Metabolic flux profiling of Escherichia coli mutants in central carbon metabolism using GC-MS.

We describe here a novel methodology for rapid diagnosis of metabolic changes, which is based on probabilistic equations that relate GC-MS-derived mass distributions in proteinogenic amino acids to in vivo enzyme activities. This metabolic flux ratio analysis by GC-MS provides a comprehensive perspective on central metabolism by quantifying 14 ratios of fluxes through converging pathways and reactions from [1-13C] and [U-13C]glucose experiments. Reliability and accuracy of this method were experimentally verified by successfully capturing expected flux responses of Escherichia coli to environmental modifications and seven knockout mutations in all major pathways of central metabolism. Furthermore, several mutants exhibited additional, unexpected flux responses that provide new insights into the behavior of the metabolic network in its entirety. Most prominently, the low in vivo activity of the Entner-Doudoroff pathway in wild-type E. coli increased up to a contribution of 30% to glucose catabolism in mutants of glycolysis and TCA cycle. Moreover, glucose 6-phosphate dehydrogenase mutants catabolized glucose not exclusively via glycolysis, suggesting a yet unidentified bypass of this reaction. Although strongly affected by environmental conditions, a stable balance between anaplerotic and TCA cycle flux was maintained by all mutants in the upper part of metabolism. Overall, our results provide quantitative insight into flux changes that bring about the resilience of metabolic networks to disruption.     

Dissection of central carbon metabolism of hemoglobin-expressing Escherichia coli by 13C nuclear magnetic resonance flux distribution analysis in microaerobic bioprocesses

Escherichia coli MG1655 cells expressing Vitreoscilla hemoglobin (VHb), Alcaligenes eutrophus flavohemoprotein (FHP), the N-terminal hemoglobin domain of FHP (FHPg), and a fusion protein which comprises VHb and the A. eutrophus C-terminal reductase domain (VHb-Red) were grown in a microaerobic bioreactor to study the effects of low oxygen concentrations on the central carbon metabolism, using fractional (13)C-labeling of the proteinogenic amino acids and two-dimensional [(13)C, (1)H]-correlation nuclear magnetic resonance (NMR) spectroscopy. The NMR data revealed differences in the intracellular carbon fluxes between E. coli cells expressing either VHb or VHb-Red and cells expressing A. eutrophus FHP or the truncated heme domain (FHPg). E. coli MG1655 cells expressing either VHb or VHb-Red were found to function with a branched tricarboxylic acid (TCA) cycle. Furthermore, cellular demands for ATP and reduction equivalents in VHb- and VHb-Red-expressing cells were met by an increased flux through glycolysis. In contrast, in E. coli cells expressing A. eutrophus hemeproteins, the TCA cycle is running cyclically, indicating a shift towards a more aerobic regulation. Consistently, E. coli cells displaying FHP and FHPg activity showed lower production of the typical anaerobic by-products formate, acetate, and D-lactate. The implications of these observations for biotechnological applications are discussed.     

Mammalian pyruvate kinase hybrid isozymes: tissue distribution and physiological significance

The purpose of this study was to examine the pyruvate kinase isozymic patterns of a wide variety of tissues from rats and mice, particularly regarding hybrid isozymes. For these studies, we employed longer electrophoresis times than used in most earlier studies in order to improve the resolution of closely spaced bands. The tissue distributions of types K, L, and M pyruvate kinases were found to be approximately the same as those reported earlier for rats and other mammals. In addition, K-M hybrids could be detected in most tissues examined in relative quantities which differed from one tissue to another in the same organism, in corresponding tissues from different species, and within a single tissue during development. Hybrid isozymes containing type L subunits occur in only a few tissues of either the fetus or the adult of either animal. In earlier studies utilizing L-M hybrid isozymes produced in vitro, we showed that the kinetic properties of a given subunit are profoundly affected by the nature of its neighbors within the tetramer (Dyson and Cardenas, ['73] J. Biol. Chem., 248: 8482-8488). Based on these altered kinetic properties, we suggest that there is little need for anorganism to suppress completely the gene activity for one subunit type of pyruvate kinase during the synthesis of larger quantities of a second subunit type.     

