MODES OF FORMATION OF PHOSPHATE COMPOUNDS AND THEIR TURNOVER IN CHLORELLA CELLS DURING THE PROCESS OF LIFE CYCLE AS STUDIED BY THE TECHNIQUE OF SYNCHRONOUS CULTURE

1. Starting with uniformly ³²P-labeled Chlorella cells, a synchronousculture was run in a medium containing non-labeled phosphate.During the synchronous growth and division of the algal cells,the changes in amount of total and labeled P in various phosphatecompounds were followed.
2. Characteristic changes were observedwith (acid-soluble) polyphosphate"A", nucleotidic labile phosphates,(acid-insoluble) polyphosphate"C", DNA-P and protein-P. Thelabeled phosphorus of polyphosphate"C" showed a decrease duringthe earlier phase of experiment,although a considerable uptakeof non-labeled P from the culturemedium into this compoundwas observed throughout the experiment.In parallel with theloss of labeled phosphorus in this compound,the increase oflabeled phosphorus occurred in polyphosphate"A", in the nucleotidiclabile-P compounds, and in DNA, suggestingthat these substancesreceived P from polyphosphate "C". Thelabeled P in polyphosphate"A" and in the nucleotidic labile-Pcompounds increased graduallywith the progress of culture,attained their maximum levelsat the stage of ripening, anddecreased markedly during theprocess of "post-ripening" anddivision of cells, indicatingthat these compounds were in activeturnover and playing someimportant roles in the process ofcell maturation and division.
3. The total amounts of inorganic P, RNA-P and lipid-P increasedcontinuously throughout the experiment and showed no significantchange in the content of labeled P.

(Received June 5, 1961; )     

31P NMR studies on the effect of phosphite on Phytophthora palmivora

31P NMR spectra were obtained from perchloric acid (PCA) and KOH extracts of Phytophthora palmivora mycelium. Signals indicating the presence of large amounts of short-chain polyphosphate were observed in the spectra of PCA extracts of mycelia grown under both low (0.1 mM) and high (10 mM) phosphate conditions. The mean chain length of polyphosphate was calculated from the relative areas of signals arising from terminal and internal P nuclei in the polyphosphate chain. The small amount of polyphosphate evident in the KOH extract had an average chain length similar to PCA-soluble polyphosphate. 32P tracer studies indicated that phosphorus in the PCA fraction accounted for between 50 and 60% of total phosphorus, the bulk of the remainder being divided between the lipid and KOH extracts. The presence of the fungicide phosphorous acid markedly reduced the average chain length of acid-soluble polyphosphate. This reduction occurred both under low-phosphate conditions, in which treatment with phosphorous acid retards growth, and under high-phosphate conditions, in which no significant growth retardation is observed. Treatment with phosphorous acid perturbed phosphorus distribution and lipid composition under low-phosphate conditions.     

The involvement of high-energy phosphate in 2-deoxy-d-glucose transport in Kluyveromyces marxianus

Under aerobic conditions 2-deoxy-d-glucose was accumulated in Kluyveromyces marxianus mainly in a phosphorylated form. During sugar uptake both ATP, polyphosphate and orthophosphate levels decreased. Under anaerobic conditions considerably less sugar was taken up. The intracellular free sugar concentration did not exceed the medium concentration, whereas sugar phosphorylation leveled off at about 3 μmol/g yeast. In response to anaerobic 2-deoxy-d-glucose uptake only ATP and polyphosphate appeared to decrease. Within the experimental error sugar phosphorylation was counterbalanced by the polyphosphate decrease. Pulse labeling experiments revealed transport-associated phosphorylation under these anaerobic conditions, Further, kinetic studies on permeabilized cells showed that cytoplasmic ATP could not be the phosphoryl donor in this transport-associated phosphorylation. These results confirm and extend previous observations, indicating that polyphosphate plays a crucial role in 2-deoxy-d-glucose transport in Kluyveromyces marxianus.     

The elemental composition dynamics of large polyphosphate granules in Acinetobacter strain 210A

Electron microscopy and energy dispersive X-ray micro-analysis were used to examine the elemental composition of large polyphosphate granules in unfixed and unstained intact cells of Acinetobacter strain 210A. When grown in medium with butyrate, Acinetobacter strain 210A possessed 1 or 2 large granules with a diameter of 0.4 m besides a relatively large number of small granules. The large granules were composed of phosphorus, magnesium and potassium. A decrease in the Mg/Ca-ratio of the medium from 5.95 to 0.0073 resulted in a decline in the intracellular Mg/Ca-ratio from 15 to 0.56. At a high intracellular Mg/Ca-ratio, magnesium was the dominant counterion in the polyphosphate granule. Calcium became the major cation in the polyphosphate bodies at a low intracellular Mg/Ca-ratio. Omission of Ca²⁺ or modification of the K/Mg ratio in the medium did not significantly affect the cation composition of the polyphosphate granules. The dissociation constants for Mg- and Ca-polyphosphate were 9.3×10^-2 mol/l and 1.5×10^-1 mol/l, respectively.     

