Effect of polyphosphate metabolism on the Escherichia coli phosphate-starvation response.

A previously developed dynamic model of the Escherichia coli Pho regulon was extended to investigate the effect of polyphosphate synthesis and degradation on this control system. Differential equations for ATP and polyphosphate were formulated, and the model was applied to the growth of cells containing the ppk and ppx genes under control of separate, inducible promoters. In agreement with recent experimental observations, the degradation of polyphosphate by PPX during a period of phosphate limitation could repress the phosphate-starvation response. This is attributed to the release of phosphate from the cell into the periplasm, where it can be detected by the external phosphate sensor. A segregated model was then developed to account for differences in K(I), the dissociation constant for the repression complex, among cells of the population. Since K(I) is the key parameter in determining whether the Pho response is induced or repressed at a particular surface phosphate concentration, this permitted the induction of some cells while others remained repressed. The induction profiles resulting from the population-averaged values more closely matched experimental results than did those with the nonsegregated model.

Engineering polyphosphate metabolism in Escherichia coli: implications for bioremediation of inorganic contaminants.

Polyphosphate metabolism plays an important role in the bioremediation of phosphate contamination in municipal wastewater, and may play a key role in heavy metal tolerance and bioremediation. However, little is known about the regulation of polyphosphate metabolism in microorganisms and its role in heavy metal toxicity. We have manipulated polyphosphate metabolism in Escherichia coli by overexpressing the genes for polyphosphate kinase (ppk) and for polyphosphatase (ppx) under control of their native promoters and inducible promoters. Overexpression of ppk results in high levels of intracellular polyphosphate, improved phosphate uptake, but no increase in tolerance to heavy metals. Overexpression of both ppk and ppx results in lower levels of intracellular polyphosphate, secretion of phosphate from the cell, and increased tolerance to heavy metals. Metabolic flux analysis indicates that the cell responds to increased flux through the PPK-PPX pathway by altering flux through the TCA cycle.

A dynamic model of the Escherichia coli phosphate-starvation response.

A mathematical model of the Escherichia coli Pho regulon was developed to study the induction of the phoA gene by starvation for inorganic phosphate. The model includes phosphate transport, detection of the phosphate concentration at the cell surface, and the signal transduction cascade ultimately leading to the induction of various Pho-controlled genes. Four parameters were manipulated to match the dynamic response of a culture growing with phosphate as the growth-limiting substrate to available experimental data for alkaline phosphatase production and internal phosphate concentration. Steady-state analysis demonstrates that the cascade design of this genetic control system gives rise to a harp transition between the uninduced and induced state for a small change in the external phosphate concentration. Parameter sensitivity indicates that the dissociation constant of the repression complex (which holds PhoR in the inactive form when phosphate is in excess), the rate constants for PhoB and PhoR phosphorylation, and the rate constant for induced transcription of Pho genes have the most influence over the expression of Pho-controlled genes. Changes in the repression complex dissociation constant and the PhoB/PhoR phosphorylation rates alter the sensitivity of the phosphate-starvation response to external phosphate concentration, whereas changes in the transcription rate constant affect the gain of the system. The model also predicts that additional Pho promoter (i.e., for the production of a heterologous protein from the phoA promoter on a plasmid) titrate activator protein PhoB A, such that a lower phosphate concentration is required to initiate expression from a high-copy plasmid than from a single-copy plasmid or the chromosome.

Manipulation of independent synthesis and degradation of polyphosphate in Escherichia coli for investigation of phosphate secretion from the cell.

