Inorganic polyphosphate and polyphosphate kinase: their novel biological functions and applications

In this review, we discuss the following two subjects: 1) the physiological function of polyphosphate (poly(P)) as a regulatory factor for gene expression in Escherichia coli, and 2) novel functions of E. coli polyphosphate kinase (PPK) and their applications. With regard to the first subject, it has been shown that E. coli cells in which yeast exopolyphosphatase (poly(P)ase), PPX1, was overproduced reduced resistance to H2O2 and heat shock as did a mutant whose polyphosphate kinase gene is disrupted. Sensitivity to H2O2 and heat shock evinced by cells that overproduce PPX1 is attributed to depressed levels of rpoS expression. Since rpoS is a central element in a regulatory network that governs the expression of stationary-phase-induced genes, poly(P) affects the expression of many genes through controlling rpoS expression. Furthermore, poly(P) is also involved in expression of other stress-inducible genes that are not directly regulated by rpoS. The second subject includes the application of novel functions of PPK for nucleoside triphosphate (NTP) regeneration. Recently E. coli PPK has been found to catalyze the kination of not only ADP but also other nucleoside diphosphates using poly(P) as a phospho-donor, yielding NTPs. This nucleoside diphosphate kinase-like activity of PPK was confirmed to be available for NTP regeneration essential for enzymatic oligosaccharide synthesis using the sugar nucleotide cycling method. PPK has also been found to express a poly(P):AMP phosphotransferase activity by coupling with adenylate kinase (ADK) in E. coli. The ATP-regeneration system consisting of ADK, PPK, and poly(P) was shown to be promising for practical utilization of poly(P) as ATP substitute.     

Polyphosphate kinase of Acinetobacter sp. strain ADP1: purification and characterization of the enzyme and its role during changes in extracellular phosphate levels.

Polyphosphate (polyP) is a ubiquitous biopolymer whose function and metabolism are incompletely understood. The polyphosphate kinase (PPK) of Acinetobacter sp. strain ADP1, an organism that accumulates large amounts of polyP, was purified to homogeneity and characterized. This enzyme, which adds the terminal phosphate from ATP to a growing chain of polyP, is a 79-kDa monomer. PPK is sensitive to magnesium concentrations, and optimum activity occurs in the presence of 3 mM MgCl(2). The optimum pH was between pH 7 and 8, and significant reductions in activity occurred at lower pH values. The greatest activity occurred at 40 degrees C. The half-saturation ATP concentration for PPK was 1 mM, and the maximum PPK activity was 28 nmol of polyP monomers per microg of protein per min. PPK was the primary, although not the sole, enzyme responsible for the production of polyP in Acinetobacter sp. strain ADP1. Under low-phosphate (P(i)) conditions, despite strong induction of the ppk gene, there was a decline in net polyP synthesis activity and there were near-zero levels of polyP in Acinetobacter sp. strain ADP1. Once excess phosphate was added to the P(i)-starved culture, both the polyP synthesis activity and the levels of polyP rose sharply. Increases in polyP-degrading activity, which appeared to be mainly due to a polyphosphatase and not to PPK working in reverse, were detected in cultures grown under low-P(i) conditions. This activity declined when phosphate was added.     

Immobilized polyphosphate kinase: preparation, properties, and potential for use in adenosine 5'-triphosphate regeneration

