Effects of testosterone suppression, hindlimb immobilization, and recovery on [3H]ouabain binding site content and Na+, K+-ATPase isoforms in rat soleus muscle

We investigated the effects of testosterone suppression, hindlimb immobilization, and recovery on skeletal muscle Na+,K+-ATPase (NKA), measured via [3H]ouabain binding site content (OB) and NKA isoform abundances (α1–3, β1–2). Male rats underwent castration or sham surgery plus 7 days of rest, 10 days of unilateral immobilization (cast), and 14 days of recovery, with soleus muscles obtained at each time from cast and noncast legs. Testosterone reduction did not modify OB or NKA isoforms in nonimmobilized control muscles. With sham surgery, OB was lower after immobilization in the cast leg than in both the noncast leg (−26%, P = 0.023) and the nonimmobilized control (−34%, P = 0.001), but OB subsequently recovered. With castration, OB was lower after immobilization in the cast leg than in the nonimmobilized control (−34%, P = 0.001), and remained depressed at recovery (−34%, P = 0.001). NKA isoforms did not differ after immobilization or recovery in the sham group. After castration, α2 in the cast leg was ~60% lower than in the noncast leg ( P = 0.004) and nonimmobilized control ( P = 0.004) and after recovery remained lower than the nonimmobilized control (−42%, P = 0.039). After immobilization, β1 was lower in the cast than the noncast leg (−26%, P = 0.018), with β2 lower in the cast leg than in the noncast leg (−71%, P = 0.004) and nonimmobilized control (−65%, P = 0.012). No differences existed for α1 or α3. Thus, both OB and α2 decreased after immobilization and recovery in the castration group, with α2, β1, and β2 isoform abundances decreased with immobilization compared with the sham group. Therefore, testosterone suppression in rats impaired restoration of immobilization-induced lowered number of functional NKA and α2 isoforms in soleus muscle. NEW & NOTEWORTHY: The Na+,K+-ATPase (NKA) is vital in muscle excitability and function. In rats, immobilization depressed soleus muscle NKA, with declines in [3H]ouabain binding, which was restored after 14 days recovery. After testosterone suppression by castration, immobilization depressed [3H]ouabain binding, depressed α2, β1, and β2 isoforms, and abolished subsequent recovery in [3H]ouabain binding and α2 isoforms. This may have implications for functional recovery for inactive men with lowered testosterone levels, such as in prostate cancer or aging.

The Na,K-ATPase-Dependent Src Kinase Signaling Changes with Mesenteric Artery Diameter

Inhibition of the Na,K-ATPase by ouabain potentiates vascular tone and agonist-induced contraction. These effects of ouabain varies between different reports. In this study, we assessed whether the pro-contractile effect of ouabain changes with arterial diameter and the molecular mechanism behind it. Rat mesenteric small arteries of different diameters (150–350 µm) were studied for noradrenaline-induced changes of isometric force and intracellular Ca2+ in smooth muscle cells. These functional changes were correlated to total Src kinase and Src phosphorylation assessed immunohistochemically. High-affinity ouabain-binding sites were semi-quantified with fluorescent ouabain. We found that potentiation of noradrenaline-sensitivity by ouabain correlates positively with an increase in arterial diameter. This was not due to differences in intracellular Ca2+ responses but due to sensitization of smooth muscle cell contractile machinery to Ca2+. This was associated with ouabain-induced Src activation, which increases with increasing arterial diameter. Total Src expression was similar in arteries of different diameters but the density of high-affinity ouabain binding sites increased with increasing arterial diameters. We suggested that ouabain binding induces more Src kinase activity in mesenteric small arteries with larger diameter leading to enhanced sensitization of the contractile machinery to Ca2+.

