Accumulation of Polyphosphates and Expression of High Molecular Weight Exopolyphosphatase in the Yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The effect of cultivation time and concentration of inorganic phosphate (P(i)) in the culture medium on the accumulation of polyphosphates (polyP) and the activity of two cytosolic exopolyphosphatases of the yeast Saccharomyces cerevisiae was studied: an exopolyphosphatase of 40 kD encoded by PPX1 and a high molecular weight exopolyphosphatase encoded by another gene. Depletion of polyP in the cells on P(i) starvation is a signal factor for the accumulation of polyP after the subsequent addition of 5-20 mM P(i) and glucose to the cells or spheroplasts. A high activity of both exopolyphosphatases does not prevent the accumulation of polyP. The expression of the high molecular weight exopolyphosphatase is due to the acceleration of metabolism in cells that have reached the stage of growth deceleration on the addition of P(i) and glucose or complete culture medium. This process may occur independently from the accumulation of polyP. The activity of exopolyphosphatase PPX1 depends less on the mentioned factors, decreasing 10-fold only under conditions of phosphate surplus at the stationary growth stage.     

Inorganic Polyphosphates and Exopolyphosphatases in Cell Compartments of the Yeast Saccharomyces cerevisiae Under Inactivation of PPX1 and PPN1 Genes

Purified fractions of cytosol, vacuoles, nuclei, and mitochondria of Saccharomyces cerevisiae possessed inorganic polyphosphates with chain lengths characteristic of each individual compartment. The most part (80–90%) of the total polyphosphate level was found in the cytosol fractions. Inactivation of a PPX1 gene encoding ~40-kDa exopolyphosphatase substantially decreased exopolyphosphatase activities only in the cytosol and soluble mitochondrial fraction, the compartments where PPX1 activity was localized. This inactivation slightly increased the levels of polyphosphates in the cytosol and vacuoles and had no effect on polyphosphate chain lengths in all compartments. Exopolyphosphatase activities in all yeast compartments under study critically depended on the PPN1 gene encoding an endopolyphosphatase. In the single PPN1 mutant, a considerable decrease of exopolyphosphatase activity was observed in all the compartments under study. Inactivation of PPN1 decreased the polyphosphate level in the cytosol 1.4-fold and increased it 2- and 2.5-fold in mitochondria and vacuoles, respectively. This inactivation was accompanied by polyphosphate chain elongation. In nuclei, this mutation had no effect on polyphosphate level and chain length as compared with the parent strain CRY. In the double mutant of PPX1 and PPN1, no exopolyphosphatase activity was detected in the cytosol, nuclei, and mitochondria and further elongation of polyphosphates was observed in all compartments.     

Inorganic polyphosphates and exopolyphosphatases in different cell compartments of Saccharomyces cerevisiae

The cytosol, nuclei, vacuoles, and mitochondria of the yeast Saccharomyces cerevisiae possess inorganic polyphosphates (polyPs). PolyP levels, spectra of polyP chain lengths, and their dependence on the growth phase are distinguished in the mentioned compartments. Inactivation of the PPX1 gene has no effect on the polyP metabolism under cultivation of the yeast in medium with glucose and 5–7 mM P_i. Inactivation of the PPN1 gene results in elimination of the high-molecular-mass exopolyphosphatases (∼120 to 830 kD) of the cytosol, nuclei, vacuoles, and mitochondria of S. cerevisiae suggesting that it is just PPN1 that encodes these enzymes. Expression of the low-molecular-mass exopolyphosphatase of ∼45 kD encoded by the PPX1 gene decreases under PPN1 inactivation as well. While PPN1 inactivation has negligible effect on polyP levels, it results in increase in the long-chain polyPs in all the compartments under study. Published in Russian in Biokhimiya, 2006, Vol. 71, No. 11, pp. 1445–1450.     

