23Na and 31P NMR studies of the effects of salt stress on the freshwater cyanobacterium Synechococcus 6311

We have used 23Na and 31P nuclear magnetic resonance (NMR) spectroscopy to elucidate some of the bioenergetic changes that occur in the freshwater cyanobacterium Synechococcus 6311 after a transition from growth medium (Na concentration 0.01 M) to medium containing 0.5 M NaCl. 23Na NMR analysis showed Na rapidly penetrates the cells under dark aerobic conditions; cells grown for several days in high salt medium, however, reestablish a low internal sodium content, comparable to control cells. For 31P NMR analysis, a system was devised to aerate and illuminate cell suspensions during spectral acquisition. The NMR spectra showed that when cells are presented with 0.5 M NaCl (final concentration), nucleotide triphosphate peaks decrease, the inorganic phosphate peak increases, and the cytoplasmic pH transiently increases from 7.4 to 7.9. Pyrophosphate added to cell suspensions is hydrolyzed to inorganic phosphate apparently by an extracellular phosphatase, allowing external and internal pools of inorganic phosphate to be distinguished. Nucleotide triphosphate levels fall almost as much when cells are incubated in darkness as under anoxia, indicating that both respiration and photosynthesis contribute to the maintenance of intracellular ATP levels. Cells grown in high salt medium for several generations exhibited a pattern of 31P metabolites similar to control cells, except that they produced more (and more intense) peaks in the monoester phosphate region, presumably signals from sugar phosphates.     

Diffusional limitations of immobilized Escherichia coli in hollow-fiber reactors: influence on 31P NMR spectroscopy

Escherichia coli cells were immobilized and grown in hollow-fiber reactors allowing simultaneous NMR spectroscopy and perfusion with nutrient medium. The extent to which the cells were starved due to inadequate mass transfer was predicted using a mathematical model of reaction and diffusion. Reactors were experimentally characterized using (35)S autoradiography to visualize spatial variations in protein synthesis rates and transmission electron microscopy to indicate spatial variations in cell morphology. Mass transfer limitations in reactors operated at 37 degrees C were shown to be severe, with regions of starved cells occupying up to 80% of the cell-containing region. Phosphorus-31 nuclear magnetic resonance (NMR) spectra of the immobilized, perfused cells revealed abnormally low volume-averaged concentrations of sugar phosphates, NTP, and ratios of NTP/NDP in these reactors. Intracellular pH was also depressed in the cells. In order to overcome mass transfer limitations in the cell layer, the reactor growth temperature was decreased. Sulfur-35 autoradiographs of a reactor operated at 16 degrees C did not indicate the presence of starved cells. The NMR spectra obtained from this reactor showed near-normal intracellular pH, metabolite concentrations, and NTP/NDP ratios. The presence of significant mass transfer limitations in a perfused cell sample during NMR spectroscopy is generally undesirable since the resulting spectra can be ambiguous and difficult to interpret. The strategy adopted in this work, namely estimation of the relative rates of reaction and diffusion in the cell mass and appropriate changes in reactor design and operating parameters, should prove generally applicable for the design of perfused cell samples for NMR spectroscopic experiments.     

Elucidation of the cytoplasmic and vacuolar components in the inorganic phosphate region in the 31P NMR spectrum of yeast

Subcellular compartments, such as the vacuole in yeast, play important roles in cell metabolism and in cell response to external conditions. Concentrations of inorganic phosphate and pH values of the vacuole and cytoplasm were determined for anaerobic Saccharomyces cerevisiae cells based upon (31)P NMR spectroscopy. A new approach allows the determination of these values for the vacuole in cases when the resonance for inorganic phosphate in the cytoplasm overlaps with the resonance for inorganic phosphate in the vacuole. The intracellular inorganic phosphate resonance was first decomposed into two components by computer analysis. The assignments of the components were determined from in vivo correlations of P(i) chemical shift and the chemical shifts of the cytoplasmic sugar phosphates, and the pH dependency of the resonance of pyrophosphate and the terminal phosphate of poly-phosphate (PP(1)) which reside in the vacuole. An in vivo correlation relating PP(1) and P(i) (vac) chemical shifts was established from numerous evaluations of intracellular compositions for several strains of S. cerevisiae. This correlation will aid future analysis of (31)P NMR spectra of yeast and will extend NMR studies of compartmentation to cellular suspensions in phosphate-containing medium. Application of this method shows that both vacuolar and extracellular P(i) were phosphate reserves during glycolysis in anaerobic S. cerevisiae. Net transport of inorganic phosphate across the vacuolar membrane was not correlated with the pH gradient across the membrane.     

