The phenomenon of separate intra- and extracellular resonances of difluorophosphate in 31P and 19F NMR spectra of erythrocytes

The NMR 'split peak effect' in cell suspensions: Historical perspective, explanation and applications

The physicochemical environment inside cells is distinctly different from that immediately outside. The selective exchange of ions, water and other molecules across the cell membrane, mediated by integral, membrane-embedded proteins is a hallmark of living systems. There are various methodologies available to measure the selectivity and rates (kinetics) of such exchange processes, including several that take advantage of the non-invasive nature of NMR spectroscopy. A number of solutes, including particular inorganic ions, show distinctive NMR behaviour, in which separate resonances arise from the intra- and extracellular solute populations, without the addition of shift reagents, differences in pH, or selective binding partners. This 'split peak effect/phenomenon', discovered in 1984, has become a valuable tool, used in many NMR studies of cellular behaviour and function. The explanation for the phenomenon, based on the differential hydrogen bonding of the reporter solutes to water, and the various ways in which this phenomenon has been used to investigate aspects of cellular biochemistry and physiology, are the topics of this review.

Determination of glucose exchange rates and permeability of erythrocyte membrane in preeclampsia and subsequent oxidative stress-related protein damage using dynamic-19F-NMR

The cause of the pregnancy condition preeclampsia (PE) is thought to be endothelial dysfunction caused by oxidative stress. As abnormal glucose tolerance has also been associated with PE, we use a fluorinated-mimic of this metabolite to establish whether any oxidative damage to lipids and proteins in the erythrocyte membrane has increased cell membrane permeability. Data were acquired using ¹⁹F Dynamic-NMR (DNMR) to measure exchange of 3-fluoro-3-deoxyglucose (3-FDG) across the membrane of erythrocytes from 10 pregnant women (5 healthy control women, and 5 from women suffering from PE). Magnetisation transfer was measured using the 1D selective inversion and 2D EXSY pulse sequences, over a range of time delays. Integrated intensities from these experiments were used in matrix diagonalisation to estimate the values of the rate constants of exchange and membrane permeability. No significant differences were observed for the rate of exchange of 3-FDG and membrane permeability between healthy pregnant women and those suffering from PE, leading us to conclude that no oxidative damage had occurred at this carrier-protein site in the membrane.

NMR magnetization-transfer analysis of rapid membrane transport in human erythrocytes

Nuclear magnetic resonance (NMR) magnetization-transfer (MT) experiments provide a convenient tool for studying rapid sub-second membrane-transport processes in situ in metabolically active cells. These experiments are used with membrane-permeable substances when separate (resolved) NMR signals are observed from their populations inside and outside the cells. Here, we provide a description of the theory and practice of the most common NMR MT experiments that have been used to study membrane-transport processes in human erythrocytes (red blood cells; RBCs). The procedures, involved in the analysis of the experimental data for defining mechanisms of transport, and for estimating values of kinetic parameters in the corresponding mathematical models, are given special attention.

Chemical shift and magnetic susceptibility contributions to the separation of intracellular and supernatant resonances in variable angle spinning NMR spectra of erythrocyte suspensions

Factors contributing to the observation of two separate water resonance arising from erythrocyte suspensions under magic- and variable-angle spinning conditions were examined. By observing the 1H NMR spectra of different chemical species in erythrocytes at different spinning angles, two major effects of comparable magnitude were shown to contribute to the separation: 1) an isotropic chemical shift difference, and 2) a susceptibility difference between the intracellular and supernatant compartments. When the sample was spun at the magic angle, the susceptibility difference did not contribute to the separation. Use of different angles between the spinning axis and the main magnetic field provided a method for quantifiying the isotropic chemical shift and susceptibility differences between the compartments.

Scalar couplings as pH probes in compartmentalized biological systems: 31P NMR of phosphite

The use of scalar couplings in nuclear magnetic resonance (NMR) spectra was investigated as a possible tool for the measurement of pH in different compartments of biological systems. The proposed method is attractive because no internal reference is required, unlike more widely used chemical shift titrations. The phosphite anion is shown to be ideal for the measurement of pH in the physiological range. In isotonic solution, the divalent anion PHO(3)(2-) has a one-bond (1)J(PH) of 568.1 Hz, increasing to 620.7 Hz for the monovalent anion PH(OH)O(2)(-), with a measured pK(a) of 6.19. The technique was applied to the measurement of pH in a suspension of human erythrocytes. The (31)P spectra of these species give well-resolved doublets for the intra- and extracellular spaces, and can be used to measure the pH difference across the cell membrane with errors on the order of about 0.01 pH units in the range of pH 5-7. Variations in erythrocyte pH due to metabolic changes are clearly observed.

