多聚磷酸盐及其代谢酶的研究进展

多聚磷酸盐(polyP)是由几个到几百个无机磷酸盐单体通过高能磷酸键聚合而成的线性多聚体,广泛分布于自然界和生物体.本文总结了polyP在生物体中的重要功能,包括基因表达和调控、DNA的摄取、微生物的运动性、对胁迫和饥饿的应答、病原菌的毒性以及对细胞凋亡、血液凝固、细胞钙化、线粒体功能的调节,需要polyP的酶有内切酶、葡萄糖激酶、NAD激酶和AMP磷酸转移酶等.本文对调控polyP的多聚磷酸盐激酶(polyphosphate kinase,ppk)和外切聚磷酸酶(exopolyphosphatase,PPX )的生化性质和结构也进行了总结.同时,结合我们的研究工作,重点分析了结核分枝杆菌中PPX的同源蛋白和可能的生物化学活性.     

多聚磷酸盐：不仅是异染粒

无机的多聚磷酸盐（inorganic polyphosphate,polyP）是由3个到几百个磷酸根通过高能磷酸酐键聚合而成的聚合物,具有广泛的生物学功能。然而,polyP的所有发现都是在不同的生物体和模式生物中进行研究产生的,因此,这些结果都各自独立,而不能形成一般性结论,即polyP在生物体中到底起什么样的作用。本文综述了polyP在DNA复制、基因转录、翻译和翻译后的修饰、蛋白质的折叠和降解中所发挥的生物学功能。本文尝试将polyP的各种不相关的生物学功能,从中心法则的角度进行了统一认识,希望能为polyP生物学功能的研究带来新的思考。     

生物细胞中颗粒状多聚磷酸盐细胞器的结构与功能

多聚磷酸盐(polyphosphat,poly P)是一种由数十个或上百个磷酸根聚合而成的生物大分子,以颗粒状、胶体状和溶解状等多种状态存在于各类生物细胞中。生物体中的poly P能够通过分解提供能量;鳌合金属离子来调节细胞内渗透压,维持质膜稳定;与蛋白质或DNA结合稳定其结构,减轻细胞应激损伤。颗粒状多聚磷酸盐细胞器主要指细胞中用于贮存颗粒状poly P、金属阳离子以及蛋白质、氨基酸和少量水等物质的细胞器。在寄生虫细胞中颗粒状聚磷细胞器常称为酸性钙体,而细菌或者其他微生物细胞中则称为异染颗粒,但是随着研究的不断深入,发现酸性钙体和异染颗粒都具有相似的结构特征,遂将其统一定义为颗粒状多聚磷酸盐细胞器。颗粒状聚磷细胞器的发现拓展了生物共同祖先(last universal common ancestor,LUCA)的学说,丰富了原核生物细胞器认知,我们相信该细胞器在生命起源、抗环境胁迫、生物互作和代谢调控等方面具有重要功能,在疾病治疗以及磷生物地球化学循环过程中发挥重要作用。     

Cadmium-induced loss of surface polyphosphate in Acinetobacter lwoffi

Abstract Cadmium is accumulated in Acinetobacter lwoffi by an active transport process. Growth in synthetic medium is not affected until cadmium concentrations exceed 0.5 μM. Cd uptake is accompanied by release of inorganic phosphate to the medium. ³¹P-NMR spectra show that the surface polyphosphate pool disappears preferentially in response to Cd.     

The structure of the exopolyphosphatase (PPX) from Escherichia coli O157:H7 suggests a binding mode for long polyphosphate chains

Polyphosphate (polyP) is a linear polymer consisting of tens to hundreds of phosphate molecules joined together by high-energy anhydride bonds. These polymers are found in virtually all prokaryotic and eukaryotic cells and perform many functions; prominent among them are the responses to many stresses. Polyphosphate is synthesized by polyP kinase (PPK), using the terminal phosphate of ATP as the substrate, and degraded to inorganic phosphate by both endo- and exopolyphosphatases. Here we report the crystal structure and analysis of the polyphosphate phosphatase PPX from Escherichia coli O157:H7 refined at 2.2 Angstroms resolution. PPX is made of four domains. Domains I and II display structural similarity with one another and share the ribonuclease-H-like fold. Domain III bears structural similarity to the N-terminal, HD domain of SpoT. Domain IV, the smallest domain, has structural counterparts in cold-shock associated RNA-binding proteins but is of unknown function in PPX. The putative PPX active site is located at the interface between domains I and II. In the crystal structure of PPX these two domains are close together and represent the "closed" state. Comparison with the crystal structure of PPX/GPPA from Aquifex aeolicus reveals close structural similarity between domains I and II of the two enzymes, with the PPX/GPPA representing an "open" state. A striking feature of the dimer is a deep S-shaped canyon extending along the dimer interface and lined with positively charged residues. The active site region opens to this canyon. We postulate that this is a likely site of polyP binding.     