31P nuclear magnetic resonance evidence for the regulation of intracellular pH by Ehrlich ascites tumor cells

The phenomenon of intracellular pH (pHin) regulation in cultured Ehrlich ascites cells was investigated using 31P nuclear magnetic resonance (NMR) spectroscopy. Measurements were made with a Bruker WH 360 wide bore NMR spectrometer at a 31P frequency of 145.78 MHz. Samples at a density of 10(8) cells ml-1 were suspended in a final volume of 2 ml of growth medium in 10 mm diameter NMR tubes. Intracellular pH was calculated from the chemical shifts of either intracellular inorganic phosphate (Piin) or intracellular 2- deoxyglucose-6-phosphate (2dG6Pin). The sugar phosphate was used as a pH probe to supplement the Piin measurements, which could not always be observed. When available, the pHin calculated from the Piin peak was identical within experimental error to the pHin calculated from the 2dG6Pin peak. Intracellular pH was measured to be more alkaline than the medium at an external pH (pHex) below 7.1. Typical values were pHin = 7.00 for pHex = 6.50. These measurements were constant for times up to 165 min using well-energized, respiring cells. This pH gradient was seen to collapse immediately upon onset of anaerobic shock. Above a pHex of 7.2 there was no significant difference between pHin and pHex. These results unequivocally demonstrate the steady state nature of the pH regulation and its dependence upon energization.     

31P-NMR studies of Mycoplasma gallisepticum cells using a continuous perfusion technique

31P-NMR studies of Mycoplasma gallisepticum cells have been carried out using a continuous perfusion technique; these are the first such studies with this organism. Using this technique, glucose metabolism was monitored in the intact organisms, and cell extracts were prepared to identify the intermediates. Under glycolytic conditions, high levels of fructose-1,6-diphosphate were observed, indicating that this sugar may play a key role in the regulation of metabolism. The level of phosphoenolpyruvate was low under normal glycolytic conditions, and did not increase during starvation. From the position of the internal inorganic phosphate peak, the intracellular pH was estimated. The cells were found to maintain an intracellular pH of approximately 7.1 over an investigated external pH range of 6.6-8.6.     

Use of gated perfusion to study early effects of anoxia on cardiac energy metabolism: a new 31P NMR method

A novel 31P NMR method is described that is capable of determining rapid changes in the intracellular levels of various phosphorus-containing compounds in an isolated, perfused working rat heart. This technique involves the gating of 31P NMR measurements to a heart that is alternately perfused with a modified Krebs-Henseleit medium containing 10 mM pyruvate and equilibrated with either 95% O2/5% CO2 or 95% N2/5% CO2. The experimental design allows up to three NMR measurements to be made during a single O2/N2 perfusion cycle. When these measurements are repeated at different intervals during the cycle, rapid changes in metabolite levels can be determined. Preliminary studies have shown that hearts remain hemodynamically stable to the aerobic/anoxic perfusion cycle as judged by heart rate, peak systolic pressure, aortic output, and coronary flow for at least 80 min in the magnet when subjected to cycle times of 4.5-s O2 and 1.5-s N2 perfusions. NMR measurements made under these conditions showed that a transition from full aerobic perfusion to this cycle revealed a new steady state, with an increased inorganic phosphate level from 6% total observable phosphorus to 10% and a possibly significant decreased measurement of creatine phosphate level (from 35 to 31%). Comparison of individual NMR measurements made during this perfusion cycle shows apparent rapid cyclical variations in intracellular pH and the levels of Pi, ATP, and NAD(H). These changes, expressed as variations above and below mean values measured during the cycle, showed that (a) intracellular pH, as measured by the chemical shift of Pi, reversibly decreases by more than 0.1 pH unit within 0.5-1 s following maximal anoxic perfusion and (b) coincident with a decrease in intracellular pH, Pi levels increased by a maximum of 30-40% whereas ATP levels decreased by a maximum of 15-20%. The amount of total observable phosphorous detected during the cycle is essentially constant. Unexpectedly, creatine phosphate levels are most stable, indicating that their levels are being maintained at the expense of ATP. Also unexpected is the finding that NAD(H) levels varied from maximal to undetectable levels during the perfusion cycle. The current method of aerobic/anoxic perfusion is capable of resolving metabolic events much faster than previous NMR methods and yielding information that is unobtainable by any other technique.     

