1. Temporal responses of oxidative vs. glycolytic skeletal muscles to K+ deprivation: Na+ pumps and cell cations
- Author
-
Cheolsoo Choi, Alicia A. McDonough, Jang H. Youn, and Curtis B. Thompson
- Subjects
Male ,medicine.medical_specialty ,Time Factors ,Physiology ,Intracellular Fluid ,Hypokalemia ,Oxidative phosphorylation ,Biology ,Rats, Sprague-Dawley ,Internal medicine ,Cations ,Extracellular fluid ,medicine ,Animals ,Protein Isoforms ,Glycolysis ,RNA, Messenger ,Muscle, Skeletal ,chemistry.chemical_classification ,Osmolar Concentration ,Skeletal muscle ,Cell Biology ,Rats ,Enzyme ,Endocrinology ,medicine.anatomical_structure ,chemistry ,Biophysics ,Potassium ,medicine.symptom ,Sodium-Potassium-Exchanging ATPase ,Extracellular Space ,Oxidation-Reduction ,Homeostasis - Abstract
When K+output exceeds input, skeletal muscle releases intracellular fluid K+to buffer the fall in extracellular fluid (ECF) K+. To investigate the mechanisms and muscle specificity of the K+shift, rats were fed K+-deficient chow for 2–10 days, and two muscles at phenotypic extremes were studied: slow-twitch oxidative soleus and fast-twitch glycolytic white gastrocnemius (WG). After 2 days of low-K+chow, plasma K+concentration ([K+]) fell from 4.6 to 3.7 mM, and Na+-K+-ATPase α2 (not α1) protein levels in both muscles, measured by immunoblotting, decreased 36%. Cell [K+] decreased from 116 to 106 mM in soleus and insignificantly in WG, indicating that α2 can decrease before cell [K+]. After 5 days, there were further decreases in α2 (70%) and β2 (22%) in WG, not in soleus, whereas cell [K+] decreased and cell [Na+] increased by 10 mM in both muscles. By 10 days, plasma [K+] fell to 2.9 mM, with further decreases in WG α2 (94%) and β2 (70%); cell [K+] fell 19 mM in soleus and 24 mM in WG compared with the control, and cell [Na+] increased 9 mM in soleus and 15 mM in WG; total homogenate Na+-K+-ATPase activity decreased 19% in WG and insignificantly in soleus. Levels of α2, β1, and β2 mRNA were unchanged over 10 days. The ratios of α2 to α1 protein levels in both control muscles were found to be nearly 1 by using the relative changes in α-isoforms vs. β1- (soleus) or β2-isoforms (WG). We conclude that the patterns of regulation of Na+pump isoforms in oxidative and glycolytic muscles during K+deprivation mediated by posttranscriptional regulation of α2β1 and α2β2 are distinct and that decreases in α2-isoform pools can occur early enough in both muscles to account for the shift of K+to the ECF.
- Published
- 1999