Project description:Adults with cystic fibrosis (CF) have chronic antibiotic-resistant polymicrobial lung infections, the leading cause of death in CF. We developed a polymicrobial culture model containing four genera that represents a ‘pulmotype’ detected in ~34% of lung infections in people with CF (pwCF), and accounts for 27% of the variability in lung function. This community, comprised of Pseudomonas aeruginosa, Staphylococcus aureus, Streptococcus sanguinis, and Prevotella melaninogenica, is grown in synthetic CF media (SCFM2) under anoxic conditions that mimic the environment in mucus plugs in CF. We have shown that Pseudomonas in monoculture communicates with primary human bronchial epithelial cells (pHBEC) by secreting bacterial extracellular vesicles (bEVs) that diffuse through mucus and deliver virulence factors, DNA, and RNA to pHBEC. We report herein that each bacterial genus in the polymicrobial community secretes bEVs containing proteins and RNAs predicted to promote the establishment of chronic infection by enhancing virulence and biofilm formation, and upregulating the stress response and pro-inflammatory pathways in pHBEC. This response is most pronounced in CF pHBEC. Trikafta, a highly effective drug, does not ameliorate the response or return it to WT levels. Bacterial EVs also inhibited Trikafta-stimulated CFTR Cl- currents by CF pHBEC. These studies provide insight into why Trikafta does not eliminate polymicrobial lung infections and a hyperinflammatory lung environment in pwCF.

Project description:Adults with cystic fibrosis (CF) have chronic antibiotic-resistant polymicrobial lung infections, the leading cause of death in CF. We developed a polymicrobial culture model containing four genera that represents a ‘pulmotype’ detected in ~34% of lung infections in people with CF (pwCF), and accounts for 27% of the variability in lung function. This community, comprised of Pseudomonas aeruginosa, Staphylococcus aureus, Streptococcus sanguinis, and Prevotella melaninogenica, is grown in synthetic CF media (SCFM2) under anoxic conditions that mimic the environment in mucus plugs in CF. We have shown that Pseudomonas in monoculture communicates with primary human bronchial epithelial cells (pHBEC) by secreting bacterial extracellular vesicles (bEVs) that diffuse through mucus and deliver virulence factors, DNA, and RNA to pHBEC. We report herein that each bacterial genus in the polymicrobial community secretes bEVs containing proteins and RNAs predicted to promote the establishment of chronic infection by enhancing virulence and biofilm formation, and upregulating the stress response and pro-inflammatory pathways in pHBEC. This response is most pronounced in CF pHBEC. Trikafta, a highly effective drug, does not ameliorate the response or return it to WT levels. Bacterial EVs also inhibited Trikafta-stimulated CFTR Cl- currents by CF pHBEC. These studies provide insight into why Trikafta does not eliminate polymicrobial lung infections and a hyperinflammatory lung environment in pwCF.

Project description:Cystic fibrosis (CF), resulting from a dysfunction in the cystic fibrosis transmembrane conductance regulator (CFTR), affects multiple organs through mucus obstruction and differences in secretion. The CFTR modulator drug combination elexacaftor/tezacaftor/ivacaftor (ELX/TEZ/IVA, ETI) has markedly improved clinical symptoms, but its broader molecular and systemic effects remain to be fully elucidated. We employed mass spectrometry-based proteomics to compare the plasma and serum proteomes of person with CF (pwCF) treated with the earlier, less effective lumacaftor/ivacaftor (LUM/IVA) combination against those receiving the more potent ELX/TEZ/IVA therapy. Our analysis revealed both specific and common pharmacodynamic signatures associated with inflammation and metabolic processes under each treatment regimen. Notably, ELX/TEZ/IVA therapy exhibited more consistent alterations across pwCF that were directed towards profiles observed in healthy individuals. Furthermore, by comparing sputum and serum proteomes of ELX/TEZ/IVA treated pwCF we identified counter directional changes in the pulmonary surfactant-associated protein B, SFTPB, a potential biomarker of lung permeability, which also correlated with lung function improvements and could be validated in an independent cohort. This study provides a comprehensive resource that enhances our understanding of CFTR modulator-driven proteome alterations, offering insights to both systemic and local protein regulation in CF. Our findings indicate that ELX/TEZ/IVA promotes broader systemic health improvements, providing critical insights that could shape future therapeutic strategies in CF.

