Changes in phosphate metabolism in thymoma cells suggest mechanisms for resistance to dexamethasone-induced apoptosis. A 31P NMR spectroscopic study of cell extracts

Treatment of the mouse thymoma-derived WEHI7.2 cell line with dexamethasone, a synthetic glucocorticoid, causes the cells to undergo apoptosis. Previous studies have shown that WEHI7.2 cell variants with an increased antioxidant defense exhibit increased resistance to dexamethasone-induced apoptosis, suggesting that oxidative stress may play a role in glucocorticoid-induced apoptosis. In this work we compared metabolic profiles of WEHI7.2 parental cells with those of WEHI7.2 variants with an increased antioxidant defense or overexpressing bcl-2, to determine whether bolstering the antioxidant defense results in altered metabolic parameters that could translate into increased resistance to dexamethasone-induced apoptosis. WEHI7.2 parental cells and cells overexpressing catalase, thioredoxin or bcl-2, or selected for resistance to 200 micro M H(2)O(2) were cultured in low-glucose DMEM medium supplemented with 10% calf serum, and extracted using chloroform-methanol-water (1:1:1). Metabolites contained in the aqueous and organic phases of the extracts were processed separately and subjected to high-resolution (31)P NMR spectroscopy. In most of the steroid-resistant variants, ATP levels and energetic status were decreased compared with the steroid-sensitive parental cell line, while the concentrations of hexose and triose phosphates were increased. Furthermore, the ratio of choline-containing phospholipids to ethanolamine-containing phospholipids was generally reduced in steroid-resistant cells. Phosphatidylethanolamine and its derivatives contain a higher amount of polyunsaturated fatty acids (PUFA) than the choline-containing analogs, and PUFA are readily oxidized by reactive oxygen species. Therefore, an increased initial amount of phosphatidylethanolamine may increase the 'buffering capacity' of this antioxidant and may thus contribute to the steroid resistance of WEHI7.2 variants.

Metabolism of alternative substrates and the bioenergetic status of EMT6 tumor cell spheroids

In order to evaluate the ability of EMT6/Ro multicellular spheroids to utilize various pathways of energy production, (13)C and (31)P MRS have been employed to monitor the metabolism of glucose, glutamine, acetate and propionate. EMT6/Ro spheroids perfused with culture medium containing 5.5 mM glucose maintain stable levels of nucleotide triphosphates (NTP) and phosphocreatine (PCr) for up to 48 h, even in the absence of glutamine. The metabolism of 1-(13)C-glucose was almost entirely to 3-(13)C-lactate (88 +/- 12%, n = 7), even though the perfusion medium was equilibrated with 95% O(2). Labeling was also observed in other glycolytic metabolites, primarily alanine and alpha-glycerolphosphate. A low level of (13)C labeling in glutamate, indicative of mitochondrial oxidative metabolism (TCA cycle), was consistently detected when spheroids were perfused with 1-(13)C-glucose, almost exclusively in the C4 position of glutamate. Labeling of glutamate C2 and C3 was always less than 20% of the labeling in C4 and was usually undetectable. No evidence of adjacent carbon labeling in individual glutamate molecules (indicative of multiple cycles of label incorporation) was found, even in high-resolution (13)C NMR spectra of extracts from cells or spheroids. Despite the predominantly glycolytic metabolism of glucose, the mitochondrial substrate glutamine (2 mM, in the presence of < or =0.5 mM glucose from fetal bovine serum), supported stable levels of NTP and PCr in the tumor cells for up to 12 h. In the presence of 2.5 mM acetate, the bioenergetic status of cells in EMT6 spheroids declined slowly but measurably, and no incorporation of label from 2-(13)C-acetate into other metabolites was detected either in intact perfused spheroids or in high-resolution spectra of extracts. In contrast, when the anaplerotic TCA cycle substrate 3-(13)C-propionate replaced acetate, the high-energy phosphate levels in EMT6/Ro spheroids were somewhat reduced, but stabilized at a new lower level. Incubation of spheroids with 3-(13)C-propionate (with natural abundance glucose and glutamine) resulted in label detectable in the C2 and C3 of glutamate, but the primary labeled compound was methylmalonate, an intermediate in propionate metabolism. Addition of vitamin B(12), a cofactor for methylmalonyl CoA reductase, to the growth medium 24 h prior to perfusion with propionate resulted in the elimination of the methylmalonate resonance. A variety of 2- and 3-labeled metabolites were detected, including succinate, malate and glutamate. Labeling of C2 and C3 of lactate implicated cytoplasmic malic enzyme activity.

NMR spectroscopy of single neurons

The first spatially localized NMR spectra of osmolytes and metabolites from single isolated neurons have been obtained using a combination of high magnetic field strengths and NMR radio frequency (RF) microcoils. The proton spectra display peaks at high concentrations (100-300 mM) assigned to betaine and choline, and other metabolite resonances including lactate at lower concentrations in the order of 10s of millimoles. The volumes examined were approximately 10 nl, over two orders of magnitude less than previously possible. In these initial experiments; the cells were unperfused and the signal intensities of the osmolytes decrease with time, a phenomenon consistent with cell swelling. This work demonstrates the technical feasibility of NMR spectroscopy of single cells, further broadening the scope of NMR spectroscopy of living tissues from application to entire living organisms (man and animal models) and isolated tissues (perfused organs and cultured assemblies of cells) and now to single cells. Magn Reson Med 44:19-22, 2000.

