A simple procedure for NMR measurements of intra- and extracellular sodium in intact tissues

The total Na+ and both the intra- and extracellular Na+ content of excised rat and frog tissues was quantitated by 23Na NMR at 95.51 MHz. An external capillary containing 33 mM Na7[Dy(P3O10)2], resonating about 30 ppm upfield relative to the 0.00 ppm of the intracellular Na+, was inserted into the tissues. The capillary was calibrated against a concentration range of pure NaCl solution, for measurement of intracellular Na+, and against the same concentrations of NaCl solutions containing 4-6 mM K7[Dy(P3O10)2] in 50 mM histidine. Cl and 100 mM choline. Cl, for measurement of extracellular Na+. Spectra were recorded on tissues first in the absence of the shift reagent for determination of the total Na+. After addition of a K7[Dy(P3O10)2] solution to the sample, the 23Na spectra were recorded immediately so that data accumulation was completed within 15 min. Under these conditions, the extracellular Na+ resonated from 10 to 20 ppm upfield relative to the intracellular Na+, and no loss in the intensity of the extracellular Na+ resonance occurred due to the lability of dysprosium(III)tripolyphosphate (cf. Matwiyoff et al., Magn. Reson. Med. 3: 164, 1986). The intra- and extracellular Na+ content of the tissue was calculated from the integrated areas of the respective Na+ resonances and that of the calibrated capillary, from the known weight of the tissue, and from the known volumes of the solutions added.(ABSTRACT TRUNCATED AT 250 WORDS)     

Measurement of a wide range of intracellular sodium concentrations in erythrocytes by 23Na nuclear magnetic resonance.

The accuracy of the 23Na nuclear magnetic resonance (NMR) method for measuring the sodium concentration in erythrocytes was tested by comparing the NMR results to those obtained by emission-flame photometry. Comparisons were made on aqueous solutions, hemolysates, gels, ghosts, and intact erythrocytes. The intra- and extracellular 23Na NMR signals were distinguished by addition of the dysprosium tripolyphosphate [Dy(PPP)7-2] shift reagent to the extracellular fluid. The intra- and extracellular volumes of ghosts and cells were determined by the isotope dilution method. Our results indicate that greater than 20% of the intracellular signal remains undetected by NMR in ghosts and cells. When the cells are hemolyzed, the amount of NMR-detectable sodium varies depending on the importance of gel formation. In hemolysates prepared by water addition, the NMR and flame photometry results are identical. The loss of signal in ghosts, cells, and undiluted hemolysates is attributed to partial binding of the Na+ ion to intracellular components, this binding being operative only when these components exist in a gel state. In a second part, 31P NMR was used to monitor the penetration of the shift reagent into the cells during incubation. Our data demonstrate that free Dy3+ can slowly accumulate inside the red cell.     

Measurement of intracellular sodium concentration and sodium transport in Escherichia coli by 23Na nuclear magnetic resonance

Escherichia coli is known to actively extrude sodium ions, but little is known concerning the concentration gradient it can develop. We report here simultaneous measurements, by 23Na NMR, of intracellular and extracellular Na+ concentrations of E. coli cells before and after energization. 23Na spectra in the presence of a paramagnetic shift reagent (dysprosium tripolyphosphate) consisted of two resonances, an unshifted one corresponding to intracellular Na+ and a shifted one corresponding to Na+ in the extracellular medium, including the periplasm. Extracellular Na+ was found to be completely visible despite the presence of a broad component in its resonance; intracellular Na+ was only 45% visible. Measurements of Na+ were made under aerobic and glycolytic conditions. Na+ extrusion and maintenance of a stable low intracellular Na+ concentration were found to correlate with the development and maintenance of proton motive force, a result that is consistent with proton-driven Na+/H+ exchange as a means of Na+ transport. In both respiring and glycolyzing cells, at an extracellular Na+ concentration of 100 mM, the intracellular Na+ concentration observed (4 mM) corresponded to an inwardly directed Na+ gradient with a concentration ratio of about 25. The kinetics of Na+ transport suggest that rapid extrusion of Na+ against its electrochemical gradient may be regulated by proton motive force or intracellular pH.     