Inorganic polyphosphates in mitochondria

Current data concerning the crucial role of inorganic polyphosphates (polyP) in mitochondrial functions and dysfunctions in yeast and animal cells are reviewed. Biopolymers with short chain length (∼15 phosphate residues) were found in the mitochondria of Saccharomyces cerevisiae. They comprised 7–10% of the total polyP content of the cell. The polyP are located in the membranes and intermembrane space of mitochondria. The mitochondrial membranes possess polyP/Ca²⁺/polyhydroxybutyrate complexes. PolyP accumulation is typical of promitochondria but not of functionally active mitochondria. Yeast mitochondria possess two exopolyphosphatases splitting P_i from the end of the polyP chain. One of them, encoded by the PPX1 gene, is located in the matrix; the other one, encoded by the PPN1 gene, is membrane-bound. Formation of well-developed mitochondria in the cells of S. cerevisiae after glucose depletion is accompanied by decrease in the polyP level and the chain length. In PPN1 mutants, the polyP chain length increased under glucose consumption, and the formation of well-developed mitochondria was blocked. These mutants were defective in respiration functions and consumption of oxidizable carbon sources such as lactate and ethanol. Since polyP is a compound with high-energy bonds, its metabolism vitally depends on the cell bioenergetics. The maximal level of short-chain acid-soluble polyP was observed in S. cerevisiae under consumption of glucose, while the long-chain polyP prevailed under ethanol consumption. In insects, polyP in the mitochondria change drastically during ontogenetic development, indicating involvement of the polymers in the regulation of mitochondrial metabolism during ontogenesis. In human cell lines, specific reduction of mitochondrial polyP under expression of yeast exopolyphosphatase PPX1 significantly modulates mitochondrial bioenergetics and transport.     

Effects of inactivation of the PPN1 gene on exopolyphosphatases, inorganic polyphosphates and function of mitochondria in the yeast Saccharomyces cerevisiae

Mutants of Saccharomyces cerevisiae with inactivated endopolyphosphatase gene PPN1 did not grow on lactate and ethanol, and stopped growth on glucose earlier than the parent strain. Their mitochondria were defective in respiration functions and in metabolism of inorganic polyphosphates. The PPN1 mutants lacked exopolyphosphatase activity and possessed a double level of inorganic polyphosphates in mitochondria. The average chain length of mitochondrial polyphosphates at the stationary growth stage on glucose was about 15-20 and about 130-180 phosphate residues in the parent strain and PPN1 mutants, respectively. Inactivation of the PPX1 gene encoding exopolyphosphatase had no effect on respiration functions and on polyphosphate level and chain length in mitochondria.     

Inactivation of endopolyphosphatase gene PPN1 results in inhibition of expression of exopolyphosphatase PPX1 and high-molecular-mass exopolyphosphatase not encoded by PPX1 in Saccharomyces cerevisiae

Saccharomyces cerevisiae possesses multiple forms of exopolyphosphatases, the enzymes involved in the metabolism of inorganic polyphosphates, which are important regulatory compounds. In S. cerevisiae, inactivation of endopolyphosphatase gene PPN1 leads to the inhibition of expression of both exopolyphosphatase PPX1 and high-molecular-mass exopolyphosphatase of approximately 1000 kDa not encoded by PPX1. In the single endopolyphosphatase mutant CRN, the expression of exopolyphosphatase PPX1 decreases 6.5-fold and 2.5-fold at the stationary and exponential growth phases, respectively, as compared with the parent strain CRY. In this mutant, the activity of the high-molecular-mass exopolyphosphatase of approximately 1000 kDa decreases approximately 10-fold as compared with that in strains with the PPN1 gene. In a double mutant of PPX1 and PPN1, no exopolyphosphatase activity is detected in the cytosol at the stationary growth phase. Thus, the exopolyPase activity in cell cytosol depends on the endopolyPase gene PPN1.     

