Evolutionary cheating in Escherichia coli stationary phase cultures

Starved cultures of Escherichia coli are highly dynamic, undergoing frequent population shifts. The shifts result from the spread of mutants able to grow under conditions that impose growth arrest on the ancestral population. To analyze competitive interactions underlying this dynamic we measured the survival of a typical mutant and the wild type during such population shifts. Here we show that the survival advantage of the mutant at any given time during a takeover is inversely dependent on its frequency in the population, its growth adversely affects the survival of the wild type, and its ability to survive in stationary phase at fixation is lower than that of its ancestor. These mutants do not enter, or exit early, the nondividing stationary-phase state, cooperatively maintained by the wild type. Thus they end up overrepresented as compared to their initial frequency at the onset of the stationary phase, and subsequently they increase disproportionately their contribution in terms of progeny to the succeeding generation in the next growth cycle, which is a case of evolutionary cheating. If analyzed through the game theory framework, these results might be explained by the prisoner's dilemma type of conflict, which predicts that selfish defection is favored over cooperation.     

Persistence of pBR322-related plasmids in Escherichia coli grown in chemostat cultures

Abstract The stability of plasmid pBR322 and a number of close derivatives was examined by continuous culture of Escherichia coli . Cultures were subjected to either glucose, phosphate or magnesium limitation in non-selective medium at a dilution rate of 0.1/h. Under these conditions pBR322 was eventually lost from the population, but only after a distinct lag period. The closely related plasmids pBR325 and especially pBR327 and pBR328, but not pAT153, were lost more rapidly. Three cosmids pHC79, pSJ55 and pJB8 were generally found to be less stable than the pBR322-type plasmids from which they were derived. Chimaeric plasmids containing DNA from yeast and from a thermophilic bacillus were also unstable in E. coli .     

Correlation between steady-state cell concentration and cell death of hybridoma cultures in chemostat

In the present study, the steady-state cell density (X) of chemostat cultures of murine hybridoma was varied by the concentration of glucose and glutamine in culture medium and the dissolved oxygen partial pressure. Except at low glutamine and low oxygen levels, the specific death rate (k(d)) of the cultures was found to decrease with increasing dilution rate (D). However, the plot of k(d) vs. X/D yielded linear relation, which suggests that cell death was due to a non-growth-linked inhibitory product of the cells. The k(d) value measured at low glutamine and low oxygen levels remained practically unchanged over a wide range of D between 0.020 and 0.029 h(-1). The k(d) for low oxygen cultures was always lower than the values obtained in low glucose and low glutamine cultures. A low-molecular-weight component of possibly less than 3000 MW was detected to be cell-death-inducing in the supernatant of exponentially growing cultures. It was neither lactate nor ammonium. The autoinhibitor was not cell-line specific. (c) 1995 John Wiley & Sons, Inc.     

Bistability in the activity of glutamine synthetase in ammonium-limiting chemostat cultures of Escherichia coli ML 30]

The approximative estimation of the function micron([NH+4]) in cultures of E. coli ML 30 had shown that bistability of the ammonium concentration in ammonium limited continuous cultures could be possible (BERGTER et al. 1977). This phenomenon suggested a bistability in the regulation of ammonia assimilation. Therefore, the activity of one key enzyme of the two ammonia assimilation systems was measured. The distribution of the activity of glutamine synthetase in ammonia limited continuous cultures after different transition states confirmed this suggestion.     

Replication and repair of UV-induced mutational lesions in chemostat cultures of Escherichia coli WP2 Hcr

Mutation to resistance to bacteriophage T5 was studied in chemostat cultures of Escherichia coli strain WP2 Hcr exposed to ultraviolet radiation (UV). The results are in generally good agreement with those obtained earlier by Bridges and Munson for UV-induced reversion to tryptophan independence in exponentially growing cultures of the same strain: expressed mutant yields followed a dose-squared response, mutations were not expressed before approximately one generation after exposure to UV, there was a slow disappearance of dimers especially noticeable in slowly growing and stationary cultures, and the first replication gave rise to duplex mutants in both strands. Several new results were also obtained. In addition to expressed mutant yields, induction of mutational capacity was also observed to follow a dose-squared response, indcating that the response is not an artifact of selection or repair. Induction also increased with growth rate, apparently as the square of the number of genes for T5-sensitivity per cell. It is suggested that mutagenesis is proportional to the number of genes per cell, that recombination is also proportional to the number of genes per cell, and that the number of mutational lesions is proportional to the product of the two. These results also provide evidence that DNA replication occurs near the end of the cell cycle in slowly growing cultures. Under all growth conditions, latent mutant concentrations mutational capacity) decreased by a factor of two with each successive division. Latent mutants were, however, photoreversible for only the first two generations. If mutagenesis occurs as a recombinant event between two mutational lesions, then the results also indicate that these lesions are separated, on the average, by no more than a single cistron.     