23Na, 19F, 35Cl and 31P multinuclear nuclear magnetic resonance studies of perfused rat kidney

The concentration of intracellular sodium [Na+]i has been measured in the perfused rat kidney using 23Na nuclear magnetic resonance (NMR) in combination with the extracellular shift reagent Dy(PPPi)7-(2). The data show 100% visibility of Na+ in interstitial spaces. A measurement of the resonance intensities of intra- and extracellular 23Na ions along with a knowledge of the extracellular space as a fraction of the total kidney water space yielded an average [Na+]i of 27 +/- 2 mM for the kidney at 37 degrees C. After prolonged ischemia [Na+]i rose to approach that in the external medium. In the absence of 5% albumin in the perfusion medium, the linewidth of the 35Cl resonance of an adult kidney (45 Hz) was about twofold larger than that of the medium alone (25 Hz). In contrast, the linewidth of 35Cl resonance of an adult kidney perfused with an albumin-containing medium (82 Hz) was only about 27% of that from the medium alone (300 Hz). We interpret this effect to be due to compartmentation of albumin in the extracellular space such that the interstitial space is not freely accessible to albumin. However, for a developing, immature kidney from a growing animal, perfused with an albumin-containing medium, the linewidth of the 35Cl resonance (233 Hz) was only slightly less than that of the medium alone (300 Hz), indicating a much greater albumin permeability of the capillary walls. 19F NMR of a perfused adult kidney, loaded with the membrane-impermeant intracellular calcium indicator 5FBAPTA, yielded a value of 256 nM for [Ca2+]i. Induction of ischemia for 10 min caused the [Ca2+]i to rapidly rise to 660 nM, which could not be fully reversed by reperfusion, suggesting irreversible injury.     

23Na and 39K nuclear magnetic resonance studies of perfused rat hearts. Discrimination of intra- and extracellular ions using a shift reagent.

High-resolution 23Na and 39K nuclear magnetic resonance (NMR) spectra of perfused, beating rat hearts have been obtained in the absence and presence of the downfield shift reagent Dy(TTHA)3- in the perfusing medium. Evidence indicates that Dy(TTHA)3- enters essentially all extracellular spaces but does not enter intracellular spaces. It can thus be used to discriminate the resonances of the ions in these spaces. Experiments supporting this conclusion include interventions that inhibit the Na+/K+ pump such as the inclusion of ouabain in and the exclusion of K+ from the perfusing medium. In each of these experiments, a peak corresponding to intracellular sodium increased in intensity. In the latter experiment, the increase was reversed when the concentration of K+ in the perfusing medium was returned to normal. When the concentration of Ca2+ in the perfusing medium was also returned to normal, the previously quiescent heart resumed beating. In the beating heart where the Na+/K+ pump was not inhibited, the intensity of the intracellular Na+ resonance was less than 20% of that expected. Although the data are more sparse, the NMR visibility of the intracellular K+ signal appears to be no more than 20%.     

Multinuclear NMR studies of the Langendorff perfused rat heart

The quantitation of intracellular sodium ion concentration [Na+]in perfused organs using NMR spectroscopy requires a knowledge of the extent of visibility of the 23Na resonance and of the intracellular volume of the organ. We have used a multinuclear NMR approach, in combination with the extracellular shift reagent dysprosium (III) tripolyphosphate, to determine the NMR visibility of intra- and extracellular 23Na and 35Cl ions, intracellular volume, and [Na+]in in the isolated Langendorff perfused rat heart. Based on a comparison of the extracellular volumes calculated using 2H and 23Na, 35Cl, or 59Co NMR of the perfused heart we conclude that resonances of extracellular sodium and chloride ions (including ions in interstitial spaces) are fully visible, contrary to assumptions in the literature. Furthermore, prolonged hypoxia or ischemia caused a dramatic increase in intracellular Na+ and [Na+] in rose to approach that in the external medium indicating full visibility of the intracellular 23Na resonance. Resonance intensities of intra- and extracellular 23Na ions, along with a knowledge of the extracellular space as a fraction of the total organ water space, yielded an average [Na+] in of about 10 mM (10 +/- 1.5 mM) for the rat heart at 37 degrees C. Double-quantum filtered 23Na NMR of the perfused rat heart in the absence and presence of paramagnetic reagents revealed, contrary to assumptions in the literature, that both intra- and extracellular sodium ions contribute to the detected signal.     

