Elise Maurat

House Dust Mites Induce Proliferation of Severe Asthmatic Smooth Muscle Cells via an Epithelium-Dependent Pathway

RATIONALE Asthma is a frequent airway disease, and asthma control determinants have been associated with indoor allergen sensitization. The most frequent allergens are house dust mites (HDM), which act in vivo on the bronchial epithelial layer. Severe asthma has also been associated with bronchial remodeling and more specifically with increased mass of bronchial smooth muscle (BSM). However, the relationship between HDM stimulation of the bronchial epithelial layer and BSM remodeling is unknown. OBJECTIVES To evaluate whether epithelial stimulation with HDM induces BSM cell proliferation in subjects with severe asthma. METHODS A total of 22 subjects with severe asthma and 27 subjects with no asthma were recruited. We have developed an in vitro culture model combining an epithelium layer in air-liquid interface (ALI) interacting with BSM. We assessed BSM proliferation using BrdU incorporation. We explored the role of epithelium-derived mediators using reverse-transcriptase polymerase chain reaction (RT-PCR) and ELISA in vitro and in vivo. Finally, leukotrienes receptor expression was assessed in vitro by flow cytometry and RT-PCR and ex vivo by laser microdissection and RT-PCR. MEASUREMENTS AND MAIN RESULTS We found that epithelial stimulation by HDM selectively increased the proliferation of asthmatic BSM cells and not that of nonasthmatic cells. The mechanism involved epithelial protease-activated receptor-2-dependent production of leukotrienes C4 associated with an overexpression of leukotrienes receptor CysLTR1 by asthmatic BSM cells in vitro and ex vivo. CONCLUSIONS This work demonstrates the selective role of HDM on BSM remodeling in patients with severe asthma and points out different therapeutic targets at epithelial and smooth muscle levels.

New practical definitions for the diagnosis of autosomal recessive spastic ataxia of Charlevoix–Saguenay

Autosomal recessive spastic ataxia of Charlevoix–Saguenay (ARSACS) is caused by mutations in the SACS gene. SACS encodes sacsin, a protein whose function remains unknown, despite the description of numerous protein domains and the recent focus on its potential role in the regulation of mitochondrial physiology. This study aimed to identify new mutations in a large population of ataxic patients and to functionally analyze their cellular effects in the mitochondrial compartment.

Atypical male and female presentations of FLNA-related periventricular nodular heterotopia.

Periventricular nodular heterotopia, the most common form of cortical malformation in adulthood, is characterized by nodules of neurons ectopically placed along the lateral ventricles. Classically, ectopic nodules are bilateral and symmetric defining bilateral periventricular nodular heterotopia (BPNH). BPNH can lead to epilepsy and intellectual disability of variable severity. The X-linked dominant form of BPNH, related to mutations in FLNA encoding filamin A, is the major cause of BPNH, causing prenatal and neonatal lethality in males that explain the excess of affected women. However, few living males have been described with this condition. In addition, mutations in FLNA have been also exceptionally associated with unilateral nodular heterotopia. We describe here three new patients, all carrying a novel missense mutation in FLNA. Two of the patients were adult males with BPNH; both had normal cognitive development and one did not manifest any seizure until he died at age 57. The last patient was a female adult with epilepsy and focal nodules essentially located along the right ventricle. We compare the clinical and imaging data of our patients with those of previously described similar cases. The type and location of FLNA mutations leading to such atypical presentations are discussed.

Bronchial Smooth Muscle Remodeling in Nonsevere Asthma

RATIONALE Increased bronchial smooth muscle (BSM) mass is a key feature of airway remodeling that classically distinguishes severe from nonsevere asthma. Proliferation of BSM cells involves a specific mitochondria-dependent pathway in individuals with severe asthma. However, BSM remodeling and mitochondrial biogenesis have not been examined in nonsevere asthma. OBJECTIVES We aimed to assess whether an increase in BSM mass was also implicated in nonsevere asthma and its relationship with mitochondria and clinical outcomes. METHODS We enrolled 34 never-smoker subjects with nonsevere asthma. In addition, we recruited 56 subjects with nonsevere asthma and 19 subjects with severe asthma as comparative groups (COBRA cohort [Cohorte Obstruction Bronchique et Asthme; Bronchial Obstruction and Asthma Cohort; sponsored by the French National Institute of Health and Medical Research, INSERM]). A phenotypic characterization was performed using questionnaires, atopy and pulmonary function testing, exhaled nitric oxide measurement, and blood collection. Bronchial biopsy specimens were processed for immunohistochemistry and electron microscopy analysis. After BSM remodeling assessment, subjects were monitored over a 12-month period. MEASUREMENTS AND MAIN RESULTS We identified characteristic features of remodeling (BSM area >26.6%) and increased mitochondrial number within BSM in a subgroup of subjects with nonsevere asthma. The number of BSM mitochondria was positively correlated with BSM area (r = 0.78; P < 0.001). Follow-up analysis showed that subjects with asthma with high BSM had worse asthma control and a higher rate of exacerbations per year compared with subjects with low BSM. CONCLUSIONS This study reveals that BSM remodeling and mitochondrial biogenesis may play a critical role in the natural history of nonsevere asthma (Mitasthme study). Clinical trial registered with www.clinicaltrials.gov (NCT00808730).

Fibrocyte accumulation in bronchi: a cellular hallmark of COPD

Background The remodeling mechanism and cellular players causing persistent airflow limitation in chronic obstructive pulmonary disease (COPD) remain largely elusive. We have recently demonstrated that circulating fibrocytes, a rare population of fibroblast-like cells produced by the bone marrow stroma, are increased in COPD patients during an exacerbation. It remains, however, unclear, whether fibrocytes are present in bronchial tissue of COPD patients. Objective We aimed to quantify fibrocytes density in bronchial specimens from both control subjects and COPD patients, and to define associations with clinical, functional and computed tomography relevant parameters. Methods 17 COPD patients and 25 control subjects with normal lung function testing and no chronic symptoms, all of them requiring thoracic surgery, were recruited. LFT and CT-scan were performed before surgery. Using co-immunostaining and image analysis, we identify CD45+ FSP1+ cells as tissue fibrocytes and quantify their density in distal and proximal bronchial specimens from the whole series. Results Here, we demonstrate that fibrocytes are increased in both distal and proximal tissue specimens of COPD patients, compared to those of controls. The density of fibrocytes is negatively correlated with lung function parameters, such as FEV1 and FEV1/FVC, and positively with bronchial wall thickness assessed by CT scan. High density of distal bronchial fibrocytes predicts presence of COPD with a sensitivity of 83% and a specificity of 70%. Conclusions Our results thus suggest that recruitment of fibrocytes in the bronchi may participate to lung function decline during COPD progression. Clinical Implications High density of tissue fibrocytes is associated with a deteriorated lung function and an increase in airway wall thickness. A low density tissue fibrocytes virtually eliminates the presence of COPD. Capsule summary Blood fibrocytes assessed during exacerbation is a predictor of mortality in COPD. This study shows an increase of bronchial fibrocytes, that is associated with lower lung function, increased bronchial thickness and air trapping in COPD.