Kinetics of benzoate-induced loss of the TOL plasmid from Pseudomonas putida MT15 during growth in chemostat culture

Potassium-limited chemostat cultures of Pseudomonss putida MT15, grown on excess glucose, displayed approximately 100% plasmid loss after 60 generations of growth in the presence of 5 mM benzoate. The kinetics of plasmid loss indicated that plasmid-free cells displayed a growth rate advantage, which we attribute to selective inhibition of the growth of plasmid-containing cells by benzoate. However, stable, mixed populations of plasmid-free cells, deletants and plasmid-containing cells were selected during growth under glucose limitation in the presence of benzoate. This behaviour indicated that the plasmid-free cells in these cultures displayed a growth rate disadvantage and that their appearance was due entirely to benzoate-induced segregational instability of the plasmid.     

Data analysis of plasmid stability in continuous culture of recombinantSaccharomyces cerevisiae

Summary A simple method using non-linear regression is developed to analyse experimental data from plasmid stability studies of recombinantSaccharomyces cerevisiae grown in continuous cultures with non-selective and selective media. This method simultaneously provides quantitative information on the probability of plasmid loss due to segregation during cell division and the specific growth rates of plasmid-containing and plasmid-free cells at particular dilution rates. The method is applied to a set of experimental data. The three-parameter model, together with the estimated parameter values, provides a good fit to the experimental data.     

Adaptation of Escherichia coli growth rates to the presence of pBR322

Changes in the growth rate of Escherichia coli K12 J62-1 in response to the presence of plasmid pBR322 have been investigated. Plasmid-free and plasmid-containing strains were grown in batch culture and their maximum specific growth rate (μ_max) determined. The acquisition of pBR322 by the host resulted in a decreased μ_max. Following repeated subculturing of the plasmid-containing strain on selective medium, restoration in μ_max was observed. The copy number and structure of the plasmid were not significantly altered during the experiment Growth rate measurements for a series of strains constructed using a combination of host cells and plas-mids with and without culture histories, indicated that the site of the adaptive mutation was located on the host chromosome rather than on the plasmid.     

Stability studies of recombinant Saccharomyces cerevisiae in the presence of varying selection pressure

A recombinant yeast plasmid carrying the Ieu2 gene for auxotrophic complementation and a reporter gene for beta-galactosidase under the control of Gal10 promoter was studied in Saccharomyces cerevisiae. Growth, product formation, and plasmid stability were studied in defined, semi-defined, and complex media. The biomass concentration and specific activity were higher in complex medium than in defined medium, which was selective for the growth of plasmid-containing cells, leading to a 10-fold increase in volumetric activity. However, plasmid instability was very high in complex media with 50% plasmid-free cells emerging in the culture within 75 h of cultivation. In order to control instability, the growth rates of the plasmid-containing and plasmid-free cells were determined in semi-defined media, which consisted of defined medium supplemented with different concentrations of yeast extract. Below a critical concentration of yeast extract (0.05 g/L), the plasmid-containing cells had a growth rate advantage over the plasmid-free cells. This was possibly because, at this concentration of yeast extract, the availability of leucine became the rate-determining factor in the specific growth rate of plasmid-free cells. A feeding strategy was designed which maintained a low concentration of the residual yeast extract in the medium and thus continuously provided the plasmid-containing cells with a competitive advantage over the plasmid-free cells. This resulted in high stability as well as high cell density under non-selective conditions, which led to a 10-fold increase in the volumetric activity compared to that achieved in defined selective media. A simple mathematical model was formulated to verify the experimental data. The important state variables and process parameters, i.e., biomass concentration, beta-galactosidase expression, sucrose consumption, yeast extract consumption, and specific growth rates of the two cell populations, were evaluated. These variables and parameters along with the differential equations based on material balances as well as the experimental results obtained were used in a mathematical model for the fed-batch cultivation. These correctly verified the experimental data and clearly illustrated the concept behind the success of the fed-batch strategy under yeast extract starvation.     

Frequency-Dependent Selection for Plasmid-Containing Cells of ESCHERICHIA COLI

Colicin-producing plasmid-containing cells of E. coli exhibit frequency-dependent selection when grown in glucose-limited continuous culture with the corresponding plasmid-free strain. The bases of this frequency-dependent effect are shown to be (1) the lower growth rate of the plasmid-containing strain under these conditions, and (2) the production of colicin, which attenuates the growth rate of the plasmid-free strain. These results are discussed in relationship to the maintenance of genetic variation in prokaryotes.     