An Na-23 and P-31 NMR investigation of sonicated cardiolipin sodium salt in aqueous medium

Na-23 and P-31 nuclear magnetic resonance was used to investigate the structure and dynamics of Na+ trapped in the enclosed aqueous spaces of unilamellar vesicles of Cardiolipin sodium salt. After sonicated Cardiolipin sodium salt forms a clear solution in aqueous medium and gives rise to a narrow, isotropic P-31 NMR line. This line was attributed to the presence of either vesicles or more complex liquid crystalline structures showing superposed-signals for inner and outer phosphate groups. The use of paramagnetic shift reagent Dy(PPPi)2 made it possible to observe only the line of the phosphate groups arranged within the structures. From an analysis of the spin-lattice relaxation parameters of Na-23 at 21.04 MHz and 52.6 MHz, the correlation time tau = 1.3 x 10(-9) sec was estimated. It was then possible to calculate the value of 1.9 MHz for the quadrupolar coupling parameter. These findings were interpreted in terms of the occurrence of specific bindings between Na+ and the phosphate moieties within the unilamellar structures of Cardiolipin.     

In vivo measurements of intra- and extracellular Na+ and water in the brain and muscle by nuclear magnetic resonance spectroscopy with shift reagent.

The introduction of new paramagnetic shift reagents in the nuclear magnetic resonance (NMR) method has made it possible to distinguish intra- and extracellular ions in tissues or organs in vitro. We measured the intra- and extracellular 23Na and 1H in vivo in the gerbil brain and skeletal muscle by NMR spectroscopy employing the shift reagent, dysprosium triethylenetetraminehexaacetate (Dy[TTHA]3-). Without Dy(TTHA)3-, the 23Na and 1H signals were seen only as single peaks, but gradual intravenous infusion of Dy(TTHA)3- separated these signals into two peaks, respectively. The unshifted peaks reflected the intracellular 23Na and 1H signals, while the shifted peaks reflected the extracellular signals. In the brain spectra, an additional small peak, which represented intravascular signals, was detected and its intensity increased after injection of papaverine hydrochloride. The present method is advantageous over the microelectrode technique because of its nondestructiveness and its capability for obtaining intra- and extracellular volume information from measurements of the 1H spectra, the peaks of which reflect the intra- and extracellular water amounts. The intracellular Na+ increase associating with increased cellular volume after ouabain in the muscle was clearly visualized by this method. The technique is clearly of use for physiological and pathophysiological studies of organs.     

23Na NMR study of Fibrobacter succinogenes S85: comparison of three chemical shift reagents and calculation of sodium concentration using ionophores

In order to measure intracellular sodium concentrations in resting cells of Fibrobacter succinogenes S85 by (23)Na NMR spectrometry, two methodological aspects were studied. First, three different shift reagents (Dy(PPP(i))(7-)(2), Tm(DOTP)(5-), and Dy(TTHA)(3-)) were tested for their ability to separate internal and external (23)Na NMR resonances. Their toxicity toward F. succinogenes cells was evaluated by in vivo(13)C NMR experiments. Tm(DOTP)(5-) was found to be the most efficient shift reagent while being nontoxic. Second, a new methodology was developed to calculate intracellular sodium concentration in F. succinogenes by using ionophores. This approach avoided the problem of intracellular volume measurement and that of sodium visibility determination.     