Determination of the role of polyphosphate in transport-coupled phosphorylation in the yeast Saccharomyces cerevisiae

The role of polyphosphate in 2-deoxy-D-glucose transport was studied in yeast cells, pulse-labeled with [³²P]orthophosphate, by comparing the concentrations and specific activities of polyphosphate, orthophosphate and 2-dGlc-phosphate. When 2-dGlc transport was measured under aerobic conditions, it appeared that polyphosphate replenished the orthophosphate pool, indicating that polyphosphate has, at least mainly, an indirect role in sugar phosphorylation. Also in cells with a reduced respiratory capacity, due to a treatment with antimycin A, no direct role for polyphosphate in 2-dGlc transport could be detected. Under these conditions, only a very limited breakdown of polyphosphate occurred, probably because of the small decrease in the orthophosphate concentration.Abbreviations 2-dGlc 2-deoxy-D-glucose - P_i orthophosphate - P_n polyphosphate - SP sugar phosphate     

PHOSPHATE UPTAKE UNDER NITRATE LIMITATION BY SCENEDESMUS SP. AND ITS ECOLOGICAL IMPLICATIONS1

Under nitrogen limitation the phosphate content of Scenedesmus sp. shows little variation regardless of growth rate and the N/P atomic ratio of the medium. P uptake therefore can be calculated as the product of P content and N-dependent growth rate. The maximum rate of P uptake in N limitation is lower by a factor of about 8 than the rate in P limitation. As reported earlier, P uptake by this alga under P limitation is described by the kinetics resembling non-competitive enzyme inhibition, with one or several intracellular P fractions as inhibitors. These fractions include surplus P (water extractable) and inorganic polyphosphate fractions A (acid soluble) and B, C, and D (acid insoluble). In N limitation, the ratios of fractions A, B, C, and D are quite different from the ratios of P limitation at comparable growth rates. The concentrations of polyphosphate fraction A in N-limited cells are much, higher than the levels in P-limited cells, and this fraction becomes more predominant at low growth rates in N limitation. This fraction, if introduced as the inhibitor into the noncompetitive scheme, explains the uptake kinetics in both N- and P-limited cells and the low maximum uptake rate in N limitation. This finding may have two significant ecological implications: (1) A nutrient imbalance which brings about changes in the internal, level or the metabolism, of fraction A would affect P uptake. (2) Nitrogen sufficiency would cause a competitive advantage in P uptake. This advantage would be shared by N₂ fixers and algae with low optimum N/P ratios. In Scenedesmus sp. P limitation switches to N limitation and vice versa when the cell N/P atomic ratio is about 30.     

31P-NMR DIFFERENTIATION BETWEEN INTRACELLULAR PHOSPHATE POOLS IN COSMARIUM (CHLOROPHYTA)1

³¹P nuclear magnetic resonance (NMR) spectroscopy of intact Cosmarium sp. cells is presented as a suitable tool for the differentiation of intracellular accumulation pools of polyphosphates. The cold trichloroacetic acid (TCA) insoluble fraction is shown to contain most of the total cellular phosphate in the phosphate rich Cosmarium cells. Moreover, evidence from a ³¹ P-NMR study and electron microscopic observations of cold TCA treated Cosmarium cells indicate that this fraction consists mostly of polyphosphates which seem to retain the native morphological structure observed in the untreated cells. The determination of orthophosphate in the hot water extract of Cosmarium cells did not measure the polyphosphate pools. Determination of total phosphorus content in the hot water extract rendered a value three times higher than the frequently used orthophosphate determination procedure. However, as revealed by the ³¹P-NMR spectra and the chemical analyses of the extract and of the treated cells, even total phosphorus in the extract measured only 30% of the total cellular phosphorus. ³¹P-NMR enabled the unequivocal chemical identification of the major phosphate compounds in the hot water extract (“Surplus P”) as orthophosphate and polyphosphates of about 10 phosphate units chainlength. More than 70% of the accumulation pool of polyphosphates was still in the cells after extraction. However, the electron microscopy study revealed that the native granular structure of polyphosphates had been destroyed by the hot water extraction procedure.     

