Changes in Escherichia coli cells starved in seawater or grown in seawater-wastewater mixtures.

Some metabolic modifications of Escherichia coli cells during starvation in seawater were studied in laboratory microcosms. The apparent die-off of this bacterium under such conditions, as observed by comparing the enumeration of CFU in conventional freshwater media and direct epifluorescence counts, was partially prevented when cells were previously grown in salted organic medium or on seawater-wastewater agar. beta-Galactosidase activity of starved cells disappeared gradually with time, even though some other enzymatic activities, such as that of alkaline phosphatase, increased. Moreover, some modifications of sensitivity to antibiotics, heavy metals, and bacteriophages in seawater- and wastewater-grown cells suggested that the cells undergo structural changes under natural marine conditions. These results provide additional experimental data indicating the possible active adaptation of E. coli cells to seawater.     

Survival in seawater of Escherichia coli cells grown in marine sediments containing glycine betaine

Considering both the protective effect of glycine betaine (GB) on enteric bacteria grown at high osmolarity and the possible presence of GB in marine sediments, we have analyzed the survival, in nutrient-free seawater, of Escherichia coli cells incubated in sediments supplemented with GB or not supplemented and measured the efficiency of GB uptake systems and the expression of proP and proU genes in both seawater and sediments. We did this by using strains harboring proP-lacZ and proU-lacZ operon or gene fusions. We found that the uptake of GB and the expression of both proP and proU were very weak in seawater. The survival ability of cells in seawater supplemented with GB was a linear function of GB concentration, although the overall protection by the osmolyte was low. In sediments, proP expression was weak and GB uptake and proU expression were variable, possibly depending on the availability of organic nutrients. In a sediment with a high total organic carbon content, GB uptake was very high and proU expression was enhanced; cells previously incubated in this sediment showed a higher resistance to decay in seawater. GB might therefore play a significant role in the long-term maintenance of enteric bacterial cells in some marine sediments.     

Survival in seawater of Escherichia coli cells grown in marine sediments containing glycine betaine.

Considering both the protective effect of glycine betaine (GB) on enteric bacteria grown at high osmolarity and the possible presence of GB in marine sediments, we have analyzed the survival, in nutrient-free seawater, of Escherichia coli cells incubated in sediments supplemented with GB or not supplemented and measured the efficiency of GB uptake systems and the expression of proP and proU genes in both seawater and sediments. We did this by using strains harboring proP-lacZ and proU-lacZ operon or gene fusions. We found that the uptake of GB and the expression of both proP and proU were very weak in seawater. The survival ability of cells in seawater supplemented with GB was a linear function of GB concentration, although the overall protection by the osmolyte was low. In sediments, proP expression was weak and GB uptake and proU expression were variable, possibly depending on the availability of organic nutrients. In a sediment with a high total organic carbon content, GB uptake was very high and proU expression was enhanced; cells previously incubated in this sediment showed a higher resistance to decay in seawater. GB might therefore play a significant role in the long-term maintenance of enteric bacterial cells in some marine sediments.     

Non-growing Escherichia coli cells starved for glucose or phosphate use different mechanisms to survive oxidative stress

Recent data suggest that superoxide dismutases are important in preventing lethal oxidative damage of proteins in Escherichia coli cells incubated under aerobic, carbon starvation conditions. Here, we show that the alkylhydroperoxide reductase AhpCF (AHP) is specifically required to protect cells incubated under aerobic, phosphate (Pi) starvation conditions. Additional loss of the HP-I (KatG) hydroperoxidase activity dramatically accelerated the death rate of AHP-deficient cells. Investigation of the composition of spent culture media indicates that DeltaahpCF katG cells leak nutrients, which suggests that membrane lipids are the principal target of peroxides produced in Pi-starved cells. In fact, the introduction of various mutations inactivating repair activities revealed no obvious role for protein or DNA lesions in the viability of ahp cells. Because the death of ahp cells was directly related to ongoing aerobic glucose metabolism, we wondered how glycolysis, which requires free Pi, could proceed. 31P nuclear magnetic resonance spectra showed that Pi-starved cells consumed Pi but were apparently able to liberate Pi from phosphorylated products, notably through the synthesis of UDP-glucose. Whereas expression of the ahpCF and katG genes is enhanced in an OxyR-dependent manner in response to H2O2 challenge, we found that the inactivation of oxyR and both oxyR and rpoS genes had little effect on the viability of Pi-starved cells. In stark contrast, the inactivation of both oxyR and rpoS genes dramatically decreased the viability of glucose-starved cells.     

Role of ribosome degradation in the death of starved Escherichia coli cells.

In Escherichia coli cultures limited for phosphate, the number of ribosomal particles was reduced to a small percentage of its earlier peak value by the time the viable cell count began to drop; the 30S subunits decreased more than the 50S subunits. Moreover, the ribosomal activity was reduced even more: these cells no longer synthesized protein, and their extracts could not translate phage RNA unless ribosomes were added. The translation initiation factors also disappeared, suggesting that they become less stable when released from their normal attachment to 30S subunits. In contrast, elongation factors, aminoacyl-tRNA synthetases, and tRNA persisted. During further incubation, until viability was reduced to 10(-5), the ribosomal particles disappeared altogether, while tRNA continued to be preserved. These results suggest that an excessive loss of ribosomes (and of initiation factors) may be a major cause of cell death during prolonged phosphate starvation.     