Double-quantum-filtered 23Na NMR study of intracellular sodium in the perfused liver.

We acquired double-quantum-filtered 23Na NMR spectra from perfused liver, using a range of tau values from 0.2 to 24 ms, where tau is the separation between the first and second pi/2 pulses in the radio-frequency pulse sequence. For each tau value we compared the amplitude of the double-quantum-filtered 23Na NMR signal acquired from intracellular sodium ions when the liver was perfused with buffer containing the "shift reagent" Dy(PPP)2 to the amplitude of the total double-quantum-filtered 23Na NMR signal acquired when the liver was perfused with buffer containing no Dy(PPP)2. For tau < or = 4 ms, the average ratio of the two amplitudes was 0.98 +/- 0.03 (mean +/- SEM). For tau > or = 8 ms, the average ratio was significantly less than 1. These results demonstrate that double-quantum-filtered 23Na NMR signals acquired from perfused liver using short tau values arise almost exclusively from intracellular sodium ions, but double-quantum-filtered 23Na NMR signals acquired from perfused liver using long tau values contain contributions from both intracellular and extracellular sodium ions. This conclusion suggests that multiple-quantum-filtered 23Na NMR spectroscopy will be useful in studying intracellular sodium levels in the perfused liver, and possibly in the intact liver in vivo.     

Energy requirements for the Na+ gradient in the oxygenated isolated heart: effect of changing the free energy of ATP hydrolysis

This study tests the hypothesis that a decrease of the free energy of ATP hydrolysis (Delta GATP) below a threshold value will inhibit Na+-K+-ATPase (Na+ pump) activity and result in an increase of intracellular Na+ concentration ([Na+]i) in the heart. Conditions were designed in which hearts were solely dependent on ATP derived from oxidative phosphorylation. The only substrate supplied was the fatty acid butyrate (Bu) at either low, 0.1 mM (LowBu), or high, 4 mM (HighBu), concentrations. Escalating work demand reduced the Delta GATP of the LowBu hearts. 31P, 23Na, and 87Rb NMR spectroscopy measured high-energy phosphate metabolites, [Na+]i, and Rb+ uptake. Rb+ uptake was used to estimate Na+ pump activity. To measure [Na+]i using a shift reagent for cations, extracellular Ca2+ was reduced to 0.85 mM, which eliminated work demand Delta GATP reductions. Increasing extracellular Na+ (Nae+) to 200 mM restored work demand Delta GATP reductions. In response to higher [Na+]e, [Na+]i increased equally in LowBu and HighBu hearts to approximately 8.6 mM, but Delta GATP decreased only in LowBu hearts. At lowest work demand the LowBu heart Delta GATP was -53 kJ/mol, Rb+ uptake was similar to that of HighBu hearts, and [Na+]i was constant. At highest work demand the LowBu heart Delta GATP decreased to -48 kJ/mol, the [Na+]i increased to 25 mM, and Rb+ uptake was 56% of that in HighBu hearts. At the highest work demand the HighBu heart Delta GATP was -54 kJ/mol and [Na+]i increased only approximately 10%. We conclude that a Delta GATP below -50 kJ/mol limits the Na+ pump and prevents maintenance of [Na+]i homeostasis.     

