Potassium depletion increases potassium clearance capacity in skeletal muscles in vivo during acute repletion

doi:10.1152/ajpcell.00588.2001

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Am J Physiol Cell Physiol 283: C1163-C1170, 2002; doi:10.1152/ajpcell.00588.2001
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Vol. 283, Issue 4, C1163-C1170, October 2002

Potassium depletion increases potassium clearance capacity in skeletal muscles in vivo during acute repletion

Henning Bundgaard and Keld Kjeldsen

Medical Department, The Heart Centre, Rigshospitalet, National University Hospital, University of Copenhagen, 2100 Copenhagen, Denmark

Muscular K uptake depends on skeletal muscle Na-K-ATPase concentration and activity. Reduced K uptake is observed in vitroin K-depleted rats. We evaluated skeletal muscle K clearance capacityin vivo in rats K depleted for 14 days. [³H]ouabain binding, $alpha$ ₁ and $alpha$ ₂ Na-K-ATPase isoform abundance, andK, Na, and Mg content were measured in skeletal muscles. Skeletalmuscle K, Na, and Mg and plasma K were measured in relation tointravenous KCl infusion that continued until animals died, i.e.,maximum KCl dose was administered. In soleus, extensor digitorumlongus (EDL), and gastrocnemius muscles K depletion significantlyreduced K content by 18%, 15%, and 19%, [³H]ouabain binding by 36%, 41%, and 68%, and $alpha$ ₂ isoform abundanceby 34%, 44%, and 70%, respectively. No significant change wasobserved in $alpha$ ₁ isoform abundance. In EDL and gastrocnemius musclesK depletion significantly increased Na (48% and 59%) and Mg (10%and 17%) content, but only tendencies to increase were observedin soleus muscle. K-depleted rats tolerated up to a fourfold higherKCl dose. This was associated with a reduced rate of increasein plasma K and increases in soleus, EDL, and gastrocnemius muscleK of 56%, 42%, and 41%, respectively, but only tendencies to increasein controls. However, whereas K uptake was highest in K-depletedanimals, the K uptake rate was highest in controls. In vivo Kdepletion is associated with markedly increased K tolerance andK clearance despite significantly reduced skeletal muscle Na-K-ATPaseconcentration. The concern of an increased risk for K intoxicationduring K repletion seemsunwarranted.

sodium-potassium-adenosinetriphosphatase; magnesium

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