Hyperosmolar Solution Effects in Guinea Pig Airways. IV. Lipopolysaccharide-Induced Alterations in Airway Reactivity and Epithelial Bioelectric Responses to Methacholine and Hyperosmolarity

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In the guinea pig isolated perfused trachea contracted with serosal methacholine (MCh), increasing the osmolarity of the mucosal bathing solution elicits relaxation of smooth muscle mediated by epithelium-derived relaxing factor (EpDRF). The present study was undertaken to determine whether a specific modality of the hyperosmolar stimulus induced the relaxation response. Mucosal hyperosmolar challenge with D-mannitol, N-methyl-D-glucamine (NMDG)-chloride, NMDG-gluconate (NMDG-Glu), or urea elicited relaxation with equal potency. In contrast, hyperosmolar solutions at the serosal surface induced diverse, osmolyte-specific responses. In tracheae contracted with MCh, abrupt replacement of the mucosal modified KrebsHenseleit solution (MKHS) with isosmolar osmolyte solutions to stimulate cell shrinkage elicited five discrete response patterns related to the membrane permeance of the solute, but increasing the osmolarity of the isosmolar solution via the further addition of the same solute always induced relaxation. Similarly, perfusion of the lumen with water induced a transient contraction, but subsequent addition of MKHS, or isosmolar D-mannitol, urea, NMDG-Glu, NaCl, or KCl induced relaxation. Subsequent hyperosmolar addition of the same osmolyteevoked relaxation. Compatible osmolytes had no effect on smooth muscle tone and did not affect responses to hyperosmolar challenge. The results suggest that the airway epithelium acts as an osmolarity sensor, which communicates with airway smooth muscle through EpDRF. The mechanical responses of the smooth muscle resulting from changes in the osmotic environment are associated with discrete modalities of the osmolar stimulus, including membrane reflection of the particles, incremental change in osmolarity and directionality, but not cell shrinkage.

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confidence: 99%

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confidence: 99%

Hyperosmolar Solution Effects in Guinea Pig Airways. I. Mechanical Responses to Relative Changes in Osmolarity

Fedan

Dowdy

Johnston

et al. 2003

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“…EpDRF is released in association with transepithelial depolarization (Dortch-Carnes et al, 1999) and is associated with Na ϩ and Cl Ϫ transport, as judged by the inhibitory effects of Na ϩ and Cl Ϫ channel blockers . EpDRF is neither nitric oxide nor a prostanoid (Munakata et al, 1990;Spina and Page, 1991;Fedan et al, 1999Fedan et al, , 2003aJohnston et al, 2003).…”

Section: Abbreviationsmentioning

confidence: 99%

“…Mention of brand name does not constitute product endorsement. This article is the second one of a series of four companion articles that report the effects of hyperosmolar solutions in guinea pig airways (Fedan et al, 2003a,b;Johnston et al, 2003).…”

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confidence: 99%

Hyperosmolar Solution Effects in Guinea Pig Airways. II. Epithelial Bioelectric Responses to Relative Changes in Osmolarity