Polyphosphate kinase (ATP:polyphosphate phosphotransferase; EC 2.7.4.1), partially purified from Escherichia coli, has been immobilized on glutaraldehyde-activated aminoethyl cellulose with a 10% retention of enzymatic activity. The immobilized enzyme can carry out the synthesis of ATP from ADP, using long-chain inorganic polyphosphate as a phosphoryl donor. Chromatographic analyses of the product mixture produced from ADP and [32P]polyphosphate demonstrated that 98% of the 32P was incorporated into ATP, indicating that the immobilized polyphosphate kinase is substantially free from contaminating polyphosphate phosphohydrolase (EC 3.6.1.11), adenosine triphosphatase (EC 3.6.1.4), and adenylate kinase (EC 2.7.4.3). Immobilized polyphosphate kinase loses no activity when stored in an aqueous suspension for 2 months at 5 degrees C or for 1-2 weeks at 25 degrees C. It may be stored indefinitely as a lyophilized powder at -10 degrees C. Michaelis constants for ADP and polyphosphate were determined to be 160 and 120 microM, respectively, for the immobilized enzyme. A small-batch reactor was found to produce ATP linearly with time up to 65% conversion of polyphosphate into ATP and to attain greater than 85% conversion to ATP at equilibrium. The ease of purification and immobilization of E. coli polyphosphate kinase, its storage stability, the purity and yield of its ATP product, and the low values of the Michaelis constants for its substrates make it a highly promising enzyme for ATP regeneration.     

Polyphosphate Kinase of Acinetobacter sp. Strain ADP1: Purification and Characterization of the Enzyme and Its Role during Changes in Extracellular Phosphate Levels

Polyphosphate (polyP) is a ubiquitous biopolymer whose function and metabolism are incompletely understood. The polyphosphate kinase (PPK) of Acinetobacter sp. strain ADP1, an organism that accumulates large amounts of polyP, was purified to homogeneity and characterized. This enzyme, which adds the terminal phosphate from ATP to a growing chain of polyP, is a 79-kDa monomer. PPK is sensitive to magnesium concentrations, and optimum activity occurs in the presence of 3 mM MgCl₂. The optimum pH was between pH 7 and 8, and significant reductions in activity occurred at lower pH values. The greatest activity occurred at 40°C. The half-saturation ATP concentration for PPK was 1 mM, and the maximum PPK activity was 28 nmol of polyP monomers per μg of protein per min. PPK was the primary, although not the sole, enzyme responsible for the production of polyP in Acinetobacter sp. strain ADP1. Under low-phosphate (P_i) conditions, despite strong induction of the ppk gene, there was a decline in net polyP synthesis activity and there were near-zero levels of polyP in Acinetobacter sp. strain ADP1. Once excess phosphate was added to the P_i-starved culture, both the polyP synthesis activity and the levels of polyP rose sharply. Increases in polyP-degrading activity, which appeared to be mainly due to a polyphosphatase and not to PPK working in reverse, were detected in cultures grown under low-P_i conditions. This activity declined when phosphate was added.     

The multiple activities of polyphosphate kinase of Escherichia coli and their subunit structure determined by radiation target analysis

Polyphosphate kinase (PPK), the principal enzyme required for the synthesis of inorganic polyphosphate (polyP) from ATP, also exhibits other enzymatic activities, which differ significantly in their biochemical optima and responses to chemical agents. These several activities include: polyP synthesis (forward reaction), nATP --> polyP(n) + nADP (Equation 1); ATP synthesis from polyP (reverse reaction), ADP + polyP(n) --> ATP + polyP(n - 1) (Equation 2); general nucleoside-diphosphate kinase, GDP + polyP(n) --> GTP + polyP(n - 1) (Equation 3); linear guanosine 5'-tetraphosphate (ppppG) synthesis, GDP + polyP(n) --> ppppG + polyP(n - 2) (Equation 4); and autophosphorylation, PPK + ATP --> PPK-P + ADP (Equation 5). The Mg(2+) optima are 5, 2, 1, and 0.2 mM, respectively, for the activities in Equations 1, 2, 3, and 4. Inorganic pyrophosphate inhibits the activities in Equations 1 and 3 but stimulates that in Equation 4. The kinetics of the activities in Equations 1, 2, and 3 are highly processive, whereas the transfer of a pyrophosphoryl group from polyP to GDP (Equation 4) is distributive and demonstrates a rapid equilibrium, random Bi-Bi catalytic mechanism. Radiation target analysis revealed that the principal functional unit of the homotetrameric PPK is a dimer. Exceptions are a trimer for the synthesis of ppppG (Equation 4) and a tetrameric state for the autophosphorylation of PPK (Equation 5) at low ATP concentrations. Thus, the diverse functions of this enzyme involve different subunit organizations and conformations. The highly conserved homology of PPK among 18 microorganisms was used to determine important residues and conserved regions by alanine substitution, by site-directed mutagenesis, and by deletion mutagenesis. Of 46 single-site mutants, seven exhibit none of the five enzymatic activities; in one mutant, ATP synthesis from polyP is reduced relative to GTP synthesis. Among deletion mutants, some lost all five PPK activities, but others retained partial activity for some reactions but not for others.     