NMR studies of intracellular sodium ions in mammalian cardiac myocytes

The unambiguous measurement of intracellular sodium ion [Na+]i by the noninvasive NMR technique offers a new opportunity to monitor precisely the maintenance and fluctuations of [Na+]i levels in intact cells and tissues. The anionic frequency shift reagent, dysprosium (III) tripolyphosphate, which does not permeate intact cells, when added to suspensions of intact adult rat cardiac myocytes, alters the NMR frequency of extracellular sodium ions, [Na+]o, leaving that of intracellular ions, [Na+]i, unaffected. Using 23Na NMR in conjunction with this shift reagent, we have determined NMR-visible intracellular Na+ ion concentration in a suspension of isolated cardiac myocytes under standard conditions with insulin and Ca2+ in the extracellular medium to be 8.8 +/- 1.2 mmol/liter of cells (n = 4). This value is comparable to that measured by intracellular ion-selective microelectrodes in heart tissue. Cardiac myocytes incubated for several hours in insulin-deficient, Ca2+-containing medium prior to NMR measurement exhibited a somewhat lower [Na+]i value of 6.9 +/- 0.5 mmol/liter of cells (n = 3). Reversible Na+ loading of the cells by manipulation of extracellular calcium levels is readily measured by the NMR technique. Incubation of myocytes in a Ca2+-free, insulin-containing medium causes a 3-fold increase in [Na+]i to a level of 22.8 +/- 2.6 mmol/liter of cells (n = 10). In contrast to cells with insulin, insulin-deficient myocytes exhibit a markedly lower level of [Na+]i of only 14.6 +/- 2.0 mmol/liter of cells (n = 4) in Ca2+-free medium. These observations suggest that insulin may stimulate a pathway for Na+ influx in heart cells.     

23Na NMR studies of rat outer medullary kidney tubules

Two reservations have previously made interpretation of biological 23Na NMR measurements difficult: the "size" of the extracellular space penetrated by the shift reagent and the possibility of a 60% reduction in the intensity of the NMR-visible 23Na signal due to quadrupolar interactions (Berendsen, H. J. C., and Edzes, H. T. (1973) Ann. N. Y. Acad. Sci. 204, 459-485; Civan, M. M., Degani, H., Margalit, Y., and Shporer, M. (1983) Am. J. Physiol. 245, C213-C219; Gupta, R. K., and Gupta, P. (1982) J. Magn. Reson. 47, 344-350). We have addressed both these issues using a suspension of rat outer medullary kidney tubules, nephron segments responsible for the fine control of total body volume and electrolyte balance. First, the extracellular space penetrated by the shift reagent dysprosium tripolyphosphate, as defined by the extracellular 23Na resonance, revealed a space similar to that which contained extracellular 35Cl- ions. Measurement of an extracellular 35Cl- space using 35Cl NMR was possible because the intracellular 35Cl- resonance was broadened beyond detection in the cells studied. Second, to characterize the reduction of the 23Na signal by quadrupolar interactions, the intracellular 23Na level was raised artificially by simultaneously inhibiting Na+ efflux and increasing the ion permeability of the plasma membrane. Under these conditions, NMR-observable intracellular Na+ reached a level which was approximately 81% of that in the medium, a level determined using chemical techniques. This observation would suggest that the resonance of the intracellular 23Na pool was not subject to a 60% reduction in signal intensity, as a result of nuclear quadrupolar interaction. The intracellular 23Na level measured, under basal conditions, was 23 +/- 2 mumol/ml of cell water (37 degrees C) (n = 3, S.D.) and was demonstrated to be responsive to a number of physiological stimuli. The level was temperature-sensitive. It was reduced by inhibitors of apical Na+ transport, furosemide and amiloride, and it was raised with (Na+ + K+)-ATPase inhibition. The furosemide and amiloride actions described would suggest that the Na+-transporting mechanisms sensitive to these agents (e.g. Na+/K+/Cl- cotransport system, Na+:H+ exchange system) contribute to the regulation of the intracellular Na+ level in the kidney tubular preparation studied.     

Monitoring of intracellular ammonium in perfused rat salivary gland by nitrogen-14 nuclear magnetic resonance spectroscopy.

