The mechanism of utilization of polyphosphate by polyphosphate glucokinase from Propionibacterium shermanii

The phosphorylation of glucose by polyphosphate glucokinase with both long- and short-chain polyphosphates has been shown to occur by either a nonprocessive mechanism, i.e. with repeated association and dissociation of the polyphosphate from the enzyme after each phosphorylation or by a quasiprocessive mechanism in which several phosphorylations occur prior to the release of polyphosphate and the reassociation with the enzyme. In contrast, the phosphorylation of ADP to ATP by polyphosphate kinase is by a strictly processive mechanism; the phosphorylation occurs without release of the polymer from the enzyme prior to termination of the reaction (Robinson, N. A., Clark, J. E., and Wood, H. G. (1987) J. Biol. Chem. 262, 5216-5222). The demonstration that the mechanism is quasi-or nonprocessive was accomplished by electrophoresis using a variety of concentrations of polyacrylamide gels which made it possible to detect the intermediate sizes formed during the reactions. It also has been shown that all chains longer than about 100 are used simultaneously, but with chains of less than 100 residues, there is preferential utilization of the longest chains. Thus a narrow range of sizes is formed from a heterogeneous mixture of long chains. It is this formation of the narrow range of sizes that makes it possible to use polyphosphate glucokinase for the determination of the average size of long chains (Pepin, C. A., Wood, H. G., and Robinson, N. A. (1986) Biochem. Int. 12, 111-123).     

Polyphosphate kinase from Propionibacterium shermanii: formation of an enzymatically active insoluble complex with basic proteins and characterization of synthesized polyphosphate

Polyphosphate kinase, which catalyzes the synthesis of polyphosphate from ATP, has been partially purified from Propionibacterium shermanii. The reaction is unusual in that addition of basic protein causes the enzyme to precipitate and the insoluble form has optimal activity. The synthesized [32P]polyphosphate is non-covalently bound to the precipitated material and was isolated from the complex by proteolysis. The gel electrophoresis procedure of Maxam and Gilbert was adapted to sizing polyphosphates. When polyphosphate was treated with alkali, polyphosphates ranging from 1-100 phosphate residues were obtained as individual bands. The untreated enzymatically synthesized polyphosphate migrated as a species in excess of 200 phosphate moieties.     

Polyphosphate kinase from Propionibacterium shermanii. Demonstration that polyphosphates are primers and determination of the size of the synthesized polyphosphate

Polyphosphate kinase from Propionibacterium shermanii was purified to 70% homogeneity and shown to be a monomeric enzyme of molecular weight 83,000 +/- 3,000. It was demonstrated that short chains of polyphosphate serve as primers by using [32P]polyphosphate, 6-80 residues in length for synthesis of long-chain polyphosphate glucokinase, the radiolabel was found to be at the end of the polymer, proving that the mechanism of elongation of polyphosphate by polyphosphate kinase is strictly processive. Only 1 out of 3-8 of the polyphosphate chains contained the primer, indicating that there is a second unknown pathway of initiation which does not involve the polyphosphate primer. The termination of polyphosphate synthesis was investigated. With polyphosphate as a primer, the majority of the synthesized polyphosphate was 750 residues in length. With phosphate, in place of the polyphosphate primer, the major portion was about 2,000 residues in length but there was a large span of chain lengths down to 300. Termination is influenced by pH, temperature, and the concentration of the polyphosphate primer, with the chain length decreasing as either the temperature or the concentration of primer is increased.     

Polyphosphate glucokinase from Propionibacterium shermanii. Kinetics and demonstration that the mechanism involves both processive and nonprocessive type reactions

Polyphosphate glucokinase (EC 2.7.1.63, polyphosphate glucose phosphotransferase) has been partially purified (960-fold) from Propionibacterium shermanii. Throughout the purification, the ratio of polyphosphate glucokinase activity to ATP glucokinase activity remained approximately constant at 4 to 1. It is considered that both activities are catalyzed by the same protein. The mechanism of utilization of polyphosphate by polyphosphate glucokinase was investigated using polyphosphates of limited sizes that were isolated following gel electrophoresis of commercial heterogeneous polyphosphates. The results show that with long chain polyphosphates, the reaction proceeds by a processive type mechanism, and with short polyphosphates, it is nonprocessive. The Km for polyphosphate of chain length 724 is 2 X 10(-3) microM and increases with a decrease in chain length to 3.7 X 10(-2) microM at chain length 138. Subsequently, there is a very rapid increase of Km and at chain length 30 the Km is 4.3 microM. The rapid change in Km coincides with the shift in mechanism from the processive type mechanism in which there apparently is successive phosphorylation prior to release from the enzyme to a nonprocessive process in which the polyphosphate is released from the enzyme after each transfer. During the nonprocessive process, there is preferential utilization of the longer species. The Vmax is relatively constant with shorter polyphosphates but decreases with chain lengths longer than 347. In the cell, as a consequence of the low Km, the long chain polyphosphates probably are used preferentially to phosphorylate glucose.     