Measurement of intracellular (compartmental) pH by 31P NMR in Aspergillus niger

31P nuclear magnetic resonance (31P NMR) was used to monitor cytoplasmic and vacuolar pH values in the filamentous fungus Aspergillus niger. To obtain a homogeneous cell sample and to be able to perform long term in vivo NMR measurements A. niger mycelium was kept in a setup that allows perfusion of the cell plug within the NMR tube. Mycelial samples, however, became rapidly clogged during perfusion leading to (partial) anaerobiosis of the plug with subsequent acidification of the cytoplasm. As a result, only short-term NMR measurements (5-10 min) were possible using free mycelium. To increase and to prolong perfusion, A. niger was immobilized in Ca(2+)-alginate beads. Deteriorated spectra recorded under hypoxia could be completely restored in the presence of oxygen. With this system perfusion in the presence of citrate could be maintained for at least 18 h at much higher rates (15 ml min-1 compared with 4 ml min-1 for free mycelium). During this period 31P NMR spectra were highly invariable, indicating approximate steady-state intracellular conditions during long term measurements. Perfusion in the presence of glucose resulted in complete depletion of the vacuolar inorganic phosphate pool within 45 min and yielded a higher pH gradient over the tonoplast than when citrate was used (delta pH = 1.6 and 1.4, respectively).     

Development and application of a membrane cyclone reactor for in vivo NMR spectroscopy with high microbial cell densities

A new bioreactor system has been developed for in vivo NMR spectroscopy of microorganisms under defined physiological conditions. This cyclone reactor with an integrated NMR flow cell is continuously operated in the magnet of a 400-MHz wide-bore NMR spectrometer system. The residence times of medium and cells are decoupled by a circulation-integrated cross-flow microfiltration module to achieve higher cell densities as compared to continuous fermentations without cell retention (increase in cell density up to a factor of 10 in steady state). Volumetric mass transfer coefficients k(L)a of more than 1.0 s(-1) are possible in the membrane cyclone reactor, ensuring adequate oxygen supply [oxygen transfer rate >15,000 mg O(2) .(L h)(-1)] of high cell densities. With the aid of the membrane cyclone reactor we were able to show, using continuous in vivo (31)P NMR spectroscopy of anaerobic glucose fermentation by Zymomonas mobilis, that the NMR signal intensity was directly proportional to the cell concentration in the reactor. The concentration profiles of intracellular inorganic phosphate, NAD(H), NDP, NTP, UDP-sugar, a cyclic pyrophosphate, two sugar phosphate pools, and extracellular inorganic phosphate were recorded after a shift from one steady state to another. The intracellular cyclic pyrophosphate had not been detected before in in vitro measurements of Zymomonas mobilis extracts due to the high instability of this compound. Using continuous in vivo (13)C NMR spectroscopy of aerobic glucose utilization by Corynebacterium glutamicum at a density of 25 g(cell dry weight) . L(-1), the membrane cyclone reactor served to measure the different dynamics of labeling in the carbon atoms of L-lactate, L-glutamate, succinate, and L-lysine with a time resolution of 10 min after impressing a [1-(13)C]-glucose pulse.     

Phosphorus-31 nuclear magnetic resonance studies of wild-type and glycolytic pathway mutants of Saccharomyces cerevisiae.