Nuclear magnetic resonance studies of cesium-133 in the halophilic halotolerant bacterium Ba1. Chemical shift and transport studies

Ba1 bacteria (Halomonas israelensis) were grown on different salt concentrations 0.2-4 M. When the cells were transferred to a medium containing 25 mM CsCl without potassium there was an uptake of cesium by the cells. The intracellular cesium signal was shifted from the cesium signal in the medium without the use of a shift reagent. The shift was depended on the salt concentration in the growth medium. The intracellular cesium shift showed a much smaller dependence on the concentration of salts in the medium than the extracellular cesium; the same results were detected for cells grown on a medium containing 25 mM CsCl. The cesium transport through the cell membrane was mostly by active transport. The cesium concentration in the cell was higher than that of the medium, approximately 100 mM intracellular concentration compared to 25 mM in the medium. The first order constants for influx or efflux of cesium were from 2 x 10(-4) and up to 24 x 10(-4)/min for the different medium concentrations.

Anomeric dependence of fluorodeoxyglucose transport in human erythrocytes

The transport of several n-fluoro-n-deoxy-D-glucose derivatives across the human erythrocyte membrane has been studied under equilibrium exchange conditions using one- and two-dimensional nuclear magnetic resonance (NMR) techniques. This approach is based on the intracellular 19F shift, which was found to depend on the anomeric form and on the F/OH substitution position. Since the transport behavior of both glucose anomers can be followed simultaneously, this approach is particularly sensitive to differences in anomeric permeability. For 2-, 3-, 4-, and 6-fluorodeoxyglucose analogs, the alpha anomers permeate more rapidly, and the P alpha/P beta ratio is dependent on the position of fluorination, with values of 1.1, 1.3, 2.5, and 1.6, respectively, obtained at 37 degrees C. These results have been analyzed in terms of a simple alternating conformation model for the glucose transporter. Although mutarotase activity has been reported for red cells, mutarotation behavior for all anomers was found to be completely negligible on the transport and spin-lattice relaxation time scales. Metabolic transformation of the fluorinated glucose analogs, primarily to fluorinated gluconate and sorbitol analogs, is very slow and does not significantly interfere with the transport measurements. A mean ratio of 2.6 was found for the extracellular/intracellular fluorine spin-lattice relaxation rates.

Characterisation of erythrocyte transmembrane exchange of trifluoroacetate using 19F-NMR: evidence for transport via the monocarboxylate transporter

The transport of trifluoroacetate (TFA) and difluorophosphate (DFP) into and out of human and sheep erythrocytes was measured using 19F-NMR. The pathways for the transport in human erythrocytes were characterised by differentiating between the transport inhibition caused by different reagents. (1) Pre-treatment of human erythrocytes with N-ethylmaleimide (10 mM) caused a decrease of the membrane-permeability coefficients for TFA influx and efflux to 0.74 +/- 0.05 and 0.83 +/- 0.09-times, respectively, of those determined in the absence of inhibition. Concomitantly there was no apparent effect on the band-3-mediated transport of DFP. Thus, the decrease of the permeability of TFA is consistent with the inhibition being that of the monocarboxylate transporter. (2) Inhibition of TFA and DFP exchange was also seen in human erythrocytes treated with p-chloromercuriphenylsulfonate (pCMBS). The extent of inhibition reached a maximum value for the pCMBS concentrations beyond which further inhibition was not achieved and there was substantial residual exchange of the two solutes. (3) Residual flux of TFA was found in the presence of high concentrations of the inhibitors, alpha-cyano-4-hydroxycinnamate (> or = 4 mM) or 4,4'-dinitrostilbene-2,2'-disulfonate (> or = 1 mM) when each compound was used alone. (4) Complete inhibition of TFA uptake was obtained when human erythrocytes were treated with both alpha-cyano-4-hydroxycinnamate (4 mM) and a stilbene disulfonate. It was, therefore, concluded that simple diffusion of TFA via the lipid bilayer was negligible in human erythrocytes and that incomplete inhibition of the monocarboxylate transporter occurred when the compounds were used alone.

Dimethyl methylphosphonate (DMMP): a 31P nuclear magnetic resonance spectroscopic probe of intracellular volume in mammalian cell cultures

Dimethyl methylphosphonate (DMMP), when added to a suspension of erythrocytes, has been reported to have a lower frequency chemical shift inside of cells than outside. This work further investigates the same phenomenon in hollow-fiber bioreactor cultures of six mammalian cell lines and describes the application of DMMP as a measure of intra- versus extracellular volumes in mammalian cell cultures. No toxic effects of the DMMP were observed at the concentrations used here. The dependence of the shift of intracellular DMMP on intracellular protein content was shown to be similar for cultured mammalian and red blood cells. Also consistent with shifts in erythrocytes, an increase in the intracellular protein concentration due to a reduction in cultured cell volume increased the magnitude of the shift to lower frequency. Longitudinal relaxation (T1) values for intra- and extracellular DMMP were measured so that partially saturated DMMP peaks in 31P NMR spectra of mammalian cell cultures can be corrected to give the relative volumes of the intra- and extracellular compartments; this information provides a relative measure of culture growth. Intracellular volume measured by this method can also be used to quantify intracellular metabolites such as ATP during the growth of the culture. To explore the mechanism behind the intracellular shift, we have also addressed the three possible contributions to the chemical shift of DMMP: hydrogen-bonding interactions, magnetic susceptibility, and ionic strength. Data is presented which eliminates the latter two mechanisms and strongly supports the hypothesis that the observed intracellular shift is due to a reduction in hydrogen bonding between water and DMMP in the cytoplasm.

