Alteration of cylindrospermopsin production in sulfate- or phosphate-starved cyanobacterium Aphanizomenon ovalisporum

The effect of sulfate and phosphate deprivation on cell growth and cylindrospermopsin level was studied in Aphanizomenon ovalisporum ILC-164. Sulfate starvation induced a characteristic reduction of cylindrospermopsin pool size on the basis of cell number and unit of dry mass of culture. Phosphorous starvation of A. ovalisporum cultures induced a lesser reduction of cylindrospermopsin pool size. This divergence in the pool size of cylindrospermopsin may be the consequence of different growth rate. To show the metabolic changes concomitant with reduction of cylindrospermopsin pool size were obtained by measurement of ATP sulfurylase and alkaline phosphatase activity. The present study is the first concerning the cylindrospermopsin content under sulfate starvation and discusses it in relation to phosphorous starvation.     

Serum-stimulated phosphate uptake and initiation of fibroblast proliferation

Previous studies have shown that initiation of proliferation of density-inhibited fibroblasts by fresh serum is accompanied by a rapid increase in phosphate uptake. This increase might be a key event in the initiation of DNA synthesis. The present studies examined this possibility. Mouse 3T3, secondary chick embryo, or human diploid foreskin cultures were grown to quiescence in medium containing varying levels of serum. When proliferation of the cultures was initiated by addition of fresh serum, the changes in phosphate uptake were inversely related to the final increases in cell number. Additional experiments showed that the change in phosphate uptake following serum addition was determined by the level of phosphate uptake prior to serum addition. Addition of dexamethasone to quiescent 3T3 cultures caused them to proliferate but did not increase phosphate uptake. Similarly, trypsin or insulin stimulated proliferation of quiescent secondary chick embryo cultures, but caused little or no change in phosphate uptake. Quiescent 3T3 cultures switched to medium containing fresh serum and reduced levels of phosphate showed a decrease in both phosphate uptake and intracellular phosphate pool size. Cell proliferation in these cultures, however, was stimulated to the same degree as cultures switched to medium containing fresh serum and the normal amount of phosphate. In addition, quiescent secondary chick embryo cultures switched to medium containing fresh serum and no phosphate showed a decrease in the intracellular phosphate pool size. Thymidine incorporation and final cell number in these cultures, however, was stimulated to the same or higher degree than in cultures switched to medium containing fresh serum and the normal amount of phosphate. These results demonstrate that the rapid increase in phosphate uptake following addition of fresh serum to quiescent fibroblasts is not a necessary event for the initiation of proliferation.     

Some remarks on the presence of organic phosphates in sediments

This article describes a new method developed to assess the size and nature of the organic phosphate pool. Using sediment suspensions from the Rhone, Garonne and Po rivers, inorganic P compounds, Fe(OOH) and CaCO₃ were removed using mild extractants at sediment pH. The residual phosphate was then fractionated into an acid soluble organic phosphate pool and a residual organic phosphate pool by acid hydrolysis (0.5 M H⁺). Both pools were quantitatively important, accounting for between 16 and 54% and 16 and 51% of total phosphate respectively. Acid hydrolysis was chosen since it yielded a distinct plateau, with high reproducibility, within 30 minutes.This fractionation permits a further study of dynamics and bioavailability of sediment org-P, without interference of Fe(OOH) and CaCO₃.In many studies in which changes in the organic pool were examined after extraction of inorganic phosphate, 0.5 M HCl was used to extract apatite bound phosphate. The results presented here show that this is likely to result in a considerable underestimation of the organic phosphate pool.     