A study of diffusion isotropy in single neurons by using NMR microscopy

The apparent diffusion coefficient (ADC) of water was measured in single Aplysia californica neurons by using NMR microscopy encoded in each of two perpendicular gradient directions. Comparisons of the mean ADCs of the gross nuclear and cytoplasmic compartments in five cells, and 50 subregions within these cells, showed no significant difference between the diffusion measurements in the majority of cases. Since anisotropic diffusion would make the ADC dependent on the encoding direction, the results indicate that the ADC in these single neurons is isotropic at the spatial and temporal resolutions used in these studies. Consequently, a single scalar ADC measurement is sufficient for characterizing the ADC in these cells, hence reducing the acquisition time and measurement complexity that would have been required had the ADC been anisotropic.

Nuclear magnetic resonance microscopy of single neurons under hypotonic perturbation

Nuclear magnetic resonance (NMR) characteristics of water in perfused single neurons undergoing a 20% hypotonic perturbation were examined quantitatively using NMR microscopy. The transverse relaxation times (T2) in the cytoplasm and nucleus increased by 24.0 +/- 8.5% (average +/- SE, n = 8) and 29.7 +/- 5.3% (n = 6), respectively, whereas the apparent diffusion coefficients (ADC) showed no significant change. These findings are consistent with the behaviors of a perfect osmometer and with accepted molecular relaxation and diffusion models and have significant impacts on current views of properties of cellular water. Furthermore, the results suggest that the increase of tissue intracellular-to-extracellular volume ratio during cell swelling is the predominant mechanism underlying the ADC reduction in acute brain ischemia. These data are the first direct quantitative measurements of the NMR characteristics of water in the cytoplasm and nucleus of single cells undergoing physiological perturbations and may lead to an improved diagnostic capability for NMR imaging in a variety of disease states.

Maturation effects on the NMR microimaging characteristics of single neurons

We have used an isolated neuronal preparation of single Aplysia californica L7 cells to study the effects of development on the nuclear magnetic resonance (NMR) characteristics, T2 spin-spin relaxation rate (RT2) and apparent diffusion coefficient (D), of intracellular water within the nuclear and cytoplasmic compartments. These studies demonstrate a significant correlation of animal weight, but not age, with RT2. On the other hand, D was not significantly different as a function of either age or weight in single L7 neurons. Demonstration of maturation dependence in single cells is important in understanding the cellular origins of developmental effects on NMR characteristics in cell assemblies such as brain.

Metabolism of phosphonium choline by rat-2 fibroblasts: effects of mitogenic stimulation studied using 31P NMR spectroscopy

Phospholipid turnover increases with both mitogenic stimulation and oncogenic transformation (1-9). Recent 31P nuclear magnetic resonance (NMR) spectroscopy studies of human tumors, animal tumor models and cell systems have reported elevated phosphomonoesters with growth and oncogenic transformation, as well as changes in these levels associated with treatment (10). In order to gain insights into the mechanisms underlying these changes, we used a phosphonium analog of choline and 31P NMR spectroscopy to study choline metabolism in quiescent and mitogenically stimulated Rat-2 fibroblasts. Cell growth status of these cells has a significant effect on choline metabolism. While overall uptake of the analog was similar in both quiescent and growing cells, distribution among metabolite pools differed. Quiescent cells accumulate label in the phosphodiester pool, with little or none in the phosphomonoester pool. On the other hand, mitogenic stimulation resulted in a significant fraction of the label in the phosphomonoester pool.

Phosphomonoester metabolism as a function of cell proliferative status and exogenous precursors

Elevations of phosphomonoesters (PMEs) correlate with increased cell growth or increased cell degradation, and have been shown to occur in human tumors as well as animal tumor models and cell lines. Furthermore, decreased PME levels have been observed in tumor patients who respond to therapy. Therefore, understanding the mechanisms underlying the interactions of intrinsic and extrinsic control of PMEs may assist diagnosis and treatment of tumors at the clinical level. In order to probe the underlying mechanisms controlling PME concentrations, we used cells grown in bioreactors and 31P nuclear magnetic resonance spectroscopy to study the effects of proliferative status and exogenous precursor amines on the PMEs phosphorylcholine (PCho) and phosphorylethanolamine (PEtn). In general, PEtn demonstrated an inverse correlation with cell growth, beginning to rise as the stationary growth phase was approached. PCho, on the other hand, generally decreased during log growth, an effect that was reversed by the addition of exogenous choline. The net effect of these changes was a consistent and dramatically lower PCho/PEtn ratio in stationary cultures compared to actively proliferating cultures.