EFFECT OF PHOSPHATE CONCENTRATION ON THE FINE STRUCTURE OF THE CYANOBACTERIUM,MICROCYSTIS AERUGINOSA KÜTZ. EMEND. ELENKIN

SUMMARY

Microcystis aeruginosa toxic strain UV-006 stored a fixed amount of polyphosphate in spherical granules located in the centroplasm. Twenty four hours of phosphate starvation induced use of stored polyphosphate, manifested by reduction in granule numbers. Reintroduction of 2, 4 or 8 mg l^?1 K₂HPO₄ resulted in redeposition of polyphosphate in a critical number of centroplasmic polyphosphate granules. Growth rate was unaffected by phosphate concentrations, although the final cell yield was slightly lower at 8 mg l ^?1

Continued starvation decreased photosynthetic rate and growth ceased. Cells appeared senescent. Cyanophycin and polyglucoside reserves apparently increased in these cells, whilst thylakoids were reduced in number and reorientated away from. the cell wall and polyhedral bodies were lost. After the initial decrease, centroplasmic polyphosphate bodies increased to about half of the maximum numbers stored in cells grown in the presence of phosphate, suggesting that translocation of phosphorus from other areas in the phosphate-starved cell occurred.

Two further polyphosphate deposition areas were observed. DNA fibrils may have represented nucleation sites for developing polyphosphate granules. Intrathylakoidal deposits were rare.     

Enhanced phosphate uptake and polyphosphate accumulation in Burkholderia cepacia grown under low pH conditions

Of bacterial cells in a sample of activated sludge, 34% contained detectable intracellular polyphosphate inclusions following Neisser staining, when grown on glucose/mineral salts medium at pH 5.5; at pH 7.5 only 7% of cells visibly accumulated polyphosphate. In a sludge isolate of Burkholderia cepacia chosen for further study, maximal removal of phosphate and accumulation of polyphosphate occurred at pH 5.5; levels were up to 220% and 330% higher, respectively, than in cells grown at pH 7.5. During the early stationary phase of growth at pH 5.5 a maximum level of intracellular polyphosphate that comprised 13.6% of cellular dry weight was reached. Polyphosphate kinase activity was detected in actively growing cells only when cultured at pH 5.5. The phenomenon of acid-stimulated phosphate uptake and polyphosphate accumulation in this environmental bacterial population parallels observations previously made by us in the yeast Candida humicola and may thus represent a widespread microbial response to low external pH values.     

Intracellular accumulation of trehalose and glycogen in an extreme oligotroph,Rhodococcus erythropolis N9T-4

An extreme oligotroph, Rhodococcus erythropolis N9T-4, showed intracellular accumulation of trehalose and glycogen under oligotrophic conditions. No trehalose accumulation was observed in cells grown on the rich medium. Deletion of the polyphosphate kinase genes enhanced the trehalose accumulation and decreases the intracellular glycogen contents, suggesting an oligotrophic relationship between among the metabolic pathways of trehalose, glycogen, and inorganic polyphosphate biosyntheses.     

Changes in polyphosphate composition and localization in Propionibacterium acnes after near-ultraviolet irradiation.

Electron microscopy showed that electron-dense granules accumulated in Propionibacterium acnes in larger amounts when the bacteria were grown on a phosphate-rich medium. X-ray microanalysis demonstrated that the granules contained mostly phosphorus and potassium, indicating that the cells contained polyphosphate granules. When cells were grown on a complex Bacto-agar medium, the amount and the size of the polyphosphate granules were reduced. Polyphosphate was also detected with 31P nuclear magnetic resonance (31P-NMR). Of the polyphosphates observed with 31P-NMR, 20% seemed to be located outside the cell membrane. Broad-band near-ultraviolet irradiation (emission maximum 366 nm) corresponding to doses that killed 37% of the cells increased the amount of polyphosphate in cells grown on the phosphate-rich medium. The fluorescent chromophore 4',6-diamidino-2-phenylindole (DAPI) shifted the fluorescence emission from 478 to 538 nm when bound to polyphosphate and excited at 340 nm. DAPI was used to detect polyphosphates generated after near-ultraviolet irradiation of the cells. Nonirradiated cells showed no increased fluorescence at 538 nm, indicating no polyphosphate is presented in the cells. We conclude that DAPI did not have "access" to the intracellular polyphosphate as long as the cells were not light damaged. This observation is important for the interpretation of near-UV damage to cells.     

