The contribution of magnetic susceptibility effects to transmembrane chemical shift differences in the 31P NMR spectra of oxygenated erythrocyte suspensions

Triethyl phosphate, dimethyl methylphosphonate, and the hypophosphite ion all contain the phosphoryl functional group. When added to an oxygenated erythrocyte suspension, the former compound gives rise to a single 31P NMR resonance, whereas the latter compounds give rise to separate intra- and extracellular 31P NMR resonances. On the basis of experiments with intact oxygenated cell suspensions (in which the hematocrit was varied) and with oxygenated cell lysates (in which the lysate concentration was varied), it was concluded that the chemical shifts of the intra- and extracellular populations of triethyl phosphate differ as a consequence of the diamagnetic susceptibility of intracellular oxyhemoglobin but that this difference is averaged by the rapid exchange of the compound across the cell membrane. The difference in the magnetic susceptibility of the intra- and extracellular compartments contributes to the observed separation of the intra- and extracellular resonances of dimethyl methylphosphonate and hypophosphite. The magnitude of this contribution is, however, substantially less than that calculated using a simple two-compartment model and varies with the hematocrit of the suspension. Furthermore, it is insufficient to fully account for the transmembrane chemical shift differences observed for dimethyl methylphosphonate and hypophosphite. An additional effect is operating to move the intracellular resonances of these compounds to a lower chemical shift. The effect is mediated by an intracellular component, and the magnitude of the resultant chemical shift variations depends upon the chemical structure of the phosphoryl compound involved.     

Characterization of transmembrane chemical shift differences in the 31P NMR spectra of various phosphoryl compounds added to erythrocyte suspensions

Trimethyl phosphate, dimethyl methylphosphonate, diethyl methylphosphonate, trimethylphosphine oxide, and the hypophosphite, phenylphosphinate, and diphenylphosphinate ions all contain the phosphoryl functional group. When added to an intact erythrocyte suspension at 20 degrees C, each of the compounds gave rise to separate intra- and extracellular 31P NMR resonances, and the separation between the two resonances of each compound varied with the mean cell volume. The differences between the intra- and extracellular chemical shifts were shown to be primarily attributable to the effects of hemoglobin. The presence of hemoglobin inside the cell gave rise to a significant difference in the magnetic susceptibilities of the two compartments. In addition, it exerted a large susceptibility-independent chemical shift effect, the magnitude of which was dependent upon the chemical structure of the phosphoryl compound involved. A number of other intra- and extracellular components were also shown to cause chemical shift variations, smaller than those arising from hemoglobin but nonetheless significant. The cell volume dependence of the transmembrane chemical shift differences therefore reflected not only the cell volume dependence of the intracellular hemoglobin concentration but also the changing concentration of the other solutes in the two compartments. In addition to their cell volume dependence, the transmembrane chemical shift differences varied with temperature. In the case of the nonelectrolytes this reflected not only the temperature dependence of the mechanism(s) responsible for the susceptibility-independent shift effects but also the temperature dependence of the rates at which the compounds traversed the cell membrane.     

Intracellular pH in stored erythrocytes. Refinement and further characterisation of the 31P-NMR methylphosphonate procedure

Methylphosphonate in conjunction with 31P-NMR spectroscopy was used for the measurement of transmembrane delta pH in human erythrocytes stored at 4 degrees C for up to 5 weeks in a nutrient medium. Intra- and extracellular pH was determined using calibration curves based on the pH-dependent separation between the NMR resonances of methylphosphonate and orthophosphate (Pi). A comprehensive statistical procedure is presented for the determination of the variance of NMR-based pH estimates. The entry of methylphosphonate into erythrocytes was more rapid at low pH and uptake was fully inhibited by the band 3 reagent, disodium 4,4-diisothiocyano-2,2'-disulphonic acid stilbene. The distribution ratio of methylphosphonate concentration inside and outside the cells was used to calculate the membrane potential; the analysis depends on a consideration of the Donnan equilibrium for an anion with one or two charges. Furthermore, the analysis does not depend on the pH estimates but relies solely on concentration estimates. The chemical shift of methylphosphonate was not subject to the variations associated with specific intracellular binding encountered with many other phosphorus compounds, including Pi. On the other hand, the ionic strength dependence of the chemical shift of methylphosphonate, contrary to earlier reports, is comparable in magnitude (but opposite in sign) to that of Pi.     

