Optimization of polyphosphate degradation and phosphate secretion using hybrid metabolic pathways and engineered host strains

Polyphosphate degradation and phosphate secretion were optimized in Escherichia coli strains overexpressing the E. coli polyphosphate kinase gene (ppk) and either the E. coli polyphosphatase gene (ppx) or the Saccharomyces cerevisiae polyphosphatase gene (scPPX1) from different inducible promoters on medium- and high-copy plasmids. The use of a host strain without functional ppk or ppx genes on the chromosome yielded the highest levels of polyphosphate, as well as the fastest degradation of polyphosphate when the gene for polyphosphatase was induced. The introduction of a hybrid metabolic pathway consisting of the E. coli ppk gene and the S. cerevisiae polyphosphatase gene resulted in lower polyphosphate concentrations than when using both the ppk and ppx genes from E. coli, and did not significantly improve the degradation rate. It was also found that the rate of polyphosphate degradation was highest when ppx was induced late in growth, most likely due to the high intracellular polyphosphate concentration. The phosphate released from polyphosphate allowed the growth of phosphate-starved cells; excess phosphate was secreted into the medium, leading to a down-regulation of the phosphate-starvation (Pho) response. The production of alkaline phosphatase, an indicator of the Pho response, can be precisely controlled by manipulating the degree of ppx induction. Copyright 1998 John Wiley & Sons, Inc.     

Phosphite disrupts the acclimation of Saccharomyces cerevisiae to phosphate starvation.

The influence of phosphite (H2PO3-) on the response of Saccharomyces cerevisiae to orthophosphate (HPO4(2-); Pi) starvation was assessed. Phosphate-repressible acid phosphatase (rAPase) derepression and cell development were abolished when phosphate-sufficient (+Pi) yeast were subcultured into phosphate-deficient (-Pi) media containing 0.1 mM phosphite. By contrast, treatment with 0.1 mM phosphite exerted no influence on rAPase activity or growth of +Pi cells. 31P NMR spectroscopy revealed that phosphite is assimilated and concentrated by yeast cultured with 0.1 mM phosphite, and that the levels of sugar phosphates, pyrophosphate, and particularly polyphosphate were significantly reduced in the phosphite-treated -Pi cells. Examination of phosphite's effects on two PHO regulon mutants that constitutively express rAPase indicated that (i) a potential target for phosphite's action in -Pi yeast is Pho84 (plasmalemma high-affinity Pi transporter and component of a putative phosphate sensor-complex), and that (ii) an additional mechanism exists to control rAPase expression that is independent of Pho85 (cyclin-dependent protein kinase). Marked accumulation of polyphosphate in the delta pho85 mutant suggested that Pho85 contributes to the control of polyphosphate metabolism. Results are consistent with the hypothesis that phosphite obstructs the signaling pathway by which S. cerevisiae perceives and responds to phosphate deprivation at the molecular level.     

A membrane protein based biosensor: use of a phosphate--H+ symporter membrane protein (Pho84) in the sensing of phosphate ions

A label free biosensor for direct detection of inorganic phosphate based on potential-step capacitance measurements has been developed. The high-affinity Pho84 plasma membrane phosphate/proton symporter of Saccharomyces cerevisiae was used as a sensing element. Heterologously expressed and purified Pho84 protein was immobilized on a self-assembled monolayer (SAM) on a capacitance electrode. Changes in capacitance were recorded upon exposure to phosphate compared to the control substance, phosphate analogue methylphosphonate. Hence, even without the explicit use of lipid membranes, the Pho84 membrane protein could retain its capacity of selective substrate binding, with a phosphate detection limit in the range of the apparent in vivo K(m). A linear increase in capacitance was monitored in the phosphate concentration range of 5-25 μM. The analytical response of the capacitive biosensor is in agreement with that the transporter undergoes significant conformational changes upon exposure to inorganic phosphate, while exposure to the analogue only causes minor responses.     