Project description:Progressive lung disease remains the major cause of morbidity and mortality of people with cystic fibrosis (CF). CF lung disease evolves from mucus obstruction into non-resolving airway inflammation, bronchiectasis, and damage that impairs respiratory and fitness activity. Therefore, therapeutic strategies that promote resolution of airway inflammation in CF to alleviate the burden of airflow obstruction and improve physical capacity are of wide interest. Here, we report that the proresolving lipid mediator resolvin (Rv) D1 halts mucus-driven inflammation in CF human cells and in vivo. RvD1 dampened migration and pathogenic phenotypes of neutrophils from volunteers with CF as well as inflammatory signaling pathways of CF bronchial epithelial cells triggered by CF mucus. In mice overexpressing the β-subunit of the epithelial Na+ channel (βENaC) RvD1 administration prevented and reverted lung inflammation caused by mucus accumulation and promoted the resolution of pulmonary exacerbation caused by P. aeruginosa. RvD1 also significantly improved physical activity and energy expenditure that are impaired in βENaC mice compared to wild type littermates. These findings demonstrate efficacy of RvD1 in enhancing resolution of lung disease and chronic inflammation associated with mucus obstruction and provide proof of concept for its potential therapeutic approach in FC.

Project description:Despite Cystic Fibrosis Transmembrane conductance Regulator (CFTR) being identified as the gene responsible for cystic fibrosis (CF), there are multiple CF-causing genetic variants affecting phenotypes in people with CF (pwCF). Animal models generated so far have introduced various mutations in the Cftr gene, but none replicate the genetic diversity found in humans. Yet, CF mice exhibit variable degrees of extra-pulmonary phenotypes, lacking the lung dysfunction and susceptibility to infection that are primary manifestations in humans, thus limiting pathogenic studies. We opted for Collaborative Cross (CC) mice, a genetically diverse animal resource population, to identify a suitable genetic background for CF. Here, we show that ΔF508-Cftr homozygosity in CC037 mice produced a fully penetrant lethal phenotype within two months of age. Early in life, in the absence of mucus production, inflammatory and immune responses arise in the lungs and blood. The CF murine lung exhibits an activated immunoinflammatory and defense response to bacterial pathogens, sharing microbiology with the gut. Intestinal mucosal function shows impaired barrier integrity, provides an environmental niche for bacterial accumulation and triggers inflammation. Treating gut pathology protected CF mice from respiratory and systemic inflammation, establishing the groundwork for inter-organ communication, likely via the gut-lung axis. In sum, we report the first mouse model that reproduces human CF and provides a paradigm for mouse modeling relevant to multiple other genetic disorders. The significance of our findings is fundamental for CF, supporting the role of the gut in lung pathology and suggesting new diagnostic and therapeutic interventions beyond lung-related treatments.

Project description:Pseudomonas aeruginosa chronically infects the lungs of people with cystic fibrosis (pwCF), where it produces a broad range of proteases that impact host immunity and inflammation. While some studies suggest these enzymes induce inflammation and may contribute to the excessive inflammatory response in pwCF, others indicate that they degrade cytokines and suppress the immune response. Here, we investigate the role of P. aeruginosa proteases in chronic CF lung inflammation by culturing clinical isolates under physiologically relevant conditions (synthetic CF sputum medium) and studying the inflammatory response in an organotypic 3-D lung cell culture model. Exposure to supernatants from isolates with proteolytic and elastolytic activity led to cytokine degradation and reduced cytokine release in the 3-D lung model. To identify the specific protease(s) responsible for the observed degradation effects, we performed a proteomics analysis on the supernatants of the P. aeruginosa CF isolates with and without proteolytic and elastolytic activity. Using functional annotation, 79 proteases were identified in the supernatants of the clinical isolates, with extracellular proteases among the most differentially expressed in the proteolytically active isolate group. The metalloprotease Elastase B (LasB) exhibited the highest level of differential expression. Therefore, we determined the specific contribution of LasB to the observed cytokine degradation by utilizing P. aeruginosa lasB knockout mutants. Compared to the lasB mutant, the wild-type strain significantly decreased inflammation by degrading key lung cytokines including MCP-1, IL-1β, GM-CSF and IL-8. While this study brings to light a key role for LasB, our findings demonstrate that immunomodulation by P. aeruginosa most likely involves the combined action of multiple proteases. This study provides a foundation for future research into protease-mediated immune evasion during chronic infection.