Some blood parameters of the rainbow trout (Salmo gairdneri Richardson)

Fifty rainbow trout of the Kamloops strain were examined for 12 haematological parameters: erythrocyte sedimentation rate, haemoglobin, packed cell volume, erythrocyte count, erythrocyte diameters, mean cell volume, mean cell haemoglobin, mean cell haemoglobin concentration, leukocyte count, differential leukocyte count, plasma total protein and plasma glucose concentration. The fish had been held under known environmental and dietetic conditions, and at the time of sampling were 14 months old. The majority of results for erythrocyte sedimentation rate, haemoglobin, packed cell volume, erythrocyte count, erythrocyte diameters, total protein and differential leukocyte count fell within narrow ranges. The total leukocyte counts and glucose levels were more widely spread. The results are discussed and compared with those already published for Idaho and Shasta strains. It is impossible to say whether the differences that were observed between Kamloops and these other varieties were due to strain alone, since other variables were present. Some problems associated with establishing normal ranges for these parameters in fish are discussed.     

Physical basis of the effect of hemoglobin on the 31P NMR chemical shifts of various phosphoryl compounds

The marked difference between the intra- and extracellular 31P NMR chemical shifts of various phosphoryl compounds when added to a red cell suspension may be largely understood in terms of the effects of hemoglobin on the 31P NMR chemical shifts. The presence of [oxy- or (carbonmonoxy)-] hemoglobin inside the red cell causes the bulk magnetic susceptibility of the cell cytoplasm to be significantly less than that of the external solution. This difference is sufficient to account for the difference in the intra- and extracellular chemical shifts of the two phosphate esters trimethyl phosphate and triethyl phosphate. However, in the case of the compounds dimethyl methylphosphonate, diethyl methylphosphonate, and trimethyl-phosphine oxide as well as the hypophosphite, phenylphosphinate, and diphenylphosphinate ions, hemoglobin exerts an additional, much larger, effect, causing the 31P NMR resonances to shift to lower frequency in a manner that cannot be accounted for in terms of magnetic susceptibility. Lysozyme is a protein structurally unrelated to hemoglobin and was shown to cause similar shifts to lower frequency of the resonances of these six compounds; this suggests that the mechanism may involve a property of proteins in general and not a specific property of hemoglobin. The effect of different solvents on the chemical shifts of the eight phosphoryl compounds provided an insight into the possible physical basis of the effect.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vivo 31P NMR study of early cellular responses to hyperosmotic shock in cultured glioma cells.

Cell volume regulation in the face of osmotic stress is a fundamental homeostatic activity, and is most critical in brain, which is spatially constrained. Despite the importance of this phenomenon, little is known about volume regulation in the brain, primarily because of the cellular heterogeneity in the tissue. We describe here simultaneous in vivo 31P nuclear magnetic resonance (NMR) measurements of cell volume, intracellular pH and phosphate metabolites during early responses to hyperosmotic stress in C6 glioma cells perfused in NMR-compatible bioreactors. Cell volume was measured using dimethyl methylphosphonate (DMMP) as a probe which has an intracellular NMR resonance shifted upfield from the extracellular resonance. The sensitivity of these measurements allowed 31P NMR spectra to be collected every 30 s. Following an increase in osmolarity from 320 to 480 mOsm by addition of NaCl to the perfusate, C6 glioma cells shrank to 67% of their original volume. We also observed a simultaneous increase of intracellular pH coincident with the decrease in cell volume. The signals from ATP decreased by 10%, but those from phosphocreatine (PCr) increased by 31% after hyperosmotic shock. However, correcting the ATP signals for the decrease in cell volume indicated that its intracellular concentrations increased after treatment. Signals from glycerophosphorylcholine (GPC) and glycerophosphorylethanolamine (GPE) were not changed significantly. This is the first in vivo report of early cellular responses monitored by NMR spectroscopy following hyperosmotic shock in cultured cells.     