Energy metabolism in rat brain in vivo studied by 31P nuclear magnetic resonance: changes during postnatal development

The energy metabolism in rat brains during postnatal development was followed by in vivo 31P NMR. Using a small surface coil (from several to 10 mm in diameter) placed at the head of a conscious rat, high-energy phosphate compounds in the brain and the steady-state kinetics among them were measured. The cellular contents of some phosphate compounds changed widely during the period of postnatal cell growth from age 10 to 20 days. During the same period, the cellular activity of creatine kinase increased by a factor of more than 5 as measured by a saturation transfer technique. The in vivo value of the creatine/creatine phosphate ratio was estimated from the in vitro value (in perchloric acid extracts), assuming that the in vivo ratio of the creatine and creatine phosphate pool over the ATP and ADP pool was the same as the corresponding in vitro value. From the creatine/creatine phosphate ratio thus obtained, the value of the cytosolic ATP/ADP ratio was estimated for brains of adult rats and neonate rats. Unexpectedly the value in the latter was found to be smaller.     

Evidence against necessary phosphorylation during hexose transport in Aspergillus nidulans

The transport of 2-deoxy-d-glucose, a nonmetabolizable glucose analogue, into Aspergillus nidulans against a concentration gradient does not appear to require phosphorylation, despite the high levels of sugar phosphates accumulated rapidly within the cell. Two other deoxy analogues of d-glucose, 6-deoxy-d-glucose and 1,5-anhydro-d-glucitol (1-deoxy-d-glucose), although they lack the C-6 and the C-1 hydroxyl groups, respectively, and thus cannot be phosphorylated in those positions, still competitively inhibit the entry of 2-deoxy-d-glucose. Moreover, 6-deoxy-d-glucose can be concentrated against a gradient within the cell without the accumulation of 6-deoxy-d-glucose-phosphate. d-Galactose shows an intracellular ratio of free to phosphorylated sugar similar to that found for 2-deoxy-d-glucose in cells that have galactokinase, but no sugar phosphates are found in a galactokinaseless mutant strain. These data suggest that intracellular kinases are responsible for the sugar phosphate pool; and indeed, a kinase capable of phosphorylating 2-deoxy-d-glucose has been demonstrated. Finally, experiments on the kinetics of labeling of intracellular free sugar and sugar phosphate pools with (14)C-2-deoxy-d-glucose show that radioactivity appears first in the free sugar pool and after a delay enters the sugar phosphate pool.     

Kinetic analysis of calcium movements in cell culture

Summary The distribution of intracellular calcium was determined in isolated kidney cells by kinetic analyses of⁴⁵Ca fluxes. Isotopic desaturation curves reveal an intracellular calcium compartment with a very slow time constant. The size of this calcium compartment is markedly increased by raising the extracellular calcium, by increasing the extracellular phosphate and may contain up to 99% of the intracellular exchangeable calcium. Accumulation of calcium in this pool is completely abolished by two specific inhibitors of mitochondrial calcium uptake, Antimycin A and Warfarin^®. These results suggest that this compartment represents a pool of calcium in the cell mitochondria. The sudden removal of phosphate from the medium immediately stimulates calcium efflux from the cell. Conversely, an increase in medium phosphate immediately inhibits calcium efflux. Both effects are rapidly reversible. Finally, calcium efflux from the cells is stimulated after the cells are exposed to low temperature suggesting that calcium transport out of the cell may be regulated by the cytoplasmic calcium activity. These experiments are consistent with the view that mitochondria play an important role in the control and regulation of cytoplasmic calcium activity and of calcium transport.     

Phosphate Incorporation by Euglena gracilis During pH-dependent Photo-inhibition1

Inhibition of cell division in Euglena gracilis by visible light is pH-dependent, being most severe in the pH range 3.5–5.0. Transfer of phototrophic cells from pH 6.8 to pH 4.2 can lead to cell death at modest light intensities (500 ft-cd) and inhibition of division at lower intensities (300 ft-cd). Inhibition is preceded by a large influx of phosphate, most of which remains in the cold PCA pool. It is suggested that light may act to reduce control over phosphate entry at these intermediate pH levels, and excess phosphate leads to inhibition of cell division or death.     

