Raphael Zahler scite author profile

By participating in the regulation of ion and voltage gradients, the Na-K pump (i.e., Na,K-ATPase) influences many aspects of cellular physiology. Of the four α isoforms of the pump, α1 is ubiquitous, α2 is predominant in skeletal muscle, and α3 is found in neurons and the cardiac conduction system. To determine whether the isoforms have different intracellular Na+ affinities, we used the Na+-sensitive dye sodium-binding benzofuran isophthalate (SBFI) to measure pump-mediated Na+ efflux as a function of [Na+]i in human HeLa cells stably transfected with rat Na-K pump isoforms. We Na+-loaded the cells, and then monitored the time course of the decrease in [Na+]i after removing external Na+. All transfected rat α subunits were highly ouabain resistant: the α1 isoform is naturally resistant, whereas the α2 and α3 isoforms had been mutagenized to render them resistant. Thus, the Na+ efflux mediated by endogenous and transfected pumps could be separated by studying the cells at low (1 μM) and high (4 mM) ouabain concentrations. We found that the apparent K m for Na+ efflux attributable to the native human α1 isoform was 12 mM, which was similar to the K m of rat α1. The α2 and α3 isoforms had apparent K m's of 22 and 33 mM, respectively. The cells expressing α3 had a high resting [Na+]i. The maximal activity of native α1 in the α3-transfected cells was only ∼56% of native α1 activity in untransfected HeLa cells, suggesting that transfection with α3 led to a compensatory decrease in endogenous α1 pumps. We conclude that the apparent K m(Na+) for rat Na-K pump isoforms increases in the sequence α1 < α2 < α3. The α3 isoform may be suited for handling large Na+ loads in electrically active cells.

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Analysis of compartmentation of ATP in skeletal and cardiac muscle using 31P nuclear magnetic resonance saturation transfer

Zahler¹,

Bittl²,

Ingwall³

1987

Biophysical Journal

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We have developed a model for the analysis of the forward creatine kinase reaction in muscle as measured by the nuclear magnetic resonance (NMR) technique of magnetization transfer. The model, accounting for the double-exponential behavior observed in some NMR magnetization transfer data, allows for the existence of two ATP pools, one that is NMR-visible (NMR-VIS) and another that is NMR-invisible (NMR-INVIS). We have applied the model to experimental data for the forward creatine kinase reaction in skeletal and cardiac muscles to study the dependence of the creatine kinase rate constants and fluxes on workload and to account for the differences between heart and skeletal muscle. The results suggest that an NMR-distinct ATP pool exists in both heart and skeletal muscles, and that phosphate exchange with this pool catalyzed by creatine kinase increases with increased workload. The results also agree with previously published estimates of the rates of mitochondrial translocase and net ATP synthesis obtained by traditional biochemical methods.

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Expression of α isoforms of the Na,K-ATPase in human heart

Zahler

Gilmore-Hebert

Baldwin

et al. 1993

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Na-K-ATPase alpha-isoform expression in heart and vascular endothelia: cellular and developmental regulation

