Inorganic polyphosphate in Vibrio cholerae: genetic, biochemical, and physiologic features.

Vibrio cholerae O1, biotype El Tor, accumulates inorganic polyphosphate (poly P) principally as large clusters of granules. Poly P kinase (PPK), the enzyme that synthesizes poly P from ATP, is encoded by the ppk gene, which has been cloned from V. cholerae, overexpressed, and knocked out by insertion-deletion mutagenesis. The predicted amino acid sequence of PPK is 701 residues (81.6 kDa), with 64% identity to that of Escherichia coli, which it resembles biochemically. As in E. coli, ppk is part of an operon with ppx, the gene that encodes exopolyphosphatase (PPX). However, unlike in E. coli, PPX activity was not detected in cell extracts of wild-type V. cholerae. The ppk null mutant of V. cholerae has diminished adaptation to high concentrations of calcium in the medium as well as motility and abiotic surface attachment.

The Escherichia coli starvation gene cstC is involved in amino acid catabolism.

Escherichia coli strains mutant in the starvation gene cstC grow normally in a mineral salts medium but are impaired in utilizing amino acids as nitrogen sources. They are also compromised in starvation survival, where amino acid catabolism is important. The cstC gene encodes a 406-amino-acid protein that closely resembles the E. coli ArgD protein, which is involved in arginine biosynthesis. We postulate that CstC is a counterpart of ArgD in an amino acid catabolic pathway. The cstC upstream region contains several regulatory consensus sequences. Both sigmaS and sigma54 promoters are probably involved in cstC transcription and appear to compete with each other, presumably to match cstC expression to the cellular amino acid catabolic needs.

Novel assay reveals multiple pathways regulating stress-induced accumulations of inorganic polyphosphate in Escherichia coli.

A major impediment to understanding the biological roles of inorganic polyphosphate (polyP) has been the lack of sensitive definitive methods to extract and quantitate cellular polyP. We show that polyP recovered in extracts from cells lysed with guanidinium isothiocynate can be bound to silicate glass and quantitatively measured by a two-enzyme assay: polyP is first converted to ATP by polyP kinase, and the ATP is hydrolyzed by luciferase to generate light. This nonradioactive method can detect picomolar amounts of phosphate residues in polyP per milligram of extracted protein. A simplified procedure for preparing polyP synthesized by polyP kinase is also described. Using the new assay, we found that bacteria subjected to nutritional or osmotic stress in a rich medium or to nitrogen exhaustion had large and dynamic accumulations of polyP. By contrast, carbon exhaustion, changes in pH, temperature upshifts, and oxidative stress had no effect on polyP levels. Analysis of Escherichia coli mutants revealed that polyP accumulation depends on several regulatory genes, glnD (NtrC), rpoS, relA, and phoB.

Use of Starvation Promoters To Limit Growth and Selectively Enrich Expression of Trichloroethylene- and Phenol-Transforming Activity in Recombinant Escherichia coli.

Volume 61, no. 9, p. 3323: the title of the article should read as shown above. [This corrects the article on p. 3323 in vol. 61.].

Use of starvation promoters to limit growth and selectively enrich expression of trichloroethylene- and phenol-transforming activity in recombinant Escherichia coli [corrected].

The expression of much useful bacterial activity is facilitated by rapid growth. This coupling can create problems in bacterial fermentations and in situ bioremediation. In the latter process, for example, it necessitates addition of large amounts of nutrients to contaminated environments, such as aquifers. This approach, termed biostimulation, can be technically difficult. Moreover, the resulting in situ bacterial biomass production can have undesirable consequences. In an attempt to minimize coupling between expression of biodegradative activity and growth, we used Escherichia coli starvation promoters to control toluene monooxygenase synthesis. This enzyme complex can degrade the environmental contaminants trichloroethylene (TCE) and phenol. Totally starving cell suspensions of such strains degraded phenol and TCE. Furthermore, rapid conversions occurred in the postexponential batch or very slow growth (dilution) rate chemostat cultures, and the nutrient demand and biomass formation for transforming a given amount of TCE or phenol were reduced by 60 to 90%. Strong starvation promoters have recently been clones and characterized in environmentally relevant bacteria like Pseudomonas species; thus, starvation promoter-driven degradative systems can now be constructed in such bacteria and tested for in situ efficacy.

The putative sigma factor KatF is regulated posttranscriptionally during carbon starvation.

Transcriptional and translational 'lacZ reporter fusions were constructed to the katF gene, which encodes a putative sigma factor centrally involved in starvation-mediated general resistance in Escherichia coli. Transcription of katF was found to increase ca. twofold after carbon starvation in minimal medium. The protein fusion containing the longest fragment of katF induced ca. eightfold under the same conditions, whereas fusions to shorter segments showed only a twofold increase in expression. The protein fusion was expressed at higher levels in a strain containing a katF::Tn10 mutation, indicating katF autoregulation. The posttranscriptional regulation of katF by starvation did not require a component of the spent minimal medium. katF was also posttranscriptionally regulated during entry into late log phase in complex medium. This induction was coincident with an increase in katE transcription, suggesting that the cellular concentration of KatF directly followed the induction of the katF protein fusion.