Inducing mechanism of biological phosphorus removal driven by the aerobic/extended-idle regime

Recently, it was found that excess phosphorus (Pi) removal could be achieved in activated sludge with an aerobic/extended‐idle (AEI) process. In this study, batch tests were performed to further reveal the inducing mechanism of Pi removal involved in the AEI process. Unlike the classical anaerobic/aerobic process where an anaerobic Pi release along with a significant polyhydroxyalkanoate (PHA) accumulation drives polyphosphate (poly‐P) accumulating organisms (PAOs) to over‐store Pi as poly‐P, an idle Pi release accompanied by a low‐idle PHA production, which is usually considered to be detrimental for biological Pi removal, was observed to induce some cells to effectively uptake Pi in excess of metabolic requirement in the AEI process. With the increase of idle Pi release, Pi removal efficiency linearly increased. The results also showed that a long idle period with a low level of intracellular glycogen could significantly increase Pi release contents, thus remarkably enhancing Pi removal performances. Fluorescence in situ hybridization analysis further revealed that activated sludge in the AEI process contained 37.6% of Accumulibacter (PAOs) and 28.2% of Competibacter and Defluviicoccus‐related organisms (glycogen accumulating organisms). This study revealed an actually existent, yet previously unrecognized, inducing mechanism of poly‐P accumulation, and this mechanism behind the AEI regime may provide a scientific basis for the development of an alternative strategy for Pi removal from wastewaters. Biotechnol. Bioeng. 2012; 109: 2798–2807. © 2012 Wiley Periodicals, Inc.     

Inorganic pyrophosphatase from the red flour beetle (Tribolium castaneum) modulates mitochondrial polyphosphate metabolism

Polyphosphates (polyPs) have been found in all cell types examined to date and play diverse roles, depending on the cell type. In eukaryotic organisms, polyPs have been mainly investigated in mammalian cells, with few studies on insects. In this study, we investigated mitochondrial polyphosphate metabolism in the red flour beetle, Tribolium castaneum. Substrate specificity for different chain lengths demonstrated the presence of two exopolyphosphatase isoforms in mitochondria. T. castaneum mitochondrial polyP levels decreased after injection with soluble pyrophosphatase (Tc‐sPPase) dsRNA, while the membrane exopolyphosphate activity increased. Mitochondrial respiration modulated exopolyphosphatase activity only in wild‐type beetles. Tripolyphosphate was able to increase the F‐ATPase activity in wild‐type and Tc‐sPPase RNAi beetles. We suggest that inorganic pyrophosphatase modulates polyphosphate metabolism in mitochondria and affects the link between mitochondrial activity and polyphosphate metabolism in T. castaneum.     

多聚磷酸盐及其在分枝杆菌中的生理功能

结核病仍然是全球性传染病。缩短疗程的新药和新疫苗是控制结核病的关键。研究分枝杆菌的生理功能有助于实现上述目的。多聚磷酸盐在细菌胁迫应答中发挥重要作用。结核分枝杆菌具有两类多聚磷酸盐代谢酶以控制细胞内多聚磷酸盐的动态平衡:多聚磷酸盐激酶和多聚磷酸酸盐水解酶。本文综述多聚磷酸盐在分枝杆菌中的代谢及其生理功能,以期为研究多聚磷酸盐在结核分枝杆菌中的生理功能提供参考。     

The gene for an exopolyphosphatase of Pseudomonas aeruginosa.

In Pseudomonas aeriginosa, a gene, ppx, that encodes exopolyphosphatase [exopoly(P)ase; EC 3.6.1.11] of 506 amino acids (56,419 Da) was found downstream of the gene for polyphosphate kinase, ppk. Since ppx is located in the opposite direction of the ppk gene, they do not constitute an operon. The predicted amino acid sequence of PPX is 41% identical with Escherichia coli PPX. The gene product of ppx (paPPX) was overproduced in E. coli, and its activity was evaluated. Orthophosphate (Pi) is released from polyphosphate [poly(P)], the average chain lengths of which are 79 and 750, respectively. The amount of Pi released matched the amount of poly(P) lost. Thus ppx encodes an enzyme that has exopoly(P)ase activity.     