Tertiary structure of histidine-containing protein of the phosphoenolpyruvate:sugar phosphotransferase system of Escherichia coli

The tertiary structure of the histidine-containing phosphocarrier protein (HPr) of the Escherichia coli phosphoenolpyruvate:sugar phosphotransferase system has been determined by x-ray diffraction at 2.8-A resolution. Initially, a partial structure was fitted to the multiple isomorphous replacement map and then least-squares refined by the Konnert/Hendrickson restrained parameter method (Konnert, J. H., and Hendrickson, W. A. (1980) Acta Crystallogr. A36, 344-350) and finally, a subsequent map was computed by use of the phase combination method of Read (Read, R. J. (1986) Acta Crystallogr. A42, 140-149). More of the protein structure was located in the latter map. The procedure of model building, least-squares refinement, and electron density map recalculation was repeated until the tertiary structure of HPr was obtained. The overall structure of HPr consists of four beta-strands, three helical regions, and four beta-turns. At the active center, the His15 imidazole interacts with one oxygen atom of the alpha-carboxyl C terminus of the polypeptide chain; the conserved Arg17 side chain interacts with the other oxygen atom of the alpha-carboxyl C terminus as well as with the side chain of Glu85. This is the first x-ray analysis of a protein of the phosphoenolpyruvate:sugar phosphotransferase system. Furthermore, this work represents a protein structure which has been solved by starting with a model that represented only one-third of the scattering matter.     

Acetate metabolism in Escherichia coli strains lacking phosphoenolpyruvate: carbohydrate phosphotransferase system; evidence of carbon recycling strategies and futile cycles

The ptsHIcrr operon was deleted from Escherichia coli wild-type JM101 to generate strain PB11 (PTS(-)). In a mutant derived from PB11 that partially recovered its growth capacity on glucose by an adaptive evolution process (PB12, PTS(-)Glc(+)), part of the phosphoenolpyruvate not used in glucose transport has been utilized for the synthesis of aromatic compounds. In this report, it is shown that on acetate as a carbon source, PB11 displayed a specific growth rate (mu) higher than PB12 (0.21 and 0.13 h(-1), respectively) while JM101 had a mu of 0.28 h(-1). To understand these growth differences on acetate, we compared the expression profiles of central metabolic genes by RT-PCR analysis. Obtained data revealed that some gluconeogenic genes were downregulated in both PTS(-) strains as compared to JM101, while most glycolytic genes were upregulated in PB12 in contrast to PB11 and JM101. Furthermore, inactivation of gluconeogenic genes, like ppsA, sfcA, and maeB,and poxB gene that codes for pyruvate oxidase, has differential impacts in the acetate metabolism of these strains. Results indicate that growth differences on acetate in the PTS(-) derivatives are due to potential carbon recycling strategies, mainly in PB11, and futile carbon cycles, especially in PB12.     

Purification of the mannitol-specific enzyme II of the Escherichia coli phosphoenolpyruvate:sugar phosphotransferase system.

The inducible, mannitol-specific Enzyme II of the phosphoenolpyruvate:sugar phosphotransferase system has been purified approximately 230-fold from Escherichia coli membranes. The enzyme, initially solubilized with deoxycholate, was first subjected to hydrophobic chromatography on hexyl agarose and then purified by several ion exchange steps in the presence of the nonionic detergent, Lubrol PX. The purified protein appears homogeneous by several criteria and probably consists of a single kind of polypeptide chain with a molecular weight of 60,000 (+/- 5%). In addition to catalyzing phosphoenolpyruvate-dependent phosphorylation of mannitol in the presence of the soluble enzymes of the phosphotransferase system, the purified Enzyme II also catalyzes mannitol 1-phosphate:mannitol transphosphorylation in the absence of these components. A number of other physical and catalytic properties of the enzyme are described. The availability of a stable, homogeneous Enzyme II should be invaluable for studying the mechanism of sugar translocation and phosphorylation catalyzed by the bacterial phosphotransferase system.     

An inducible phosphoenolpyruvate: dihydroxyacetone phosphotransferase system in Escherichia coli

A phosphoenolpyruvate: dihydroxyacetone phosphotransferase was induced in Escherichia coli grown on dihydroxyacetone as sole carbon source or in its presence. This is the first example of a triose which can be acted upon by the membrane complex to provide a central intermediate in glycolysis. The presence of this system explains the ability of a mutant, in which the ATP-dependent glycerol kinase is genetically replaced by a glycerol: NAD 2-oxidoreductase, to grow on glycerol.     

Characterization of mutant histidine-containing proteins of the phosphoenolpyruvate:sugar phosphotransferase system of Escherichia coli and Salmonella typhimurium.

