Polyphosphate and Its Diverse Functions in Host Cells and Pathogens

Silvia N. J. Moreno; Roberto Docampo

doi:10.1371/journal.ppat.1003230

Citation: Moreno SNJ, Docampo R (2013) Polyphosphate and Its Diverse Functions in Host Cells and Pathogens. PLoS Pathog 9(5): e1003230. https://doi.org/10.1371/journal.ppat.1003230

Editor: Laura J. Knoll, University of Wisconsin Medical School, United States of America

Published: May 2, 2013

Copyright: © 2013 Moreno, Docampo. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: Work in the authors' laboratories is supported by the U.S. National Institutes of Health grants AI096836 to SNJM and AI077538 to RD. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Polyphosphate (polyP) is a linear polymer of a few to many hundreds of phosphate (P_i) residues linked by high-energy phosphoanhydride bonds (Figure 1A). This ubiquitous polymer is found in bacteria, protists, and mammalian cells, and it was likely present prebiotically [1]. In bacteria, polyP accumulates in volutin or metachromatic granules, which are equivalent to acidocalcisomes [2]. In eukaryotic cells, polyP is present in different compartments, including the cytosol, nucleus, lysosomes, and mitochondria, but is preferentially accumulated in acidic vacuoles such as the yeast vacuole and acidocalcisomes [1], [3]. In these organelles, polyP, which is negatively charged, is in close association of inorganic (Ca²⁺, Mg²⁺, Zn²⁺, Fe²⁺, Na⁺, K⁺) and organic (basic amino acids, polyamines) cations. PolyP also combines with calcium and polyhydroxybutyrate forming channels in bacterial membranes, which make them competent for DNA entry; in mitochondria, as part of the mitochondrial permeability transition pore; and in the plasma membrane, as part of the potassium channel and the calcium pump (reviewed in [1], [4]). PolyP is arbitrarily divided into two forms: short-chain (from 3 to ∼300 P_i) and long-chain (from 300 to ∼1000 P_i) polyP, based on the method used for its extraction. For the detection of polyP, several methods have been described and a few examples are shown in Figure 1B–F.

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Figure 1. Methods used to detect polyP in cells.

(A) Structure of polyP. (B) 303.6-MHz spectrum (¹H decoupled) of a perchloric acid extract of isolated acidocalcisomes from epimastigotes of T. cruzi, showing peaks corresponding to P_i; the α phosphates of pentapolyphosphate (polyP₅), tetrapolyphosphate (polyP₄), tripolyphosphate (polyP₃); PP_i; the β phosphates of tri-, tetra-, and pentapolyphosphate (β-P); and the γ phosphate (central) of pentapolyphosphate (γ-P). Reproduced with permission from reference [31], © the American Society for Biochemistry and Molecular Biology. (C) Urea-PAGE analysis of polyP from human platelets from three different donors. PolyP extracted from platelets was electrophoresed by 6% urea-PAGE. Chain lengths of standards are on the left. The lanes named “Samples" show the position of migration of samples from three different donors. Reproduced with permission from reference [22], © the American Society for Biochemistry and Molecular Biology. (D) Fluorescence analysis (left) and merge with bright field image (right) of the localization of polyP in mast cell granules (acidocalcisomes) using the recombinant polyP binding domain (PPBD) of Escherichia coli PPX linked with an Xpress epitope tag. Reproduced with permission from reference [23], © the American Society for Biochemistry and Molecular Biology. (E) DAPI staining of epimastigotes of T. cruzi showing the punctate staining of acidocalcisomes. Kinetoplast DNA is stained blue.

https://doi.org/10.1371/journal.ppat.1003230.g001

Acidocalcisomes and PolyP

Acidocalcisomes were first described in trypanosomes and later found in Apicomplexan parasites, algae, slime molds, fungi, eggs of different origins, and human cells [3]. These organelles were originally described as acidic compartments storing high concentrations of calcium, and later work found that they are highly enriched in polyP [2]. As the description of acidocalcisomes progressed over the years, it was found that they are similar to the volutin or metachromic granules described in bacteria and are now considered to be the only organelles maintained over evolutionary time from bacteria to human cells [2]. Acidocalcisomes of some organisms are known to possess a number of pumps (H⁺-vacuolar pyrophosphatase, H⁺-vacuolar ATPase, Ca²⁺-ATPase), exchangers (Na⁺/H⁺; Ca²⁺/H⁺), channels (aquaporin, inositol 1,4,5-trisphosphate receptor (InsP₃R)), and transporters that are necessary for their cation and water accumulation and release, as well as enzymes involved in the synthesis and degradation of pyrophosphate and polyP [3]. Recent studies have indicated that they belong to the group of lysosome-related organelles (reviewed in [5]). The recent discovery that they possess an InsP₃R [6] suggests that they are also involved in Ca²⁺ signaling.