Changes in organic solutes,volume, energy state,and metabolism associated with osmotic stress in a glial cell line: A multinuclear NMR study

Diffusion-weighted in vivo¹H-NMR spectroscopy of F98 glioma cells embedded in basement membrane gel threads showed that the initial cell swelling to about 180% of the original volume induced under hypotonic stress was followed by a regulatory volume decrease to nearly 100% of the control volume in Dulbecco's modified Eagle's medium (DMEM) but only to 130% in Krebs-Henseleit buffer (KHB, containing only glucose as a substrate) after 7 h. The initial cell shrinkage to approx. 70% induced by the hypertonic stress was compensated by a regulatory volume increase which after 7 h reached almost 100% of the control value in KHB and 75% in DMEM.¹H-,¹³C-and³¹P-NMR spectroscopy of perchloric acid extracts showed that these volume regulatory processes were accompanied by pronounced changes in the content of organic osmolytes. Adaptation of intra- to extracellular osmolarity was preferentially mediated by a decrease in the cytosolic taurine level under hypotonic stress and by an intracellular accumulation of amino acids under hypertonic stress. If these solutes were not available in sufficient quantities (as in KHB), the osmolarity of the cytosol was increasingly modified by biosynthesis of products and intermediates of essential metabolic pathways, such as alanine, glutamate and glycerophosphocholine in addition to ethanolamine. The cellular nucleoside triphosphate level measured by in vivo³¹P-NMR spectroscopy indicated that the energy state of the cells was more easily sustained under hypotonic than hypertonic conditions.To whom to address reprint requests.     

Use of erythrocyte indicators of health and condition in vertebrate ecophysiology: a review and appraisal

We review evidence for and against the use of erythrocyte indicators of health status and condition, parasite infection level and physiological stress in free‐living vertebrates. The use of indicators that are measured directly from the blood, such as haemoglobin concentration, haematocrit and erythrocyte sedimentation rate, and parameters that are calculated from multiple measured metrics, such as mean cell volume, mean cell haemoglobin content or mean cell haemoglobin concentration is evaluated. The evidence for or against the use of any given metric is equivocal when the relevant research is considered in total, although there is sometimes strong support for using a particular metric in a particular taxon. Possibly the usefulness of these metrics is taxon, environment or condition specific. Alternatively, in an uncontrolled environment where multiple factors are influencing a metric, its response to environmental change will sometimes, but not always, be predictable. We suggest that (i) researchers should validate a metricfres utility before use, (ii) multiple metrics should be used to construct an overall erythrocyte profile for an individual or population, (iii) there is a need for researchers to compile reference ranges for free‐living species, and (iv) some metrics which are useful under controlled, clinical conditions may not have the same utility or applicability for free‐living vertebrates. Erythrocyte metrics provide useful information about health and condition that can be meaningfully interpreted in free‐living vertebrates, but their use requires careful forethought about confounding factors.     

Microviscosity of human erythrocytes studied with hypophosphite and 31P-NMR

A 31P-NMR method, which complements earlier 13C-NMR procedures for probing the intra-erythrocyte microenvironment, is described. Hypophosphite is an almost unique probe of the erythrocyte microenvironment, since it is rapidly transported into the cell via the band 3 protein, and intra- and extracellular populations give rise to distinct resonances in the 31P-NMR spectrum. Relaxation mechanisms of the 31P nucleus in the hypophosphite ion were shown to be spin-rotation and dipole-dipole. Analysis of longitudinal relaxation rates in human erythrocytes, haemolysates and concentrated glycerol solutions allowed the determination of microviscosity using the Debye equation. Bulk viscosities of lysates and glycerol solutions were measured using Ostwald capillary viscometry. Translational diffusion coefficients were then calculated from the viscosity estimates using the Stokes-Einstein equation. The results with a range of solvent systems showed that 'viscosity' is a relative phenomenon and that bulk (i.e., macro-) viscosity is therefore not necessarily related to the NMR-determined viscosity. The intracellular NMR-determined viscosities from red cells, ranging in volume from 65.5 to 100.1 fl, varied from 2.10 to 2.67 mPa s. This is consistent with the translational diffusion coefficients of the hypophosphite ion altering by only 20%, whereas the values determined from bulk viscosity measurements conducted on lysates of these cells are consistent with a 230% change.     

