Asthma is severe when it cannot be controlled with maximum-dose inhaled therapies while management of comorbidities and other precipitating or aggravating factors has been optimized. Allergic bronchopulmonary aspergillosis (ABPA) is a complex bronchopulmonary disease resulting from immunological reactions against Aspergillus Fumigatus. The development of a model of bronchial epithelium generated from patients with chronic lung disease will allow the modeling of bronchial tissue to understand the formation of these mucus plugs. This study aims to validate this model The investigators propose to verify the feasibility of obtaining and comparing two epithelia in two populations based on the following experiments: Differentiation of an Induced Pluripotent Stem cell (iPSC) clone derived from blood sample (Peripheral Blood Mononuclear Cells) of Type 2 inflammation (T2) severe asthma and Allergic Bronchopulmonary Aspergillosis (ABPA) in order to obtain differentiated bronchial epithelia in vitro.
Asthma is severe when it cannot be controlled with maximum-dose inhaled therapies while management of comorbidities and other precipitating or aggravating factors has been optimized. Allergic bronchopulmonary aspergillosis (ABPA) is a complex bronchopulmonary disease resulting from immunological reactions against Aspergillus Fumigatus. At the cellular and molecular level, severe asthma and ABPA are chronic bronchial diseases characterized by type 2 (T2) airway inflammation, bronchial smooth muscle hyperplasia, excessive mucus production by mucus cell metaplasia and epithelial remodeling. Type 2 inflammation in asthma is predominant and is characterized by the accumulation of immune cells, such as eosinophils, mast cells, T-helper 2 (Th2) cells, innate lymphoid cells type 2 (ILC2s) and dendritic cells. Persistent airway obstruction despite maximal therapy is currently considered the greatest unmet medical need in asthma treatment. Fahy and colleagues published a key paper in 2018 that may explain airway obstruction. Using chest CT scans, they demonstrated the presence of mucus plugs that completely occlude segments of the airways of severe asthmatics. These mucus plugs are associated with a high number of circulating eosinophils in the blood. There is no large-scale model to model severe asthma and ABPA. The investigators propose to develop a bronchial epithelium with pluripotent stem cells (iPSC) in air-liquid interface called iALI generated from these patients in aim to model severe asthma and ABPA and in particular the epithelium. The secondary objectives aims to answer are: * Comparison of the iPSC derived airway epithelium with nasal epithelial cells isolated from the same patient (nasal brush). * To characterize the phenotype of the iPSC derived airway epithelium from ABPA and T2 severe asthma patient, in comparison to a healthy control. * Differentiation of iPSC into mature eosinophils * Co culture of the epithelia with iPSC derived eosinophils * Culture of iPSC derived airway epithelium with Charcot-Leyden crystal * Demonstrate the feasibility of obtaining iPSC from peripheral blood sampling.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
OTHER
Masking
NONE
Enrollment
4
A blood sample and a nasal brush for each participant. The nasal brushing will allow the isolation of epithelial cells that will serve as a comparison for the bronchial tissue produced from blood-derived iPS. A blood sample of approximately 14 ml will be taken for isolation and freezing of the blood mononuclear cells allowing the generation of iPS.
university Hospital of Montpellier
Montpellier, France
Obtention of functional bronchial epithelium from iPSC: yes/no
Was a functional bronchial epithelium obtained from the patient's induced pluripotent stem cells from blood? (yes/no) The achievement of functional bronchial epithelium (iALI) from iPSCs of a T2 severe asthma patient and an ABPA patient will be assessed by quantification of differentiation markers by immunofluorescence, integrity of the bronchial epithelium by measurement of trans-epithelial resistance (TEER), secretory function by measurement of mucin concentrations (CCSP, MUC5AC and MUC5B) and analysis of ciliary beat
Time frame: Day 0 + culture (cross-sectional study)
Comparison of the transcriptomic profile between iALI and airway epithelial cells
the transcriptomic profile of iALI from iPSCs of a T2 severe asthma patient and an ABPA patient will be compare to the one of airway epithelial cells from nasal brushing from the same patients
Time frame: Day 0 + culture (cross-sectional study)
Comparison of the transcriptomic profile between bronchial epithelia generated from severe asthma patients and from healthy subjects
The transcriptomic profile of iALI from iPSCs of a T2 severe asthma patient and an ABPA patient will be compare to those from healthy subjects
Time frame: Day 0 + culture (cross-sectional study)
Differentiation of iPSC into mature eosinophils : yes/no
Characterization of eosinophils obtained from iPSCs of a T2 severe asthma patient and an ABPA patient by the presence of specific markers by flow cytometry, immunohistochemistry and immunofluorescence
Time frame: Day 0 + culture (cross-sectional study)
Evaluation of immune cell/bronchial epithelium dialogue
Co culture of the epithelia with iPSC derived eosinophils and the immune cell/bronchial epithelium dialogue in the co-culture of eosinophils with iALI will be evaluated by the activation of eosinophils in contact with the epithelium and by the characterization and study of the phenotype of the exposed epithelium
Time frame: Day 0 + culture (cross-sectional study)
Obtention of iPSC from peripheral blood sampling : yes/no
Qualification of blood-derived iPSC lines by morphology, culture behavior, karyotype and expression of specific markers
Time frame: Day 0 + culture (cross-sectional study)
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