Polyphosphate:AMP phosphotransferase as a polyphosphate-dependent nucleoside monophosphate kinase in Acinetobacter johnsonii 210A

We have cloned the gene for polyphosphate:AMP phosphotransferase (PAP), the enzyme that catalyzes phosphorylation of AMP to ADP at the expense of polyphosphate [poly(P)] in Acinetobacter johnsonii 210A. A genomic DNA library was constructed in Escherichia coli, and crude lysates of about 6,000 clones were screened for PAP activity. PAP activity was evaluated by measuring ATP produced by the coupled reactions of PAP and purified E. coli poly(P) kinases (PPKs). In this coupled reaction, PAP produces ADP from poly(P) and AMP, and the resulting ADP is converted to ATP by PPK. The isolated pap gene (1,428 bp) encodes a protein of 475 amino acids with a molecular mass of 55.8 kDa. The C-terminal region of PAP is highly homologous with PPK2 homologs isolated from Pseudomonas aeruginosa PAO1. Two putative phosphate-binding motifs (P-loops) were also identified. The purified PAP enzyme had not only strong PAP activity but also poly(P)-dependent nucleoside monophosphate kinase activity, by which it converted ribonucleoside monophosphates and deoxyribonucleoside monophosphates to ribonucleoside diphosphates and deoxyribonucleoside diphosphates, respectively. The activity for AMP was about 10 times greater than that for GMP and 770 and about 1,100 times greater than that for UMP and CMP.     

Membrane bound and soluble adenosine triphosphatase of Escherichia coli K 12. kinetic properties of the basal and trypsin-stimulated activities

Basal and trypsin-stimulated adenosine triphosphatase activities of Escherichia coli K 12 have been characterized at pH 7.5 in the membrane-bound state and in a soluble form of the enzyme. The saturation curve for Mg2+/ATP = 1/2 was hyperbolic with the membrane-bound enzyme and sigmoidal with the soluble enzyme. Trypsin did not modify the shape of the curves. The kinetic parameters were for the membrane-bound ATPase: apparent Km = 2.5 mM, Vmax (minus trypsin) = 1.6 mumol-min-1-mg protein-1, Vmax (plus trypsin) = 2.44 mumol-min-1-mg protein-1; for the soluble ATPase: [S0.5] = 1.2 mM, Vmax (-trypsin) = 4 mumol-min-1-mg protein-1; Vmax (+ trypsin) = 6.6 mumol-min-1-mg protein-1. Hill plot analysis showed a single slope for the membrane-bound ATPase (n = 0.92) but two slopes were obtained for the soluble enzyme (n = 0.98 and 1.87). It may suggest the existence of an initial positive cooperativity at low substrate concentrations followed by a lack of cooperativity at high ATP concentrations. Excess of free ATP and Mg2+ inhibited the ATPase but excess of Mg/ATP (1/2) did not. Saturation for ATP at constant Mg2+ concentration (4 mM) showed two sites (groups) with different Kms: at low ATP the values were 0.38 and 1.4 mM for the membrane-bound and soluble enzyme; at high ATP concentrations they were 17 and 20 mM, respectively. Mg2+ saturation at constant ATP (8 mM) revealed michealian kinetics for the membrane-bound ATPase and sigmoid one for the protein in soluble state. When the ATPase was assayed in presence of trypsin we obtained higher Km values for Mg2+. These results might suggest that trypsin stimulates E. coli ATPase by acting on some site(s) involved in Mg2+ binding. Adenosine diphosphate and inorganic phosphate (Pi) act as competitive inhibitors of Escherichia coli ATPase. The Ki values for Pi were 1.6 +/- 0.1 mM for the membrane-bound ATPase and 1.3 +/- 0.1 mM for the enzyme in soluble form, the Ki values for ADP being 1.7 mM and 0.75 mM for the membrane-bound and soluble ATPase, respectively. Hill plots of the activity of the soluble enzyme in presence of ADP showed that ADP decreased the interaction coefficient at ATP concentrations below its Km value. Trypsin did not modify the mechanism of inhibition or the inhibition constants. Dicyclohexylcarbodiimide (0.4 mM) inhibited the membrane-bound enzyme by 60-70% but concentrations 100 times higher did not affect the residual activity nor the soluble ATPase. This inhibition was independent of trypsin. Sodium azide (20 muM) inhibited both states of E. coli ATPase by 50%. Concentrations 25-fold higher were required for complete inhibition. Ouabain, atebrin and oligomycin did not affect the bacterial ATPase.     

