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.     

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.     

竹红菌素对人红细胞Na^＋—K^＋ATPase和钠通透性光敏损伤的研究

The hypocrellin B (HB)-sensitized photodamage on Na(+)-K+ ATPase and sodium permeability of human erythrocytes by means of NMR and biochemical techniques was studied in this paper. The decrease of the enzyme activity and increase of intracellular sodium concentration were usually observed simultaneously. The evidences suggested that the integrality of membrane phospholipid played an important role in maintaining the physiological sodium content of erythrocytes. The loss of the enzyme activity was a sensitive index compared with the increase of intracellular Na+ concentration during the photosensitization. From the comparison tests among HB, HA, protoporphyrin and bilirubin, we found that HB had more ability to increasing intracellular Na+ concentration than the other photosensitization even though the photodamage on the enzyme activity caused by HB, HA, and protoporphyrin were nearly the same. Besides the photoinactivation of Na(+)-K+ ATPase induced by HB and light, the enzyme was also inactivated in the medium containing HB in absence of light. The active oxygen radicals generated though HB mediated redox-cycling might be involved in the dark inactivation of the enzyme.     

Coupling between the sodium and proton gradients in respiring Escherichia coli cells measured by 23Na and 31P nuclear magnetic resonance

The relationship between the steady-state sodium gradient (delta pNa) and the protonmotive force developed by endogenously respiring Escherichia coli cells has been studied quantitatively, using 23Na NMR for measurement of intracellular and extracellular sodium concentrations, 31P NMR for measurement of intracellular and extracellular pH, and tetraphenylphosphonium distribution for measurement of membrane potential. At constant protonmotive force, the sodium concentration gradient was independent of extracellular concentrations over the measured range of 4-285 mM, indicating that intracellular sodium concentration is not regulated. The magnitude of delta pNa was measured as a function of the composition and magnitude of the protonmotive force. At external pH values below 7.2, delta pNa was parallel to delta pH but showed no simple relationship to the membrane potential; above pH 7.2 the parallel relationship began to diverge, with delta pH continuing to decrease but delta pNa starting to level off or increase. Although plots of delta pNa versus delta pH had slopes of close to 1, the value of delta pNa consistently exceeded that of delta pH by approximately 0.4 units, indicating a partially electrogenic character to the putative H+/Na+ antiport. The apparent stoichiometry was 1.13 +/- 0.01 at external pH below 7.2. The possible significance of this nonintegral stoichiometry is discussed according to a model in which two distinct integral stoichiometries (possibly 1H+/1Na+ and 2H+/1Na+) are available with some relative probability; the model predicts futile cycling of sodium ions and a dissipative proton current. In the course of this study, we discovered that the magnitude of the pH gradient developed by the cells was osmolarity-dependent, yielding steady-state intracellular pH values that varied from 7.1 at 100 mosm to 7.7 at 800 mosm.     

Nuclear Magnetic Resonance Studies on Intracellular Sodium in Human Erythrocytes and Frog Muscle

The nuclear magnetic resonance (NMR) spectrum of sodium was determined in muscle and erythrocytes using conventional continuous wave techniques. NMR spectra of fresh intact muscle revealed a single line with a width of about 38 Hz equivalent in intensity to about 53% of the total muscle sodium, in general agreement with previous work. Prolonged washing with sodium-free solutions led to a marked loss of both total and NMR-detectable sodium. The NMR-visible sodium remaining in the muscle was somewhat larger than the fraction calculated to remain extracellular and, presumably, was intracellular. The original sodium signal is thus interpreted as arising from both extracellular sodium and the narrow line portion of the signal from intracellular sodium. NMR spectra of sodium were also obtained for human erythrocytes under conditions preserving the sodium transport system. The intensity of the sodium signal in fresh cells was 98% of that present in the same samples after complete hemolysis of the cells. The NMR sodium present in intact cells was 92% of the sodium recovered by flame photometric determination of sodium from ashed samples. It is concluded that no NMR-“invisible” sodium occurs in human erythrocytes and that the presence of such sodium is not necessary for the normal functioning of the sodium transport system in erythrocytes.     

Interstitial sodium nuclear magnetic resonance relaxation times in perfused hearts.