Pho91 Is a vacuolar phosphate transporter that regulates phosphate and polyphosphate metabolism in Saccharomyces cerevisiae

Inorganic polyphosphate (poly P) is a biopolymer that occurs in all organisms and cells and in many cellular compartments. It is involved in numerous biological phenomena and functions in cellular processes in all organisms. However, even the most fundamental aspects of poly P metabolism are largely unknown. In yeast, large amounts of poly P accumulate in the vacuole during growth. It is neither known how this poly P pool is synthesized nor how it is remobilized from the vacuole to replenish the cytosolic phosphate pool. Here, we report a systematic analysis of the yeast phosphate transporters and their function in poly P metabolism. By using poly P content as a read-out, it was possible to define novel functions of the five phosphate transporters: Pho84, Pho87, Pho89, Pho90, and Pho91, in budding yeast. Most notably, it was found that the low-affinity transporter Pho91 limits poly P accumulation in a strain lacking PHO85. This phenotype was not caused by a regulatory effect on the PHO pathway, but can be attributed to the unexpected localization of Pho91 in the vacuolar membrane. This finding is consistent with the hypothesis that Pho91 serves as a vacuolar phosphate transporter that exports phosphate from the vacuolar lumen to the cytosol.     

Copper ions stimulate polyphosphate degradation and phosphate efflux in Acidithiobacillus ferrooxidans

For some bacteria and algae, it has been proposed that inorganic polyphosphates and transport of metal-phosphate complexes could participate in heavy metal tolerance. To test for this possibility in Acidithiobacillus ferrooxidans, a microorganism with a high level of resistance to heavy metals, the polyphosphate levels were determined when the bacterium was grown in or shifted to the presence of a high copper concentration (100 mM). Under these conditions, cells showed a rapid decrease in polyphosphate levels with a concomitant increase in exopolyphosphatase activity and a stimulation of phosphate efflux. Copper in the range of 1 to 2 microM greatly stimulated exopolyphosphatase activity in cell extracts from A. ferrooxidans. The same was seen to a lesser extent with cadmium and zinc. Bioinformatic analysis of the available A. ferrooxidans ATCC 23270 genomic sequence did not show a putative pit gene for phosphate efflux but rather an open reading frame similar in primary and secondary structure to that of the Saccharomyces cerevisiae phosphate transporter that is functional at acidic pH (Pho84). Our results support a model for metal detoxification in which heavy metals stimulate polyphosphate hydrolysis and the metal-phosphate complexes formed are transported out of the cell as part of a possibly functional heavy metal tolerance mechanism in A. ferrooxidans.     

Uranyl Precipitation by Pseudomonas aeruginosa via Controlled Polyphosphate Metabolism

The polyphosphate kinase gene from Pseudomonas aeruginosa was overexpressed in its native host, resulting in the accumulation of 100 times the polyphosphate seen with control strains. Degradation of this polyphosphate was induced by carbon starvation conditions, resulting in phosphate release into the medium. The mechanism of polyphosphate degradation is not clearly understood, but it appears to be associated with glycogen degradation. Upon suspension of the cells in 1 mM uranyl nitrate, nearly all polyphosphate that had accumulated was degraded within 48 h, resulting in the removal of nearly 80% of the uranyl ion and >95% of lesser-concentrated solutions. Electron microscopy, energy-dispersive X-ray spectroscopy, and time-resolved laser-induced fluorescence spectroscopy (TRLFS) suggest that this removal was due to the precipitation of uranyl phosphate at the cell membrane. TRLFS also indicated that uranyl was initially sorbed to the cell as uranyl hydroxide and was then precipitated as uranyl phosphate as phosphate was released from the cell. Lethal doses of radiation did not halt phosphate secretion from polyphosphate-filled cells under carbon starvation conditions.     

Uranyl precipitation by Pseudomonas aeruginosa via controlled polyphosphate metabolism

The polyphosphate kinase gene from Pseudomonas aeruginosa was overexpressed in its native host, resulting in the accumulation of 100 times the polyphosphate seen with control strains. Degradation of this polyphosphate was induced by carbon starvation conditions, resulting in phosphate release into the medium. The mechanism of polyphosphate degradation is not clearly understood, but it appears to be associated with glycogen degradation. Upon suspension of the cells in 1 mM uranyl nitrate, nearly all polyphosphate that had accumulated was degraded within 48 h, resulting in the removal of nearly 80% of the uranyl ion and >95% of lesser-concentrated solutions. Electron microscopy, energy-dispersive X-ray spectroscopy, and time-resolved laser-induced fluorescence spectroscopy (TRLFS) suggest that this removal was due to the precipitation of uranyl phosphate at the cell membrane. TRLFS also indicated that uranyl was initially sorbed to the cell as uranyl hydroxide and was then precipitated as uranyl phosphate as phosphate was released from the cell. Lethal doses of radiation did not halt phosphate secretion from polyphosphate-filled cells under carbon starvation conditions.     