Modulation of the phosphate-starvation response in Escherichia coli by genetic manipulation of the polyphosphate pathways

The effect of intracellular polyphosphate on the phosphate-starvation response in Escherichia coli was studied by genetically manipulating the intracellular polyphosphate levels and by performing phosphate shifts on the genetically engineered strains. Strains that produced large quantities of polyphosphate and were able to degrade it induced the phosphate-starvation response to a lesser extent than wild-type strains, whereas strains that were unable to degrade a large intracellular polyphosphate pool induced the phosphate-starvation response to a greater extent than wild-type strains. These results have important implications for expression of heterologous genes under control of the phoA promoter. (c) 1996 John Wiley & Sons, Inc.     

Two internal pools of soluble polyphosphate in the cyanobacterium Synechocystis sp. strain PCC 6308: an in vivo 31P NMR spectroscopic study

Two intracellular pools of soluble polyphosphate were identified by in vivo ³¹P NMR spectroscopy in the cyanobacterium Synechocystis sp. strain PCC 6308. Polyphosphate was present in the cells after growth in sulfur-limited media containing excess phosphate. The presence of polyphosphate was confirmed by transmission electron microscopy and chemical analysis. ³¹P NMR spectroscopy of whole cells treated with EDTA revealed two pools of mobile polyphosphate. A downfield shift and narrowing of part of the broad polyphosphate resonance was observed after EDTA treatment, suggesting that EDTA binds metal ions normally associated with some of the polyphosphate. Phosphate, but not polyphosphate, leaked out of the cells after this treatment. Addition of magnesium ions caused the downfield shift in the polyphosphate resonance to move back toward its original value. These data show that only part of the cation-complexed polyphosphate is accessible to the added EDTA and suggest that there are two internal fractions of NMR-visible polyphosphate in the cells, only one of which loses its associated cations to EDTA. Spheroplast formation showed that polyphosphate was not present in the periplasm of the cells. Received: 3 July 1997 / Accepted: 26 September 1997     

<Superscript>31</Superscript>P NMR study of polyphosphate levels during different growth phases of <Emphasis Type="Italic">Phycomyces blakesleeanus</Emphasis>

The changes in relative polyphosphate content, estimated as the intensity ratio of core polyphosphate signal and intracellular inorganic phosphate signal from ³¹P NMR spectra, during the growth of Phycomyces blakesleeanus are reported. The ratio increases from 16 h to 28 h of growth, the minimum occurs at 32 h, followed by sharp increase up to 36 h, and a steady decrease afterwards. The changes in the biomass during mycelium growth showed steady increases, with a stagnation period between 32 h and 36 h during which a pronounced increase in the intensity ratio of core polyphosphates to intracellular inorganic phosphate signal occurred. The reduction of growth temperature from 22°C to 18°C significantly decreased the rate and intensity of growth, but the pattern of polyphosphate changes remained unchanged. The changes of the intensity ratio of core polyphosphates to intracellular inorganic phosphate signal are linked to characteristic stages of sporangiophore development. Analysis of core polyphosphates, intracellular inorganic phosphate and β-ATP signal intensities suggest the role of polyphosphates as an energy and/or a phosphate reserves during Phycomyces development.     

Possible role of high molecular weight polyphosphates in ATP synthesis from exogenous adenine by the culture of Corynebacterium sp., strain VSTI-301]

An addition of exogenous adenine to an autolysing 72-hour culture of Corynebacterium sp., strain BSTI-301 results in accumulation of as much as 0,6--1,0 mp of ATP per 1 ml of medium. Extracellular ATP accumulation under such conditions is coupled with a considerable decrease of the intracellular content of 5'-phosphoribosyl-1-pyrophosphate, orthophosphate, pyrophosphate and two fractions of high-polymeric polyphosphates PPh3 and PPh4, as compared to the control. The activity of pyrophosphate phosphohydrolase (EC 3.6.1.1) and polyphosphate phosphohydrolase (EC 3.6.1.11) is thereby considerably decreased in the cells growing on exogenous adenine, while the activity of ADP-phosphotransferase (EC 2.7.4.1) is increased 2-fold. It was found that in experiments with 14C-adenine the intracellular content of both ATP and ADP remains unchanged despite a considerable accumulation of extracellular ATP in Corynebacterium sp., strain BSTI-301 cells.     