Changes in Orthophosphate, Pyrophosphate and Long-Chain Polyphosphate Levels in Leishmania major Promastigotes Incubated With and Without Glucose

The intracellular levels of orthophosphate (P₁), pyrophosphate (PP₁) and short- and long-chain polyphosphate (Poly P) were measured in Leishmania major promastigotes incubated in a phosphate-free medium. In the absence of exogenous substrate, the levels of both P₁ and PP₁ increased during a 1 h incubation. The increase in both P₁ and PP₁ was prevented when glucose was present, but glycerol prevented the rise in P₁ only. A rise in P₁ and PP₁ was also seen in cells incubated in the absence of exogenous substrate under anaerobic conditions. This was reversed upon addition of glucose plus oxygen. Polyphosphate, here shown to be present in L. major , was measured by means of a polyphosphate glucokinase assay. Short-chain Poly P content did not differ between cells incubated for 1 h in the absence of exogenous substrate or in the presence of glucose or glycerol. Long-chain Poly P content, however, was lower in cells incubated without glucose than in cells incubated with glucose and was also lower in cells incubated for 1 h with glycerol as compared with freshly washed cells. Up to 61% of the increase in P₁ and PP₁ that occurred in promastigotes incubated in the absence of exogenous substrate could have arisen from the concomitant decrease in long-chain Poly P.     

Arabidopsis thaliana inositol 1,3,4-trisphosphate 5/6-kinase 4 (AtITPK4) is an outlier to a family of ATP-grasp fold proteins from Arabidopsis

The Arabidopsis genome encodes a family of inositol 1,3,4-trisphosphate 5/6-kinases which form a subgroup of a larger group of ATP-grasp fold proteins. An analysis of the inositol 1,3,4-trisphosphate 5/6-kinase family might, ultimately, be best rewarded by detailed comparison of related enzymes in a single genome. The enzyme encoded by At2G43980, AtITPK4; is an outlier to its family. At2G43980 is expressed in male and female organs of young and mature flowers. AtITPK4 differs from other family members in that it does not display inositol 3,4,5,6-tetrakisphosphate 1-kinase activity; rather, it displays inositol 1,4,5,6-tetrakisphosphate and inositol 1,3,4,5-tetrakisphosphate isomerase activity.     

Microbial communities associated with phosphogenic sediments and phosphoclast‐associated DNA of the Benguela upwelling system

The processes that lead to the precipitation of authigenic calcium phosphate minerals in certain marine pore waters remain poorly understood. Phosphogenesis occurs in sediments beneath some oceanic upwelling zones that harbor polyphosphate‐accumulating bacteria. These bacteria are believed to concentrate phosphate in sediment pore waters, creating supersaturated conditions with respect to apatite precursors. However, the relationship between microbes and phosphorite formation is not fully resolved. To further study this association, we examined microbial community data generated from two sources: sediment cores recovered from the shelf of the Benguela upwelling region where phosphorites are currently forming, and DNA preserved within phosphoclasts recovered from a phosphorite deposit along the Benguela shelf. iTag and clone library sequencing of the 16S rRNA gene showed that many of our sediment‐hosted communities shared large numbers of phylotypes with one another, and that the same metabolic guilds were represented at localities across the shelf. Sulfate‐reducing bacteria and sulfur‐oxidizing bacteria were particularly abundant in our datasets, as were phylotypes that are known to carry out nitrification and the anaerobic oxidation of ammonium. The DNA extracted from phosphoclasts contained the signature of a distinct microbial community from those observed in the modern sediments. While some aspects of the modern and phosphoclast communities were similar, we observed both an enrichment of certain common microbial classes found in the modern phosphogenic sediments and a relative depletion of others. The phosphoclast‐associated DNA could represent a relict signature of one or more microbial assemblages that were present when the apatite or its precursors precipitated. While these taxa may or may not have contributed to the precipitation of the apatite that now hosts their genetic remains, several groups represented in the phosphoclast extract dataset have the genetic potential to metabolize polyphosphate, and perhaps modulate phosphate concentrations in pore waters where carbonate fluorapatite (or its precursors) are known to be precipitating.     

DISSECTING THE PHYSIOLOGICAL RESPONSE TO PHOSPHORUS STRESS IN MARINE SYNECHOCOCCUS ISOLATES (CYANOPHYCEAE)1

Marine Synechococcus is ubiquitous in aquatic environments. However, distinct phylogenetic lineages of this genus have a complex ecological distribution that is not fully explained. Here, we undertook a broad study of the phosphorus (P)–related behavior of marine Synechococcus isolates from all previously described ribotypes (sensu Fuller et al. 2003 ). A wide variability in P‐related physiology was noted among members of this genus, particularly in the utilization of organic P sources. However, some characteristics (e.g., cell size change during P limitation and the ability to accumulate polyphosphate) were largely consistent with their phylogenetic lineage and inferred ecology, with clear distinctions between oligotrophic, mesotrophic, and opportunistic lineages. Similarly, the ability to induce protein expression in response to P limitation was consistent with the presence/absence of phoB/R regulatory capacity of the corresponding strain. Taxonomic differences in P uptake, storage, and utilization strategies could explain the ubiquitous distribution of marine Synechococcus throughout the world’s oceans and explain the coexistence and/or ecological partitioning of multiple phototrophic taxa in the photic zone of tropical and subtropical oligotrophic oceans.     