Analysis of unstable recombinant Saccharomyces cerevisiae population growth in selective medium

Widely applied selection strategies for plasmid-containing cells in unstable recombinant populations are based upon synthesis in those cells of an essential, selection gene product. Regular partitioning of this gene product combined with asymmetric plasmid segregation produces plasmid-free cells which retain for some time the ability to grow in selective medium. This theory is elaborated here in terms of a segregated model for an unstable recombinant population which predicts population growth characteristics and composition based upon experimental data for stable strain growth kinetics, plasmid content, and selection gene product stability. Analytical solutions from this model are compared with an unsegregated phenomenological model to evaluate the effective specific growth rate of plasmid-free cells in selective medium. Model predictions have been validated using experimental growth kinetics and flow cytometry data for Saccharomyces cerevisiae D603 populations containing one of the plasmids YCpG1ARS1, YCpG1DeltaR8, YCpG1DeltaR88, YCpG1DeltaH103, YCpG1DeltaH200, pLGARS1, and pLGSD5. The recombinant strains investigated encompass a broad range of plasmid content (from one to 18 plasmids per cell) and probability alpha of plasmid loss at division (0.05 相似文献   

Effect of R-plasmid RP1 on surface hydrophobicity of Proteus mirabilis

The presence of R-plasmid RP1, as well as the conditions of growth, affected the surface hydrophobicity of a clinical isolate of Proteus mirabilis. However, results depended upon the method of assessment. Stationary phase plasmid-containing cells appeared to be less hydrophobic than plasmid-free cells when hydrophobicity was measured by the contact angle method, but more hydrophobic when measured by bacterial adherence to hydrocarbons or hydrophobic interaction chromatography. Cells growing in a chemostat differed in hydrophobicity from stationary phase cells and results varied with the growth rate. Plasmid-mediated effects were greatest in iron-depleted cells, and differences between plasmid-containing and plasmid-free cells were virtually eliminated by pre-treatment with antiserum.     

Variation and modeling of the probability of plasmid loss as a function of growth rate of plasmid-bearing cells of Escherichia coli during continuous cultures

A large number of models concerning cultures of genetically engineered bacteria have been described. Among them, some are specifically adapted to continuous cultures and lead to the determination of two variables: (i) the difference in the specific growth rates between plasmid-carrying cell and plasmid-free cells (deltamu) and (ii) the frequency of plasmid loss by plasmid-containing cells (p(r)mu(+)). Until now, studies have been performed on the global expression p(r)mu(+) and deltamu, whose value during continuous assays have been supposed approximately constant (mean value) and not on separate values of both terms p(r) and mu(+), respectively, probability of plasmid loss and specific growth rate of the plasmid-carrying cells. So far these studies do not allow examination of the relationship between these two last parameters. Experimental results were obtained with Escherichia coli C600 galk (GAPDH), a genetically engineered strain that synthetizes an elevated quantity of glyceraldehyde-3-phosphate dehydrogenase (GAPDH). From data obtained during continuous cultures, it is shown that during an assay, deltamu, and p(r)mu(+) do not remain constant. An appropriate mathematical analysis of the expression of mu(-) (specific growth rate of the plasmid-free cells) and mu(+) has been built up. This allows the evaluation of the values of mu(+) and mu(-) during the continuous cultures carried out at different dilution rates. Values of p(r) have been calculated from these data. Indeed our results show that p(r) increases with mu(+). A modeling approach which allows correct simulation of this variation is also proposed. This model is derived from the Hill equation regarding cooperative binding of enzymic type reaction. (c) 1993 John Wiley & Sons, Inc.     

Effect of growth rate on stability and gene expression of a recombinant plasmid during continuous culture ofEscherichia coli in a non-selective medium

Summary Experimental results were obtained withEscherichia coli C600 galK (GAPDH), a genetically engineered strain that synthetizes a large quantity of glyceraldehyde-3-phosphate dehydrogenase (GAPDH), (80 % of the soluble proteins). Data concerning the stability of plasmid-containing cells and gene expression as a function of dilution rate have been obtained in continuous cultures. Contrary to other studies, our results show a clear indication that the rate of the recombinant activity was dependent on dilution rate. The results support the finding that the apparent stability of the plasmid decreases with dilution rate.     

A segregated model for plasmid content and product synthesis in unstable binary fission recombinant organisms

Plasmid propagation in populations of unstable, binary fission recombinant organisms has been studied using a segregated, population balance mathematical model. Segregated models have the advantage of direct incorporation of basic information on mechanisms and kinetics of plasmid replication and segregation at the single-cell level. The distribution of cellular plasmid content and specific rates of plasmid gene expression have been obtained for several single-cell models of plasmid replication, partition, and gene expression. Plasmid replication kinetics during cell growth significantly influence the plasmid content distribution. In the case of transient growth of plasmid-containing and plasmid-free cells in partially selective medium, the degree of selection required for stable maintenance of plasmid-containing cells has been determined. Guidelines are presented for applicability of simpler, nonsegregated models and for evaluation of the parameters in these models based on single-cell mechanisms and associated parameters.     