The genes involved in polyphosphate metabolism in Escherichia coli were cloned behind different inducible promoters on separate plasmids. The gene coding for polyphosphate kinase (PPK), the enzyme responsible for polyphosphate synthesis, was placed behind the Ptac promoter. Polyphosphatase, a polyphosphate depolymerase, was similarly expressed by using the arabinose-inducible PBAD promoter. The ability of cells containing these constructs to produce active enzymes only when induced was confirmed by polyphosphate extraction, enzyme assays, and RNA analysis. The inducer concentrations giving optimal expression of each enzyme were determined. Experiments were performed in which ppk was induced early in growth, overproducing PPK and allowing large amounts of polyphosphate to accumulate (80 mumol in phosphate monomer units per g of dry cell weight). The ppx gene was subsequently induced, and polyphosphate was degraded to inorganic phosphate. Approximately half of this polyphosphate was depleted in 210 min. The phosphate released from polyphosphate allowed the growth of phosphate-starved cells and was secreted into the medium, leading to a down-regulation of the phosphate-starvation response. In addition, the steady-state polyphosphate level was precisely controlled by manipulating the degree of ppx induction. The polyphosphate content varied from 98 to 12 mumol in phosphate monomer units per g of dry cell weight as the arabinose concentration was increased from 0 to 0.02% by weight.

Modulation of the phosphate-starvation response in Escherichia coli by genetic manipulation of the polyphosphate pathways.

The effect of intracellular polyphosphate on the phosphate-starvation response in Escherichia coli was studied by genetically manipulating the intracellular polyphosphate levels and by performing phosphate shifts on the genetically engineered strains. Strains that produced large quantities of polyphosphate and were able to degrade it induced the phosphate-starvation response to a lesser extent than wild-type strains, whereas strains that were unable to degrade a large intracellular polyphosphate pool induced the phosphate-starvation response to a greater extent than wild-type strains. These results have important implications for expression of heterologous genes under control of the phoA promoter. (c) 1996 John Wiley & Sons, Inc.

Application of polyphosphate metabolism to environmental and biotechnological problems.

The synthesis and degradation of polyphosphate (polyP) are influenced by the energy state of the cell and extracellular phosphate levels. The import of excess phosphate and its incorporation into polyP under phosphate- and energy-rich growth conditions allows organisms to survive when phosphate or energy are depleted. Under phosphate-starvation conditions, phosphate can be recovered from polyP by hydrolysis. When the organism is energy starved, energy can be recovered either by regenerating the high-energy phosphoanhydride bond donor (ATP in most cases) or by hydrolysis of polyP and subsequent secretion of orthophosphate to recharge the transmembrane proton gradient. Understanding how the energy state of the cell and environmental phosphate levels affect polyP metabolism is essential to improving such environmental processes as enhanced biological phosphorus removal, a treatment process that is widely used to remove excess phosphate from wastewater. Manipulation of the genes responsible for polyP metabolism can also be used to improve gene expression from phosphate-starvation promoters and to remove heavy metals from contaminated environments.

Complete genome sequence of the genetically tractable hydrogenotrophic methanogen Methanococcus maripaludis.

The genome sequence of the genetically tractable, mesophilic, hydrogenotrophic methanogen Methanococcus maripaludis contains 1,722 protein-coding genes in a single circular chromosome of 1,661,137 bp. Of the protein-coding genes (open reading frames [ORFs]), 44% were assigned a function, 48% were conserved but had unknown or uncertain functions, and 7.5% (129 ORFs) were unique to M. maripaludis. Of the unique ORFs, 27 were confirmed to encode proteins by the mass spectrometric identification of unique peptides. Genes for most known functions and pathways were identified. For example, a full complement of hydrogenases and methanogenesis enzymes was identified, including eight selenocysteine-containing proteins, with each being paralogous to a cysteine-containing counterpart. At least 59 proteins were predicted to contain iron-sulfur centers, including ferredoxins, polyferredoxins, and subunits of enzymes with various redox functions. Unusual features included the absence of a Cdc6 homolog, implying a variation in replication initiation, and the presence of a bacterial-like RNase HI as well as an RNase HII typical of the Archaea. The presence of alanine dehydrogenase and alanine racemase, which are uniquely present among the Archaea, explained the ability of the organism to use L- and D-alanine as nitrogen sources. Features that contrasted with the related organism Methanocaldococcus jannaschii included the absence of inteins, even though close homologs of most intein-containing proteins were encoded. Although two-thirds of the ORFs had their highest Blastp hits in Methanocaldococcus jannaschii, lateral gene transfer or gene loss has apparently resulted in genes, which are often clustered, with top Blastp hits in more distantly related groups.