The rate-limiting reaction in phosphatidylcholine synthesis by alveolar type II cells isolated from fetal rat lung

The rate-limiting reaction in the formation of phosphatidylcholine by type II cells isolated from fetal rat lung was examined. Studies on the uptake of [Me-3H]choline and its incorporation into its metabolites indicated that in these cells the choline phosphate pool was much larger than both the choline and CDPcholine pools. Chemical measurements of the pool sizes showed that the choline phosphate pool was indeed much larger than the intracellular choline and CDPcholine pools. Pulse-chase studies with [Me-3H]choline revealed that labelled choline taken up by the cells was rapidly phosphorylated to choline phosphate and that the radioactivity lost from choline phosphate during the chase period appeared in phosphatidylcholine. Little change was observed in the labelling of CDPcholine during the chase period. These results indicate that cholinephosphate cytidylyltransferase catalyzes a rate-limiting reaction in phosphatidylcholine formation by fetal rat lung type II cells.     

The phosphoinositide pathway of lymphoid cells: labeling after permeabilization by alveolysin, a bacterial sulfhydryl-activated cytolysin.

An improved method allowing incorporation of [3H]myo-inositol into the phosphoinositide pool of human lymphoid cells is described. The procedure devised involves cell permeabilization with a thiol-activated membranolytic toxin, alveolysin, and optimization of the phosphoinositide labeling and extraction. In these conditions 4 to 10% of the added [3H]myo-inositol is found intracellularly and half of this amount (2-5%) is incorporated into the phosphoinositide pool in only 1 h as compared to the classical 0.2 to 0.3% incorporation obtained after 10 to 20 h. The integrity of coupling between receptors and phospholipase C was assessed by the inositol phosphate production after cell stimulation by various agonists.     

Redistribution of phosphate pools and the regulation of Escherichia coli adenylate cyclase activity

The enzyme adenylate cyclase plays a key role in mediating the phenomenon of catabolite repression in Escherichia coli. The mechanism by which one sugar prevents the expression of the gene for another catabolite depends on the capacity of the cell to take up the sugar. Sugars that are most effective in the repression mechanism are those that are transported by the phosphoenolpyruvate-energized phosphotransferase system. The hypothesis presented here is that one or more of the proteins associated with this sugar transport system interact with adenylate cyclase and, when they are in their phosphorylated form, activate the enzyme, provided other factors that permit this activation are present. Another essential activator of adenylate cyclase is inorganic orthophosphate. When E. coli are starved for sugars, the pool of total phosphate is accounted for primarily as inorganic orthophosphate, ATP, phosphoenolpyruvate, and transport proteins in their phospho-forms, a condition that promotes activation of adenylate cyclase. When cells are exposed to sugars, the phosphate pool becomes drastically redistributed, such that the level of inorganic orthophosphate and transport phosphoproteins decreases markedly while the pool of sugar phosphate increases. This translation of the extracellular availability of carbon sources into an intracellular phosphate redistribution is the immediate event that is responsible for catabolite repression.     

Mixing rate of phosphate between plasma and interstitial body fluid of cows

Radiophosphate was injected into the left jugular vein of dairy cows. Blood samples were taken frequently from the right jugular vein during the first hour after injection. Between 20 minutes and 1 hour after injection, the decrease in plasma radioactivity could be formulated as a first order process, designated as "process 3," with a turnover time of 50 minutes. From 5 to 20 minutes after injection the decrease in plasma activity could be interpreted as the result of mixing plasma phosphate with another phosphate pool, designated as the second pool. The capacity of this second pool was derived as a constant in a kinetic equation, so chosen that the resulting mixing rates were independent of time. For two cows the capacity of the second pool was 5 and 8 times, respectively. the phosphate content of the plasma. This result led to the working hypothesis that the major part of the second pool was the phosphate in the interstitial tissue fluid. The turnover time of the plasma phosphate in the mixing process with the second pool amounted to an average of 14 minutes for 5 lactating cows, and an average of 21 minutes for 2 dry cows. This result was obtained under the assumption that the slow first order process 3 is parallel to the mixing process. The assumption that the slower first order process is in series with the mixing process reduces the resulting mixing time to about four-fifths of that reported above. The calculation of process 2 which deviates from first order may be applicable to numerous turnover processes in which both exchange pools have a limited capacity.     