Separation of intracellular and extracellular sodium nuclear magnetic resonance (NMR) signals would enable nondestructive monitoring of intracellular sodium. It has been proposed that differences between the relaxation times of intracellular and extracellular sodium be used either directly or indirectly to separate the signal from each compartment. However, whereas intracellular sodium relaxation times have been characterized for some systems, these times were unknown for interstitial sodium. In this study, the interstitial sodium NMR relaxation times have been measured in perfused frog and rat hearts under control conditions. This was achieved by eliminating the NMR signal from the extracardiac (perfusate) sodium, and then quantifying the remaining cardiac signal. The intracellular signal was measured to be 8% (frog) or 22% (rat) of the cardiac signal and its subtraction was found to have a negligible effect on the cardiac relaxation times. Therefore this cardiac signal is considered to provide a good estimate of interstitial relaxation behavior. For perfused frog (rat) hearts under control conditions, this signal was found to have a T1 of 31.6 +/- 3.0 ms (27.3 +/- 1.6 ms) and a biexponential T2 of 1.9 +/- 1.0 ms (2.1 +/- 0.3 ms) and 25.2 +/- 1.3 ms (26.3 +/- 3.2 ms). Due to the methods used to separate cardiac signal from perfusate signal, it is possible that this characterized only a part of the signal from the interstitium. The short T2 component attributable to the interstitial signal indicates that separation of the NMR signals from each compartment on the basis of relaxation times alone may be difficult.     

竹红菌乙素对人红细胞Na~+-K~+ATPase和钠通透性光敏损伤的研究

本文用NMR和生化方法研究了竹红菌乙素对人红细胞膜Na~+-K~+ATPase和钠通透性的光敏损伤。结果表明:在通常情况下,可同时观察到乙素对Na~+-K~+ATPase和钠通透性的光敏损伤。比较乙素、甲素、原卟啉和胆红素对上述两项指标的光敏能力,发现乙素对Na~+-K~+ATPase损伤能力与甲素和原卟啉相当,比胆红素大,对钠通透性的损伤大于其它几种敏化剂。实验指出,Na~+-K~+ATPase活力下降比钠通透性增加敏感。在乙素光敏作用时,加入Vit E可基术上保持胞内钠离子浓度不变,但无法使Na~+-K~+ATPase活力不损伤,这表明膜磷脂的结构完整对保持胞内钠浓度比较重要。对照试验指出乙素可使Na~+-K~+ATPase暗失活,这可能是经乙素介导的,由膜还原物质向氧的电子传递生成活性氧自由基攻击靶分子所致。     

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.     

Na-NMR Studies of the Intracellular Sodium Ion Concentration in the Halotolerant Alga Dunaliella salina

The Intracellular Na⁺ concentration in the halotolerant alga Dunaliella salina was measured in intact cells by ²³Na-NMR spectroscopy, utilizing the dysprosium tripolyphosphate complex as a sodium shift reagent, and was found to be 88 ± 28 millimolar. Intracellular sodium ion content and intracellular volume were the same, within the experimental error, in cells adapted to grow in media containing between 0.1 and 4.0 molar NaCl. These values assume extracellular and intracellular NMR visibilities of the ²³Na nuclei of 100 and 40%, respectively. The relaxation rate of intracellular sodium was enhanced with increasing salinity of the growth medium, in parallel to the intracellular osmosity due to the presence of glycerol, indicating that Na⁺ ions and glycerol are codistribbuted within the cell volume.     

23Na NMR study of intracellular sodium ions in Dictyostelium discoideum amoeba

The intracellular sodium concentration in the amoebae from the slime mold Dictyostelium discoideum has been studied using 23Na NMR. The 23Na resonances from intracellular and extracellular compartments could be observed separately in the presence of the anionic shift reagent Dy(PPPi)7-2 which does not enter into the amoebae and thus selectively affects Na+ in the extracellular space. 31P NMR was used to control the absence of cellular toxicity of the shift reagent. The intracellular Na+ content was calculated by comparison of the intensities of the two distinct peaks arising from the intra- and extracellular spaces. It remained low (0.6 to 3 mM) in the presence of external Na+ (20 to 70 mM), and a large Na+ gradient (20- to 40-fold) was maintained. A rapid reloading of cells previously depleted of Na+ was readily measured by 23Na NMR. Nystatin, an antibiotic known to perturb the ion permeability of membranes, increased the intracellular Na+ concentration. The time dependence of the 23Na and 31P NMR spectra showed a rapid degradation of Dy(PPPi)7-2 which may be catalyzed by an acid phosphatase.     

The phosphate pool of isolated dog heart during global ischaemia: comparison of two cardioplegic solutions with 31P NMR spectroscopy.

31P NMR spectroscopy was used to study the time course of changes in the concentration of high-energy metabolites and intracellular pH in the dog myocardium during hypothermic ischaemia at 9 degrees C in Bretschneider (HTK-B) and St. Thomas' Hospital (StTH) cardioplegic solutions. It was found that ATP and phosphocreatine degrade slowlier in HTK-B than in StTH, with phosphocreatine depletion occurring within 7.9 +/- 1.4 h in HTK-B and within 6.2 +/- 1.4 h in StTH. The values are virtually identical with the time intervals at which ATP concentration falls below the critical level (60% of initial ATP concentration). In agreement with biochemical analysis, a higher concentration of phosphomonoesters was noted until the 180th minute of ischaemia in HTK-B, a finding suggesting more rapid glycogen degradation in HTK-B. Even though HTK-B contains a high concentration of histidine buffer, higher values of intracellular pH were found during ischaemia in StTH. The effect of extracellular concentration of sodium ions on intracellular pH is discussed.     

