Responsiveness of mutants of NHE1 isoform of Na+/H+ antiport to osmotic stress (original) (raw)
Related papers
The EMBO Journal
Na+/H+ exchange (antiport) is a major pathway for the regulation of intracellular pH. Antiport activity is stimulated when suspended cells adhere to the substratum. In this report, immunofluorescence was used to study the subcellular localization of the ubiquitous NHE-1 isoform of the antiport. NHE-1 was not distributed homogeneously on the surface of the cells. Instead, antiports were found to accumulate along the border of lamellipodia and near the edge of fmer processes. Dual immunofluorescence experiments demonstrated that vinculin, talin and F-actin are concentrated at sites of NHE-1 accumulation. A mutated construct of NHE-1 lacking residues 566-635 of the cytosolic domain also accumulated near marginal lamellae. In contrast, the focal distribution observed in adherent cells was not detectable in cells grown in suspension. Fluorescence ratio imagng was used to define the functional consequences of focal accumulation of NHE-1. In the steady state, the pH was virtually identical throughout the cytosol. Moreover, no pH gradients were found to develop when cells recovered from an acid load by activation of Na+/H+ exchange. This is probably because of the presence of high concentrations of mobile buffers in the cytosol. The focal accumulation of antiporters near the cell margins may be involved in stimulation by adherence and/or generation of local osmotic gradients.
PLoS ONE, 2011
The Na + /H + Exchanger isoform 1 (NHE1) is a highly versatile, broadly distributed and precisely controlled transport protein that mediates volume and pH regulation in most cell types. NHE1 phosphorylation contributes to Na + /H + exchange activity in response to phorbol esters, growth factors or protein phosphatase inhibitors, but has not been observed during activation by osmotic cell shrinkage (OCS). We examined the role of NHE1 phosphorylation during activation by OCS, using an ideal model system, the Amphiuma tridactylum red blood cell (atRBC). Na + /H + exchange in atRBCs is mediated by an NHE1 homolog (atNHE1) that is 79% identical to human NHE1 at the amino acid level. NHE1 activity in atRBCs is exceptionally robust in that transport activity can increase more than 2 orders of magnitude from rest to full activation. Michaelis-Menten transport kinetics indicates that either OCS or treatment with the phosphatase inhibitor calyculin-A (CLA) increase Na + transport capacity without affecting transport affinity (K m = 44 mM) in atRBCs. CLA and OCS act non-additively to activate atNHE1, indicating convergent, phosphorylation-dependent signaling in atNHE1 activation. In situ 32 P labeling and immunoprecipitation demonstrates that the net phosphorylation of atNHE1 is increased 4-fold during OCS coinciding with a more than 2-order increase in Na + transport activity. This is the first reported evidence of increased NHE1 phosphorylation during OCS in any vertebrate cell type. Finally, liquid chromatography and mass spectrometry (LC-MS/MS) analysis of atNHE1 immunoprecipitated from atRBC membranes reveals 9 phosphorylated serine/threonine residues, suggesting that activation of atNHE1 involves multiple phosphorylation and/or dephosphorylation events.
The Journal of biological chemistry, 1994
ATP is not hydrolyzed during the transport cycle of the Na+/H+ exchanger (NHE), yet depletion of the nucleotide drastically reduces the rate of cation exchange. The mechanism underlying this inhibition was investigated in fibroblasts transfected with NHE-1, the growth factor-sensitive isoform of the antiport. NHE-1 was found to be phosphorylated in serum-starved, unstimulated cells. Acute ATP depletion induced a profound inhibition of transport without detectable changes in NHE-1 phosphorylation. Analysis of cells transfected with truncated mutants of NHE-1 indicated that the carboxyl-terminal cytosolic domain of the antiport is required for expression of its ATP dependence. To define whether inhibition of Na+/H+ exchange resulted from internalization of NHE-1, extracellularly exposed proteins were labeled with impermeant biotin derivatives. The proportion of NHE-1 exposed to the surface was comparable before and after ATP depletion. Immunofluorescence determinations revealed focal ...