Response of nucleoside diphosphate kinase to the adenylate energy charge

The reaction catalyzed by nucleoside diphosphate kinase responds to the energy charge of the adenylate pool. The velocity is maximal at a charge of 1.0, and decreases sharply with a decrease in the charge. This response may control the flow of phosphate from ATP into the other nucleotide pools and thus participate in the regulation of macromolecular synthesis by the energy level of the cell, as reflected in the charge of the adenylate pool.     

Specific localization of inorganic polyphosphate (poly P) in fungal cell walls by selective extraction and immunohistochemistry

Inorganic polyphosphate (poly P) is a linear polymer of phosphoanhydride-linked phosphate residues that occurs in all organisms and cells. It was found in all organelles and is particularly abundant in fungal vacuoles. The fungal cell wall also contains poly P, but very little is known about the nature and functions of poly P in this compartment. Here, we describe a novel method for the specific quantification and visualization of poly P in fungal cell walls. Selective extraction in high salt buffer revealed large poly P stores in cell walls of Mucorales and lower amounts in most other fungi tested. Staining with specific poly P binding proteins (PBPs) enabled the visualization of poly P in cell walls of selected species from all fungal phyla. The presence of an extracellular phosphate pool in the form of a strongly negatively charged polymer is suggested to have important functions as a phosphate source in mycorrhizal interactions, an antimicrobial compound or protection against toxicity of heavy metals.     

The residual value of fertilizer phosphate applied in two field experiments

Summary Of the phosphate applied to two soils in the field, 42 and 100 per cent respectively remained in the top six inches three years later. The loss from the organic soil is believed to have been due to leaching. In the soils from both sites, half the residual phosphate (measured by isotopic dilution) was still labile, and within each soil the uptake of phosphate by ryegrass was highly correlated with the L-value. However, the phosphate in the labile pools of the two soils differed: in the soil that had lost phosphate, a greater fraction of the pool was in the soil solution and a greater proportion was taken up by ryegrass grown in pots. It is suggested that such differences in the behaviour of the phosphate within the labile pool may yield information on the mechanism of phosphate retention.     

Vacuolar Function in the Phosphate Homeostasis of the Yeast Saccharomyces cerevisiae

We studied physiological roles of the yeast vacuole in the phosphatemetabolism using ³¹P-in vivo nuclear magnetic resonance (NMR)spectroscopy. Under phosphate starvation wild-type yeast cellscontinued to grow for two to three generations, implying thatwild-type cells contain large phosphate pool to sustain thegrowth. During the first four hours under the phosphate starvedcondition, the cytosolic phosphate level was maintained almostconstant, while the vacuolar pool of phosphate decreased significantly.³¹P-NMR spectroscopy on the intact cells and perchloric acid(PCA) extracts showed that drastic decrease of polyphosphatetook place during this phase. In contrast,     

The turnover of phosphate bound to myosin light chain-2 in perfused rat heart.

The rate of exchange of phosphate bound to ventricular myosin light chain-2 (LC2-P) was measured in rat hearts perfused with [32P]Pi at various levels of perfusate Ca2+. Computer simulations of the light-chain labelling suggested the presence of two isotopically distinct pools of LC2-P, one large pool comprising 90% of the total and a small pool consisting of the remaining 10%. At control levels of perfusate Ca2+ the phosphate of the large pool turned over very slowly (t 1/2 congruent to 250 min), whereas that of the small pool turned over much more rapidly (t 1/2 congruent to 1 min). At high levels of perfusate free Ca2+ (5mM) the turnover of the phosphate of the small pool decreased markedly, whereas that of the large pool remained little changed. Conversely, at low perfusate free Ca2+ (0.2 mM), the turnover of the large pool decreased, whereas that of the small pool remained unchanged. The possible identity of these two pools is discussed. The total myosin-light-chain kinase activity of rat ventricle was found to be only 2-3-fold higher than the kinase activity expressed in the heart under control conditions. This, coupled with the very low turnover of most of the LC2-bound phosphate, implies that, in heart, there is insufficient myosin-light-chain kinase activity to cause a rapid rise in the overall level of light-chain phosphorylation, even under conditions of increased cytoplasmic Ca2+.     