How does pressure overload cause cardiac hypertrophy and dysfunction? High-ouabain affinity cardiac Na+ pumps are crucial

Left ventricular hypertrophy is frequently observed in hypertensive patients and is believed to be due to the pressure overload and cardiomyocyte stretch. Three recent reports on mice with genetically engineered Na+ pumps, however, have demonstrated that cardiac ouabain-sensitive α2-Na+ pumps play a key role in the pathogenesis of transaortic constriction-induced hypertrophy. Hypertrophy was delayed/attenuated in mice with mutant, ouabain-resistant α2-Na+ pumps and in mice with cardiac-selective knockout or transgenic overexpression of α2-Na+ pumps. The latter, seemingly paradoxical, findings can be explained by comparing the numbers of available (ouabain-free) high-affinity (α2) ouabain-binding sites in wild-type, knockout, and transgenic hearts. Conversely, hypertrophy was accelerated in α2-ouabain-resistant (R) mice in which the normally ouabain-resistant α1-Na+ pumps were mutated to an ouabain-sensitive (S) form (α1S/Sα2R/R or “SWAP” vs. wild-type or α1R/R α2S/S mice). Furthermore, transaortic constriction-induced hypertrophy in SWAP mice was prevented/reversed by immunoneutralizing circulating endogenous ouabain (EO). These findings show that EO and its receptor, ouabain-sensitive α2, are critical factors in pressure overload-induced cardiac hypertrophy. This complements reports linking elevated plasma EO to hypertension, cardiac hypertrophy, and failure in humans and elucidates the underappreciated role of the EO-Na+ pump pathway in cardiovascular disease.

Abstract P331: Angiotensin-salt Hypertension Requires Ouabain-sensitive Na + Pumps

Dietary salt is a major factor in the pathogenesis of essential hypertension (EH), but the underlying links are unresolved. Animal models indicate that angiotensin (Ang) II and high dietary salt (HS) are convergent signals that act via the brain to elevate blood pressure (BP). Low-dose sc Ang II+HS is a common model for EH. We tested the Na + pump ouabain binding site’s role in this model because it is crucial in some other hypertension models (e.g., ACTH and Nedd4-2-knockout +HS). Mice that express Na + pumps with a mutant, ouabain-resistant α2 catalytic subunit (α2 R/R ; cation transport is normal), and wild type (WT), ouabain sensitive controls (α2 S/S ) were studied. [80-90% of rodent artery myocyte Na + pumps are ouabain-resistant (α1 R/R ); only 10-20% are α2.] BP was measured by telemetry. First, 3 basal 24 hr BPs were recorded. Osmotic 4-week minipumps were then implanted sc in all mice to deliver vehicle (saline; Expt. #1,3), or 400 (Expt. #1,2) or 800 (Expt. #3) ng/kg/min Ang II; simultaneously, in Expt. #2, the diet was switched from 0.4% (standard) to 2% NaCl (HS). BPs were monitored every 3-4 days for up to 4 weeks. Also, in Expt. #2, on day 21, all mice received 2 ip injections, 4 hrs apart, of 10 mg/kg DigiFab, Fab fragments that immuno-neutralize ouabain, while BP was continuously monitored; on day 23, the mice received 2 ip injections of CroFab, anti-crotalus toxin (‘control’) Fab fragments. Results: 1. Basal mean BP (MBP) was 10±2 mm Hg higher in α2 R/R than in WT mice ( P <0.01; n =21 & 29; ANOVA). 2. In WT mice, 400 ng/kg/min sc Ang II and Ang II+HS raised MBP by 15±1 and 34±1 mm Hg, respectively ( P <0.01; n =7-8; ANOVA). 3. The MPB elevation in Ang II+HS α2 R/R (17±2 mm Hg) was only half that in WT mice ( P <0.01; n =7 each; ANOVA). 4. DigiFab rapidly (<1 hr) reduced MBP by 14±2 mm Hg in Ang II+HS hypertensive WT mice ( P <0.001; n =7; T-test), but not in α2 R/R mice ( P <0.01; n =7 each; ANOVA); CroFab did not lower MBP in either strain. 5. 800 ng/kg/min sc Ang II elevated systolic BP by 55±3 mm Hg in WT mice, but by only 37±3 mm Hg in α2 R/R mice ( P <0.05; n =3-5; ANOVA). Conclusions: Ouabain-sensitive α2 Na + pumps and their endogenous ligand are both required for full expression of low-dose Ang II-salt hypertension. Ouabain-sensitive α2 pumps apparently also contribute to high-dose Ang II-hypertension.