Polyphosphate kinase activity in yeast vacuoles]

The enzyme polyphosphate kinase (ATP: Polyphosphate phosphotransferase EC 2.7.4.1) relating to the class of transferases was detected in the vacuoles of Saccharomyces carlsbergensis yeast. The direct ATP: Polyphosphate phosphotransferase reaction resulting in the synthesis of polyphosphates from ATP was shown to occur mainly in vacuoles. The localization of the reverse polyphosphate: ADP phosphatransferase reaction was not established in any of the subcellular yeast fractions studied. The activity of the direct reaction in the yeast protoplasts makes up about 1% of the reverse one, but in vacuoles it is significantly higher and makes up to 19%. Under activation of biochemical processes involved in the production of cell wall components by protoplasts, vacuolar polyphosphates work mainly in the direction of ATP synthesis at the expense of polyphosphates accumulated in vacuoles.     

Polyphosphate binding and chain length recognition of Escherichia coli exopolyphosphatase

Exopolyphosphatase of Escherichia coli (PPX) is a highly processive enzyme demonstrating the ability to recognize polyphosphates of specific lengths. The mechanisms responsible for the processivity and polymer length recognition of the enzyme were investigated in relation to the manner in which polyphosphate is bound to the enzyme. Multiple polyphosphate binding sites were identified on distant portions of the enzyme and were determined to be responsible for the polymer length recognition of the enzyme. In addition, two independently folded domains were identified. The N-terminal domain contained a quasi-processive polyphosphatase active site belonging to the sugar kinase/actin/hsp70 superfamily. The C-terminal domain contained a single polyphosphate binding site and was responsible for nearly all of the PPX affinity for polyphosphate. This domain was also found to confer a highly processive mode of action to PPX. Collectively, these results were used to describe the interaction of polyphosphate with PPX.     

Basic amino acids and inorganic polyphosphates in Neurospora crassa: independent regulation of vacuolar pools

At least 78%, and perhaps all, of inorganic polyphosphate is shown to be contained within the vesicles (vacuoles) of Neurospora crassa, where over 97% of the soluble arginine, lysine, and ornithine pools are known to accumulate. Furthermore, synthetic polyphosphate can concentrate arginine up to 400-fold from dilute (0.01 mM) solutions in equilibrium dialysis. For these reasons and because the molar ratio of basic amino acids and polyphosphate phosphorus is approximately 1, we tested the hypothesis that there was an obligate physiological relationship between them. Experiments in which nitrogen starvation and arginine excess were imposed upon cells showed that polyphosphate content was insensitive to changes in the basic amino acid content. Experiments involving phosphate starvation and restoration showed that basic amino acid content was almost wholly independent of polyphosphate pools. Moreover, the normal high degree of compartmentation of arginine in vesicles was maintained despite polyphosphate depletion, and arginine was still exchanged across the vesicular membrane. We conclude that N. crassa, like yeasts, can regulate polyphosphates and basic amino acids independently, and that the accumulation of basic amino acids in vesicles may depend upon an energy-requiring mechanism in addition to the demonstrated charge interaction with polyphosphate.     

Effect of inhibitors on polyphosphate metabolism in the yeast Saccharomyces cerevisiae under hypercompensation conditions