Regulation of bacterial phosphate taxis and polyphosphate accumulation in response to phosphate starvation stress

Phosphorus (P) is an essential constituent in all types of living organisms. Bacteria, which use inorganic phosphate (P_i), as the preferred P source, have evolved complex systems to survive during P_i starvation conditions. Recently, we found thatPseudomonas aeruginosa, a monoflagellated, obligately aerobic bacterium, is attracted to P_i. The evidence that the chemotactic response to P_i (P_i taxis) was observed only with cells grown in P_i-limiting medium suggests that P_i taxis plays an important role in scavenging P_i residues under conditions of P_i starvation. Many bacteria also exhibit rapid and extensive accumulation of polyphosphate (polyP), when P_i is added to cells previously subjected to P_i starvation stress. Since polyP can serve as a P source during P_i starvation conditions, it is likely that polyP accumulation is a protective mechanism for survival during P_i starvation. In the present review, we summarize our current knowledge on regulation of bacterial P_i taxis and polyP accumulation in response to P_i starvation stress.     

Deciphering the Genome of Polyphosphate Accumulating Actinobacterium Microlunatus phosphovorus

Polyphosphate accumulating organisms (PAOs) belong mostly to Proteobacteria and Actinobacteria and are quite divergent. Under aerobic conditions, they accumulate intracellular polyphosphate (polyP), while they typically synthesize polyhydroxyalkanoates (PHAs) under anaerobic conditions. Many ecological, physiological, and genomic analyses have been performed with proteobacterial PAOs, but few with actinobacterial PAOs. In this study, the whole genome sequence of an actinobacterial PAO, Microlunatus phosphovorus NM-1^T (NBRC 101784^T), was determined. The number of genes for polyP metabolism was greater in M. phosphovorus than in other actinobacteria; it possesses genes for four polyP kinases (ppks), two polyP-dependent glucokinases (ppgks), and three phosphate transporters (pits). In contrast, it harbours only a single ppx gene for exopolyphosphatase, although two copies of ppx are generally present in other actinobacteria. Furthermore, M. phosphovorus lacks the phaABC genes for PHA synthesis and the actP gene encoding an acetate/H⁺ symporter, both of which play crucial roles in anaerobic PHA accumulation in proteobacterial PAOs. Thus, while the general features of M. phosphovorus regarding aerobic polyP accumulation are similar to those of proteobacterial PAOs, its anaerobic polyP use and PHA synthesis appear to be different.     

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.     

POTASSIUM IN POLYPHOSPHATE BODIES OF CHLORELLA PYRENOIDOSA (CHLOROPHYCEAE) AS DETERMINED BY X-RAY MICROANALYSIS1

Potassium is an important component information of polyphosphate bodies (PB) by Chlorella pyrenoidosa Chick. However, it was not detected in PB by X-ray energy dispersive microanalyses when the specimens were subjected to a standard preparation procedure for transmission electron microscopy. Intact cells were incinerated at 350 C on stainless steel grids coated with silicon monoxide. X-ray spectra from PB showed conspicuous peaks of energy counts in the Kα lines for phosphorus and potassium. It is proposed that potassium is a major cationic component of PB in C. pyrenoidosa grown in potassium sufficient medium.     

Dynamics of inositol phosphate pools (tris-, tetrakis- and pentakisphosphate) in relation to the rate of phytate synthesis during seed development in common bean (Phaseolus vulgaris)

Four cultivars of Phaseolus vulgaris were grown in a greenhouse and each flower was Labeled with date of anthesis. Seeds were collected at six different stages of development and inositol phosphates (InsPs) were analyzed by ion-pair reversed-phase HPLC. Phytate accumulation was similar in all cultivars, and the specific rate of phytate synthesis (Rs) peaked at about 22 days after flowering (DAF). Variations in the concentrations of the InsP3 and InsP4 pools matched changes in Rs in cultivars Una and Aru?. These results suggest mass-action effects. Thus, the rates of conversion of InsP3 to InsP5 appeared to be at least partly dependent on substrate concentration. Proportional increases in size of all InsP pools up to 21 DAF are also consistent with Little regulation in this part of the pathway. However, this did not appear to be the case in cv. Diamante Negro or with the conversion of InsP5 to InsP6 in all cultivars, where concentrations of the InsP precursor pools peaked earlier or even dropped as Rs peaked, suggesting activation of enzyme activity. Therefore, the evidence is consistent with a control point regulating this metabolic route upstream of InsP3 and possibly in the conversion of InsP5 to InsP6.