Expression and functional significance of the cystic fibrosis transmembrane conductance regulator (CFTR) in human mast cells

Déry, René

Unknown Date

No description available.

cystic fibrosis

cftr

mast cells

Expression and functional significance of the cystic fibrosis transmembrane conductance regulator (CFTR) in human mast cells

Dry, Ren

11 1900

Mast cells (MC) are present in nearly all tissues in the body and participate in many physiological processes including allergy, tissue remodelling, fibrosis, angiogenesis, and autoimmunity. They can be activated by many stimuli, including allergic and innate immune stimulation. When activated, MC release mediators through which they can regulate inflammatory processes. Recently, we have discovered that rat and human MC express the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR), the gene responsible for Cystic Fibrosis (CF). We showed that CFTR had functional activity in MC and its expression was differentially regulated by IFNg. In this thesis, we compared CFTR expression between MC and epithelial cells (EC) by Western blot analysis and found that CFTR expression in MC is similar to that in EC, but there are some differences which suggest either glycosylation or post-transcriptional/translational differences between MC and EC. We also explored the role of CFTR in human MC secretion from various cellular compartments, in response to various stimuli. When we blocked CFTR using pharmacological inhibitors, there was an inhibition of cAMP-dependent Cl- flux. Our data also shows that CFTR pharmacological inhibition had no effect on IgE/anti-IgE-mediated b-hexosaminidase or eicosanoid release from MC. When we stimulated MC with either IgE/anti-IgE or the adenosine receptor agonist NECA (3 uM) for 24h in the presence of CFTR inhibitors, secretion of several mediators appeared to be dysregulated including IL-8, MIF, IL-13, IL-16, PAI-1 and CCL1. To add to these findings, we also used short hairpin RNA (shRNA) to reduce CFTR expression in MC. CFTR deficient MC were unresponsive to NECA and showed reduced constitutive IL-6 secretion. Finally, we cultured MC from CF and non-CF donor peripheral blood progenitors and compared several phenotypic and functional aspects of the cells. We saw no difference in growth, protease content and surface marker expression between CF and non-CF MC, but stimulation of the cells with IgE/anti-IgE or Pseudomonas aeruginosa appeared to differentially induce cytokine synthesis and secretion from CF and non-CF MC. These findings suggest that MC function is dysregulated in CF and that CF MC may be involved in the pathophysiology of CF. / Experimental Medicine

cystic fibrosis

cftr

mast cells

Expression of beta subunit of epithelium sodium channel and cystic fibrosis transmembrane regulator in small airways obstruction in chronic obstructive pulmonary disease

Chan, Becky Ka Man

11 1900

Background: Excess plugging of small airways is associated with premature death in chronic obstructive pulmonary disease (COPD). Over-expression of beta-epithelial sodium channel (β-ENaC) in airway epithelia in mice resulted in plugging of small airways while cystic fibrosis transmembrane regulator (CFTR) negatively regulated ENaC activity in cell models. Purpose: To test the hypothesis that accumulation of mucus exudates observed with the progression of COPD is related to excess airway epithelial sodium re-absorption as a result of over-expression of β-ENaC and reduced expression of CFTR by small airway epithelia. Methods: Small airway epithelial samples from frozen lungs from patients at different levels of COPD severity were isolated by laser capture microdissection (LCM). β-ENaC, CFTR, and β-actin (control) gene expression was determined by qRT-PCR and compared to expression in entire airways and lung parenchyma surrounding these airways. β-ENaC protein as well as epithelial mucin expression and mucus plugging were localized and quantified after immunohistochemical and periodic acid Schiff staining, respectively. Results: β-ENaC mRNA expression had a strong positive correlation with that of CFTR (p<O.0001) in airway epithelia and surrounding lung parenchyma (p=O.Ol) but not whole airways. β-ENaC mRNA and protein expression were positively correlated (p=O.4O, p=O.O5) and protein expression significantly increased with GOLD stage of COPD severity. Epithelial mucin expression positively correlated with β-ENaC (p=O.38, p=O.O5) and CFTR (p=OAO, p=O.O4.) mRNA and with mucus plugging (p=O. 43 , ptO.OOO2). CFTR mRNA also correlated positively with mucus plugging (p=O. 48 , p=O.O2). Conclusions: Strong positive correlations between β-ENaC and CFTR mRNA expression that are limited to the lung parenchyma and epithelium suggest a novel mechanism of mRNA regulation. This differs from their functional relationship where an inverse relationship between CFTR expression and β-ENaC activity has been reported. Positive correlations of epithelial mucin or mucus plugging with CFTR mRNA but not β-ENaC protein expression in the small airway epithelium suggest that CFTR may regulate mucin at this site independently of β-ENaC protein. The relationship between β-ENaC mRNA andepithelial mucin expression could be due to strong correlations between β-ENaC and CFTR mRNA expression but β-ENaC’s relationship with COPD GOLD stage suggests it may nevertheless play a role in COPD. / Medicine, Faculty of / Medicine, Department of / Experimental Medicine, Division of / Graduate

ENaC

CFTR

Mucin expression

COPD

Chronic ß2AR stimulation limits CFTR activation in human airway epithelia

Brewington, John J., III

05 October 2021

No description available.