The haematology of triploid landlocked Atlantic salmon, Salmo solar L.

Triploid landlocked Atlantic salmon had a larger mean erythrocyte volume but lower erythrocyte count than diploids; the haematocrit was the same in diploids and triploids. Although the total blood haemoglobin content and the mean corpuscular haemoglobin concentration were lower in triploids than in diploids, the actual mean corpuscular haemoglobin content of triploid erythrocytes was higher than that of diploids. The increase in triploid mean erythrocyte volume was mainly due to an increase in cell length; there was only a minor increase in cell width and no increase in cell height. The nucleus of triploid erythrocytes occupied a greater percentage of the corpuscular volume than did the diploid nucleus. Mean cytoplasmic haemoglobin concentration was found to be the same for diploids and triploids when this was taken into account     

Intraspecific allometry of haematological parameters in Basilichthys australis

Allometry of haematological parameters (haematocrit, erythrocyte number, mean cell volume and haemoglobin concentration) of Basilichthys australis , suggested that small individuals and juveniles had larger red blood cells, less haemoglobin per volume of blood, and more diluted plasma than large and mature animals.     

Total body haematocrit iron kinetics and erythrocyte life span in pigeons (Columba livia)

1. The mean pigeon erythrocyte life span was found to be 17-25 days by Cr51-labeled erythrocytes and 21 +/- 3.4 days by iron kinetics. 2. Total red blood cell volume has been calculated by Cr51-labeled erythrocytes while total plasma volume was determined both by a dye method and iron kinetic data. From these results total blood volume and total body haematocrit were found to be 0.090 +/- 0.002 ml/g body wt and 36 +/- 4.3%, respectively. 3. Venous haematocrit, haemoglobin concentration, erythrocyte count, mean corpuscular haemoglobin concentration, plasma iron and red blood cell iron have also been measured. 4. A significant difference between total body and venous haematocrit and a short mean red blood cell life span, due to ageing and to random destruction of erythrocytes were shown. 5. The above observations are compared with analogous available data for human beings and their physiological significance is discussed.     

Haematological studies on the prewintering and wintering frog, Rana esculenta

1. A study of the haematology of the frog Rana esculenta including erythrocyte count (RBC), haemoglobin content (Hb), haematocrit (HCT), mean cell volume (MCV), mean corpuscular haemoglobin (MCH), mean corpuscular haemoglobin concentration (MCHC) and erythrocyte size as a function of prewinter and winter was made. 2. The RBC count and Hb were significantly higher in contrast to MCV and MCH values during prewinter in both sexes. 3. The surface area to volume ratio was higher in prewinter whereas the length to width ratio (eccentricity) of the cytosome and nucleus was significantly higher during winter in both sexes. 4. Sexual differences in the erythrocyte count, Hb content and the surface area to volume ratio were also observed. 5. The physiological significance of these observations are reported for Rana esculenta.     

31P-NMR determination of phosphomonoesters in relation to phospholipid biosynthesis in testis of the rat at different ages

Changes in the phosphomonoester (PM) peak, as observed in in vivo 31P-NMR spectra, are often attributed to changes in phospholipid synthesis and therefore to changes in cell proliferation. However, this technique provides information about the absolute size of the phosphomonoester pool rather than its turnover rate. To investigate whether there is a good correlation between changes in PM concentration and its turnover rate, we studied the turnover rate of the two major PM compounds, phosphocholine and phosphoethanolamine, in rat testes at different stages of testis development. [3H]Choline and [3H]ethanolamine were injected intraperitoneally into rats at the age of 3, 6 and 13 weeks, respectively. Phosphorylation of these compounds and their incorporation into phospholipids, were followed up to 6 h after injection of the phospholipid precursors. When these data were compared with the changes observed in the in vivo 31P-NMR PM peak, the concentration of the PM compounds appeared to correlate linearly, both with the conversion of choline into phosphocholine, as well with the rate of phospholipid synthesis, and therefore with the rate of cell proliferation. Hence, it is suggested that cell proliferation can be monitored by determining the changes in the PM peak that is observed in in vivo 31P-NMR spectra.     

