Sodium/proton exchanger 1 (NHE1) is an electroneutral secondary active transporter present on the plasma membrane of most mammalian cells and plays critical roles in regulating intracellular pH and volume homeostasis. Calcineurin B-homologous protein 1 (CHP1) is an obligate binding partner that promotes NHE1 biosynthetic maturation, cell surface expression and pH-sensitivity. Dysfunctions of either protein are associated with neurological disorders. Here, we elucidate structures of the human NHE1-CHP1 complex in both inward- and inhibitor (cariporide)-bound outward-facing conformations. We find that NHE1 assembles as a symmetrical homodimer, with each subunit undergoing an elevator-like conformational change during cation exchange. The cryo-EM map reveals the binding site for the NHE1 inhibitor cariporide, illustrating how inhibitors block transport activity. The CHP1 molecule differentially associates with these two conformational states of each NHE1 monomer, and this association difference probably underlies the regulation of NHE1 pH-sensitivity by CHP1.
Bicarbonate facilitates mucin unpacking and bacterial killing however its transport mechanisms in the airways are not well understood. cAMP stimulates anion efflux through the CFTR (ABCC7) anion channel and this is defective in CF. The anion exchanger pendrin (SLC26A4) also mediates HCO3− efflux and is upregulated by proinflammatory cytokines. Here we examined pendrin and CFTR expression and their contributions to HCO3− secretion by human nasal and bronchial epithelia. In native tissue, both proteins were most abundant at the apical pole of ciliated surface cells with little expression in submucosal glands. In well‐differentiated primary nasal and bronchial cell cultures, IL‐4 dramatically increased pendrin mRNA levels and apical immunostaining. Exposure to low‐Cl− apical solution caused intracellular alkalinization (ΔpHi) that was enhanced 4‐fold by IL‐4 pretreatment. ΔpHi was unaffected by DIDS or CFTRinh‐172 but was reduced by adenoviral shRNA targeting pendrin. Forskolin increased ΔpHi and this stimulation was prevented by CFTRinh‐172 implicating CFTR, yet forskolin only increased ΔpHi after pendrin expression had been induced by IL‐4. The dependence of ΔpHi on pendrin suggests there is minimal electrical coupling between Cl− and HCO3− fluxes and that CFTR activation increases anion exchange‐mediated HCO3− influx. Conversely, inducing pendrin expression increased forskolin‐stimulated, CFTRinh‐172‐sensitive current by ~2‐fold in epithelial and non‐epithelial cells. We conclude that pendrin mediates most HCO3− secretion across airway surface epithelium during inflammation and enhances electrogenic Cl− secretion via CFTR as described for other SLC26A transporters. Support or Funding Information Support: Cystic Fibrosis Canada, Canadian Institutes of Health Research, Canada Foundation for Innovation This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
Little is known about how CFTR, the Cl− channel that is mutated in cystic fibrosis, interacts with lipids. Abu-Arish et al. show that agents that stimulate salt and fluid secretion reduce CFTR lateral mobility and promote its clustering into ceramide-rich platforms, thereby increasing its surface expression.
The pH of airway epithelial secretions influences bacterial killing and mucus properties and is reduced by acidic pollutants, gastric reflux, and respiratory diseases such as cystic fibrosis (CF). The effect of acute acid loads depends on buffer capacity, however the buffering of airway secretions has not been well characterized. In this work we develop a method for titrating micro-scale (30 μl) volumes and use it to study fluid secreted by the human airway epithelial cell line Calu-3, a widely used model for submucosal gland serous cells. Microtitration curves revealed that HCO−3 is the major buffer. Peak buffer capacity (β) increased from 17 to 28 mM/pH during forskolin stimulation, and was reduced by >50% in fluid secreted by cystic fibrosis transmembrane conductance regulator (CFTR)-deficient Calu-3 monolayers, confirming an important role of CFTR in HCO−3 secretion. Back-titration with NaOH revealed non-volatile buffer capacity due to proteins synthesized and released by the epithelial cells. Lysozyme and mucin concentrations were too low to buffer Calu-3 fluid significantly, however model titrations of porcine gastric mucins at concentrations near the sol-gel transition suggest that mucins may contribute to the buffer capacity of ASL in vivo. We conclude that CFTR-dependent HCO−3 secretion and epithelially-derived proteins are the predominant buffers in Calu-3 secretions.
Bicarbonate plays an important role in airway host defense, however, its transport mechanisms remain uncertain. Here we examined the relative contributions of the anion channel CFTR (cystic fibrosis transmembrane conductance regulator, ABCC7) and the anion exchanger pendrin (SLC26A4) to HCO 3 − secretion by the human airway cell line Calu‐3. Pendrin and CFTR were both detected in parental Calu‐3 cells, although mRNA and protein expression appeared higher for CFTR than for pendrin. Targeting pendrin transcripts with lentiviral shRNA reduced pendrin detection by immunofluorescence staining but did not alter the rates of HCO 3 − or fluid secretion, HCO 3 − transport under pH‐stat conditions, or net HCO 3 − flux across basolaterally permeabilized monolayers. Intracellular pH varied with step changes in apical Cl− and HCO 3 − concentrations in control and pendrin knockdown Calu‐3 cells, but not in CFTR deficient cells. Exposure to the proinflammatory cytokine IL‐4, which strongly upregulates pendrin expression in airway surface epithelia, had little effect on Calu‐3 pendrin expression and did not alter fluid or HCO 3 − secretion. Similar results were obtained using air–liquid interface and submerged cultures, although CFTR and pendrin mRNA expression were both lower when cells were cultured under submerged conditions. While the conclusions cannot be extrapolated to other airway epithelia, the present results demonstrate that most HCO 3 − secretion by Calu‐3 cells is mediated by CFTR.
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