Project description:Lung disease causes most of the morbidity and mortality in cystic fibrosis (CF). However, understanding its pathogenesis has been hindered by lack of an animal model with characteristic features of CF. To overcome this problem, we recently generated pigs with targeted CFTR genes. We now report that within months of birth, CF pigs spontaneously develop hallmark features of CF lung disease including airway inflammation, remodeling, mucus accumulation, and infection. Their lungs contained multiple bacterial species, suggesting an equal opportunity host defense defect. In humans, the temporal and/or causal relationships between inflammation and infection have remained uncertain. To investigate these processes, we studied newborn pigs. Their lungs showed no inflammation, but were less often sterile than controls. Moreover, after intrapulmonary bacterial challenge, CF pigs failed to eradicate bacteria as effectively as wild- type pigs. These results suggest that impaired bacterial elimination is the pathogenic event that initiates a cascade of inflammation and pathology in CF lungs. Finding that CF pigs have a bacterial host defense defect within hours of birth provides an exciting opportunity to further investigate pathogenesis and to test therapeutic and preventive strategies before secondary consequences develop. Pig model of human CF lung disease

Project description:Sweat plays a crucial role in thermo-regulation and skin health and potentially antimicrobial defense. Its composition is highly dynamic and its homeostasis involves a fine tuning of metabolic pathways. In-depth profiling of sweat protein composition will increase our understanding of skin disorders. Cystic Fibrosis (CF) is associated with high NaCl sweat concentration due to the absence of the CFTR protein. Patients with CF (pwCF) often display aquagenic palmoplantar keratodermia, a rare skin disorder characterized by skin wrinkling with oedema and whitish papules on the palms and/or soles, the pathophysiology of which is unknown. We report an in-depth analysis of the human sweat proteome of pwCF patients in comparison with that of healthy subjects (S).

Project description:A set of paired lung and sinus mucus samples from CF patients, sinus mucus from non-CF sinusitis patients, and healthy controls. LC-MS/MS UPLC

Project description:Hallmarks of cystic fibrosis (CF) are increased viscosity of mucus and impaired mucociliary clearance within the airways due to mutations of the cystic fibrosis conductance regulator gene. This paves the way for the colonization by microbial pathogens and the concomitant establishment of chronic infections leading to lung tissue damage, reduced lung function, and to decreased life expectancy. Although microbial infections play a key role during disease progression, only a few studies investigated the pathophysiology of the microbial community in vivo so far. Moreover, no CF study so far applied metaproteomics, a powerful approach to unravel molecular mechanisms of microbial infection, mainly reasoned due to (I) the challenging processability of inhomogeneous, viscous, slimy sputum, and (II) the high number of human proteins masking comparably low abundant microbial proteins. Consequently, we developed a reliable, reproducible and widely applicable protocol for sputum processing, microbial enrichment, and subsequent metaproteomics analyses with a focus on microbial pathogens overcoming the aforementioned challenges. Metaproteomics data were complemented and validated by 16S sequencing, metabolomic as well as microscopic analyses. In total, we processed 21 CF sputum samples and selected three for detailed metaproteome analysis. The number of bacterial proteins/protein groups increased from 199-425 to 392-868. Moreover, our data suggest that the arginine deiminase pathway and multiple proteases and peptidases identified from various bacterial genera are so far underappreciated in their contribution to the CF pathophysiology. By providing a standardized and effective protocol for sputum processing and microbial enrichment, our study represents an important basis for future studies investigating the physiology of microbial pathogens in CF in vivo – an important prerequisite for the development of novel antimicrobial therapies against mucoviscidosis.