ABSTRACT
The potassium affinities of Na,K-ATPase isozymes are important determinants of their physiological roles in skeletal muscle. This study measured the apparent K⺠and Rb⺠affinities of the Na,K-ATPase α1 and α2 isozymes in intact, dissociated myofibers obtained from WT and genetically altered mice (α1S/Sα2R/R and skα2-/-). It also validates a new method to quantify cations in intact, dissociated myofibers, using inductively coupled plasma mass spectrometry (ICP-MS). Our findings were that: (1) The extracellular substrate sites of Na,K-ATPase bind Rb⺠and K⺠with comparable apparent affinities; however; turnover rate is reduced when Rb⺠is the transported ion; (2) The rate of Rb⺠uptake by the Na,K-ATPase is not constant but declines with a half-time of approximately 1.5 min; (3) The apparent K⺠affinity of the α2 isozymes for K⺠is significantly lower than α1. When measured in intact fibers of WT and α1S/Sα2R/R mice in the presence of 10 µM ouabain; the K1/2,K of α1 and α2 isozymes are 1.3 and 4 mM, respectively. Collectively, these results validate the single fiber model for studies of Na,K-ATPase transport and kinetic constants, and they imply the existence of mechanisms that dynamically limit pump activity during periods of active transport.
Subject(s)
Isoenzymes/metabolism , Potassium/metabolism , Rubidium/metabolism , Sodium-Potassium-Exchanging ATPase/metabolism , Animals , Biological Transport , Kinetics , Male , Mass Spectrometry , Mice , Mice, Inbred C57BL , Muscle, Skeletal/metabolism , Sodium/metabolismABSTRACT
The use of ICP-MS to measure metal ion content in biological tissues offers a highly sensitive means to study metal-dependent physiological processes. Here we describe the application of ICP-MS to measure membrane transport of Rb and K ions by the Na,K-ATPase in mouse skeletal muscles and human red blood cells. The ICP-MS method provides greater precision and statistical power than possible with conventional tracer flux methods. The method is widely applicable to studies of other metal ion transporters and metal-dependent processes in a range of cell types and conditions.
Subject(s)
Ion Transport , Ions/metabolism , Leukocytes/chemistry , Metals/metabolism , Muscle, Skeletal/chemistry , Animals , Cells, Cultured , Humans , Ion Pumps/metabolism , Mass Spectrometry/methods , Mice , Potassium/metabolism , Sulfur/metabolismABSTRACT
The Na(+)-K(+)-ATPase α2-isoform in skeletal muscle is rapidly stimulated during muscle use and plays a critical role in fatigue resistance. The acute mechanisms that stimulate α2-activity are not completely known. This study examines whether phosphorylation of phospholemman (PLM/FXYD1), a regulatory subunit of Na(+)-K(+)-ATPase, plays a role in the acute stimulation of α2 in working muscles. Mice lacking PLM (PLM KO) have a normal content of the α2-subunit and show normal exercise capacity, in contrast to the greatly reduced exercise capacity of mice that lack α2 in the skeletal muscles. Nerve-evoked contractions in vivo did not induce a change in total PLM or PLM phosphorylated at Ser63 or Ser68, in either WT or PLM KO. Isolated muscles of PLM KO mice maintain contraction and resist fatigue as well as wild type (WT). Rb(+) transport by the α2-Na(+)-K(+)-ATPase is stimulated to the same extent in contracting WT and contracting PLM KO muscles. Phosphorylation of sarcolemmal membranes prepared from WT but not PLM KO skeletal muscles stimulates the activity of both α1 and α2 in a PLM-dependent manner. The stimulation occurs by an increase in Na(+) affinity without significant change in Vmax and is more effective for α1 than α2. These results demonstrate that phosphorylation of PLM is capable of stimulating the activity of both isozymes in skeletal muscle; however, contractile activity alone is not sufficient to induce PLM phosphorylation. Importantly, acute stimulation of α2, sufficient to support exercise and oppose fatigue, does not require PLM or its phosphorylation.