The (Na + K)-dependent ATPase: mode of inhibition of ADP/ATP exchange activity by MgCl2

Na⁺-dependent ADP/ATP exchange activity, of a (Na⁺ + K⁺)-dependent ATPase preparation from eel electric organ, was measured in terms of the incorporation of ¹⁴C into ATP during incubations with unlabeled ATP and [¹⁴C]ADP. Estimates of initial rates of exchange were possible by keeping changes in nucleotide concentrations, from both exchange and extraneous hydrolytic processes, to less than 10%. Under these conditions, increases in MgCl₂ concentration, from 0.2 to 3 mM, generally inhibited this exchange activity. The concentrations of free Mg²⁺, Mg · ATP, and Mg · ADP present, with a range of MgCl₂, ATP, and ADP concentrations, were calculated from measured dissociation constants. Inhibition was associated with Mg · ATP as well as with Mg²⁺, at concentrations from 0.4 to 1 mM (Mg · ADP, in the same concentration range, probably inhibited also). The affinity of the enzyme for these inhibitors is in fair correspondence with demonstrated affinities for Mg²⁺, Mg · ATP, and Mg · ADP at low affinity substrate sites, measured kinetically. These observations are considered in terms of a dimeric enzyme with high and low affinity substrates sites: ADP/ATP exchange being catalyzed at the high affinity sites, with inhibition occurring through occupancy by Mg²⁺, Mg · ATP, or Mg · ADP, of the low affinity sites, thereby pulling the reaction process away from those steps involved in exchange.     

Polyphosphate kinase from Escherichia coli. Purification and demonstration of a phosphoenzyme intermediate

Polyphosphate kinase (PPK) polymerizes the terminal phosphate of ATP to a long chain polyphosphate (poly(P) or (Pi)n) in a freely reversible reaction (Kornberg, S. R. (1957) Biochim. Biophys. Acta 26, 294-300), nATP in equilibrium nADP + (Pi)n, PPK, now purified to homogeneity, is a tetramer of 69-kDa subunits. Addition of a primer in the synthetic reaction is not required, nor does ATP or inorganic orthophosphate (Pi) serve in this role. PPK is autophosphorylated under the conditions of poly(P) synthesis; Pi is linked by a nitrogen-phosphate bond as judged by its acid lability and alkali stability. Incorporation of phosphate from the isolated phosphoenzyme into poly(P) upon the addition of ATP in the synthetic reaction and its incorporation into ATP upon the addition of ADP indicate phosphoenzyme to be an intermediate in the reaction. At an ATP level of 5 microM, well below its Km of 2 mM, a pronounced lag in poly(P) synthesis can be removed by tetrapolyphosphate but not by Pi, PPi, or tripolyphosphate. The basis for this stimulatory effect is not clear inasmuch as tetrapolyphosphate does not promote the dephosphorylation of the presumed phosphoenzyme intermediate.     