We have observed the changes in the intracellular ammonium (NH4+) content and the intracellular pH during administration of 20 mM NH4Cl (the ammonium pulse experiment) using nitrogen-14 and phosphorus-31 nuclear magnetic resonance spectroscopy (14N and 31P NMR) at 8.45 T. In the isolated perfused rat mandibular salivary gland, resonances of trimethylamines (-328 p.p.m.) and betaine (-329 p.p.m. from the resonance of NO3-) were detected. A chemical shift reagent, 10 mM of dysprosium triethylenetetramine-N,N,N',N",N"',N"'-hexaacetic acid (Dy(TTHA], was used to discriminate between the resonances from the extracellular NH4+ (-352 p.p.m.) and the intracellular NH4+ (-355 p.p.m.). During the NH4Cl application, the intracellular NH4+ content [( NH4+]i) increased quickly to ca. 50 mmol per litre intracellular fluid (ICF), then increased gradually to ca. 70 mmol per litre ICF. The intracellular pH (pHi), calculated from the 31P chemical shift of inorganic phosphate, increased transiently by 0.5 pH units and then decreased gradually in spite of the high level of [NH4+]i. The initial increase of [NH4+]i, which was observed by 14N NMR, was larger than that calculated from the intracellular pH on an assumption of a non-ionic diffusion process for ammonia. These results suggest a possibility of influx of NH4+, and also suggest an activation of cellular buffering mechanism that extrudes the excess bases from the cells.     

A 133Cs nuclear magnetic resonance study of endothelial Na(+)-K(+)-ATPase activity: can actin regulate its activity?

Using (133)Cs+ NMR, we developed a technique to repetitively measure, in vivo, Na(+)-K(+)-ATPase activity in endothelial cells. The measurements were made without the use of an exogenous shift reagent, because of the large chemical shift of 1.36 +/- 0.13 ppm between intra- and extracellular Cs+. Intracellularly we obtained a spin lattice relaxation time (T1) of 2.0 +/- 0.3 s, and extracellular T1 was 7.9 +/- 0.4 s. Na(+)-K+ pump activity in endothelial cells was determined at 12 +/- 3 nmol Cs+ x min(-1) x (mg Prot)[-1] under control conditions. When intracellular ATP was depleted by the addition of 5 mM 2-deoxy-D-glucose (DOG) and NaCN to about 5% of control, the pump rate decreased by 33%. After 80 min of perfusion with 5 mM DOG and NaCN, reperfusion with control medium rapidly reestablished the endothelial membrane Cs+ gradient. Using (133)Cs+ NMR as a convenient tool, we further addressed the proposed role of actin as a regulator of Na(+)-K+ pump activity in intact cells. Two models of actin rearrangement were tested. DOG caused a rearrangement of F-actin and an increase in G-actin, with a simultaneous decrease in ATP concentration. Cytochalasin D, however, caused an F-actin rearrangement different from that observed for DOG and an increase in G-actin, and cellular ATP levels remained unchanged. In both models, the Na(+)-K(+)-pump activity remained unchanged, as measured with (133)Cs NMR. Our results demonstrate that (133)Cs NMR can be used to repetitively measure Na(+)-K(+)-ATPase activity in endothelial cells. No evidence for a regulatory role of actin on Na(+)-K(+)-ATPase was found.     

NMR studies of intracellular sodium ions in amphibian oocytes, ovulated eggs, and early embryos

23Na NMR, in combination with an anionic paramagnetic shift reagent dysprosium bis(tripolyphosphate), has been used to study intracellular Na+ in Rana oocytes, ovulated eggs, and early cleavage embryos. The technique allows accurate and simultaneous determination of both extracellular space and intracellular Na+ concentration. In prophase-arrested, follicle-enclosed oocytes, only about 17% of the total oocyte Na+ (approximately 40 mmol/kg of cells) was NMR-visible. Homogenizing oocytes in 0.24 M sucrose did not significantly affect the 23Na resonance. About 30% of the total oocyte Na+ was associated with the yolk platelets isolated at room temperature by differential centrifugation. NMR analysis, however, did not yield a detectable 23Na signal from these intact platelets. Thus, while yolk platelets are rich in Na+, this Na+ does not contribute to the oocyte 23Na NMR signal. Denuded oocytes, obtained by removing the follicular epithelium, gained about 10 mmol of total Na+/kg of cells and exhibited a comparable increase in NMR-visible Na+, suggesting the existence of compartments with varying degree of NMR visibility within the oocyte. Partially relaxed 23Na Fourier transform NMR spectra revealed the existence of at least two major intracellular compartments of NMR-visible Na+ with different magnetic environments and relaxation behavior in denuded oocytes. Since platelet Na+ appears to be NMR-invisible, one of the two observed compartments may be the nucleus. Progesterone action on the amphibian oocyte caused measurable changes in NMR-visible Na+. By ovulation (second metaphase), there is a gain in total egg Na+, and the NMR-visible Na+ is also increased. Following fertilization, however, there is some loss of total cell Na+ but, by the 2-4 cell stage, about 70% of the total Na+ becomes NMR-visible. These results indicate that a sizable fraction of the Na+ in follicle-enclosed, prophase oocyte is sequestered and located in NMR-invisible compartments and that changes in NMR-visible intracellular Na+ occur following hormonal and developmental stimuli.     