Purification and Properties of Exopolyphosphatase from the Cytosol of Saccharomyces cerevisiae Not Encoded by the PPX1 Gene

A novel exopolyphosphatase has been isolated from the cytosol of Saccharomyces cerevisiae grown to the stationary phase after its transfer from phosphate-deficient to complete medium. The PPX1 gene responsible for 40-kD exopolyphosphatase of the cytosol does not encode it. Specific activity of the preparation is 150 U/mg, purification degree is 319, and the yield is 16.9%. The minimal molecular mass of the active but unstable enzyme complex is approximately 125 kD. A stable enzyme complex with a molecular mass of approximately 500 kD is composed of two polypeptides of approximately 32 and 35 kD and apparently polyphosphates (polyP). Unlike the enzyme encoded by PPX1, the high-molecular-mass exopolyphosphatase is slightly active with polyP3, not inhibited by antibodies suppressing the activity of 40-kD exopolyphosphatase, inhibited by EDTA, and stimulated by divalent cations to a lesser extent. The high-molecular-mass exopolyphosphatase hydrolyzes polyP with an average chain length of 208 to 15 phosphate residues to the same extent, but is inactive with ATP, PPi, and p-nitrophenyl phosphate. The activity with polyP3 is 13% of that with polyP208. The Km values for polyP208, polyP15, and polyP3 hydrolysis are 3.5, 75, and 1100 microM, respectively. The enzyme is most active at pH approximately 7. Co2+ at the optimal concentration of 0.1 mM stimulates the activity 6-fold, while Mg2+ at the optimal concentration of 1 mM enhances it 2-fold. The enzyme under study is similar in some properties to an exopolyphosphatase purified earlier from yeast vacuoles.     

Effect of PPX1 inactivation on the exopolyphosphatase spectra in cytosol and mitochondria of the yeast Saccharomyces cerevisiae

Inactivation of PPX1 encoding exopolyphosphatase PPX1 in Saccharomyces cerevisiae results in a change in the exopolyphosphatase spectrum in the yeast cells. In the PPX1-deficient strain, elimination of an 45 kD exopolyphosphatase is observed in the cytosol, and activity of an exopolyphosphatase with molecular mass of 830 kD increases fivefold. The latter activity differs greatly in properties from the low-molecular-mass enzyme of the parent strain. In the soluble fraction of the mutant mitochondria, exopolyphosphatase of 45 kD characteristic of the soluble mitochondrial fraction in the parent strain is eliminated, and exopolyphosphatase with a molecular mass of 440 to 830 kD is found. On PPX1 inactivation, a membrane-bound form of mitochondrial exopolyphosphatase is unaffected in its activity level and properties. Therefore, the membrane-bound exopolyphosphatase of mitochondria and the high-molecular-mass enzyme of the cytosol of S. cerevisiae are not encoded by the PPX1 gene, unlike the soluble low-molecular-mass exopolyphosphatase of mitochondria, which is probably a product of this gene with a posttranslational modification. In the PPX1 mutant, exopolyphosphatase properties in the cell as a whole undergo modifications including the ability to hydrolyze polyphosphates (polyP) with different polymer degree.     

The patterns of utilization and accumulation of polyphosphates in the cytosol of the yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> under inactivation of exopolyphosphatase genes <Emphasis Type="Italic">PPX1</Emphasis> and <Emphasis Type="Italic">PPN1</Emphasis>