Bulk magnetic susceptibility induced broadening in the 19F NMR of suspended leukemic cells

The relevance of bulk magnetic susceptibility (BMS) induced broadening to in vivo NMR studies of intact cells has been examined and the significance of the contribution of BMS difference to the resolution of intra- and extracellular resonances was demonstrated. BMS difference between intra- and extracellular compartments was found to limit the resolution of intra- and extracellular 19F resonances of fluoro compounds in leukemic cells.

Transmembrane 19F NMR chemical shift difference of fluorinated solutes in liposomes, erythrocytes and erythrocyte ghosts

In erythrocytes suspended in isotonic medium, a number of fluorinated anions showed well resolved 19F NMR resonances from the solute populations in the intra- and extracellular compartments; the intracellular resonances were shifted to higher frequency (low field). In addition 19F NMR resonances of extracellular solutes were shifted to higher frequency when bovine serum albumin was incorporated into the extracellular medium. The dependence of 19F NMR chemical shift on protein concentration was also demonstrated using resealed red cell ghosts and liposomes; in the presence of external hemoglobin, lysozyme and bovine serum albumin, the shift of the external resonances was to higher frequency. In addition, significant high frequency shifts of 19F NMR resonances were evident along with an increase of temperature. The results of the present study further support the contention that the principal physical basis for the shifts is the disruption of direct hydrogen bonds between 19F of the solutes and (primarily) solvent H2O by protein hydration. The 'split peak' phenomenon is of general importance in biological systems where a transmembrane protein-concentration difference exists.

Aqueous shift reagents for high-resolution cation NMR. VI. Titration curves for in vivo 23Na and 1H2O MRS obtained from rat blood

Frequency shift/concentration calibration curves applicable to the use of shift reagents (SRs) for in vivo 23Na MRS studies can be obtained from experiments with whole blood. Here, they are reported for titrations of rat blood with the SRs DyTTHA3- and TmDOTP5-. There are a number of considerations that must be made in order to derive accurate calibration curves from the experimental data. These include the effects of bulk magnetic susceptibility (BMS, since the SRs are paramagnetic), the effects of water flux (since addition of the SR stock solution to blood renders the plasma hyperosmotic), and the consequences of restricted distribution of the SR anion in the erythrocyte suspension. We give in some detail the BMS shift theory that obtains in this case and show also how it applies to excised perfused organ as well as in vivo studies. Also, we report significant effects of adjuvant Ca2+ additions in the TmDOTP5- titrations. These are very important to the successful use of this SR in vivo. Finally, our considerations of BMS lead naturally to an understanding of its manifestations in the shifts of the 1H2O resonance frequencies of cell suspensions and tissues induced by SRs. Since these are being increasingly reported, and often misinterpreted, we devote an experiment and some discussion to this subject. We show that this phenomenon cannot be used to quantitatively discriminate intra- and extracellular 1H2O signals.

Band-3 mediated uptake of beryllofluoride complexes by human erythrocytes

Beryllium forms several multivalent fluoride complexes in aqueous solution; the relative concentration of each is governed by the relative concentrations of the constituent ions and pH. In 9Be NMR spectra the 9Be (spin = 3/2) and 19F (spin = 1/2) spin coupling gave rise to an overlapping resonance triplet, quartet, and quintet of BeF2, BeF3-, and BeF4(2-), respectively. The low frequency shift of the quartet (0.31 ppm) and the quintet (0.62 ppm) from the triplet correlated with an increase in the number of 19F-ions in each complex. 19F NMR spectra of the complexes showed that the spin-coupled quartet of each complex was progressively shifted to higher frequency with an increase in the number of F- ions in the complex. Using 9Be and 19F NMR, the multiple equilibrium mixture of complexes was found to shift substantially to favor the BeF3- and BeF4(2-) with a relative increase of NaF concentration. The association constants for BeF2, BeF3-, and BeF4(2-) at 25 degrees C were determined directly from the peak intensities of the spectra, and by a numerical fitting procedure for multiple spectra, and were 0.51 +/- 0.17 mM-2, 0.26 +/- 0.03 mM-1, and 1.0 x 10(-2) +/- 0.1 x 10(-2) mM-1, respectively. 19F NMR spectra of human erythrocytes to which Be2+ and F- were added showed separate resonances from the intracellular populations of the complexes and these were shifted to higher frequency from their extracellular counterparts.(ABSTRACT TRUNCATED AT 250 WORDS)