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.     

Changes of intracellular Na~ concentration in erythrocytes caused by pulsed electrical field

Changes of sodium ionic concentration of human erythrocytes applied to pulsed electrical field (PEF) were studied by using shift reagent and NMR spectroscopy. The results show that the concentration of intracellular Na increases with the increasing intensity of PEF when the erythrocytes are applied to PEF with higher intensities. The relationship between intracellular Na concentrations and the intensities of PEF does not follow linear or exponen-tial behavior. As the intensities increase, the intracellular Na concentrations increase even faster by an exponential curve. However under effects of PEF at lower intensities, intracellular Na concentration decreases. Ouabain can in-hibit the decrease of intracellular Na concentration, and the inhibition increases with the increasing concentration of ouabain, suggesting that Na , K -ATPase on cell membrane can be activated by PEF at lower intensities. Direct measurement of activities of the enzyme by using Malachite green method has confirmed this observatio     

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.     

Changes of intracellular Na+ concentration in erythrocytes caused by pulsed electrical field

Changes of sodium ionic concentration of human erythrocytes applied to pulsed electrical field (PEF) were studied by using shift reagent and NMR spectroscopy. The results show that the concentration of intracellular Na⁺ increases with the increasing intensity of PEF when the erythrocytes are applied to PEF with higher intensities. The relationship between intracellular Na concentrations and the intensities of PEF does not follow linear or exponen-tial behavior. As the intensities increase, the intracellular Na⁺concentrations increase even faster by an exponential curve. However under effects of PEF at lower intensities, intracellular Na⁺ concentration decreases. Ouabain can in-hibit the decrease of intracellular Na concentration, and the inhibition increases with the increasing concentration of ouabain, suggesting that Na⁺ , K⁺ -ATPase on cell membrane can be activated by PEF at lower intensities. Direct measurement of activities of the enzyme by using Malachite green method has confirmed this observation. Cell perme-abilities to ions, activation of enzymes by electrical fields and transmission of physical signals like PEF across cell mem-branes are discussed.     

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.     

Changes of intracellular Na+ concentration in erythrocytes caused by pulsed electrical field

Changes of sodium ionic concentration of human erythrocytes applied to pulsed electrical field (PEF) were studied by using shift reagent and NMR spectroscopy. The results show that the concentration of intraceUular Na⁺ increases with the increasing intensity of PEF when the erythrocytes are applied to PEF with higher intensities. The relationship between intracellular Na⁺ concentrations and the intensities of PEF does not follow linear or exponential behavior. As the intensities increase, the intracellular Na⁺ concentrations increase even faster by an exponential curve. However under effects of PEF at lower intensities, intracellular Na⁺ concentration decreases. Ouabain can inhibit the decrease of intracellular Na⁺ concentration, and the inhibition increases with the increasing concentration of ouabain, suggesting that Na⁺, K⁺-ATPase on cell membrane can be activated by PEF at lower intensities. Direct measurement of activities of the enzyme by using Malachite green method has confirmed this observation. Cell permeabilities to ions, activation of enzymes by electrical fields and transmission of physical signals like PEF across cell membranes are discussed.     

Application of linear prediction singular value decomposition for processingin vivo NMR data with low signal-to-noise ratio

Summary Low sensitivity of nuclear magnetic resonance (NMR) measurements of living cell composition by conventional methods requires samples with high cell density compared to that in growing cultures. Reasonably accurate intracellular concentration estimates from lower cell density samples can be obtained by treating the time-domain NMR data by linear prediction singular value decomposition (LPSVD) prior to Fourier transformation. Alternatively, application of LPSVD enables intracellular concentration estimates in less NMR acquisition time, improving time resolution in NMR measurements of intracellular transients.     

The effects of a low extracellular concentration of potassium on the activity and numbers of Na+/K+ pumps in an EB-virus transformed human lymphocyte cell line

The BM1A EB-virus transformed human lymphocyte cell line contains approximately 950,000 Na+/K(+)-ATPase sites per cell. The turnover number of each site is approx. 2240 molecules of rubidium per min. When cells are exposed to a low extracellular concentration of potassium the intracellular concentration of sodium rises, and the cells respond in the short term by increasing the Vmax of 86Rb+ uptake. In the longer term the cells respond by increasing both the Vmax of 86Rb+ uptake and the Bmax of [3H]ouabain binding. The suggestion that increases in the intracellular concentration of sodium is responsible for these changes is supported by the finding that monensin, which increases intracellular sodium without affecting intracellular potassium, is capable of inducing both the short- and long-term changes associated with a low external concentration of potassium.     

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%.