Opposite effects of Ni2+ on Xenopus and rat ENaCs expressed in Xenopus oocytes

doi:10.1152/ajpcell.00419.2004

Opposite effects of Ni²⁺ on Xenopus and rat ENaCs expressed in Xenopus oocytes

Dana Cucu,¹ Jeannine Simaels,¹ Jan Eggermont,¹ Willy Van Driessche,¹ and Wolfgang Zeiske²

¹Laboratory of Physiology, Department of Molecular Cell Biology, K. U. Leuven, Campus Gasthuisberg O & N, Leuven, Belgium; ²Division of Animal Physiology, Department of Biology/Chemistry, University of Osnabrück, Osnabrück, Germany

Submitted 25 August 2004 ; accepted in final form 30 May 2005

Opposite effects of Ni²⁺ on Xenopus and rat ENaCs expressedin Xenopus oocytes. Am J Physiol Cell Physiol 289: C946–C958,2005. First published June 8, 2005; .—The epithelial Na⁺channel (ENaC) is modulated by various extracellular factors,including Na⁺, organic or inorganic cations, and serine proteases.To identify the effect of the divalent Ni²⁺ cation on ENaCs,we compared the Na⁺ permeability and amiloride kinetics of XenopusENaCs (xENaCs) and rat ENaCs (rENaCs) heterologously expressedin Xenopus oocytes. We found that the channel cloned from thekidney of the clawed toad Xenopus laevis [wild-type (WT) xENaC]was stimulated by external Ni²⁺, whereas the divalent cationinhibited the channel cloned from the rat colon (WT rENaC).The kinetics of amiloride binding were determined using noiseanalysis of blocker-induced fluctuation in current adapted forthe transoocyte voltage-clamp method, and Na⁺ conductance wasassessed using the dual electrode voltage-clamp (TEVC) technique.The inhibitory effect of Ni²⁺ on amiloride binding is not speciesdependent, because Ni²⁺ decreased the affinity (mainly reducingthe association rate constant) of the blocker in both speciesin competition with Na⁺. Importantly, using the TEVC method,we found a prominent difference in channel conductance at hyperpolarizingvoltage pulses. In WT xENaCs, the initial ohmic current responsewas stimulated by Ni²⁺, whereas the secondary voltage-activatedcurrent component remained unaffected. In WT rENaCs, only avoltage-dependent block by Ni²⁺ was obtained. To further studythe origin of the xENaC stimulation by Ni²⁺, and based on therationale of the well-known high affinity of Ni²⁺ for histidineresidues, we designed ${alpha}$ -subunit mutants of xENaCs by substitutinghistidines that were expressed in oocytes, together with WT ${beta}$ - and ${gamma}$ -subunits. Changing His²¹⁵ to Asp in one putative amiloride-bindingdomain (WYRFHY) in the extracellular loop between Na⁺ channelmembrane segments M1 and M2 had no influence on the stimulatoryeffect of Ni²⁺, and neither did complete deletion of this segment.Next, we mutated His⁴¹⁶ flanked by His⁴¹¹ and Cys⁴¹⁷, a uniquesite for possible heavy metal ion chelation, and, with thisquality, most proximal ( $~$ 100 amino acids upstream of the secondputative amiloride binding site at the pore entrance), was foundlocalized at M2. Replacing His⁴¹⁶ with arginine, aspartate,tyrosine, and alanine clearly affected amiloride binding inall cases, as well as Na⁺ conductance, as expressed in the xENaCcurrent-voltage relationship, especially with regard to aspartateand tyrosine. However, similarly to those obtained with theWYRFHY stretch, none of these mutations could either abolishthe stimulating effect of Ni²⁺ or reverse it to an inhibitorytype.

epithelia; divalent cations; amiloride; Na⁺; voltage clamp

Address for reprint requests and other correspondence: W. Van Driessche, Laboratory of Physiology, Department of Molecular Cell Biology, Catholic University of Leuven, Campus Gasthuisberg O & N, Herestraat 49, Box 802, B-3000 Leuven, Belgium (e-mail: willy.vandriessche{at}med.kuleuven.be)

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