After re-inoculation of the yeast Saccharomyces cerevisiae from phosphate-deficient to complete medium, the total content of polyphosphates increased tenfold during 2 h (hypercompensation), but the content of certain fractions increased differently. The content of acid-soluble polyphosphate increased to the maximal extent. The ratio of the activities of two exopolyphosphatases also changed in the cytosol. Activity of a low molecular weight exopolyphosphatase (40 kD) decreased almost twice, whereas activity of a high molecular weight exopolyphosphatase (830 kD) increased tenfold. Cycloheximide blocks the increase in activity of high molecular weight exopolyphosphatase and hence, under these conditions the latter is synthesized de novo. Inhibitors of energy metabolism and cycloheximide, an inhibitor of protein synthesis, differently influence accumulation of certain polyphosphate fractions under hypercompensation conditions. The effect of iodoacetamide, an inhibitor of glycolysis, on any fraction is negligible, while cycloheximide suppresses accumulation of only polyP4 fraction associated with the cell envelope and bafilomycin A1, an inhibitor of vacuolar H⁺-ATPase, suppresses accumulation of polyP3 fraction. The protonophore carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP) to variable extent inhibits accumulation of all the fractions. Analysis of the effect of inhibitors on accumulation of polyphosphates under hypercompensation conditions confirms various localization, heterogeneity, and multiplicity of the routes of biosynthesis of certain fractions of these macroergic phosphorus compounds and also suggests interrelation between their biosynthesis and the gradient of H⁺ electrochemical potential.     

Isolation and characterization of polyphosphates from the yeast cell surface

When cells of Saccharomyces fragilis are subjected to osmotic shock, they release a limited amount of inorganic polyphosphate into the medium, which represents about 10% of the total cellular content. The osmotic shock procedure causes no substantial membrane damage, as judged from the unimpaired cell viability, limited K⁺ leakage and low percentage of stained cells. It is therefore suggested that this polyphosphate fraction is localized outside the plasma membrane. The released polyphosphate fraction differs from the remaining cellular polyphosphates in two respects: the mean chain length of the shock-sensitive fraction is significantly higher than that of the total cellular polyphosphates and its metabolic turnover rate, subsequent to pulsing with [³²P]orthophosphate is much lower compared to the rest of the cellular polyphosphate. Incubation of intact cells with the anion exchange resin Dowex AG 1-X4 results in the release of high molecular weight polyphosphates. These results suggest that the osmotic shock-sensitive polyphosphate fraction has specific characteristics in both its cellular localization and metabolism.     

Are polyphosphates or phosphate esters prebiotic reagents?

It is widely held that there was a phosphate compound in prebiotic chemistry that played the role of adenosine triphosphate and that the first living organisms had ribose-phosphate in the backbone of their genetic material. However, there are no known efficient prebiotic synthesis of high-energy phosphates or phosphate esters. We review the occurrence of phosphates in Nature, the efficiency of the volcanic synthesis of P₄O₁₀, the efficiency of polyphosphate synthesis by heating phosphate minerals under geological conditions, and the use of high-energy organic compounds such as cyanamide or hydrogen cyanide. These are shown to be inefficient processes especially when the hydrolysis of the polyphosphates is taken into account. For example, if a whole atmosphere of methane or carbon monoxide were converted to cyanide which somehow synthesized polyphosphates quantitatively, the polyphosphate concentration in the ocean would still have been insignificant. We also attempted to find more efficient high-energy polymerizing agents by spark discharge syntheses, but without success. There may still be undiscovered robust prebiotic syntheses of polyphosphates, or mechanisms for concentrating them, but we conclude that phosphate esters may not have been constituents of the first genetic material. Phosphoanhydrides are also unlikely as prebiotic energy sources. Correspondence to: S.L. Miller     

Cloning and characterization of polyphosphate kinase and exopolyphosphatase genes from Pseudomonas aeruginosa 8830

Pseudomonas aeruginosa accumulates polyphosphates in response to nutrient limitations. To elucidate the function of polyphosphate in this microorganism, we have investigated polyphosphate metabolism by isolating from P. aeruginosa 8830 the genes encoding polyphosphate kinase (PPK) and exopolyphosphatase (PPX), which are involved in polyphosphate synthesis and degradation, respectively. The 690- and 506-amino-acid polypeptides encoded by the two genes have been expressed in Escherichia coli and purified, and their activities have been tested in vitro. Gene replacement was used to construct a PPK-negative strain of P. aeruginosa 8830. Low residual PPK activity in the ppk mutant suggests a possible alternative pathway of polyphosphate synthesis in this microorganism. Primer extension analysis indicated that ppk is transcribed from a sigmaE-dependent promoter, which could be responsive to environmental stresses. However, no coregulation between ppk and ppx promoters has been demonstrated in response to osmotic shock or oxidative stress.     

Diphosphoinositol polyphosphates: what are the mechanisms?