Johnston

Rengasamy

et al. 2003

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Osmotic challenge of airways alters the bioelectric properties of the airway epithelium and induces the release of factors that modulate smooth muscle tone. Recent studies in our laboratory suggested that methacholine-contracted airways relax in response to incremental increases in osmolarity, rather than from cell shrinkage or absolute solute concentration. In the present study, guinea pig tracheae were mounted in Ussing chambers to elucidate the bioelectric effects of challenge of the epithelium with hyperosmolar and isosmolar solutions. Transepithelial short-circuit current (I sc ) across tracheae stimulated with basolateral methacholine was inhibited by apical amiloride, apical 5-nitro-2-(3-phenylpropylamino)benzoic acid, basolateral bumetanide, basolateral ouabain, and Cl Ϫ -free solution, but not by basolateral iberiotoxin. Apical hyperosmolar challenge with NaCl variably decreased or increased I sc , but D-mannitol (D-M) always inhibited I sc ; bumetanide attenuated decreases in I sc . The effects of the transport blockers depended upon whether I sc was initially decreased or increased. Unique concentrationdependent changes in I sc and transepithelial resistance (R t ) were observed when ionic (NaCl and KCl), nonionic impermeant (D-M and sucrose), and nonionic permeant (urea) osmolytes were added to the apical and basolateral baths. At concentrations that doubled the osmolarity of the apical bath, D-M, urea, and N-methyl-D-glucamine-gluconate (NMDG-Glu) decreased I sc . Apical isosmolar NMDG-Glu solution decreased I sc , and additional NMDG-Glu caused a further decrease in I sc . Inclusion of one permeant ion, either Na

“…EpDRF has not been isolated. Dilation responses of the perfused trachea triggered by challenge of the epithelium with hyperosmolar solution are not mediated by nitric oxide or prostanoids (Munakata et al, 1990;Johnston et al, 2004). The responses are partially inhibited by hemoglobin and zinc II protoporphyrin(IX) (Fedan et al, 2004b), which suggests that carbon monoxide contributes to the activity known as EpDRF.…”

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confidence: 99%

Hyperosmolarity-Induced Dilation and Epithelial Bioelectric Responses of Guinea Pig Trachea in Vitro: Role of Kinase Signaling

Jing

Dowdy²,

Scott³

et al. 2008

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Exercise-induced airway obstruction is thought to involve evaporative water loss and hyperosmolarity of the airway surface liquid. Hyperosmolar challenge of the epithelium of isolated, perfused guinea pig trachea rapidly alters transepithelial potential difference (V t ), and it elicits smooth muscle relaxation mediated by epithelium-derived relaxing factor (EpDRF). In many cell types, protein kinases mediate responses to hyperosmolarity and regulatory volume increase. In this study, inhibitors were used to investigate the involvement of kinases and phosphatases in bioelectric responses of epithelium to hyperosmolarity and their possible relationship to EpDRF-mediated relaxation. After contraction of the perfused trachea with extraluminal methacholine, D-mannitol applied intraluminally (Յ80 mosM) increased V t and elicited dilation of the smooth muscle with a similar concentrationdependence; higher concentrations decreased V t . In tracheas exposed to 30 mosM D-mannitol (ϳEC 50 ), 4-(4-fluorophenyl)-2-(4-methylsulfinylphenyl)-5-(4-pyridyl)1H-imidazole (SB 203580) and SKF 86002 [6-(4-fluorophenyl)-2,3-dihydro-5-(4-pyridyl)imidazo[2,1-b]thiazole] (p38 inhibitors) potentiated the dilation, whereas SP 600125 [anthra[1,9-cd]pyrazol-6(2H)-one-1,9-pyrazoloanthrone] and dicumarol [c-Jun NH 2 -terminal kinase (JNK) inhibitors], chelerythrine [nonselective protein kinase C (PKC) inhibitor], and NaAsO 2 (mitogen-activated protein kinase stress inducer) and Na 3 VO 4 (protein tyrosine phosphatase inhibitor) inhibited the hyperpolarization. Large increases in the phosphorylation of p38 and JNK occurred at concentrations higher than those needed to elicit functional responses. The phosphatidylinositol 3-kinase inhibitor 2-(4-morpholinyl)-8-phenyl-4H-1-benzopyran-4-one (LY 294002) and Na 3 VO 4 did not affect the V t responses, but they inhibited methacholine-induced constriction; SP 600125 and dicumarol potentiated, and chelerythrine inhibited, methacholine-induced epithelial hyperpolarization. These results suggest that JNK, PKC, and phosphatase(s) are involved in hyperosmolarity-induced hyperpolarization of the tracheal epithelium but that p38 is involved in EpDRF-mediated relaxation.