Intracellular phosphate serves as a signal for the regulation of the PHO pathway in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the phosphate signal transduction pathway (PHO pathway) is known to regulate the expression of several phosphate-responsive genes, such as PHO5 and PHO84. However, the fundamental issue of whether cells sense intracellular or extracellular phosphate remains unresolved. To address this issue, we have directly measured intracellular phosphate concentrations by (31)P NMR spectroscopy. We find that PHO5 expression is strongly correlated with the levels of both intracellular orthophosphate and intracellular polyphosphate and that the signaling defect in the Deltapho84 strain is likely to result from insufficient intracellular phosphate caused by a defect in phosphate uptake. Furthermore, the Deltaphm1Deltaphm2, Deltaphm3, and Deltaphm4 strains, which lack intracellular polyphosphate, have higher intracellular orthophosphate levels and lower expression of PHO5 than the wild-type strain. By contrast, the Deltaphm5 strain, which has lower intracellular orthophosphate and higher polyphosphate levels than the wild-type strain, shows repressed expression of PHO5, similar to the wild-type strain. These observations suggest that PHO5 expression is under the regulation of intracellular orthophosphate, although orthophosphate is not the sole signaling molecule. Moreover, the disruption of PHM3, PHM4, or of both PHM1 and PHM2 in the Deltapho84 strain suppresses, although not completely, the PHO5 constitutive phenotype by increasing intracellular orthophosphate, suggesting that Pho84p affects phosphate signaling largely by functioning as a transporter.     

The effect of acetate and succinate on polyphosphate formation and degradation in activated sludge,with particular reference to Acinetobacter calcoaceticus

Summary The effects of acetate and succinate were compared to the effect of phosphate starvation on the formation and degradation of polyphosphate in an Acinetobacter calcoaceticus isolate from a five-stage Bardenpho activated sludge plant and in mixed liquor from the same plant. Both acetate treatment and phosphate starvation result in significant phosphate release from the cells. Succinate treatment showed little difference from the control. A reduction in polyphosphate was observed simultaneously with the phosphate release. On resuspension of the treated samples in a complete medium, uptake of phosphate was observed. In the acetate-treated samples, this was significantly higher than in the phosphate starved samples. Polyphosphate formation was also significantly enhanced after treatment.     

Roles of major facilitator superfamily transporters in phosphate response in Drosophila

The major facilitator superfamily (MFS) transporter Pho84 and the type III transporter Pho89 are responsible for metabolic effects of inorganic phosphate in yeast. While the Pho89 ortholog Pit1 was also shown to be involved in phosphate-activated MAPK in mammalian cells, it is currently unknown, whether orthologs of Pho84 have a role in phosphate-sensing in metazoan species. We show here that the activation of MAPK by phosphate observed in mammals is conserved in Drosophila cells, and used this assay to characterize the roles of putative phosphate transporters. Surprisingly, while we found that RNAi-mediated knockdown of the fly Pho89 ortholog dPit had little effect on the activation of MAPK in Drosophila S2R+ cells by phosphate, two Pho84/SLC17A1-9 MFS orthologs (MFS10 and MFS13) specifically inhibited this response. Further, using a Xenopus oocyte assay, we show that MSF13 mediates uptake of [(33)P]-orthophosphate in a sodium-dependent fashion. Consistent with a role in phosphate physiology, MSF13 is expressed highest in the Drosophila crop, midgut, Malpighian tubule, and hindgut. Altogether, our findings provide the first evidence that Pho84 orthologs mediate cellular effects of phosphate in metazoan cells. Finally, while phosphate is essential for Drosophila larval development, loss of MFS13 activity is compatible with viability indicating redundancy at the levels of the transporters.     

Copper Ions Stimulate Polyphosphate Degradation and Phosphate Efflux in Acidithiobacillus ferrooxidans

For some bacteria and algae, it has been proposed that inorganic polyphosphates and transport of metal-phosphate complexes could participate in heavy metal tolerance. To test for this possibility in Acidithiobacillus ferrooxidans, a microorganism with a high level of resistance to heavy metals, the polyphosphate levels were determined when the bacterium was grown in or shifted to the presence of a high copper concentration (100 mM). Under these conditions, cells showed a rapid decrease in polyphosphate levels with a concomitant increase in exopolyphosphatase activity and a stimulation of phosphate efflux. Copper in the range of 1 to 2 μM greatly stimulated exopolyphosphatase activity in cell extracts from A. ferrooxidans. The same was seen to a lesser extent with cadmium and zinc. Bioinformatic analysis of the available A. ferrooxidans ATCC 23270 genomic sequence did not show a putative pit gene for phosphate efflux but rather an open reading frame similar in primary and secondary structure to that of the Saccharomyces cerevisiae phosphate transporter that is functional at acidic pH (Pho84). Our results support a model for metal detoxification in which heavy metals stimulate polyphosphate hydrolysis and the metal-phosphate complexes formed are transported out of the cell as part of a possibly functional heavy metal tolerance mechanism in A. ferrooxidans.     