In countries where adulthood is considered to be attained at age eighteen, 2011 can be the point at which the diphosphoinositol polyphosphates might formally be described as "coming of age", since these molecules were first fully defined in 1993 (Menniti et al., 1993; Stephens et al., 1993b). But from a biological perspective, these polyphosphates cannot quite be considered to have matured into the status of being independently-acting intracellular signals. This review has discussed several of the published proposals for mechanisms by which the diphosphoinositol polyphosphates might act. We have argued that all of these hypotheses need further development.We also still do not know a single molecular mechanism by which a change in the levels of a particular diphosphoinositol polyphosphate can be controlled. Yet, despite all these gaps in our understanding, there is an enduring anticipation that these molecules have great potential in the signaling field. Reflecting our expectations of all teenagers, it should be our earnest hope that in the near future the diphosphoinositol polyphosphates will finally grow up.     

Isolation and certain features of a polyphosphate phosphohydrolase deficient mutant of the fungus Neurospora crassa

A polyphosphatase deficient mutant of Neurospora crassa has been isolated. The criterion for selecting the mutant was the capacity of the fungus to assimilate polyphosphates as the source of exogenous phosphorus. The mutant like the parent strain ad-6, was an adenine auxotroph but differed from the parent strain by a lower growth rate though, at the stationary stage, its biomass reached the same level as in the strain ad-6. The character of changes in the activity of polyphosphatase in the course of growth was the same in the two cultures, but the activity of the enzyme in the mutant was considerably lower at all the growth stages. The content of polyphosphate fractions with the highest molecular weight increased twofold in the mutant culture. These data suggest that there is a close metabolic and topographic correlation between polyphosphatase and the highest molecular weight fractions of polyphosphates in N. crassa.     

Novel method for enzymatic synthesis of CMP-NeuAc

A novel method for synthesizing CMP-NeuAc was established. We first confirmed that the putative neuA gene of Haemophilus influenzae, identified by its whole genome sequence project, indeed encodes CMP-NeuAc synthetase (EC 2.7.7.43). The enzyme requires CTP as a cytidylyl donor for cytidylylation of NeuAc. The enzyme was coupled with an enzymatic CTP-generating system from CMP and inorganic polyphosphate as a sole phospho-donor driven by the combination of polyphosphate kinase and CMP kinase, where phosphorylation of CMP is done by the combined activity expressed by both enzymes, and subsequent phosphorylation of CDP by polyphosphate kinase itself occurred efficiently. When CMP-NeuAc synthetase of H. influenzae, polyphosphate kinase, and CMP kinase were added to the reaction mixture containing equimolar concentrations (15 mM) of CMP and NeuAc, and polyphosphate (150 mM in terms of phosphate), CMP-NeuAc was synthesized up to 10 mM in 67% yield.     

Properties of polyphosphatase ofAcinetobacter johnsonii 210A

Polyphosphatase, an enzyme which hydrolyses highly polymeric polyphosphates to P_i, was purified 77-fold fromAcinetobacter johnsonii 210A by Q-Sepharose, hydroxylapatite and Mono-Q column chromatography. The native molecular mass estimated by gel filtration and native gel electrophoresis was 55 kDa. SDS-polyacrylamide gel electrophoresis indicated that polyphosphatase ofAcinetobacter johnsonii 210A is a monomer. The enzyme was specific for highly polymeric polyphosphates and showed no activity towards pyrophosphate and organic phosphate esters. The enzyme was inhibited by iodoacetamide and in the presence of 10 mM Mg²⁺ by pyro- and triphosphate. The apparent K_m-value for polyphosphate with an average chain length of 64 residues was 5.9 µM and for tetraphosphate 1.2 mM. Polyphosphate chains were degraded to short chain polymers by a processive mechanism. Polyphosphatase activity was maximal in the presence of Mg²⁺ and K⁺.     

The development of A. N. Belozersky's ideas in polyphosphate biochemistry

This review covers some trends and approaches to the study of inorganic polyphosphates that originated from the fruitful ideas and pioneering works of A. N. Belozersky. This is, first of all, the elucidation of a close relationship between these biopolymers and nucleic acids in organisms at different evolutionary stages; second, the study of "fossil" reactions in polyphosphate metabolism that permit an understanding of their role in the evolution of phosphorus turnover and cell bioenergetics; third, the possible use of the conservative enzymes of polyphosphate metabolism, e.g., exopolyphosphatases, as molecular chronometers for obtaining additional data concerning the theory of the endosymbiotic origin of eukaryotic cells from prokaryotes.     