Studies of energy transport in heart cells. Mitochondrial isoenzyme of creatine phosphokinase: kinetic properties and regulatory action of Mg2+ ions.

1. The kinetic properties of mitochondrial creatine phosphokinase (Km for all substrates and maximal rates of the forward and reverse reaction) have been studied. Since (a) Km value for MgADP- (0.05 mM) and creatine phosphate (0.5 mM) are significantly lower than Km for MgATP2- (0.7 mM) and creatine (5.0 mM) and (b) maximal rate of the reverse reaction (creatine phosphate + ADP leads to ATP + creatine) equal to 3.5 mumol times min-1 times mg-1 is essentially higher than maximal rate of the forward reaction (0.8 mumol times min-1 times mg-1), ATP synthesis from ADP and creatine phosphate is kinetically preferable over the forward reaction. 2. A possible regulatory role of Mg2+ ions in the creatine phosphokinase reaction has been tested. It has been shown that in the presence of all substrates and products of the reaction the ratio of the rates of forward and reverse reactions can be effectively regulated by the concentration of Mg2+ ions. At limited Mg2+ concentrations creatine phosphate is preferably synthesized while at high Mg2+ concentrations (more ATP in the reaction medium) ATP synthesis takes place. 3. The kinetic (mathematical) model of the mitochondrial creatine phosphokinase reaction has been developed. This model accounts for the existence of a variety of molecular forms of adenine nucleotides in solution and the formation of their complexes with magnesium. It is based on the assumption that the mitochondrial creatine phosphokinase reactions mechanism is analogous to that for soluble isoenzymes. 4. The dependence of the overall rate of the creatine phosphokinase reaction on the concentration of total Mg2+ ions calculated from the kinetic model quantitatively correlates with the experimentally determined dependence through a wide range of substrates (ATP, ADP, creatine and creatine phosphate) concentration. The analysis of the kinetic model demonstrates that the observed regulatory effect of Mg2+ on the overall reaction rate can be expained by (a) the sigmoidal variation in the concentration of the MgADP- complex resulting from the competition between ATP AND ADP for Mg2+ and (b) the high affinity of the enzyme to MgADP-. 5. The results predicted by the model for the behavior of mitochondrial creatine phosphokinase under conditions of oxidative phosphorylation point to an intimate functional interaction of mitochondrial creatine phosphokinase and ATP-ADP translocase.     

Characterization of the phosphorylated intermediate of the K+-translocating Kdp-ATPase from Escherichia coli

During ATP hydrolysis the K+-translocating Kdp-ATPase from Escherichia coli forms a phosphorylated intermediate as part of the catalytic cycle. The influence of effectors (K+, Na+, Mg2+, ATP, ADP) and inhibitors (vanadate, N-ethylmaleimide, bafilomycin A1) on the phosphointermediate level and on the ATPase activity was analyzed in purified wild-type enzyme (apparent Km = 10 microM) and a KdpA mutant ATPase exhibiting a lower affinity for K+ (Km = 6 mM). Based on these data we propose a minimum reaction scheme consisting of (i) a Mg2+-dependent protein kinase, (ii) a Mg2+-dependent and K+-stimulated phosphoprotein phosphatase, and (iii) a K+-independent basal phosphoprotein phosphatase. The findings of a K+-uncoupled basal activity, inhibition by high K+ concentrations, lower ATP saturation values for the phosphorylation than for the overall ATPase reaction, and presumed reversibility of the phosphoprotein formation by excess ADP indicated similarities in fundamental principles of the reaction cycle between the Kdp-ATPase and eukaryotic E1E2-ATPases. The phosphoprotein was tentatively characterized as an acylphosphate on the basis of its alkali-lability and its sensitivity to hydroxylamine. The KdpB polypeptide was identified as the phosphorylated subunit after electrophoretic separation at pH 2.4, 4 degrees C of cytoplasmic membranes or of purified ATPase labeled with [gamma-32P]ATP.     