Quantitation of resonances in biological 31P NMR spectra via principal component analysis: potential and limitations

This paper examines the potential and limitations of peak area quantitation of biological NMR spectra using principal component analysis (PCA), including its requirement for prior knowledge. The principles of the method are presented without in-depth mathematical treatment. PCA is illustrated for simulated data, 31P NMR spectra obtained consecutively over 1-2.5 days from perfused Rat-2 cells metabolizing the choline analogue phosphoniumcholine (Chop) and in vivo proton-decoupled, NOE-enhanced, three-dimensional CSI localized 31P NMR spectra of the liver of healthy volunteers. The results show that PCA can be used to quantitate strongly overlapping peaks without prior knowledge of the peak shapes or positions and to reconstruct spectra with significantly reduced noise variance. Two major limitations of PCA are presented: (1) PCA cannot separate peaks whose intensities are well correlated; (2) PCA is sensitive to differences in chemical shift and line-width of peaks between spectra. The discussion focuses on what knowledge of the biological and spectroscopic features of the samples and the principles of PCA is necessary for peak area quantitation via PCA.

A modified imaging sequence for accurate T2 measurements using NMR microscopy

A modified spin-echo pulse sequence is described that enables accurate T2 measurements to be made in NMR microimaging experiments. The modified sequence eliminates cumulative diffusion losses that lead to an underestimation of the T2 relaxation time using conventional spin-echo pulse sequences. The approach is theoretically justified and confirmed in comparative experiments on phantoms.

A peroxidative model of human erythrocyte intracellular Ca2+ changes with in vivo cell aging: measurement by 19F-NMR spectroscopy

Numerous changes occur with human erythrocyte aging in vivo, including an increase in free ionic intracellular calcium concentration ([Ca2+]i) (N.R. Aiken et al. (1992) Biochim. Biophys. Acta 1136, 155-160). An attractive hypothesis of cell aging suggests that oxidative stress is responsible for many age-related changes. To determine whether oxidative stress leads to increased intracellular Ca2+ concentrations, we used the fluorinated calcium probe 5,5'-difluoroBAPTA and fluorine nuclear magnetic resonance spectroscopy (19F-NMR) to measure [Ca2+]i following mild hydrogen peroxide (H2O2) stress to young red cells. Cells were separated using density centrifugation, exposed to 815 microM H2O2, loaded with the calcium probe, and [Ca2+]i measured. Intracellular [Ca2+] increased from 62 nM (+/- 4, S.E.) in untreated young cells to 173 nM (+/- 11) in peroxide treated cohort young cells. This value approached our previously reported [Ca2+]i of 221 nM (+/- 25) in old human erythrocytes. Pretreatment of young cells with (a) cobalt, which blocks Ca2+ influx through calcium channels, or (b) carbon monoxide, which prevents methemoglobin formation, inhibited the peroxide-induced increase in ionic intracellular calcium. These findings are consistent with the hypothesis that oxidative stress of erythrocytes contributes to the increased [Ca2+]i found in senescent cells, and that this is due to increased membrane Ca2+ leak resulting from oxidatively induced methemoglobin-cytoskeletal protein crosslinking.

31P NMR spectroscopic studies of the effects of cyclophosphamide on perfused RIF-1 tumor cells

To determine whether direct cellular effects of chemotherapy are responsible for 31P NMR spectral changes observed in treated tumors in vivo, RIF-1 fibrosarcoma cells were examined in vitro before, during, and after treatment with 4-hydroperoxycyclophosphamide (4-HC), an activated form of cyclophosphamide. When RIF-1 cells were treated with 4-HC in a metabolically stable but nonproliferating state, the 31P NMR spectra were identical with those of untreated cells for up to 70 h. When actively proliferating RIF-1 cells were treated with 4-HC, the intensities of the nucleotide triphosphate resonances, which increased linearly during control cell growth, remained constant for 50 h or longer. These studies demonstrate that the bioenergetic improvement observed following treatment of RIF-1 tumors in vivo [S.-J. Li, J.P. Wehrle, S.S. Rajan, R.G. Steen, J.D. Glickson, and J. Hilton, Cancer Res. 48, 4736 (1988)] does not result from direct effects of cyclophosphamide metabolites on RIF-1 cell metabolism, but rather from indirect effects of treatment on tumor or host physiology.

Measurement of intracellular Ca2+ in young and old human erythrocytes using 19F-NMR spectroscopy

Elevated cell calcium has been implicated in functional changes with human erythrocyte aging. However, until recently it has been difficult to measure free ionic intracellular calcium in red cells. We have made use of a fluorinated calcium chelator probe (5,5'-difluoroBAPTA) and fluorine nuclear magnetic resonance (19F-NMR) techniques to measure changes of intracellular Ca2+ concentrations ([Ca2+]i) with cell aging. We have demonstrated in these studies that human erythrocyte [Ca2+]i is significantly elevated as a function of in-vivo aging. Young cells, the least dense fraction of density-separated erythrocytes, contained an average of 62 (+/- 4) nM Ca2+ (+/- S.E.), whereas the oldest, most dense cell fraction contained 221 nM Ca2+ (+/- 25). Mechanisms by which intracellular [Ca2+] increases with in-vivo aging are currently under investigation.