Nuclear polyphosphate as a possible source of energy during the sporulation of Physarum polycephalum

31P NMR spectroscopic analysis of the polyphosphate pool in cellular and nuclear extracts of Physarum polycephalum demonstrates that plasmodia and cysts contain inorganic polyphosphates with an average chain length of about 100 phosphates. However, only during sporulation are these high-molecular-weight polyphosphates degraded to a lower molecular weight corresponding to an average chain length of about 10 phosphates. Since polyphosphates are degraded even in the presence of a sufficiently large pool of inorganic phosphate, produced by intracellular injection, we conclude that the degradation of polyphosphates serves in supplying energy for biosynthesis during sporulation rather than in increasing the availability of phosphate.     

Regulation of ppk expression and in vivo function of Ppk in Streptomyces lividans TK24

The ppk gene of Streptomyces lividans encodes an enzyme catalyzing, in vitro, the reversible polymerization of the gamma phosphate of ATP into polyphosphate and was previously shown to play a negative role in the control of antibiotic biosynthesis (H. Chouayekh and M. J. Virolle, Mol. Microbiol. 43:919-930, 2002). In the present work, some regulatory features of the expression of ppk were established and the polyphosphate content of S. lividans TK24 and the ppk mutant was determined. In Pi sufficiency, the expression of ppk was shown to be low but detectable. DNA gel shift experiments suggested that ppk expression might be controlled by a repressor using ATP as a corepressor. Under these conditions, short acid-soluble polyphosphates accumulated upon entry into the stationary phase in the wild-type strain but not in the ppk mutant strain. The expression of ppk under Pi-limiting conditions was shown to be much higher than that under Pi-sufficient conditions and was under positive control of the two-component system PhoR/PhoP. Under these conditions, the polyphosphate content of the cell was low and polyphosphates were reproducibly found to be longer and more abundant in the ppk mutant strain than in the wild-type strain, suggesting that Ppk might act as a nucleoside diphosphate kinase. In light of our results, a novel view of the role of this enzyme in the regulation of antibiotic biosynthesis in S. lividans TK24 is proposed.     

The inositol hexakisphosphate kinase family. Catalytic flexibility and function in yeast vacuole biogenesis

Saiardi et al. (Saiardi, A., Erdjument-Bromage, H., Snowman, A., Tempst, P., and Snyder, S. H. (1999) Curr. Biol. 9, 1323-1326) previously described the cloning of a kinase from yeast and two kinases from mammals (types 1 and 2), which phosphorylate inositol hexakisphosphate (InsP(6)) to diphosphoinositol pentakisphosphate, a "high energy" candidate regulator of cellular trafficking. We have now studied the significance of InsP(6) kinase activity in Saccharomyces cerevisiae by disrupting the kinase gene. These ip6kDelta cells grew more slowly, their levels of diphosphoinositol polyphosphates were 60-80% lower than wild-type cells, and the cells contained abnormally small and fragmented vacuoles. Novel activities of the mammalian and yeast InsP(6) kinases were identified; inositol pentakisphosphate (InsP(5)) was phosphorylated to diphosphoinositol tetrakisphosphate (PP-InsP(4)), which was further metabolized to a novel compound, tentatively identified as bis-diphosphoinositol trisphosphate. The latter is a new substrate for human diphosphoinositol polyphosphate phosphohydrolase. Kinetic parameters for the mammalian type 1 kinase indicate that InsP(5) (K(m) = 1.2 micrometer) and InsP(6) (K(m) = 6.7 micrometer) compete for phosphorylation in vivo. This is the first time a PP-InsP(4) synthase has been identified. The mammalian type 2 kinase and the yeast kinase are more specialized for the phosphorylation of InsP(6). Synthesis of the diphosphorylated inositol phosphates is thus revealed to be more complex and interdependent than previously envisaged.     

The metabolic properties of acid soluble polyphosphates in Saccharomyces cerevisiae

Summary Tripolyphosphate was found to be the predominant species of soluble polyphosphate in yeast. Evidence is presented which shows that under normal growth conditions tripolyphosphate had little or no turnover. The amounts of the various polyphosphates decreased as the chain length increased. Tetrapolyphosphate was shown to be synthesized more rapidly than tripolyphosphate. These observations suggest that short chain polyphosphates arise by degradation of longer chain length polyphosphates with tripolyphosphate the ultimate degradation product.During nitrogen starvation, the normal accumulation of tripolyphosphate rapidly ceased even though the cells continued normal growth for at least two hours. After the addition of L-amino acids or (NH₄)₂SO₄ to nitrogen starved cells, there was a dramatic increase in the accumulation of tripolyphosphate and tetrapolyphosphate which occurred at the same time as the increase in growth rate. Implications of this result are discussed in terms of possible functions of polyphosphate.