Enzymes Involved in PolyP Metabolism

The concentration of polyP in cells is the result of the action of enzymes that catalyze the synthesis and degradation of this polymer—namely, the polyP kinases and the endo- (PPNs) and exopolyphosphatases (PPXs), respectively. Bacteria express one or two polyP kinases: PPK1, which catalyzes the reversible transfer of P_i from ATP to polyP and from polyP to ADP, and PPK2, which catalyzes the synthesis of polyP from GTP or ATP [7]. Bacteria also have PPXs but no PPNs [7]. Genes encoding eukaryotic PPNs [8] and PPXs [9] were initially reported in Saccharomyces cerevisiae. Recombinant PPXs from Leishmania major [10], Trypanosoma cruzi [11], and human cells (H-prune) [12] have also been characterized. A role for polyP in cancer has been proposed based on the role of the human PPX on tumor metastasis [12]. Another interesting finding in this regard is that polyP could activate mTOR kinase, a key step in the proliferation of mammary cancer cells [13]. A putative polyP kinase gene of bacterial origin (DdPPK1) was found in Dictyostelium discoideum [14] together with a second distinct polyP kinase (DdPPK2), which is apparently localized to the acidocalcisome [15]. DdPPK2 has a similar sequence and shares characteristics of actin-related proteins, which in turn are similar to muscle actins. Actin inhibitors such as phalloidin and DNase I also inhibit DdPPK2-mediated synthesis of polyP. Thus, this particular actin-related protein complex is an enzyme that can polymerize into an actin-like filament concurrent with its synthesis of a polyP chain in a fully reversible reaction [15]. Recent work in yeast identified the first eukaryotic enzyme involved in the synthesis and translocation of polyP to a vacuolar compartment: the vacuolar transporter chaperone 4, or VTC4 [16]. VTC4 is part of a complex of VTC proteins that are present in fungi, algae, trypanosomatids [17], and Apicomplexans [18], but is absent in mammalian cells. Another potential pathway for polyP synthesis in yeast is through the metabolism of inositol pyrophosphates (InsPP) [19], but it is not known whether this pathway is operative in other organisms. Yeast deficient in phosphoinositide phospholipase C (PI-PLC) are depleted of polyP and a pathway for polyP synthesis via InsPP (also known as diphosphoinositol polyphosphates) was postulated. Diphosphoinositol tetrakisphosphate (PP-IP₄) is the precursor proposed for polyP synthesis [19]. The polyP synthesis pathway in mammalian cells is still unknown.

Functions of PolyP

The function of polyP has been studied mainly in prokaryotes: as a P_i store, an energy source to replace ATP, in cation sequestration and storage, in cell membrane formation and function, in gene transcription control, in regulation of enzyme activities, in response to stress and stationary phase, and in the structure of channels and pumps (reviewed in [20]). Kornberg's group has also described the roles of polyP in the physiological adjustments of bacteria to growth, development, stress, and deprivation; its role in biofilm development, quorum sensing, and virulence; as well as in long-term survival and expression of virulence factors (reviewed in [1]). The functions of polyP in eukaryotic cells are not so well defined. Functions in apoptosis, enhancement of mitogenic activity of fibroblast growth factor, and in bone mineralization have been reviewed elsewhere [21]. Some critical discoveries about the function of polyP in mammalian cells have renewed interest in studying them in these cells. It was first demonstrated that polyP is stored in the dense granules of human platelets and in mast cell granules (acidocalcisomes) and released upon their activation [22], [23]. It was also shown that polyPs have a potent modulatory activity on blood coagulation [24] and inflammation [25]. Recent studies have demonstrated that polyP acts at four points in the blood-clotting cascade (reviewed by [26]). PolyP initiation of the contact pathway by activating Factor XII to Factor XIIa also leads to bradykinin formation by kallikrein-mediated high molecular weight kininogen cleavage [25]. Bradykinin is the ligand of kinin B2 receptor, which activates various intracellular signaling pathways that lead to inflammatory reactions (reviewed in [27]).

A function for polyP in adaptation to stress and osmoregulation has been assigned in less complex eukaryotic cells such as yeast, fungi, algae, and trypanosomes (reviewed in [28]). PolyP is particularly abundant in pathogenic fungi and trypanosomes. It accounts for nearly 40% of the total phosphate content of S. cerevisiae [9] and reaches levels >100 mM in P_i residues, assuming distribution across the entire volume of the cell, in trypanosomatids such as Trypanosoma brucei, T. cruzi, and L. major [2], and there are drastic changes in their levels upon osmotic stress [29].

Role of PolyP in Pathogenesis

PolyP, which in bacteria is mainly of long-chain type (>300 and up to 1,000 P_i residues), has been reported to be important for virulence of different bacteria, such as Salmonella spp., Shigella flexneri, Vibrio cholerae, Neisseria meningitides, Pseudomonas aeruginosa, and Mycobacterium tuberculosis, but the mechanism involved is not known [30]. It has also been reported that conditions that decrease the levels of polyP in parasites such as T. brucei, T. gondii, or L. major (reviewed in [3]) reduce their pathogenicity. Whether this is due to osmotic fragility of the parasites as a result of changes in polyP levels that impact their ability to grow in vivo, making the immune response against them more successful, or to a role of polyP in modulating the immune response is not yet known.

Concluding Remarks

The late Prof. Arthur Kornberg once stated [30]: “not only is polyP often absent from texts of biology and chemistry but, even when noticed, tends to be dismissed as a molecular fossil." Considering the wide distribution of this polymer and the diversity of functions that has been attributed to it, it is expected that future research will reveal new findings about this understudied compound. PolyP has been found in bacterial to human cells and has been reported to be important for virulence of different bacteria and a number of parasites, including those that cause toxoplasmosis, African trypanosomiasis, and leishmaniasis. Even more exciting are the findings about the role of polyP in cancer metastasis, blood coagulation, inflammation, and innate immunity. For example, a significant finding is that enzymes involved in polyP metabolism could be excellent targets for drug design not only against bacteria and parasites but also for regulation of important physiological and pathological processes such as coagulation, inflammation, innate immunity, and thrombosis.

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