Metabolite and enzyme profiles of glycogen metabolism in Methanococcoides methylutens

When a buffered anaerobic cell suspension of Methanococcoides methylutens was maintained under methanol-limited conditions, intracellular glycogen and hexose phosphates were consumed rapidly and a very small amount of methane formed at 4 h of a starvation period. When methanol was supplemented after a total of 20 h of starvation, a reverse pattern was observed: the glycogen level and the hexose phosphate pool increased, and formation of methane took place after a lag period of 90 min. A considerable amount of methane was formed in 120 min after its detection with a rate of 0.18 micromol mg(-1) protein min(-1). When methane formation decreased after 270 min of incubation and finally came to a halt, probably due to complete assimilation of supplemented methanol, the levels of glycogen and hexose monophosphates decreased once again. However fructose 1,6-diphosphate levels showed a continuous increase even after exhaustion of methane formation. In contrast to the hexose phosphate pool, levels of other metabolites showed a small increase after addition of methanol. The enzyme profile of glycogen metabolism showed relatively high levels of triose phosphate isomerase. Glyceraldehyde 3-phosphate dehydrogenase reacted with NADPH with a three-fold higher activity as compared to that with NADH.     

Proteolytic activation of a galactosyl transferase involved in osmotic regulation

Osmotic regulation in the flagellate Ochromonas malhamensis Pringsheim is mainly mediated by changes in the pool size of α-galactosyl-(1 → 1)-glycerol (isofloridoside). Isofloridoside phosphate synthase, a regulated key enzyme responsible for the formation of isofloridoside phosphate, appears to exist as an inactive proenzyme which can be activated by incubation of crude cell extracts with endogenous or exogenous proteases.     

Mixis strategies and resting eeg production of rotifers living in temporally-varying habitats

The organic phosphate pool of some Camargue sediments (South of France) was studied, after removal of inorganic phosphate, with Ca-NTA/dithionite (Fe bound phosphate) and Na-EDTA (Ca bound phosphate). The organic phosphate was divided into an acid soluble organic phosphate fraction (ASOP) and a residual organic phosphate fraction (ROP). The extraction of organic matter with 2.0 M NaOH (90 °C) from ROP yielded considerable quantities of Org-P. In this extract the presence of phytate (inositol hexa phosphate) could be demonstrated using phytase to hydrolyse the phytate. Phytate was shown to account for a considerable part of organic phosphate in sediments of freshwater marsh sediments as well as in the sediment of the brackish/salt water lake ‘Etang de Vaccares’. In laboratory experiments phytate was found to precipitate with all poly-valent cations tested. Furthermore, phytate was found to be strongly adsorbed onto Fe(OOH), which may explain its accumulation and its stability in sediments. Considerable quantities of ASOP were found; the chemical stucture of this pool remains unknown.     

Erythrocyte calcium metabolism. Calcium exchange in normal and sickle-cell-anaemia erythrocytes.

Under exchange conditions (no net increase in calcium), erythrocytes incubated in isoosmotic phosphate-buffered saline have an exchangeable calcium pool comprising about 10% of the total erythrocyte calcium. This pool reaches exchange equilibrium, for either inward-directed or outward-directed transfer of the 45Ca-exchange label, with a half-time of about 20 min. The uptake of Ca2+ requires phosphate, even under hypo-osmotic conditions, where the calcium loading expected as the cells swell is obtained only when phosphate is present. The phosphate requirement is not due to Ca2+ transport as a phosphate salt. This exchangeable-calcium pool is also present in sickle-cell-anemia erythrocytes, and comprises a similar proportion of total cellular calcium.