NMR measurement of cytosolic free calcium, free magnesium, and intracellular sodium in the aorta of the normal and spontaneously hypertensive rat

We have utilized multinuclear NMR spectroscopy to examine the relationship between cytosolic free Ca2+ ([Ca2+]in), free Mg2+ ([Mg2+]in) and intracellular Na+ ([Na+]in) levels of the intact thoracic aorta and primary hypertension using the Wistar-Kyoto and Sprague-Dawley rats as controls and the spontaneously hypertensive rat as a model for genetic hypertension. Cytosolic free [Ca2+] was measured using 19F NMR of the intracellular Ca2+ indicator 5,5'-difluoro-1,2-bis-(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid, free [Mg2+] using the 31P resonances of intracellular ATP, and intracellular [Na+] by 23Na NMR in combination with the extracellular shift reagent dysprosium tripolyphosphate. We have found that both the [Na+]in and [Ca2+]in levels were significantly increased in the hypertensive animals relative to normotensive controls (p less than 0.01). Mean systolic blood pressures (using tail cuff method) of control and hypertensive rats were 123 +/- 8 mm Hg (mean +/- 2 S.E., n = 7) and 159 +/- 6 mm Hg (mean +/- 2 S.E., n = 7), respectively. [Na+]in and [Ca2+]in were 21.9 +/- 6.4 mM (mean +/- 2 S.E., n = 7) and 277 +/- 28 nM (mean +/- 2 S.E., n = 5) for the spontaneously hypertensive rats versus 10.1 +/- 1.8 mM (mean +/- 2 S.E., n = 7) and 151 +/- 26 nM (mean +/- 2 S.E., n = 5) for control rats, respectively. A slight difference observed between intracellular free Mg2+ levels in hypertensives (180 +/- 38 microM, mean +/- 2 S.E., n = 4) and controls (246 +/- 76 microM, mean +/- 2 S.E., n = 4) was not statistically significant (p greater than 0.1). These data indicate alterations in the cell membrane ion transport function of the aortic smooth muscle in primary hypertension.     

Multinuclear NMR studies of intracellular cations in perfused hypertensive rat kidney.

We have investigated hypertension-associated alterations in intracellular cations in the kidney by measuring intracellular pH, free Mg2+, free Ca2+, and Na+ concentrations in perfused normotensive and hypertensive rat (8-14 weeks old) kidneys using 31P, 19F, and double quantum-filtered (DQ) 23Na NMR. The effects of both anoxia and ischemia on the 23Na DQ signal confirmed its ability to detect changes in intracellular Na+. However, there was a sizable contribution of the extracellular Na+ to the 23Na DQ signal of the kidney. The intracellular free Ca2+ concentration, measured using 19F NMR and 5,5'difluoro-1,2-bis(2-aminophenoxy)ethane N,N,N',N'-tetraacetic acid, also increased dramatically during ischemia; the increase could be partly reversed by reperfusion. No significant differences were found between normotensive and hypertensive kidneys in the ATP level, intracellular pH, intracellular free Mg2+, and the 23Na DQ signal or in the extent of the extracellular contribution to the 23Na DQ signal. Oxygen consumption rates were also similar for the normotensive (5.02 +/- 0.46 mumol of O2/min/g) and hypertensive (5.47 +/- 0.42 mumol O2/min/g) rat kidneys. The absence of a significant difference in intracellular pH, Na+ concentration, and oxygen consumption between normotensive and hypertensive rat kidneys suggests that an alteration in the luminal Na+/H+ antiport activity in hypertension is unlikely. However, a highly significant increase (64%, p less than 0.01) in free Ca2+ concentration was found in perfused kidneys from hypertensive rats (557 +/- 48 nM, blood pressure = 199 +/- 5 mmHg, n = 6) compared with normotensive rats (339 +/- 21 nM, blood pressure = 134 +/- 6, n = 4) indicating altered renal calcium homeostasis in essential hypertension. An increase in intracellular free Ca2+ concentration without an accompanying change in the intracellular Na+ suggests, among many possibilities, that the Ca2+/Mg(2+)-ATPase may be inhibited in the hypertensive renal tissue.     