DISTRIBUTION AND TURNOVER OF PHOSPHATE COMPOUNDS IN GROWING CHLORELLA CELLS

1. Using the Chlorella cells which had been uniformly labeled with³²P, the distribution of phosphorus in various fractions ofcell material was investigated. Uniformly ³²P-labeled Chlorellawas further grown in a P-free medium or in a standard "cold"medium, and the change of distribution of ³²P (as well as theuptake of exogenous P) in various cell fractions was followed.
2. Analysis of the ³²P-labeled algal cells showed that the highestin P-content was the fraction of RNA followed by those of polyphosphates,lipid, nucleotidic labile phosphate compounds, DNA and protein(in decreasing order). ATP and ADP were found to be only minorfractions of the total labile phosphates.
3. On incubating the³P-labeled alga in a P-free medium, the P.contentsin the fractionsof DNA, protein, lipid and ATP increased, thosein polyphosphatesand ADP decreased, and that in RNA remainedalmost unchanged.When the ³²P-labeled alga was further grownin the normal "cold"medium, DNA and protein increased withthe expenditure of endogenous³²P, but with practically no incorporationof external P. Inthe meantime the P in polyphosphates decreasedconsiderably,and the RNA fraction incorporated a large amountof externalP but only a little of endogenous³²P.
4. It was inferred that,under the experimental conditions of thepresent study, thephosphorus used in the syntheses of DNA andprotein was primarilytaken from polyphosphates, while thatused in the synthesesof RNA, phospholipid and polyphosphateswas, for the most part,taken from the extracellular P-source.

¹A part of this paper was read at the Vth International Congressof Biochemistry, Moscow, August 10–16, 1961. (Received June 4, 1961; )     

EVIDENCE FOR THE OCCURRENCE AND DISTRIBUTION OF INORGANIC POLYPHOSPHATES IN VERTEBRATE TISSUES

Evidence for the occurrence of polyphosphates having apparent chain-lengths ranging from less than 10 to over 5000 orthophosphate units has been found in adult brain as well as in a number of other mammalian tissues which have been examined. There appears to be three times as much polyphosphate in rat brain as there is in rat liver. Adult rat brain appears to contain at least 15 μg of phosphorus as polyphosphate per g of fresh tissue. In addition, neural polyphosphate is extremely labile to catabolic degradation after death whereas hepatic polyphosphate is relatively more stable. The nature of this inorganic polymer was elucidated through use of the technique of ³¹P nuclear magnetic resonance spectroscopy. Further structural evidence was obtained by application of the isotopic dilution technique to ³²P-labelled neural polyphosphate mixed with an abiotically prepared inorganic polyphosphate. The conditions and rates of hydrolysis of the biological polyphosphate and a non-biological polyphosphate were comparable.     

Effect of dietary supplementation of probiotic and vitamin C on the immune response of Indian major carp, Labeo rohita (Ham.)

The immunostimulatory effect of probiotics and vitamin C has been established in many systems including fish. An investigation was carried out to study the effect of dietary supplementation of a probiotic bacterium "Bacillus subtilis", vitamin C in the form of ascorbyl polyphosphate and their combination on the immune response of Indian major carp, rohu, (Labeo rohita Ham.) fingerlings fed for a period of 60 days. The total serum protein and globulin content was significantly higher (p<0.05) in probiotic (B. subtilis @ 10(8) CFU/g of the feed) fed group while the respiratory burst activity of blood neutrophils was significantly high in vitamin C (ascorbyl polyphosphate @100 mg per kg diet) fed group. The antibody level was significantly high in Bacillus subtilis treated group followed by the probiotic (B. subtilis @ 10(8) CFU/g of the feed) and ascorbyl polyphosphate (ascorbyl polyphosphate @100 mg per kg diet) combined group. The least percentage of mortality was recorded in B. subtilis treated group (25%) followed by 35 and 40% in ascorbyl polyphosphate treated and B. subtilis and ascorbyl polyphosphate combined groups, respectively.     

Changes in orthophosphate, pyrophosphate and long-chain polyphosphate levels in Leishmania major promastigotes incubated with and without glucose

The intracellular levels of orthophosphate (Pi), pyrophosphate (PPi) and short- and long-chain polyphosphate (Poly P) were measured in Leishmania major promastigotes incubated in a phosphate-free medium. In the absence of exogenous substrate, the levels of both Pi and PPi increased during a 1 h incubation. The increase in both Pi and PPi was prevented when glucose was present, but glycerol prevented the rise in Pi only. A rise in Pi and PPi was also seen in cells incubated in the absence of exogenous substrate under anaerobic conditions. This was reversed upon addition of glucose plus oxygen. Polyphosphate, here shown to be present in L. major, was measured by means of a polyphosphate glucokinase assay. Short-chain Poly P content did not differ between cells incubated for 1 h in the absence of exogenous substrate or in the presence of glucose or glycerol. Long-chain Poly P content, however, was lower in cells incubated without glucose than in cells incubated with glucose and was also lower in cells incubated for 1 h with glycerol as compared with freshly washed cells. Up to 61% of the increase in Pi and PPi that occurred in promastigotes incubated in the absence of exogenous substrate could have arisen from the concomitant decrease in long-chain Poly P.