Enhanced fitness of recombinant protein synthesis in the stationary phase of Escherichia coli batch cultures

The ability to synthesize both recombinant and homologous cell proteins has been studied during the stationary phase of E. coli batch cultures. The anabolic potential of the culture dramatically decreases when entering into the stationary phase but slightly recovers several hours latter. In addition, CI857-controlled production of -galactosidase is transiently enhanced at late stages of the stationary phase. These results show a non-synchronous distribution of the biosynthetic resources throughout culture growth phases, favouring the production of recombinant proteins in both exponentially growing and aged, stationary cells.     

Regulation of bistability in glucose metabolism of Escherichia coli ML 30 chemostat cultures by cyclic AMP

Evidence is presented that cyclic AMP is engaged in the regulation of a bistability in the glucose and energy metabolism of NH3-limited chemostat cultures of Escherichia coli ML 30. Cyclic AMP probably reverses the repression of the citric acid cycle by glucose favouring the state of glycogen and energy overproduction.     

Effect of glucose analog supplementation on metabolic flux distribution in anaerobic chemostat cultures of Escherichia coli

Previous work in our laboratories investigated the use of methyl alpha-glucoside (alpha-MG), a glucose analog that shares a phosphotransferase system with glucose, to modulate glucose uptake and therefore reduce acetate accumulation. The results of that study showed a significant improvement in batch culture performance and a reduction in acetate excretion without any significant effect on the growth rate in complex medium. The current study investigates the effect of supplementing the culture medium with the glucose analog alpha-MG on the metabolic fluxes of Escherichia coli under anaerobic chemostat conditions at two different dilution rates. Anaerobic chemostat studies utilizing complex media supplemented with glucose or glucose and alpha-MG at dilution rates of 0.1 and 0.4 h(-1), were performed, and the metabolic fluxes were analyzed. It was found that the addition of the glucose analog alpha-MG has an effect on the specific production rate of various extracellular metabolites. This effect is slightly greater at the higher dilution rate of 0.4 h(-1). However, the glucose analog does not cause any major shift in the central metabolic patterns. It was further observed that alpha-MG supplementation does not result in the reduction in specific acetate synthesis rate in anaerobic chemostat cultures. These results emphasize the importance of testing different strategies for metabolic manipulation under the actual operating conditions.     

Determinants of the quantity of the stable SecY complex in the Escherichia coli cell.

While SecY in wild-type Escherichia coli cells is stable and is complexed with other proteins within the membrane, moderately overexpressed and presumably uncomplexed SecY was degraded with a half-life of 2 min. The fact that the amount of stable SecY is strictly regulated by the degradation of excess SecY was demonstrated by competitive entry of the SecY+ protein and a SecY-LacZ alpha fusion protein into the stable pool. Simultaneous overexpression of SecE led to complete stabilization of excess SecY. Overproduced SecD and SecF did not affect the stability of SecY, but plasmids carrying ORF12 located within the secD-secF operon partially stabilized this protein. In contrast, mutational reduction of the SecE content (but not the ORF12 content) led to the appearance of two populations of newly synthesized SecY molecules, one that was immediately degraded and one that was completely stable. Thus, the E. coli cell is equipped with a system that eliminates SecY unless it is complexed with SecE, a limiting partner of SecY. Our observations implied that in wild-type cells, SecY and SecE rapidly associate with each other and remain complexed.     

Regulation of ammonia assimilation in ammonia-limited chemostat cultures of Escherichia coli ML 30: evidence of bistability

In a preceding paper evidence of two stationary stable states (bistability) in the specific activity of glutamine synthetase (GS) in ammonia-limited steady-state cultures of Escherichia coli ML 30 at dilution rates (D) about 0.15 h-1 was described (Müller et al. 1977). For better understanding of the regulation mechanisms leading to GS bistability chemostat experiments were performed over a wide range of dilution rates up to D = 0.8 h-1. For each steady state the specific activities of GS and glutamate dehydrogenase (GDH)--the other key enzyme of the two NH3 assimilation routes in E. coli--and in addition the remaining NH3 concentration in the culture liquid were determined. Parallel to GS bistability two states of GDH activity and NH3 concentration are found. The higher state of GS is connected with a lower GDH activity and NH3 concentration. With rising D the GS activities decrease whereas GDH activities and NH3 concentrations increase. Since no adenylation of the GS is detectable GS bistability seems to be regulated on the level of enzyme synthesis like GDH bistability. From the experimental findings a mathematical model is derived based on the bottle neck enzyme theory of growth. It describes the dependence between the specific growth rates on the one hand and the specific enzyme activities and NH3 concentration on the other. It is shown that the specific uptake rate of the limiting NH3 and the specific growth rates, respectively, depend on the simultaneous action of two bottle neck enzymes which are connected by a regulative link.     