The effect of inactivation of the PPX1 and PPN1 genes encoding the yeast exopolyphosphatases on the activities of these enzymes and polyphosphate content in the cytosol of Saccharomyces cerevisiae was studied under P_i deficit and P_i excess in the cultivation medium. Under P_i deficit, exopolyphosphatase activity in strain CRN (with inactivated PPN1 gene) and in the parent strain CRY increased 3- and 1.5-fold, respectively. In the strain CRX (with inactivated PPX1 gene), exopolyphosphatase activity did not change under P_i deficit. Transfer from P_i-deficient to P_i-rich medium was accompanied by an ～1.7-fold increase of exopolyphosphatase activities in the cytosol preparations of strains CRY, CRX, and CRN. In the cytosol of the double mutant, exopolyphosphatase activity was practically absent under all of the above cultivation conditions. The content of polyphosphates in the cytosol preparations of all strains under study substantially decreased under P_i deficit. Transfer from P_i-deficient to P_i-rich medium was accompanied by polyphosphate over-accumulation only in the cytosol preparations of stains CRX and CNX, where their levels increased ～1.3 and 3.5-fold, respectively. No over-accumulation was observed in the parent strain CRY and in the PPN1-deficient strain CRN. These data suggest that the exopolyphosphatases encoded by the PPX1 and PPN1 genes are not involved in polyphosphate synthesis.     

多聚磷酸相关蛋白结构及生物学功能

多聚磷酸（polyphosphate,polyP）是由几个到数百个磷酸基通过高能磷酸酐键连接而成的链状多聚体,存在于所有细胞生物中.多聚磷酸相关蛋白包括多聚磷酸相关酶和多聚磷酸结合蛋白.多聚磷酸相关酶如多聚磷酸激酶（polyphosphate kinase,PPK）催化polyPn生成polyPn+1的可逆反应;外切聚磷酸酶（exopolyphosphatase,PPX）、内切聚磷酸酶（endopolyphosphatase,PPN）能将polyP水解成磷酸残基;多聚磷酸依赖的激酶将polyP的磷转移到生物小分子上,如葡萄糖和烟酰胺腺嘌呤二核苷酸（nicotinamide adenine dinucleotide,NAD）,使其分别磷酸化为6 磷酸葡萄糖和烟酰胺腺嘌呤二核苷酸磷酸（nicotinamide adenine dinucleotide phosphate,NADP）.多聚磷酸结合蛋白可与多聚磷酸结合,发挥各种生物学功能.本文将简要介绍多聚磷酸相关蛋白的结构与主要生物学功能,以阐述多聚磷酸参与的细胞内生化过程.     

Effect of a carbon source on polyphosphate accumulation in Saccharomyces cerevisiae

The cells of Saccharomyces cerevisiae accumulate inorganic polyphosphate (polyP) when reinoculated on a phosphate-containing medium after phosphorus starvation. Total polyP accumulation was similar at cultivation on both glucose and ethanol. Five separate fractions of polyP: acid-soluble fraction polyP1, salt-soluble fraction polyP2, weakly alkali-soluble fraction polyP3, alkali-soluble fraction polyP4, and polyP5, have been obtained from the cells grown on glucose and ethanol under phosphate overplus. The dynamics of polyP fractions depend on a carbon source. The accumulation rates for fractions polyP2 and polyP4 were independent of the carbon source. The accumulation rates of polyP1 and polyP3 were higher on glucose, while fraction polyP5 accumulated faster on ethanol. As to the maximal polyP levels, they were independent of the carbon source for fractions polyP2, polyP3, and polyP4. The maximal level of fraction polyP1 was higher on glucose than on ethanol, but the level of fraction polyP5 was higher on ethanol. It was assumed that accumulation of separate polyP fractions has a metabolic interrelation with different energy-providing pathways. The polyphosphate nature of fraction polyP5 was demonstrated for the first time by ³¹P nuclear magnetic resonance spectroscopy, enzymatic assay, and electrophoresis.     

Polyphosphates as an energy source for growth of Saccharomyces cerevisiae

Cells of the yeast Saccharomyces cerevisiae with a low content of polyphosphates (polyP) are characterized by disturbance of growth in medium with 0.5% glucose. The parent strain with polyP level reduced by phosphate starvation had a longer lag phase. The growth rate of strains with genetically determined low content of polyP due to their enhanced hydrolysis (CRN/pMB1_PPN1 Sc is a superproducer of exopolyphosphatase PPN1) or reduced synthesis (the BY4741 vma2Δ mutant with impaired vacuolar membrane energization) was lower in the exponential phase. The growth of cells with high content of polyP was accompanied by polyP consumption. In cells of strains with low content of polyP, CRN/pMB1_PPN1 Sc and BY4741 vma2Δ, their consumption was insignificant. These findings provide more evidence indicating the use of polyP as an extra energy source for maintaining high growth rate.     