Interrelationship of polyphosphate metabolism and levorin biosynthesis in Streptomyces levoris

The effect of inorganic phosphate on biosynthesis of the polyene antibiotic levorin by Streptomyces levoris was studied. At phosphate concentration of 4.0 mM levorin biosynthesis is repressed by 90%, resulting in an increase of ATP and a condensed inorganic polyphosphates content in the producer cells. At phosphate concentration optimal for levorin production (0.04 mM) the level of intracellular ATP sharply falls by the beginning of the steady-state phase of the producer growth and that of polyphosphates decreases 3-6-fold. The inorganic phosphate exerts different effects on polyphosphate metabolism enzymes, such as polyphosphate: D-glucose-6-phosphotransferase, polyphosphate phosphohydrolase, tripolyphosphate phosphohydrolase, pyrophosphate phosphohydrolase, alkaline and acid phosphatase. The strongest effect of phosphate excess is observed in the case of polyphosphate: D-glucose-6-phosphotransferase, whose activity decreases 2-5-fold. The activity of this enzyme was shown to be correlated with the antibiotic accumulation. The data obtained are indicative of interrelationship between the polyphosphate metabolism and levorin biosynthesis.     

Inorganic phosphate is sensed by specific phosphate carriers and acts in concert with glucose as a nutrient signal for activation of the protein kinase A pathway in the yeast Saccharomyces cerevisiae

Yeast cells starved for inorganic phosphate on a glucose-containing medium arrest growth and enter the resting phase G0. We show that re-addition of phosphate rapidly affects well known protein kinase A targets: trehalase activation, trehalose mobilization, loss of heat resistance, repression of STRE-controlled genes and induction of ribosomal protein genes. Phosphate-induced activation of trehalase is independent of protein synthesis and of an increase in ATP. It is dependent on the presence of glucose, which can be detected independently by the G-protein coupled receptor Gpr1 and by the glucose-phosphorylation dependent system. Addition of phosphate does not trigger a cAMP signal. Despite this, lowering of protein kinase A activity by mutations in the TPK genes strongly reduces trehalase activation. Inactivation of phosphate transport by deletion of PHO84 abolishes phosphate signalling at standard concentrations, arguing against the existence of a transport-independent receptor. The non-metabolizable phosphate analogue arsenate also triggered signalling. Constitutive expression of the Pho84, Pho87, Pho89, Pho90 and Pho91 phosphate carriers indicated pronounced differences in their transport and signalling capacities in phosphate-starved cells. Pho90 and Pho91 sustained highest phosphate transport but did not sustain trehalase activation. Pho84 sustained both transport and rapid signalling, whereas Pho87 was poor in transport but positive for signalling. Pho89 displayed very low phosphate transport and was negative for signalling. Although the results confirmed that rapid signalling is independent of growth recovery, long-term mobilization of trehalose was much better correlated with growth recovery than with trehalase activation. These results demonstrate that phosphate acts as a nutrient signal for activation of the protein kinase A pathway in yeast in a glucose-dependent way and they indicate that the Pho84 and Pho87 carriers act as specific phosphate sensors for rapid phosphate signalling.     

Mutagenic and functional analysis of the C-terminus of Saccharomyces cerevisiae Pho84 phosphate transporter

A widely accepted mechanism for selective degradation of plasma membrane proteins is via ubiquitination and/or phosphorylation events. Such a regulated degradation has previously been suggested to rely on the presence of a specific SINNDAKSS sequence within the protein. Modification of a partly conserved SINNDAKSS-like sequence in the C-terminal tail of the Pho84 phosphate transporter, in combination with C-terminal fusion of green fluorescent protein or a MYC epitope, were used to evaluate the presence of this sequence and its role in the regulated degradation. The functional Pho84 mutants in which this SINNDAKSS-like sequence was altered or truncated were subjected to degradation like that of the wild type, suggesting that degradation of the Pho84 protein is regulated by factors other than properties of this sequence.