Active ion transport in the renal proximal tubule. II. Ionic dependence of the Na pump

The dependence of Na pump activity on intracellular and extracellular Na+ and K+ was investigated using a suspension of rabbit cortical tubules that contained mostly (86%) proximal tubules. The ouabain- sensitive rate of respiration (QO2) was used to measure the Na pump activity of intact tubules, and the Na,K-ATPase hydrolytic activity was measured using lysed proximal tubule membranes. The dependence (K0.5) of the Na pump on intracellular Na+ was affected by the relative intracellular concentration of K+, ranging from approximately 10 to 15 mM at low K+ and increasing to approximately 30 mM as the intracellular K+ was increased. The Na pump had a K0.5 for extracellular K+ of 1.3 mM in the presence of saturating concentrations of intracellular Na+. Measurements of the Na,K-ATPase activity under comparable conditions rendered similar values for the K0.5 of Na+ and K+. The Na pump activity in the intact tubules saturated as a function of extracellular Na at approximately 80 mM Na, with a K0.5 of 30 mM. Since Na pump activity under these conditions could be further stimulated by increasing Na+ entry with the cationophore nystatin, these values pertain to the Na+ entry step and not to the Na+ dependence of the intracellular Na+ site. When tubules were exposed to different extracellular K+ concentrations and the intracellular Na+ concentration was subsaturating, the Na pump had an apparent K0.5 of 0.4 mM for extracellular K. Under normal physiological conditions, the Na pump is unsaturated with respect to intracellular Na+, and indirect analysis suggests that the proximal cell may have an intracellular Na+ concentration of approximately 35 mM.     

Time course of myocardial sodium accumulation after burn trauma: a (31)P- and (23)Na-NMR study.

In this study, (23)Na- and (31)P- nuclear magnetic resonance (NMR) spectra were examined in perfused rat hearts harvested 1, 2, 4, and 24 h after 40% total body surface area burn trauma and lactated Ringer resuscitation, 4 ml. kg(-1). %(-1) burn. (23)Na-NMR spectroscopy monitored myocardial intracellular Na+ using the paramagnetic shift reagent thulium 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetra(methylenephosphonic acid). Left ventricular function, cardiac high-energy phosphates (ATP/PCr), and myocyte intracellular pH were studied by using (31)P NMR spectroscopy to examine the hypothesis that burn-mediated acidification of cardiomyocytes contributes to subsequent Na+ accumulation by this cell population. Intracellular Na+ accumulation was confirmed by sodium-binding benzofuran isophthalate loading and fluorescence spectroscopy in cardiomyocytes isolated 1, 2, 4, 8, 12, 18, and 24 h postburn. This myocyte Na+ accumulation as early as 2 h postburn occurred despite no changes in cardiac ATP/PCr and intracellular pH. Left ventricular function progressively decreased after burn trauma. Cardiomyocyte Na+ accumulation paralleled cardiac contractile dysfunction, suggesting that myocardial Na+ overload contributes, in part, to the progressive postburn decrease in ventricular performance.