Surgery

Cystic Fibrosis

CFTR

cAMP

Functional Dissection of FKBP38 in the Biogenesis of Cystic Fibrosis Transmembrane Conductance Regulator in the Endoplasmic Reticulum

Banasavadi-Siddegowda, Yeshavanth Kumar

27 December 2011

No description available.

Biomedical Research

CFTR

FKBP38

Hsp90

Production and characterisation of conditionally immortal cystic fibrosis cell lines

Thomas, Emma J.

January 2000

No description available.

615.1

A Biophysical Characterization of Phagolysosome Acidification

Steinberg, Benjamin Ethan

30 July 2009

Specialized cells of the innate immune system, such as macrophages, employ lysosomal enzymes, together with cationic peptides and reactive oxygen intermediates, to eliminate invading microorganisms ensnared within phagosomes. The effectiveness of this impressive armamentarium is potentiated by the acid pH generated by the vacuolar-type ATPase (V-ATPase). The determinants of the luminal pH of phagosomes and of the lysosomes they fuse with are not completely understood, but the V-ATPase is known to be electrogenic and net accumulation of protons requires charge compensation. For this reason, counter-ion pathways are thought to serve a central role in the control of acidification. It has generally been assumed that a parallel anion influx accompanies proton pumping to dissipate the voltage that tends to build up. In fact, impaired chloride channel activity in cystic fibrosis has been proposed to underlie the defective phagolysosome acidification and microbial killing reported in lung macrophages. In the first part of this thesis, I devised methods to dialyze the lumen of lysosomes in intact cells, while monitoring lysosomal pH, in order to assess the individual contribution of counter-ions to acidification. Surprisingly, anions were found to be completely dispensable for proton pumping, whereas the presence of permeant cations in the lysosomal lumen was essential. Accordingly, defects in lysosomal anion permeability cannot explain the impaired microbicidal capacity of phagocytes in cystic fibrosis. Even though counter-ion permeation pathways exist, dissipation of the electrical contribution of the V-ATPase may not be complete. If present, a transmembrane potential would alter the rate and extent of proton accumulation in phagosomes and lysosomes. However, no estimates of the voltage across the phagosomes were available. To overcome this deficiency, in the second part of this thesis, I describe a noninvasive procedure to estimate the voltage across the phagosome using fluorescence resonance energy transfer. This novel approach, in combination with organellar pH measurements, demonstrated that proton pumping is not limited by counter-ion permeability.

Lysosome

Phagosome

pH

Microscopy

Macrophage

CFTR

0379

A Biophysical Characterization of Phagolysosome Acidification

Steinberg, Benjamin Ethan

30 July 2009

Specialized cells of the innate immune system, such as macrophages, employ lysosomal enzymes, together with cationic peptides and reactive oxygen intermediates, to eliminate invading microorganisms ensnared within phagosomes. The effectiveness of this impressive armamentarium is potentiated by the acid pH generated by the vacuolar-type ATPase (V-ATPase). The determinants of the luminal pH of phagosomes and of the lysosomes they fuse with are not completely understood, but the V-ATPase is known to be electrogenic and net accumulation of protons requires charge compensation. For this reason, counter-ion pathways are thought to serve a central role in the control of acidification. It has generally been assumed that a parallel anion influx accompanies proton pumping to dissipate the voltage that tends to build up. In fact, impaired chloride channel activity in cystic fibrosis has been proposed to underlie the defective phagolysosome acidification and microbial killing reported in lung macrophages. In the first part of this thesis, I devised methods to dialyze the lumen of lysosomes in intact cells, while monitoring lysosomal pH, in order to assess the individual contribution of counter-ions to acidification. Surprisingly, anions were found to be completely dispensable for proton pumping, whereas the presence of permeant cations in the lysosomal lumen was essential. Accordingly, defects in lysosomal anion permeability cannot explain the impaired microbicidal capacity of phagocytes in cystic fibrosis. Even though counter-ion permeation pathways exist, dissipation of the electrical contribution of the V-ATPase may not be complete. If present, a transmembrane potential would alter the rate and extent of proton accumulation in phagosomes and lysosomes. However, no estimates of the voltage across the phagosomes were available. To overcome this deficiency, in the second part of this thesis, I describe a noninvasive procedure to estimate the voltage across the phagosome using fluorescence resonance energy transfer. This novel approach, in combination with organellar pH measurements, demonstrated that proton pumping is not limited by counter-ion permeability.

Lysosome

Phagosome

pH

Microscopy

Macrophage

CFTR

0379

CFTR POLYMORPHISMS OF HEALTHY INDIVIDUALS IN TWO CHINESE CITIES : CHANGCHUN AND NANJING

NARUSE, SATORU, ISHIGURO, HIROSHI, ZHANG, SU MIN, WEI, MU XIN, NAKAKUKI, MIYUKI, PING, ZHANG, SONG, YING, FUJIKI, KOTOYO, JIN, CHUN XIANG

08 1900

No description available.

Chinese

TG repeats

Poly-T

Polymorphisms

CFTR

Hétérogénéité physiologique de l'épithélium de l'épididyme : sécrétion de protons via la H+-ATPase vacuolaire dans les cellules claires et transport d'eau et de solutés via l'aquaporine 9 dans les cellules principales

Piétrement, Christine Rieu, Philippe.

January 2006

Reproduction de : Thèse doctorat : Médecine. Sciences de la vie : Reims : 2006. / Titre provenant de l'écran-titre. Bibliogr. p.115-130.