In vivo 31P- and 13C-NMR studies of ATP synthesis and methane formation by Methanosarcina barkeri

Carbon and phosphorus metabolism of cell suspensions of Methanosarcina barkeri strain MS (DSM 800), grown on methanol, were probed in vivo by NMR. The experimental conditions, which involved thick cell suspensions, did not significantly affect the efficiency of the rate of methanol uptake by cells. Following exposure to methanol an acidification of both the intracellular and the extracellular spaces was observed and a gradient of 0.5 pH units across the cytoplasmic membrane was determined from the 31P-NMR data. High levels of intracellular ATP up to 4 mM were detected. The ADP concentration determined in a suspension of starved cells was only 2 mM, suggesting that a significant amount of ADP may be immobilized and is thus not detectable by NMR. In the presence of the protonophore, 3,3',4',5-tetrachlorosalicylanilide, the proton gradient was dissipated and the synthesis of ATP stopped. The inhibitor of the ATP synthase, N,N'-dicyclohexylcarbodiimide, was rather inefficient in inhibiting ATP synthesis. High concentrations of N,N'-dicyclohexylcarbodiimide (corresponding to 300 nmol/mg protein-1) were required to decrease the ATP content by approximately 60%, and, under these conditions, formation of acetyl phosphate was detected. However, the methanol consumption rate was not affected.     

A 31P-NMR study of Propionibacterium acnes, including effects caused by near-ultraviolet irradiation

161.8 MHz 31P-NMR spectra were recorded from the light sensitive skin bacterium Propionibacterium acnes. The cells were grown anaerobically on synthetic phosphate-buffered Eagle's medium or on a complex yeast extract medium. The spectra showed a large accumulation of polyphosphates when grown on Eagles medium. A splitting of the inorganic phosphate peak indicated a difference between internal and external pH of the cells. Addition of glucose to the cell suspension gave rise to a change in the pH gradient across the cell membrane, as reported for other Gram-positive bacteria. A decrease in the polyphosphate peak was observed after addition of glucose. A lethal dose of broad-band near-ultraviolet light (corresponding to a 10% survival in a survival test), increased the amount of polyphosphates visible in the NMR-spectra. The addition of glucose to irradiated cells decreased the pH in the external solution, but no splitting of the inorganic phosphate peak could however be observed. 31P-NMR can, therefore, be used to study immediate near-ultraviolet-induced effects at the cellular level, at least in the case of P. acnes.     

Erythrocyte enrichment in hematopoietic progenitor cell cultures based on magnetic susceptibility of the hemoglobin

Using novel media formulations, it has been demonstrated that human placenta and umbilical cord blood-derived CD34+ cells can be expanded and differentiated into erythroid cells with high efficiency. However, obtaining mature and functional erythrocytes from the immature cell cultures with high purity and in an efficient manner remains a significant challenge. A distinguishing feature of a reticulocyte and maturing erythrocyte is the increasing concentration of hemoglobin and decreasing cell volume that results in increased cell magnetophoretic mobility (MM) when exposed to high magnetic fields and gradients, under anoxic conditions. Taking advantage of these initial observations, we studied a noninvasive (label-free) magnetic separation and analysis process to enrich and identify cultured functional erythrocytes. In addition to the magnetic cell separation and cell motion analysis in the magnetic field, the cell cultures were characterized for cell sedimentation rate, cell volume distributions using differential interference microscopy, immunophenotyping (glycophorin A), hemoglobin concentration and shear-induced deformability (elongation index, EI, by ektacytometry) to test for mature erythrocyte attributes. A commercial, packed column high-gradient magnetic separator (HGMS) was used for magnetic separation. The magnetically enriched fraction comprised 80% of the maturing cells (predominantly reticulocytes) that showed near 70% overlap of EI with the reference cord blood-derived RBC and over 50% overlap with the adult donor RBCs. The results demonstrate feasibility of label-free magnetic enrichment of erythrocyte fraction of CD34+ progenitor-derived cultures based on the presence of paramagnetic hemoglobin in the maturing erythrocytes.     

