Glycosylation-dependent activation of epithelial sodium channel by solnatide.

Dysfunction of the epithelial sodium channel (ENaC), which regulates salt and water homeostasis in epithelia, causes several human pathological conditions, including pulmonary oedema. This is a potentially lethal complication of acute lung injury at least partially caused by dysfunctional alveolar liquid clearance, which in turn impairs alveolar gas exchange. Solnatide (named TIP-peptide, AP301), a 17 residue peptide mimicking the lectin-like domain of TNF has been shown to activate ENaC in several experimental animal models of acute lung injury and is being evaluated as a potential therapy for pulmonary oedema. The peptide has recently completed phase 1 and 2a clinical trials. In this study, we identify a glycosylation-dependent mechanism that preserves ENaC function and expression. Since our previous data suggested that the pore-forming subunits of ENaC are essential for maximal current activation by solnatide, we performed single- and multi-N-glycosylation site mutations in αN232,293,312,397,511Q- and δN166,211,384Q-subunits, in order to identify crucial residues for interaction with solnatide within the extracellular loop of the channel. Additionally, we generated αL576X and αN232,293,312,397,511Q,L576X deletion mutants of ENaC-α, since we have previously demonstrated that the carboxy terminal domain of this subunit is also involved in its interaction with solnatide. In cells expressing αN232,293,312,397,511Q,L576Xßγ-hENaC or δN166,311,384Q,D552Xßγ-hENaC activation by solnatide, as measured in whole cell patch clamp mode, was completely abolished, whereas it was attenuated in αL576Xßγ-hENaC- and δD552Xßγ-hENaC-expressing cells. Taken together, our findings delineate an N-glycan dependent interaction between the TIP-peptide and ENaC leading to normalization of both sodium and fluid absorption in oedematous alveoli to non-oedematous levels.

Mechanism of action of novel lung edema therapeutic AP301 by activation of the epithelial sodium channel.

AP301 [Cyclo(CGQRETPEGAEAKPWYC)], a cyclic peptide comprising the human tumor necrosis factor lectin-like domain (TIP domain) sequence, is currently being developed as a treatment for lung edema and has been shown to reduce extravascular lung water and improve lung function in mouse, rat, and pig models. The current paradigm for liquid homeostasis in the adult mammalian lung is that passive apical uptake of sodium via the amiloride-sensitive epithelial Na⁺ channel (ENaC) and nonselective cyclic-nucleotide-gated cation channels creates the major driving force for reabsorption of water through the alveolar epithelium in addition to other ion channels such as potassium and chloride channels. AP301 can increase amiloride-sensitive current in A549 cells as well as in freshly isolated type II alveolar epithelial cells from different species. ENaC is expressed endogenously in all of these cell types. Consequently, this study was undertaken to determine whether ENaC is the specific target of AP301. The effect of AP301 in A549 cells as well as in human embryonic kidney cells and Chinese hamster ovary cells heterologously expressing human ENaC subunits (α, ß, γ, and δ) was measured in patch clamp experiments. The congener TIP peptide AP318 [Cyclo(4-aminobutanoic acid-GQRETPEGAEAKPWYD)] activated ENaC by increasing single-channel open probability. AP301 increased current in proteolytically activated (cleaved) but not near-silent (uncleaved) ENaC in a reversible manner. αßγ- or δßγ-ENaC coexpression was required for maximal activity. No increase in current was observed after deglycosylation of extracellular domains of ENaC. Thus, our data suggest that the specific interaction of AP301 with both endogenously and heterologously expressed ENaC requires precedent binding to glycosylated extracellular loop(s).