Plasmid instability in an industrial strain ofBacillus subtilis grown in chemostat culture

Summary A pUB110-derived plasmid/Bacillus subtilis host combination was segregationally unstable when grown in chemostat culture with complex or minimal medium and under starch, glucose or magnesium limitation. The kinetics of plasmid loss were described in terms of the difference in growth rates between plasmid-containing and plasmid-free cells (d) and the rate at which plasmid-free cells were generated from plasmid-containing cells (R). Loss of plasmid-containing cells from the population was d dominated. Changes in medium composition and the nature of growth limitation caused variations in both d and R. The plasmid was most stable in glucose-limited chemostat cultures with minimal medium and least stable under starch limitation with complex complex medium. R and d were smaller for cultures in complex media than those in minimal media. Limitation by starch induced expression of the plasmid-encoded HT amylase gene and was associated with increased values of R and d. Magnesium limitation in minimal medium caused a significant increase in d and a decrease in R.Abbreviations Cm chloramphenicol - Kan kanamycin - Cm^r cells resistant to chloramphenicol (5 mg L^–1) - Kan^r cells resistant to kanamycin (5 mg L^–1) - Cm^sKan^s cells sensitive to chloramphenicol and kanamycin     

Effect of growth conditions on the rate of loss of the plasmid pAT153 from continuous cultures of Escherichia coli HB101

Abstract The plasmid pAT153 was lost less rapidly from carbon, nitrogen, phosphorous or sulphur-limited continuous cultures of Escherichia coli HB101 as the dilution rate increased. At a fixed dilution rate of 0.3 h⁻¹, the plasmid was maintained longer as the growth-limiting nutrient was changed from glucose to casamino acids (nitrogen-limited), phosphate or sulphate. These differences in the stability of maintenance were not due to parallel changes in the plasmid copy number. We propose that the rate of loss of pAT153 from E. coli HB101 is determined primarily by the ratio of growth rates of plasmid-containing bacteria and plasmid-free bacteria. This ratio increases with increasing growth rate and depends markedly on the growth-limiting nutrient, sulphate-limited growth being particularly suitable for the maintenance of this host-plasmid combination.     

The yeast 2 micron plasmid: strategies for the survival of a selfish DNA

Summary The designation of the yeast 2 circle as a selfish DNA molecule has been confirmed by demonstrating that the plasmid is lost with exponential kinetics from haploid yeast populations grown in continuous culture. We show that plasmid-free yeast cells have a growth rate advantage of some 1.5%–3% over their plasmid-containing counterparts. This finding makes the ubiquity of this selfish DNA in yeast strains puzzling. Two other factors probably account for its survival. First, the rate of plasmid loss was reduced by allowing haploid populations to enter stationary phase periodically. Second, it was not possible to isolate a plasmid-free segregant from a diploid yeast strain. Competition experiments demonstrated that stability in a diploid is conferred at the level of segregation and that plasmid-free diploid cells are at a selective advantage compared with their plasmid-containing counterparts. Yeast cells in nature are usually homothallic and must frequently pass through both diploid and stationary phases. The 2 plasmid appears to have evolved a survival strategy which exploits these two features of its host's life cycle.     

Effects of medium composition and nutrient limitation on loss of the recombinant plasmid pLG669-z and β -galactosidase expression by Saccharomyces cerevisiae

The effects of medium composition, nutrient limitation and dilution rate on the loss of the recombinant plasmid pLG669-z and plasmid-borne β -galactosidase expression were studied in batch and chemostat cultures of Saccharomyces cerevisiae strain CGpLG. The difference in growth rates between plasmid-free and plasmid-containing cells (Δμ) and the rate of segregation (R) were determined and some common factors resulting from the effect of medium composition on plasmid loss were identified. Glucose-limited chemostat cultures of CGpLG grown on defined medium were more stable at higher dilution rates and exhibited Δμ -dominated plasmid loss kinetics. Similar cultures grown on complex medium were more stable at lower dilution rates and exhibited R-dominated plasmid loss kinetics. Overall plasmid stability was greatest in phosphate-limited chemostat cultures grown on defined medium and was least stable in magnesium-limited cultures grown on defined medium. Δμ decreased and R increased with increased dilution rate, irrespective of medium composition. Increased plasmid loss rates at high or low dilution rates would appear to be characteristic of loss kinetics dominated by R or Δμ, respectively. Growth of glucose-limited chemostat cultures on complex medium decreased Δμ values but increased R values, in comparison to those cultures grown on defined medium. Any increased stability that a complex medium-induced reduction of Δμ may have conferred was counteracted by an increased R value. Increased β-galactosidase productivity was correlated with increased plasmid stability only in glucose-limited chemostat cultures grown on defined medium and not in those grown on complex medium. Previous studies have yielded contrasting responses with regard to the effect of dilution rate on recombinant plasmid loss from S. cerevisiae. Our findings can account for these differences and may be generally valid for the stability of similar yeast plasmid constructs. This information would facilitate the design of bioprocesses, where recombinant plasmid instability results in reduced culture productivity. Received 08 July 1996/ Accepted in revised form 14 January 1997     