Inactivation of the PPN1 gene exerts different effects on the metabolism of inorganic polyphosphates in the cytosol and the vacuoles of the yeast Saccharomyces cerevisiae

Inactivation of the PPN1 gene, encoding one of the enzymes involved in polyphosphate metabolism in the yeast Saccharomyces cerevisiae, was found to decrease exopolyphosphatase activity in the cytosol and vacuoles. This effect was more pronounced in the stationary growth phase than in the phase of active growth. The gene inactivation resulted in elimination of a 440-kDa exopolyphosphatase in the vacuoles but did not influence a previously unknown vacuolar exopolyphosphatase with a molecular mass of >1000 kDa, which differed from the former enzyme in the requirement for bivalent cations and sensitivity to heparin. Inactivation of the PPN1 gene did not influence the level of polyphosphates in the cytosol but increased it more than twofold in the vacuoles. In this case, the polyphosphate chain length in the cytosol increased from 10–15 to 130 phosphate residues both in the stationary and active growth phases. In the vacuoles, the polyphosphate length increased only in the stationary growth phase. A conclusion can be made that the PPN1 gene product has different effects on polyphosphate metabolism in the cytosol and the vacuoles.     

High molecular mass exopolyphosphatase from the cytosol of the yeast Saccharomyces cerevisiae is encoded by the PPN1 gene

It has been shown that the high molecular mass exopolyphosphatase localized in cytosol of the yeast Saccharomyces cerevisiae is encoded by the PPN1 gene. This enzyme is expressed under special culture conditions when stationary phase cells are passing on to new budding on glucose addition and phosphate excess. The enzyme under study releases orthophosphate from the very beginning of polyphosphate hydrolysis.     

The gene for a major exopolyphosphatase of Saccharomyces cerevisiae.

The gene encoding a major exopolyphosphatase (scPPX1) in Saccharomyces cerevisiae (H. Wurst and A. Kornberg, J. Biol. Chem. 269:10996-11001, 1994) has been isolated from a genomic library. The gene, located at 57 kbp from the end of the right arm of chromosome VIII, encodes a protein of 396 amino acids. Overexpression in Escherichia coli allowed the ready purification of a recombinant form of the enzyme. Disruption of the gene did not affect the growth rate of S. cerevisiae. Lysates from the mutants displayed considerably lower exopolyphosphatase activity than the wild type. The enzyme is located in the cytosol, whereas the vast accumulation of polyphosphate (polyP) of the yeast is in the vacuole. Disruption of PPX1 in strains with and without deficiencies in vacuolar proteases allowed the identification of exopolyphosphatase activity in the vacuole. This residual activity was strongly reduced in the absence of vacuolar proteases, indicating a dependence on proteolytic activation. A 50-fold-lower protease-independent activity could be distinguished from this protease-dependent activity by different patterns of expression during growth and activation by arginine. With regard to the levels of polyP in various mutants, those deficient in vacuolar ATPase retain less than 1% of the cellular polyP, a loss that is not offset by additional mutations that eliminate the cytosolic exopolyphosphatase and the vacuolar polyphosphatases dependent on vacuolar protease processing.     