High-resolution phosphorus-31 nuclear magnetic resonance (31P NMR) spectra of wild-type and mutant strains of Saccharomyces cerevisiae were observed at a frequency of 145.7 MHz. Levels of various phosphorus metabolites were investigated upon addition of glucose under both aerobic and anaerobic conditions. Three mutant strains were isolated and their biochemical defects characterized: pfk lacked phosphofructokinase activity; pgi lacked phosphoglucose isomerase activity; and cif had no glucose catabolite repression of the fructose bisphosphatase activity. Each mutant strain was found to accumulate characteristic sugar phosphates when glucose was added to the cell suspension. In the case of the phosphofructokinase deficient mutant, the appearance of a pentose shunt metabolite was observed. 31P NMR peak assignments were made by a pH titration of the acid extract of the cells. Separate signals for terminal, penultimate, and central phosphorus atoms in intracellular polyphosphates allowed the estimation of their average molecular weight. Signals for glycero(3)phosphochline, glycero(3)phosphoserine, and glycero(3) phosphoethanolamine as well as three types of nucleotide diphosphate sugars could be observed. The intracellular pH in resting and anaerobic cells was in the range 6.5--6.8 and the level of adenosine 5'-triphosphate (ATP) low. Upon introduction of oxygen, the ATP level increased considerably and the intracellular pH reached a value of pH 7.2--7.3, irrespective of the external medium pH, indicating active proton transport in these cells. A new peak representing the inorganic phosphate of one of the cellular organelles, whose pH differed from the cytoplasmic pH, could be detected under appropriate conditions.     

NMR Studies of Pi-Containing Extracellular and Cytoplasmic Compartments in Brain

Abstract: The inorganic phosphate (P_i) NMR peak in brain has an irregular shape, which suggests that it represents more than a single homogeneous pool of P_i. To test the ability of the Marquardt-Levenberg (M-L) nonlinear curve fit algorithm software (Peak-Fit) to separate multiple peaks, locate peak centers, and estimate peak heights, we studied simulated P_i spectra with defined peak centers, areas, and signal-to-noise (S/N) ratios ranging from ∞ to 5.8. As the S/N ratio decreased below 15, the M-L algorithm located peak centers accurately when they were detected; however, small peaks tended to grow smaller and disappear, whereas the amplitudes of larger peaks increased. We developed an in vitro three-compartment model containing a mixture of P_i buffer, phosphocreatine, phosphate diester, and phosphate monoester (PME), portions of which were adjusted to three different pHs before addition of agar. Weighed samples of each buffered gel together with phospholipid extract and bone chips were placed in an NMR tube and covered with mineral oil. Following baseline correction, it was possible to separate the P_i peaks arising from the three compartments with different pH values if each peak made up 10–35% of total P_i area. In vivo, we identified the plasma compartment by intraarterial infusion of P_i. It was assumed that intracellular compartments contained high-energy phosphates and took up glucose. Based on these assumptions we subjected the brains to complete ischemia and observed that P_i compartments at pH 6.82, 6.92, 7.03, and 7.13 increased markedly in amplitude. If the brain cells took up and phosphorylated 2-deoxyglucose (2-DG), 2-DG-6-phosphate (2-DG-6-P) would appear in the PME portion of the spectrum ionized according to pH_i. Four 2-DG-6-P peaks with calculated pH values of 6.86, 6.94, 7.04, and 7.15 did appear in the spectrum, thereby confirming that the four larger P_i peaks represented intracellular spaces.     

31P-NMR studies of the freeze-tolerant larvae of the gall fly, Eurosta solidaginis