31P-NMR study of kinetics of 2,3-diphosphoglycerate degradation in human erythrocytes during their depletion

2.3-Diphosphoglycerate degradation kinetics was studied under conditions of human erythrocyte depletion, using the method of 31P-NMR of high performance. The kinetic curve was shown to have a plateau during the first 1.5-2 hours after the beginning of depletion. Possible mechanisms providing for the appearance of such a plateau are discussed.     

31P-NMR measurements of ATP, ADP, 2,3-diphosphoglycerate and Mg2+ in human erythrocytes

Absolute 31P-NMR measurements of ATP, ADP and 2,3-diphosphoglycerate (2,3-DPG) in oxygenated and partly deoxygenated human erythrocytes, compared to measurements by standard assays after acid extraction, show that ATP is only 65% NMR visible, ADP measured by NMR is unexpectedly 400% higher than the enzymatic measurement and 2,3-DPG is fully NMR visible, regardless of the degree of oxygenation. These results show that binding to hemoglobin is unlikely to cause the decreased visibility of ATP in human erythrocytes as deoxyhemoglobin binds the phosphorylated metabolites more tightly than oxyhemoglobin. The high ADP visibility is unexplained. The levels of free Mg2+ [( Mg2+]free) in human erythrocytes are 225 mumol/l at an oxygen saturation of 98.6% and instead of the expected increase, the level decreased to 196 mumol/l at an oxygen saturation of 38.1% based on the separation between the alpha- and beta-ATP peaks. [Mg2+]free in the erythrocytes decreased to 104 mumol/l at a high 2,3-DPG concentration of 25.4 mmol/l red blood cells (RBC) and a normal ATP concentration of 2.05 mmol/l RBC. By increasing the ATP concentration to 3.57 mmol/l RBC, and with a high 2,3-DPG concentration of 24.7 mmol/l RBC, the 31P-NMR measured [Mg2+]free decreased to 61 mumol/l. These results indicate, that the 31P-NMR determined [Mg2+]free in human erythrocytes, based solely on the separation of the alpha- and beta-ATP peaks, does not give a true measure of intracellular free Mg2+ changes with different oxygen saturation levels. Furthermore the measurement is influenced by the concentration of the Mg2+ binding metabolites ATP and 2,3-DPG. Failure to take these factors into account when interpreting 31P-NMR data from human erythrocytes may explain some discrepancies in the literature regarding [Mg2+]free.     

Time-resolved magnetic resonance spectroscopic study of freeze-trapped yeast

Rapidly changing metabolic events in actively respiring yeast under strictly physiological conditions were approached by freeze-trapping analysis with 31P magnetic resonance spectroscopy. A 50% wet weight/volume suspension of Saccharomyces cerevisiae was freeze-trapped with 20% ethylene glycol and 5% methanol as an antifreezing agent, and with 3 mM creatine phosphate as an external standard. A phosphorus spectrum of the freeze-trapped yeast was measured for 20 min at -18 degrees C at 202.46 MHz, since energy-related phosphate compounds in yeast were stable at least for 20 min at the temperature. The time scale, defined as (time required for NMR measurement)/(time for trapping), was expanded by the freeze-trapping analysis by 67-times, since the time for trapping was 0.3 min. The use of creatine phosphate as an external standard enabled exact quantification of phosphorus resonances. 31P-NMR study of freeze-trapped yeast affords a well time-resolved and highly sensitive method to study phosphate metabolism.