Zahler

Sun

Ardito

et al. 1996

American Journal of Physiology-Cell Physiology

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The Na pump (Na-K-ATPase) is important for regulation of membrane potential and transport in smooth muscle and heart. The alpha (catalytic)-subunit of this pump has three isoforms: alpha 1 is ubiquitous, but alpha 2 and alpha 3 are mainly localized to excitable tissue. Physiological differences between isoforms are not completely understood, but alpha 3 pumps appear to have a lower affinity for intracellular Na and a higher ouabain affinity than alpha 1 pumps. The alpha 2-and alpha 3-isoform mRNAs are expressed at high levels in the normal adult rat cardiac conduction system. Although alpha 1 and alpha 3 are both globally expressed in neonatal rat myocardia, there is a switch in the myocardial isoform pattern from alpha 3 to alpha 2 after birth. There are also important species differences in cardiac isoform patterns. Furthermore, changes in Na-K-ATPase isoforms in heart and vascular tissue have been reported in association with hypertension, but little is known about isoform expression in normal endothelia. We therefore studied the cellular distribution of Na pump protein isoforms in neonatal and adult myocardia and endothelia. Immunohistochemical analysis of rat tissues showed that the alpha 1-isoform was expressed throughout atrial and ventricular myocardium, with alpha 1 the only isoform detectable in the adult t tubule system. Although alpha 2 was also present in ventricular myocytes, the signal was markedly stronger in conduction tissue and papillary muscle. In hearts from neonatal rats, the alpha 3-isoform predominated in the cardiac conduction system, whereas alpha 2 was not detectable in any structure except vascular endothelium. In tissues and in cell lines representing a variety of species and vessel sizes, endothelia of large vessels expressed primarily alpha 1, whereas alpha 2 could be detected in endothelia of small vessels in rat heart. No evidence of alpha 3 expression in endothelium was found. Thus the complex spatial and developmental regulation of Na pump isoform expression in cardiovascular tissues may provide additional correlates to distinct physiological roles of these transporters.

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The α3 Isoform Protein of the Na ⁺ ,K ⁺ -ATPase Is Associated With the Sites of Cardiac and Neuromuscular Impulse Transmission

Zahler

Sun

Ardito

et al. 1996

Circulation Research

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The alpha (catalytic) subunit of the Na+ pump (Na+, K(+)-ATPase) has three isoforms; alpha1 is ubiquitous, skeletal muscle expresses predominantly alpha2, and alpha3 has been localized to specific types of neurons and, possibly, to axonal processes. The alpha3 isoform mRNA is also expressed in the rat cardiac conduction system. Thus, we studied rat heart and quadriceps muscles by immunohistochemistry using isoform-specific antibodies to the Na+ pump alpha subunit and labeled alpha-bungarotoxin as a probe for the neuromuscular junction (NMJ). We found that alpha3 pump protein is localized to three sites important for impulse transmission: the junctional complex between cardiac myocytes, the heart conduction system, and the NMJ. Specifically, all levels of the conduction system expressed alpha3 immunoreactive protein, as assessed by two isoform-specific antibodies and histological conduction system markers. Specific expression at the junctional complex was confirmed by immuno-EM. Double-labeling and denervation analysis indicated that alpha3-positive areas in skeletal muscle were presynaptic and adjacent to postsynaptic bungarotoxin-positive regions, which had the classic morphology of NMJs. Thus, specific Na+,K(+)-ATPase pump isoforms may be adapted to maintenance of membrane potential and/or intracellular ion concentrations required for impulse transmission in both heart and presynaptic motor terminals contacting skeletal muscle.

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Raphael Zahler

Sodium Kinetics of Na,K-ATPase α Isoforms in Intact Transfected HeLa Cells

Analysis of compartmentation of ATP in skeletal and cardiac muscle using 31P nuclear magnetic resonance saturation transfer

Expression of α isoforms of the Na,K-ATPase in human heart

Na-K-ATPase alpha-isoform expression in heart and vascular endothelia: cellular and developmental regulation

The α3 Isoform Protein of the Na ⁺ ,K ⁺ -ATPase Is Associated With the Sites of Cardiac and Neuromuscular Impulse Transmission

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Raphael Zahler

Sodium Kinetics of Na,K-ATPase α Isoforms in Intact Transfected HeLa Cells

Analysis of compartmentation of ATP in skeletal and cardiac muscle using 31P nuclear magnetic resonance saturation transfer

Expression of α isoforms of the Na,K-ATPase in human heart

Na-K-ATPase alpha-isoform expression in heart and vascular endothelia: cellular and developmental regulation

The α3 Isoform Protein of the Na + ,K + -ATPase Is Associated With the Sites of Cardiac and Neuromuscular Impulse Transmission

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Product

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The α3 Isoform Protein of the Na ⁺ ,K ⁺ -ATPase Is Associated With the Sites of Cardiac and Neuromuscular Impulse Transmission