31P NMR was applied to an examination of the freeze-tolerant larvae of the gall fly, Eurosta solidaginis. Resonances from sugar phosphates, inorganic phosphate, adenylates and arginine phosphate were identified. Two peaks of Pi were identified corresponding to intracellular and extracellular Pi. Anoxia produced an expected decrease in peak intensities of ATP and arginine phosphate while the peak of intracellular Pi was enhanced and shifted to indicate intracellular acidification during anoxia. Spectra of whole larvae were monitored over a temperature range from -30 degrees to +25 degrees C. No abrupt alterations in the spectra were seen at the point of extracellular freezing which occurs at about -8 degrees C but temperature had dramatic effects upon the peak intensities of ATP and arginine phosphate. A reversible increase/decrease in peak intensities, relative to Pi, was observed as temperature was raised/lowered. At 15 degrees and -20 degrees C, the beta peak of ATP was 64% and 2% of the peak intensity of Pi while that of arginine phosphate was 78% and 11%, respectively. This temperature effect was not an artifact of instrumentation (as model solutions containing Pi, ATP and arginine phosphate did not show this effect) or a result of changes in the total amounts of these compounds in the cell with temperature. Rather it is apparent that these molecules become restricted in their rotational movement as temperature is lowered perhaps via binding to subcellular components. Changes in the amounts of freely soluble ATP and arginine phosphate with temperature could have important implications for metabolism and its control. Analysis of the effect of temperature on the chemical shift of Pi was also used to determine pH in the intracellular and extracellular compartments. Temperature change had no effect on extracellular (hemolymph) pH which remained constant at 6.1-6.3. Intracellular pH varied with temperature, however, from pH 6.8 at 15 degrees C to pH 7.3 at -12 degrees C with a change, delta pH/delta 0, of -0.0185 degrees C consistent with alphastat regulation.     

Intracellular pH control in Dictyostelium discoideum: a 31P-NMR analysis

Phosphorus metabolites and intracellular pH have been examined in the slime mold Dictyostelium discoideum by non-destructive 31P-NMR measurements. In a spectrum from a suspension of aerobic amoebae, the major peaks are inorganic phosphate, nucleotide di- and triphosphates. In the corresponding perchloric acid extract, resonances originating from purine and pyrimidine nucleotides are resolved. Adenine nucleotides are the most abundant components, but the other nucleotides are present in significant amounts. In a spectrum from intact spores in a dormant state, only inorganic phosphate and polyphosphates are detected and nucleotides are no longer present in large amounts. Of particular importance is the ability to observe separately in aerobic amoebae the resonance of inorganic phosphate localized in two different cell compartments: the cytosol and the mitochondria. The cytosolic pH and mitochondrial pH have been measured as 6.7 and 7.7, respectively, on the basis of intracellular inorganic phosphate chemical shifts. They are essentially unaffected over a large range of external pH and they are not modified transiently or permanently during the initiation of the developmental program of the organism. A weak acid, such as propionate, which modifies the progression of differentiation by favoring prestalk cells, perturbs intracellular pH gradients by selectively decreasing mitochondrial pH without any effect on cytosolic pH.     

Characterization of the 31P NMR spectrum of the schistosome vector Biomphalaria glabrata and of the changes following infection by Schistosoma mansoni

The 31P nuclear magnetic resonance (NMR) spectrum of the digestive gland-gonad complex (DGG) of the schistosome vector Biomphalaria glabrata was characterized and the effects of infection by Schistosoma mansoni noted. The in vivo spectrum was comprised of 11 peaks, 5 downfield and 6 upfield of an external 85% phosphoric acid standard. Based on a variety of analytical procedures, the upfield peaks from the standard were demonstrated to be composed of carbamoyl phosphate + a mixture of 3 phosphatides and sphingomyelin, the gamma + beta phosphorus resonances of nucleotide triphosphate (NTP) and nucleotide diphosphate (NDP), respectively, the alpha phosphorus resonances of NTP + NDP, NAD(H) + the phosphorus resonance of uridine phosphate from uridine diphosphoglucose (UDPG), the phosphorus resonance of glucose phosphate from UDPG and, last, the beta phosphorus resonance of NTP. The downfield peaks were assigned as glycerophosphoryl choline, intracellular inorganic phosphate (Pi), sugar phosphates + phosphoryl choline, aminoethyl phosphonate (AEP), and ceramide AEP. T1 values for the in vivo NMR components were determined by inversion recovery. Infection produced distinct alterations in the levels of nonnucleotide components of the in vivo 31P NMR spectrum and the spectra of tissue extracts. Specifically, the levels of phosphonate, phospholipids, and carbamoyl phosphate were markedly reduced, and the relative level of Pi was increased. The potential significance of these changes to the parasite-host relationship was discussed. In contrast, starvation resulted in a decreased level of phosphonate only. The pH of the intact DGG was estimated by titrating the inorganic phosphate component of tissue extracts. The mean pH was 6.9 for both control and infected material.     