Inactivation of the ppn1 gene exerts different effects on the metabolism of inorganic polyphosphates in the cytosol and the vacuoles of the yeast Saccharomyces cerevisiae

Inactivation of the PPN1 gene, encoding one of the enzymes involved in polyphosphate metabolism in the yeast Saccharomyces cerevisiae, was found to decrease exopolyphosphatase activity in the cytosol and vacuoles. This effect was more pronounced in the stationary growth phase than in the phase of active growth. The gene inactivation resulted in elimination of a approximately 440-kDa exopolyphosphatase in the vacuoles but did not influence a previously unknown vacuolar exopolyphosphatase with a molecular mass of >1000 kDa, which differed from the former enzyme in the requirement for bivalent cations and sensitivity to heparin. Inactivation of the PPN1 gene did not influence the level of polyphosphates in the cytosol but increased it more than twofold in the vacuoles. In this case, the polyphosphate chain length in the cytosol increased from 10-15 to 130 phosphate residues both in the stationary and active growth phases. In the vacuoles, the polyphosphate length increased only in the stationary growth phase. A conclusion can be made that the PPN1 gene product has different effects on polyphosphate metabolism in the cytosol and the vacuoles.     

Partial Purification and Characterization of Nuclear Exopolyphosphatase from Saccharomyces cerevisiae Strain with Inactivated PPX1 Gene Encoding a Major Yeast Exopolyphosphatase

Inactivation of PPX1 encoding the major cytosolic exopolyphosphatase PPX1 in Saccharomyces cerevisiae did not alter exopolyphosphatase activity of the isolated nuclei compared with that in the parent strain. The nuclear exopolyphosphatase of the S. cerevisiae strain deficient in the PPX1 gene was purified 10-fold. According to gel filtration on Superose 6, this enzyme has a molecular mass of approximately 200 kD, and it hydrolyzes polyphosphates with an average chain length of 15 and 208 phosphate residues to the same extent. Its activity is much lower with tripolyphosphate. In the presence of 2.5 mM Mg2+, Km values are 133 and 25 microM in the hydrolysis of polyphosphates with chain lengths of 15 and 208 phosphate residues, respectively. The enzyme activity is stimulated by 2.5 mM Mg2+ and 0.1 mM Co2+ 15- and 31-fold, respectively. RNA does not alter the nuclear exopolyphosphatase activity, while polylysine increases it 2-fold.     

The effect of inactivation of the exo- and endopolyphosphatase genes PPX1 and PPN1 on the level of different polyphosphates in the yeast Saccharomyces cerevisiae

The inactivation of the PPX1 and PPN1 genes, which encode the major enzymes of polyphosphate degradation (exopolyphosphatase and endopolyphosphatase, respectively), was found to exert different effects on the content of different polyphosphates in the yeast Saccharomyces cerevisiae. The content of relatively low-molecular-weight acid-soluble polyphosphates in mutant yeast strains is inversely proportional to the exopolyphosphatase activity of the cytosol. At the same time, the mutation of these genes exerts no effect on salt-soluble polyphosphates. The content of high-molecular-weight alkali-soluble polyphosphates increases twofold in a mutant with inactivated genes of both exopolyphosphatase and endopolyphosphatase. The data obtained confirm the earlier suggestion that the metabolic pathways of particular polyphosphates in yeasts are different.     

Effect of PPX1 inactivation on exopolyphosphatases of different cell compartments of the yeast Saccharomyces cerevisiae

Inactivation of PPX1 encoding a major exopolyphosphatase (PPX1) in Saccharomyces cerevisiae results in a change of exopolyphosphatase spectra in the yeast cells. In the PPX1-deficient strain, an elimination of approximately 45 kDa enzyme is observed in cytosol and cell envelopes, and the activity of an exopolyphosphatase with a molecular mass of approximately 830 kDa increases 5-fold in the cytosol. These two enzyme activities differ greatly from each other not only in molecular masses but also in biochemical properties. Inactivation of PPX1 does not result in any changes in the content and properties of vacuolar exopolyphosphatase as compared with the wild strain of S. cerevisiae. In response to PPX1 mutation, exopolyphosphatase properties in the cell as a whole undergo modifications including the ability to hydrolyze polyphosphates with different lengths of the chain.