve treatments for patients and, by doing so, extend their life.”
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