In vivo 31P and multilabel 13C NMR measurements for evaluation of plant metabolic pathways

Reliable measurements of intracellular metabolites are useful for effective plant metabolic engineering. This study explored the application of in situ 31P and 13C NMR spectroscopy for long-term measurements of intracellular pH and concentrations of several metabolites in glycolysis, glucan synthesis, and central carbon metabolic pathways in plant tissues. An NMR perfusion reactor system was designed to allow Catharanthus roseus hairy root cultures to grow for 3-6 weeks, during which time NMR spectroscopy was performed. Constant cytoplasmic pH (7.40+/-0.06), observed during the entire experiment, indicated adequate oxygenation. 13C NMR spectroscopy was performed on hairy root cultures grown in solutions containing 1-13C-, 2-13C-, and 3-13C-labeled glucose in separate experiments and the flow of label was monitored. Activities of pentose phosphate pathways, nonphotosynthetic CO2 fixation, and glucan synthesis pathways were evident from the experimental results. Scrambling of label in glucans also indicated recycling of triose phosphate and their subsequent conversion to hexose phosphates.     

31P and 35Cl nuclear magnetic resonance measurements of anion transport in human erythrocytes

The exchange of anions across the erythrocyte membrane has been studied using 31P nuclear magnetic resonance (NMR) to monitor inorganic phosphate influx and 35Cl NMR to monitor chloride ion efflux. The 31P NMR resonances for intracellular Pi and extracellular Pi could be observed separately by adjusting the initial extracellular pH to 6.4, while the intracellular pH was 7.3. The 35Cl NMR resonance for intracellular Cl- was so broad as to be virtually undetectable (line width greater than 200 Hz), while that of extracellular Cl-is relatively narrow (line width of about 30 Hz). The transports of Pi and Cl-were both totally inhibited by 4,4'-diisothiocyanostilbene-2,2'-disulfonate, a potent inhibitor of the band 3 protein. Since the 31P resonance of Pi varies with pH, intra- and extracellular pH changes could also be determined during anion transport. The extracellular pH rose and intracellular pH fell during anion transport, consistent with the protonated monoanionic H2PO4-form of Pi being transported into the erythrocyte rather than the deprotonated dianionic HPO24-form. The rates of Cl-efflux and Pi influx were determined quantitatively and were found to be in close agreement with values determined by isotope measurements. The Cl-efflux was found to coincide with the influx of the monoanionic H2PO4-form of Pi.     

Development of a small-scale bioreactor: application to in vivo NMR measurement

A perfused bioreactor allowing in vivo NMR measurement was developed and validated for Eschscholtzia californica cells. The bioreactor was made of a 10-mm NMR tube. NMR measurement of the signal-to-noise ratio was optimized using a sedimented compact bed of cells that were retained in the bioreactor by a supporting filter. Liquid medium flow through the cell bed was characterized from a mass balance on oxygen and a dispersive hydrodynamic model. Cell bed oxygen demand for 4 h perfusion required a minimal medium flow rate of 0.8 mL/min. Residence time distribution assays at 0.8-2.6 mL/min suggest that the cells are subjected to a uniform nutrient environment along the cell bed. Cell integrity was maintained for all culture conditions since the release of intracellular esterases was not significant even after 4 h of perfusion. In vivo NMR was performed for (31)P NMR and the spectrum can be recorded after only 10 min of spectral accumulation (500 scans) with peaks identified as G-6P, F-6P, cytoplasmic Pi, vacuolar Pi, ATP(gamma) and ADP(beta), ATP(alpha) and ADP(alpha), NADP and NDPG, NDPG and ATP(beta). Cell viability was shown to be maintained as (31)P chemical shifts were constant with time for all the identified nuclei, thus suggesting constant intracellular pH.     