Kinetic Analysis of the Regulation of the Na+/H+ Exchanger NHE-1 by Osmotic Shocks
Biochemistry, 2008
NHE-1 is a ubiquitous, mitogen-activatable, mammalian Na + /H + exchanger that maintains cytosolic pH and regulates cell volume. We have previously shown that the kinetics of NHE-1 positive cooperative activation by intracellular acidifications fit best with a Monod-Wyman-Changeux mechanism, in which a dimeric NHE-1 oscillates between a low-and a high-affinity conformation for intracellular protons. The ratio between these two forms, the allosteric equilibrium constant L 0 , is in favor of the low-affinity form, making the system inactive at physiological pH. Conversely the high-affinity form is stabilized by intracellular protons, resulting in the observed positive cooperativity. The aim of the present study was to investigate the kinetics and mechanism of NHE-1 regulation by osmotic shocks. We show that they modify the L 0 parameter (865 (95 and 3757 (328 for 500 and 100 mOsM, respectively, vs 1549 (57 in isotonic conditions). This results in an activation of NHE-1 by hypertonic shocks and, conversely, in an inhibition by hypotonic media. Quantitatively, this modulation of L 0 follows an exponential distribution relative to osmolarity, that is, additive to the activation of NHE-1 by intracellular signaling pathways. These effects can be mimicked by the asymmetric insertion of amphiphilic molecules into the lipid bilayer. Finally, site-directed mutagenesis of NHE-1 shows that neither its association with membrane PIP 2 nor its interaction with cortical actin are required for mechanosensation. In conclusion, NHE-1 allosteric equilibrium and, thus, its cooperative response to intracellular acidifications is extremely sensitive to modification of its membrane environment.
The Journal of membrane biology, 2001
The Na+/H+ exchanger (NHE) becomes activated by hyperosmolar stress, thereby contributing to cell volume regulation. The signaling pathway(s) responsible for the shrinkage-induced activation of NHE, however, remain unknown. A family of mitogen-activated protein kinases (MAPK), encompassing p42/p44 Erk, p38 MAPK and SAPK, has been implicated in a variety of cellular responses to changes in osmolarity. We therefore investigated whether these kinases similarly signal the hyperosmotic activation of NHE. The time course and osmolyte concentration dependence of hypertonic activation of NHE and of the three sub-families of MAPK were compared in U937 cells. The temporal course and dependence on osmolarity of Erk and p38 MAPK activation were found to be similar to that of NHE stimulation. However, while pretreatment of U937 cells with the kinase inhibitors PD98059 and SB203580 abrogated the osmotic activation of Erk and p38 MAPK, respectively, it did not prevent the associated stimulation of...
Journal of Membrane Biology, 1996
Na + /H + exchanger isoforms NHE-2 and NHE-3 demonstrate distinct tissue expression patterns in renal epithelial cells. NHE-2 is predominantly expressed in the inner medulla whereas NHE-3 is highly expressed in the proximal tubule cells. The purpose of the current experiments was to study the characteristics of NHE-2 upon its own expression in cultured proximal tubule cells, LLC-PK 1 . Toward this end, LLC-PK 1 cells were subjected to six cycles of proton suicide. The mutant cells, when grown to confluence and assayed for Na + /H + exchanger by 22 Na + influx, showed significant reduction in NHE activity as compared to the parent cells (10.4 nmole/mg prot/4 min in parent cells vs. 1.8 in mutant cells, P < 0.001, n ס 4). This remaining exchanger activity was mostly mediated via NHE-3 as shown by inhibition of the Na influx following PKC stimulation (65% with PMA vs. 100% without PMA. P < 0.05, n ס 4). The mutant cells were transiently transfected with a pCMV/NHE-2 expression vector using calcium phosphate precipitation method. Northern blot analysis showed the expression of a 3.4 kb transcript only in the transfected cells. The expression peaked at 48 hr and diminished by 96 hr. The exchanger activity at 48 hr after transfection was mostly due to NHE-3 (as shown by inhibition in the presence of PMA) but was significantly lower than in sham transfected cells (1.2 nmoles/mg prot. in NHE-2-transfected and 2.1 in sham-transfected, P < 0.05, n ס 4). At 60 hr after transfection, the cells exhibited PMA-stimulated Na influx (>28%) indicating functional expression of NHE-2. Increasing the osmolality of the media to 510 mOsm/l stimulated the Na + /H + exchanger in NHE-2 transfected cells but inhibited the exchanger activity in sham transfected cells. In conclusion, NHE-2 appears as a 3.4 kb transcript in transfected LLC-PK 1 cells and functional expression of NHE-2 is preceded by inhibition of endogenous NHE-3 activity. The NHE-2 is stimulated by hypertonicity, indicating a likely role for this isoform in cell volume regulation.