幽门螺杆菌PPK 的纯化与功能分析*

目的:表达纯化幽门螺杆菌多聚磷酸激酶,并测定其功能。方法:将幽门螺杆菌多聚磷酸激酶基因克隆入原核表达载体PQE80L中,在大肠杆菌(E.coli)DH5-α中表达。用BD Talon resin纯化目的蛋白。并在体外测定其合成多聚磷酸盐及转化多聚磷酸盐至ATP的能力。结果:成功构建了原核表达载体,得到高表达量的融合蛋白。经BD Talon resin纯化获得较高纯度的His-多聚磷酸激酶N端融合蛋白。体外实验证实该酶可以有效合成不同链长的多聚磷酸盐,并且在适当条件下可将多聚磷酸盐转化为ATP。结论:利用原核表达载体可很好表达幽门螺杆菌多聚磷酸激酶,纯化后的蛋白具有良好生物活性,是一个具备合成多聚磷酸盐及转化其为ATP的双向功能的酶。     

Adenylate kinase of plants. Properties of adenylate kinase of pea leaves]

The properties of adenylate kinase in 2 ADP in equilibrium ATP + AMP reaction have been studied. The dependence of the enzyme activity on medium pH, protein concentration, substrates, Mg++ ions, AMP, adenine and adenosine has been also investigated. pH optimum is found to be 8.5 for forward reaction and 8-9--for the reverse one. The Michaelis constants are as follows: for ADP--1.17-10(-4) M, for ATP--3.33-10(-4) M at 24 degrees C, in 50 mM tris-HCl pH 7.6. The optimal ratio, Mg++ ions/substrates (ADP, ATP + AMP), is 1:2. The chelates of adenine nucleotides with Mg++ ions are proved to be "true" reaction substrates. Unlike adenine and adenosine, the product of AMP reaction inhibits adenylate kinase activity. It is concluded that the properties of adenylate kinase in plants are similar to those of animals and humans (moikinase).     

Desensitization to Mg2+ of the phosphoenzyme in sarcoplasmic reticulum Ca2+-ATPase by the addition of a nonionic detergent and the restoration of sensitivity after its removal

Sarcoplasmic reticulum (SR) membranes from rabbit skeletal muscle were solubilized with a high concentration of dodecyl octaethyleneglycol monoether (C12E8) and the kinetic properties of the Ca2+,Mg2+-dependent ATPase [EC 3.6.1.3] were studied. The following results were obtained: 1. SR ATPase solubilized in C12E8 retains high ability to form phosphoenzyme ([EP] = 4--5 mol/10(6) g protein) for at least two days in the presence of 5 mM Ca2+, 0.5 M KCl, and 20% glycerol at pH 7.55. 2. The ATPase activity was dependent on both Mg2+ and Ca2+. However, the rate of E32P decay after the addition of unlabeled ATP was independent of Mg2+. 3. Most of the EP formed in the absence of Mg2+ was capable of reacting with ADP to form ATP in the backward reaction. However, in the presence of 5 mM Mg2+, the amount of ATP formed was markedly reduced without loss of the reactivity of the EP with ADP. 4. The removal of C12E8 from the ATPase by the use of Bio-Beads resulted in the full restoration of the Mg2+ dependency of the EP decomposition. 5. These results strongly suggest that in the case of SR solubilized with a high concentration of C12E8 the decomposition of phosphoenzyme is Mg2+ independent and ATP is mainly hydrolyzed through Mg2+-dependent decomposition of an enzyme-ATP complex, which is in equilibrium with phosphoenzyme and ADP.     