The effect of lipophilic weak acids on the segregational stability of TOL plasmids in Pseudomonas putida

The effect of various lipophilic weak acids on the stability of certain TOL plasmids was investigated. Benzoate induced deletion of TOL plasmid DNA in Pseudomonas putida MT15, followed by loss of the plasmid; this effect was pH- and concentration-dependent, suggesting that undissociated benzoic acid was a more effective curing agent than the benzoate anion. Plasmid loss always approached a frequency of 100% after a lag and apparently depended on the prior occurrence of deletions, although deleted plasmid was stably maintained in the absence of the acid. m-Toluate, acetate and butyrate also induced deletions and plasmid loss at high frequencies, although these acids were less effective than benzoate. Benzoate inhibited the growth of plasmid-containing cells rather than permitting faster growth of cured cells on benzoate. Similar results were obtained with P. putida strains MT20 and MT84, which contain different TOL plasmids. We suggest that lipophilic weak acids induced deletions, possibly by excision of a transposon-like region, and disrupted the segregation of deleted plasmid.     

Higher-accuracy method for measuring minichromosome stability in Saccharomyces cerevisiae

The minichromosome maintenance assay isfrequently used to characterize mutations genetically that affect the initiation of DNA replication or to decipherfunctional components in autonomously replicating sequences. The assay determines minichromosome loss by measuring the percentage of plasmid-containing cells in cultures after a period of growth in nonselective medium. Here we analyze data acquisition errors that contribute to the low accuracy of the routine versions of the assay. We propose modifications that eliminate errors in the acquisition of two variables and significantly improve the accuracy of the assay.     

Flow Cytometry and Real-Time Quantitative PCR as Tools for Assessing Plasmid Persistence

The maintenance of a plasmid in the absence of selection for plasmid-borne genes is not guaranteed. However, plasmid persistence can evolve under selective conditions. Studying the molecular mechanisms behind the evolution of plasmid persistence is key to understanding how plasmids are maintained under nonselective conditions. Given the current crisis of rapid antibiotic resistance spread by multidrug resistance plasmids, this insight is of high medical relevance. The conventional method for monitoring plasmid persistence (i.e., the fraction of plasmid-containing cells in a population over time) is based on cultivation and involves differentiating colonies of plasmid-containing and plasmid-free cells on agar plates. However, this technique is time-consuming and does not easily lend itself to high-throughput applications. Here, we present flow cytometry (FCM) and real-time quantitative PCR (qPCR) as alternative tools for monitoring plasmid persistence. For this, we measured the persistence of a model plasmid, pB10::gfp, in three Pseudomonas hosts and in known mixtures of plasmid-containing and -free cells. We also compared three performance criteria: dynamic range, resolution, and variance. Although not without exceptions, both techniques generated estimates of overall plasmid loss rates that were rather similar to those generated by the conventional plate count (PC) method. They also were able to resolve differences in loss rates between artificial plasmid persistence assays. Finally, we briefly discuss the advantages and disadvantages for each technique and conclude that, overall, both FCM and real-time qPCR are suitable alternatives to cultivation-based methods for routine measurement of plasmid persistence, thereby opening avenues for high-throughput analyses.     

Plasmid stability and kinetics of continuous production of glucoamylase by recombinant <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> in an airlift bioreactor

Production of glucoamylase by recombinant Saccharomyces cerevisiae C468/pGAC9 (ATCC 20690) in a continuous stirred tank bioreactor was studied at different dilution rates. Plasmid stability was found to be growth (dilution rate) dependent; it increased with the dilution rate. Bioreactor productivity and specific productivity also increased with the dilution rate. A kinetic equation was used to model the plasmid stability kinetics. The growth rate ratio between plasmid-carrying and plasmid-free cells decreased from 1.397 to 1.215, and segregational instability or probability of plasmid loss from each cell division decreased from 0.059 to 0.020 as the dilution rate increased from 0.10 to 0.37 1/h. The specific growth rates increased with dilution rate, while the growth rate difference between plasmid-carrying and plasmid-free cell populations was negligible. This was attributed to the low copy number of the hybrid plasmid pGAC9. Thus, the growth rate had no significant effect on plasmid instability. The proposed kinetics was consistent with experimental results, and the model simulated the experimental data well.