Intracellular pH in Dictyostelium discoideum: a 31P nuclear magnetic resonance study

We have used phosphorus-31 nuclear magnetic resonance to determine intracellular pH in the cellular slime mold Dictyostelium discoideum. We devised an air-lift circulator to maintain the dense cell suspensions in a well-oxygenated and well-stirred state while causing minimal perturbation to the sample flowing through the detector coils. Cells continued to develop normally in this set-up. Spectra acquired under these conditions typically show two peaks in the inorganic phosphate region corresponding to pH values of 7.16 +/- 0.03 and 6.48 +/- 0.02. These peaks are believed to represent the mitochondrial and cytosolic compartments respectively, based on a comparison of these values with published data and the collapse of the two compartments upon addition of the mitochondrial uncoupler carbonyl cyanide 4-(trifluoromethoxy)-phenylhydrazone. Dictyostelium cells show a remarkable degree of intracellular pH homeostasis. Both mitochondrial and cytosolic pH remained unchanged as extracellular pH was varied from 4.3 to 8.1. There was also no apparent change in the pH of either compartment after up to 13.5 hours' development in suspension.     

Phosphorus-31 nuclear magnetic resonance studies of intracellular pH,phosphate compartmentation and phosphate transport in yeasts

³¹P NMR spectra were obtained from suspensions of Candida utilis, Saccharomyces cerevisiae and Zygosaccharomyces bailii grown aerobically on glucose. Direct introduction of substrate into the cell suspension, without interruption of the measurements, revealed rapid changes in pH upon addition of the energy source. All ³¹P NMR spectra of the yeasts studied indicated the presence of two major intracellular inorganic phosphate pools at different pH environments. The pool at the higher pH was assigned to cytoplasmic phosphate from its response to glucose addition and iodoacetate inhibition of glycolysis. After addition of substrate the pH in the compartment containing the second phosphate pool decreased. A parallel response was observed for a significant fraction of the terminal and penultimate phosphates of the polyphosphate observed by ³¹P NMR. This suggested that the inorganic phosphate fraction at the lower pH and the polyphosphates originated from the same intracellular compartment, most probably the vacuole. In this vacuolar compartment, pH is sensitive to metabolic conditions. In the presence of energy source a pH gradient as large as 0.8 to 1.5 units could be generated across the vacuolar membrane. Under certain conditions net transport of inorganic phosphate across the vacuolar membrane was observed during glycolysis: to the cytoplasm when the cytoplasmic phosphate concentration had become very low due to sugar phosphorylation, and into the vacuole when the former concentration had become high again after glucose exhaustion.Non-Standard Abbreviations NMR nuclear magnetic resonance - ppm parts per million - PP polyphosphate - P_i,c cytoplasmic inorganic phosphate - P_i,v vacuolar inorganic phosphate - pH_in,c cytoplasmic pH - pH_in,v vacuolar pH - FCCP carbonyl p-trifluoromethoxyphenylhydrazone     

Phosphorus-31 and Nitrogen- 14 NMR Studies of the Uptake of Phosphorus and Nitrogen Compounds in the Marine Macroalgae Ulva lactuca

Cytoplasmic phosphomonoesters and inorganic phosphate, as well as vacuolar inorganic phosphate and polyphosphates, gave rise to the major peaks in ³¹P nuclear magnetic resonance (NMR) spectra of the marine macroalgae Enteromorpha sp., Ceramium sp., and Ulva lactuca which were collected from the sea. In contrast, NMR-visible polyphosphates were lacking in Pylaiella sp. and intracellular vacuolar phosphate seemed to act as the main phosphorus store in this organism. In laboratory experiments, polyphosphates decreased in growing U. lactuca which was cultivated in continuous light under phosphate-deficient conditions. In contrast, the same organism cultivated in seawater with added phosphate and ammonium, accumulated phosphate mainly in the form of polyphosphates. When nitrate was provided as the only nitrogen source, accumulation of polyphosphates in the algae decreased with increasing external nitrate concentration. From the chemical shift of the cytoplasmic Pi peak, the cytoplasmic pH of superfused preparations of Ulva was estimated at 7.2. The vacuolar pH, determined from the chemical shifts of the vacuolar Pi and the terminal polyphosphate peaks, was between 5.5 and 6.0. The intracellular nitrate and ammonium levels in U. lactuca were determined by ¹⁴N NMR. Both nitrogen sources were taken up and stored intracellularly; however, the uptake of ammonium was much faster than that of nitrate.     

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.