Different chain length specificity among three polyphosphate quantification methods

Polyphosphate is ubiquitous among living organisms and has a variety of biochemical functions. Arbuscular mycorrhizal fungi have been known to accumulate polyphosphate as a key compound for their function. However, an enzymatic assay using polyphosphate kinase (PPK) reverse reaction, in which polyphosphate is converted to adenosine triphosphate (ATP) and quantified by luciferase assay, failed to detect accumulation of polyphosphate in some mycorrhizal root. When yeast exopolyphosphatase (PPX) was applied to these samples, a much higher polyphosphate level was detected than when the PPK assay was applied. Detailed analysis of substrate chain length specificity of these methods using polyphosphate chain length standards revealed that the PPX method was the most appropriate to detect short-chain polyphosphate. The average chain length of the shortest polyphosphate fraction that could be quantified with more than 50% efficiency was 3 for the PPX method and 38 for the PPK method. It was also suggested that the ratio of the PPK value to the PPX value may be useful as a simple and relative index to compare polyphosphate chain length distribution in different samples.     

In vitro ATP regeneration from polyphosphate and AMP by polyphosphate:AMP phosphotransferase and adenylate kinase from Acinetobacter johnsonii 210A

In vitro enzyme-based ATP regeneration systems are important for improving yields of ATP-dependent enzymatic reactions for preparative organic synthesis and biocatalysis. Several enzymatic ATP regeneration systems have been described but have some disadvantages. We report here on the use of polyphosphate:AMP phosphotransferase (PPT) from Acinetobacter johnsonii strain 210A in an ATP regeneration system based on the use of polyphosphate (polyP) and AMP as substrates. We have examined the substrate specificity of PPT and demonstrated ATP regeneration from AMP and polyP using firefly luciferase and hexokinase as model ATP-requiring enzymes. PPT catalyzes the reaction polyP(n) + AMP --> ADP + polyP(n-1). The ADP can be converted to ATP by adenylate kinase (AdK). Substrate specificity with nucleoside and 2'-deoxynucleoside monophosphates was examined using partially purified PPT by measuring the formation of nucleoside diphosphates with high-pressure liquid chromatography. AMP and 2'-dAMP were efficiently phosphorylated to ADP and 2'-dADP, respectively. GMP, UMP, CMP, and IMP were not converted to the corresponding diphosphates at significant rates. Sufficient AdK and PPT activity in A. johnsonii 210A cell extract allowed demonstration of polyP-dependent ATP regeneration using a firefly luciferase-based ATP assay. Bioluminescence from the luciferase reaction, which normally decays very rapidly, was sustained in the presence of A. johnsonii 210A cell extract, MgCl(2), polyP(n=35), and AMP. Similar reaction mixtures containing strain 210A cell extract or partially purified PPT, polyP, AMP, glucose, and hexokinase formed glucose 6-phosphate. The results indicate that PPT from A. johnsonii is specific for AMP and 2'-dAMP and catalyzes a key reaction in the cell-free regeneration of ATP from AMP and polyP. The PPT/AdK system provides an alternative to existing enzymatic ATP regeneration systems in which phosphoenolpyruvate and acetylphosphate serve as phosphoryl donors and has the advantage that AMP and polyP are stabile, inexpensive substrates.     

ATP amplification for ultrasensitive bioluminescence assay: detection of a single bacterial cell

We developed an ultrasensitive bioluminescence assay of ATP by employing (i) adenylate kinase (ADK) for converting AMP + ATP to two molecules of ADP, (ii) polyphosphate (polyP) kinase (PPK) for converting ADP back to ATP (ATP amplification), and (iii) a commercially available firefly luciferase. A highly purified PPK-ADK fusion protein efficiently amplified ATP, resulting in high levels of bioluminescence in the firefly luciferase reaction. The present method, which was approximately 10,000-fold more sensitive to ATP than the conventional bioluminescence assay, allowed us to detect bacterial contamination as low as one colony-forming unit (CFU) of Escherichia coli per assay.     

25Mg NMR studies of magnesium binding to erythrocyte constituents.