Histidine-containing phosphocarrier protein (HPr) is common to all of the phosphoenolpyruvate:sugar phosphotransferase systems (PTS) in Escherichia coli and Salmonella typhimurium, except the fructose-specific PTS. Strains which lack HPr activity (ptsH) have been characterized in the past, and it has proved difficult to delineate between tight and leaky mutants. In this study four different parameters of ptsH strains were measured: in vitro sugar phosphorylation activity of the mutant HPr; detection of 32P-labeled P-HPr; ability of monoclonal antibodies to bind mutant HPr; and sensitivity of ptsH strains to fosfomycin. Tight ptsH strains could be defined; they were fosfomycin resistant and produced no HPr protein or completely inactive mutant HPr. All leaky ptsH strains were fosfomycin sensitive, usually produced normal amounts of mutant HPr protein, and had low but measurable activity, and HPr was detectable as a phosphoprotein. This indicates that the regulatory functions of the PTS require a very low level of HPr activity (about 1%). The antibodies used to detect mutant HPr in crude extracts were two monoclonal immunoglobulin G antibodies Jel42 and Jel44. Both antibodies, which have different pIs, inhibited PTS sugar phosphorylation assays, but the antibody-HPr complex could still be phosphorylated by enzyme I. Preliminary evidence suggests that the antibodies bind to two different epitopes which are in part located in a beta-sheet structure.     

Genetic analysis of succinate utilization in enzyme I mutants of the phosphoenolpyruvate: sugar phosphotransferase system in Escherichia coli.

Studies on the reversion characteristics of Escherichia coli strains carrying various mutations in the pts region have led to the recognition of a mutation, suc-1, with a previously undescribed phenotype. Strains carrying the suc-1 mutation grow normally on most sources of carbon but are unable to utilize succinate effectively. The suc-1 mutation can be separated genetically from the tightly linked ptsI6 mutation. Reversion of suc-1 mutants for growth on succinate yields interesting classes of suppressor mutations.     

Substitution of aspartate and glutamate for active center histidines in the Escherichia coli phosphoenolpyruvate:sugar phosphotransferase system maintain phosphotransfer potential

The active center histidines of the Escherichia coli phosphoenolpyruvate:sugar phosphotransferase system proteins; histidine-containing protein, enzyme I, and enzyme IIA(Glc) were substituted with a series of amino acids (serine, threonine, tyrosine, cysteine, aspartate, and glutamate) with the potential to undergo phosphorylation. The mutants [H189E]enzyme I, [H15D]HPr, and [H90E]enzyme IIA(Glc) retained ability for phosphorylation as indicated by [(32)P]phosphoenolpyruvate labeling. As the active center histidines of both enzyme I and enzyme IIA(Glc) undergo phosphorylation of the N(epsilon2) atom, while HPr is phosphorylated at the N(delta1) atom, a pattern of successful substitution of glutamates for N(epsilon2) phosphorylations and aspartates for N(delta1) phosphorylations emerges. Furthermore, phosphotransfer between acyl residues: P-aspartyl to glutamyl and P-glutamyl to aspartyl was demonstrated with these mutant proteins and enzymes.     

Real-time detection of central carbon metabolism in living Escherichia coli and its response to perturbations

The direct tracking of cellular reactions in vivo has been facilitated with recent technologies that strongly enhance NMR signals in substrates of interest. This methodology can be used to assay intracellular reactions that occur within seconds to few minutes, as the NMR signal enhancement typically fades on this time scale. Here, we show that the enhancement of (13)C nuclear spin polarization in deuterated glucose allows to directly follow the flux of glucose signal through rather extended reaction networks of central carbon metabolism in living Escherichia coli. Alterations in central carbon metabolism depending on the growth phase or upon chemical perturbations are visualized with minimal data processing by instantaneous observation of cellular reactions.     

The Escherichia coli adenylate cyclase complex. Regulation by enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system.

The activity of adenylate cyclase of Escherichia coli measured in toluene-treated cells under standard conditions is subject to control by the phosphoenolpyruvate:sugar phosphotransferase system (PTS). Sugars such as glucose, which are transported by the PTS, will inhibit adenylate cyclase provided the PTS is functional. An analysis was made of the properties of E. coli strains carrying mutations in PTS proteins. Leaky mutants in the PTS protein HPr are similar to wild-type strains with respect to cAMp regulation; adenylate cyclase activity in toluene-treated cells and intracellular cAMP levels are in the normal range. Furthermore, adenylate cyclase in toluene-treated cells of leaky HPr mutants is inhibited by glucose. In contrast, mutations in the PTS protein Enzyme I result in abnormalities in cAMP regulation. Enzyme I mutants generally have low intracellular cAMP levels. Leaky Enzyme I mutants show an unusual phosphoenolpyruvate-dependent activation of adenylate cyclase that is not seen in Enzyme I⁺ revertants or in Enzyme I deletions. A leaky Enzyme I mutant exhibits changes in the temperature-activity profile for adenylate cyclase, indicating that adenylate cyclase activity is controlled by Enzyme I. Temperature-shift studies suggest a functional complex between adenylate cyclase and a regulator protein at 30 °C that can be reversibly dissociated at 40 °C. These studies further support the model for adenylate cyclase activation that involves phosphoenolpyruvate-dependent phosphorylation of a PTS protein complexed to adenylate cyclase.