Oscillations in the synthesis of cell wall components in synchronized cultures of Escherichia coli.

The rate of cell wall synthesis with respect to both proteins and lipids was determined in synchronized cultures of Escherichia coli B/r. Whereas the rate of total protein synthesis showed an exponential increase with cell age, the rate of incorporation of proteins and lipids into cell wall had a maximum at a cell age of 30 to 35 min, 15 min before cell division. This oscillation was observed in both the cytoplasmic membrane and in the outer membrane of the cell envelope.     

More stable structure of wheat germ lipase at low pH than its native state

Wheat germ lipase is a cereal lipase which is a monomeric protein. In the present study we sought to structurally characterize this protein along with equilibrium unfolding in solution. Conformational changes occurring in the protein with varying pH, were monitored by circular dichroism (CD) spectroscopy, fluorescence emission spectroscopy, binding of hydrophobic dye, 1-anilino 8-naphthalenesulfonic acid (ANS) and dynamic light scattering (DLS). Our study showed that acid denaturation of lipase lead to characterization of multiple monomeric intermediates. Native protein at pH 7.0 showed far-UV spectrum indicating mixed structure with both alpha and beta-type of characteristics. Activity of lipase was found to fall on either sides of pH 7.0–8.0. Acid-unfolded state was characterized at pH 4.0 with residual secondary structure, disrupted tertiary spectrum and red-shifted fluorescence spectrum with decreased intensity. Further decrease in pH lead to formation of secondary structure and acid-induced molten globule state was found to be stabilized at pH 1.4, with exposed tryptophan residues and hydrophobic patches. Notably, interesting finding of this study was characterization of acid-induced state at pH 0.8 with higher secondary structure content than native lipase, regain in tertiary spectrum and induction of compact conformation. Although enzymatically inactive, acid-induced state at pH 0.8 was found to be structurally more stable than native lipase, as shown by chemical and thermal denaturation profiles.     

Establishment of the steady state in glucose-limited chemostat cultures of Klebsiella pneumoniae

To investigate the relationship between growth rate and concentration of the nutrient that limits growth, 'Klebsiella aerogenes' NCTC 418 (K. pneumoniae) was grown in a glucose-limited chemostat. The actual time required to establish a steady-state glucose concentration exceeded that expected theoretically. Apparently, there is a long-term adaptation of the cells to nutrient limitation. As yet, it is not clear whether this has a phenotypic or genetic origin. In the final steady state, the dependence of the growth rate on glucose concentration could be mathematically described equally well by a hyperbolic and by a logarithmic function.     

Effect of different levels of NADH availability on metabolic fluxes of Escherichia coli chemostat cultures in defined medium

Escherichia coli overexpressing a NAD(+)-dependent formate dehydrogenase (FDH) from Candida boidinii was grown in chemostat culture on various carbon sources at 0.05 h(-1) dilution rate, under anaerobic conditions using defined medium and compared to a control without the heterologous FDH pathway. Metabolic fluxes, NADH/NAD(+) ratios and NAD(H/(+)) levels were determined under a range of intracellular NADH availability. The effect of NADH manipulation on the distribution of metabolic fluxes in E. coli was assessed under steady-state conditions. The heterologous FDH pathway converts 1 mol of formate into 1 mol of NADH and carbon dioxide, in contrast with the native FDH where no cofactor involvement is present. Previously, we found that this NADH regeneration system doubled the maximum yield of NADH from 2 to 4 mol NADH/mol glucose consumed and reached 4.6 mol NADH/mol of substrate when sorbitol was used as a carbon source in a complex medium. In the current study, it was found that higher NADH yields and NADH/NAD(+) ratios were achieved with our in vivo NADH regeneration system compared to a control lacking the new FDH pathway in the three carbon sources (glucose, gluconate and sorbitol) examined suggesting a more reduced intracellular environment. The total NAD(H/(+)) amounts were very similar for all the combinations studied. It was also found that the ethanol to acetate ratio increased with increased NADH availability. This ratio increased from 1.05 for the control strain in glucose to 9.45 for the strain expressing the heterologous NAD(+)-dependent FDH in sorbitol.