The binding of Mg2+ ion to ATP, ADP, AMP, 2,3-bisphosphyoglycerate (DPG), and hemoglobin has been studied by 25Mg NMR spectroscopy at 9.4 T. Addition of any of these ligands to a solution of 2 mM 25MgCl2 at pH 7.2 caused a progressive increase in linewidth, with no discernible chemical shift. ATP and ADP, which form tight 1:1 complexes with Mg2+, did not cause maximal broadening until present in several-fold excess, implying that bis(nucleotide) complexes also form. The studies showed progressively weaker Mg2+ binding to ATP, ADP, DPG, and AMP, consistent with published binding constants. Hemoglobin cause fairly little broadening, consistent with its known weak affinity for Mg2+. Competition studies determined ATP affinities for Ca2+ and H+ that were also in good agreement with published values. 25Mg NMR spectra of 2 mM bound 25Mg2+ were obtained with good signal to noise in less than 1 hr. The technique may now be a practical means for studying the binding of Mg2+ within erythrocytes and other cells.     

Protease La, the lon gene product, cleaves specific fluorogenic peptides in an ATP-dependent reaction

Protease La is an ATP-dependent protease that catalyzes the rapid degradation of abnormal proteins and certain normal polypeptides in Escherichia coli. In order to learn more about its specificity and the role of ATP, we tested whether small fluorogenic peptides might serve as substrates. In the presence of ATP and Mg2+, protease La hydrolyzes two oligopeptides that are also substrates for chymotrypsin, glutaryl-Ala-Ala-Phe-methoxynaphthylamine (MNA) and succinyl-Phe-Leu-Phe-MNA. Methylation or removal of the acidic blocking group prevented hydrolysis. Closely related peptides (glutaryl-Gly-Gly-Phe-MNA and glutaryl-Ala-Ala-Ala-MNA) are cleaved only slightly, and substrates of trypsin-like proteases are not hydrolyzed. Furthermore, several peptide chloromethyl ketone derivatives that inhibit chymotrypsin and cathepsin G (especially benzyloxycarbonyl-Gly-Leu-Phe-chloro-methyl ketone), inhibited protease La. Thus its active site prefers peptides containing large hydrophobic residues, and amino acids beyond the cleavage site influence rates of hydrolysis. Peptide hydrolysis resembles protein breakdown by protease La in many respects: 1) ADP inhibits this process rapidly, 2) DNA stimulates it, 3) heparin, diisopropyl fluorophosphate, and benzoyl-Arg-Gly-Phe-Phe-Leu-MNA inhibit hydrolysis, 4) the reaction is maximal at pH 9.0-9.5, 5) the protein purified from lon- E. coli or Salmonella typhymurium showed no activity against the peptide, and that from lonR9 inhibited peptide hydrolysis by the wild-type enzyme. With partially purified enzyme, peptide hydrolysis was completely dependent on ATP. The pure protease hydrolyzed the peptide slowly when only Mg2+, Ca2+, or Mn2+ were present, and ATP enhanced this activity 6-15-fold (Km = 3 microM). Since these peptides cannot undergo phosphorylation, adenylylation, modification of amino groups, or denaturation, these mechanisms cannot account for the stimulation by ATP. Most likely, ATP and Mg2+ affect the conformation of the enzyme, rather than that of the substrate.     

多聚磷酸激酶及其在ATP再生体系构建中的进展

构建高效的腺嘌呤核苷三磷酸(adenosinetriphosphate,ATP)再生体系可显著提高生物催化磷酸基团转移反应的效率。多聚磷酸激酶(poly phosphate kinase, PPK)能利用来源广、廉价且稳定的多聚磷酸(polyphosphate, Poly P)盐作为磷酸基供体，能够实现单磷酸腺苷(adenosine monophosphate,AMP)、二磷酸腺苷(adenosinediphosphate,ADP)、ATP、PolyP之间磷酸基的高效定向转移，已成为构建ATP再生体系的首选。本文介绍了不同类型PPK的结构特征、相关催化机制以及不同来源的PPK在酶活、催化效率、稳定性和底物偏好性的特征差异；归纳和列举了针对野生PPK酶学性质不足进行分子改造的实例，并对PPK在ATP再生体系构建的研究进展进行了总结。