Na/H Exchange activities in NHE1-transfected OK-cells: cell polarity and regulation
Pfl�gers Archiv European Journal of Physiology, 1993
The human fibroblast, "amiloride-sensitive" Na/H exchanger (NHE1) was transfected into opossum kidney cells (OK cells) (OK/NHE1 cells). Northern blot analysis confirmed that the NHE1 message is expressed in OKfNHE1 cells. In immunoblot analysis, an anti-human NHE1 antibody labelled a membrane protein only present in OK/NHE1 cells. In contrast to the parental cell line containing only an apically located, "amilorideresistant" Na/H exchange activity, OK/NHE1 ceils contain apically and basolaterally located Na/H exchange activities, the apical activity being "amiloride resistant" and the basolateral being "amiloride sensitive". Parathyroid hormone (PTH) inhibited apical transport activity (OK and OK/NHE1 cells) but had no effect on basolateral transport activity (OK/NHEI cells). Pharmacological activation of protein kinase A (forskolin) decreased both apical and basolateral Na/H exchange activity. Incubation with phorbol ester (exogenous activation of protein kinase C) reduced apical Na/H exchange activity (OK and OK/NHEI cells) but had only a moderate, inhibitory effect on basolateral Na/H exchange activity (OK/NHE1 cells). These results indicate that transfection of OK cells with human fibroblast NHE1 cDNA encoding an "amiloride-sensitive" form of the Na/H exchanger results in expression of basolaterally located "NHEl-related" transport activity. Regulatory control of intracellular Na/H exchange activities (apically versus basolaterally located) and intercellular Na/H exchange activities (NHEl-related) differs. This may relate to cell-specific properties as well as to exchanger-specific properties.
Regulation and characterization of the Na + /H + exchanger
Biochemistry and Cell Biology, 1998
The Na+/H+ exchanger is a ubiquitous protein present in all mammalian cell types that functions to remove one intracellular H+ for one extracellular Na+. Several isoforms of the protein exist, which are referred to as NHE1 to NHE6 (for Na+/H+ exchanger one through six). The NHE1 protein was the first isoform cloned and studied in a variety of systems. This review summarizes recent papers on this protein, particularly those that have examined regulation of the protein and its expression and activity.Key words: cation translocation, intracellular pH, membrane protein, Na+/H+ antiporter, protein phosphorylation, protein-protein interaction.
Proceedings of the National Academy of Sciences, 2005
Proximal tubular reabsorption of filtered sodium by the sodium͞ hydrogen exchanger isoform 3 (NHE3), located on the apical membrane, is fundamental to the maintenance of systemic volume and pH homeostasis. NHE3 is finely regulated by a variety of hormones and by changes in ionic composition and volume, likely requiring redistribution of the exchangers. We analyzed the subcellular distribution and dynamics of the exchangers by generating an epithelial line expressing NHE3 tagged with an exofacial epitope, which enabled us to monitor exchanger mobility and traffic in intact cells. Using determinations of fluorescence recovery after photobleaching in combination with dynamic measurements of subcellular distribution, we found that, in renal epithelial cells, NHE3 exists in four distinct subcompartments: a virtually immobile subpopulation that is retained on the apical membrane by interaction with the actin cytoskeleton in a manner that depends on the sustained activity of Rho GTPases; a mobile subpopulation on the apical membrane, which can be readily internalized; and two intracellular compartments that can be differentiated by their rate of exchange with the apical pool of NHE3. We provide evidence that detachment of the immobile fraction from its cytoskeletal anchorage leads to rapid internalization. These observations suggest that modulation of the mobile fraction of NHE3 on the apical membrane can alter the number of functional exchangers on the cell surface and, consequently, the rate of transepithelial ion transport. Regulation of the interaction of NHE3 with the actin cytoskeleton can therefore provide a new mode of regulation of sodium and hydrogen transport. fluorescence recovery after photobleaching ͉ pH regulation ͉ sodium proton exchange ͉ hypertension ͉ Madin-Darby canine kidney cells This paper was submitted directly (Track II) to the PNAS office.