Growth of starved Escherichia coli O157 cells in selective and non-selective media.

Escherichia coli O157 strains starved in sterile deionized water (SDW) and filter-sterilized natural river water (SRW) were investigated with specific reference to their culturability in selective and non-selective media. Growth of the strains starved in both SDW and SRW were markedly suppressed with time in selective liquid media such as modified trypticase soy broth supplemented with novobiocin (mTSB+n) and modified E. coli broth supplemented with novobiocin (mEC+n). This suppression was more pronounced when incubated at 42 C than at 37 C, especially with mEC+n. By contrast, such growth suppression was seldom observed when cultured at 37 C in non-selective liquid media such as trypticase soy broth (TSB) and buffered peptone water. In mEC+n at 42 C, the non-starved cells from overnight cultures with an initial density of less than 10(3) colony-forming units (CFU)/ml grew to the density of over 10(7) CFU/ml after 24 hr incubation, whereas those starved for 6 weeks in SRW were only to maintain their initial density or died off after 24 hr incubation under the same culturing conditions. These results indicated that the isolation of starved cells of E. coli O157 from water samples would be most difficult with selective enrichment or direct plating on the selective plate media. It is thus highly recommended that a "resuscitation" of the cells with non-selective enrichment should be performed as a routine practice for maximum recovery of E. coli O157 from water systems.     

Stochastic switching induced adaptation in a starved Escherichia coli population

Population adaptation can be determined by stochastic switching in living cells. To examine how stochastic switching contributes to the fate decision for a population under severe stress, we constructed an Escherichia coli strain crucially dependent on the expression of a rewired gene. The gene essential for tryptophan biosynthesis, trpC, was removed from the native regulatory unit, the Trp operon, and placed under the extraneous control of the lactose utilisation network. Bistability of the network provided the cells two discrete phenotypes: the induced and suppressed level of trpC. The two phenotypes permitted the cells to grow or not, respectively, under conditions of tryptophan depletion. We found that stochastic switching between the two states allowed the initially suppressed cells to form a new population with induced trpC in response to tryptophan starvation. However, the frequency of the transition from suppressed to induced state dropped off dramatically in the starved population, in comparison to that in the nourished population. This reduced switching rate was compensated by increasing the initial population size, which probably provided the cell population more chances to wait for the rarely appearing fit cells from the unfit cells. Taken together, adaptation of a starved bacterial population because of stochasticity in the gene rewired from the ancient regulon was experimentally confirmed, and the nutritional status and the population size played a great role in stochastic adaptation.     

Polyribosome metabolism in Escherichia coli starved for an amino acid

Most polyribosomes are inferred to be inert in starving cells, but some are in a dynamic state, since (1) messenger RNA continues to enter polyribosomes; (2) about 20 to 40% of the polyribosomes are labile after rifampycin addition; (3) β-galactosidase can be induced with a lag period no more than three times as long as in growing cells; and (4) the apparent rate of synthesis of protein chains, judged by the distribution of pulse-labeled protein between ribosomes and soluble protein, is about half that in growing cells.     

Role of guanosine tetraphosphate in gene expression and the survival of glucose or seryl-tRNA starved cells of Escherichia coli K12

The concentration of guanosine 3′,5′-bispyrophosphate (ppGpp) increases in bacteria in response to amino acid or carbon/energy source starvation. An Escherichia coli K12 ΔrelAΔspoT mutant lacking the ability to synthesize ppGpp lost viability at an increased rate during both glucose and seryl-tRNA starvation. Also, the deleterious effect of chloramphenicol on starved wild-type cells could be overcome by inducing expression of RelA from a plasmid carrying the relA gene transcribed from a tac promoter, prior to starvation and chloramphenicol treatment. As demonstrated by two dimensional gel electrophoresis, this induction of the RelA protein resulted in global alterations in gene expression including increased synthesis of some rpoS-dependent proteins. The ΔrelAΔspoT mutant maintained high expression of several ribosomal proteins during starvation and appeared to exhibit significantly decreased translational fidelity, as demonstrated by an unusual heterogeneity in the isoelectric point of several proteins and the failure to express higher molecular weight proteins during starvation. Moreover, both rpoS-dependent and independent genes failed to exhibit increased expression in the mutant. It is suggested that the deleterious effects on the cells of the relA, spoT deletions are not due solely to the inability of these cells to induce the sigma factor σ^s, but also to deficiencies in translational fidelity and failure to exert classical stringent regulation.     

Heterogeneity of ribosomal populations in Escherichia coli cells grown in different media

Summary In order to establish whether ribosomes exhibit heterogeneity with respect to their protein pattern in vivo, E. coli cells were grown in rich or minimal medium and labeled with ¹⁴C and ³H amino acid mixture, respectively. After harvesting, the cells from the different media were mixed, the differently labeled ribosomes isolated and the ribosomal proteins separated. For each protein the ratio of ¹⁴C to ³H was determined and used as an indication of whether differences exist in ribosomal populations synthesized under different growth conditions.With respect to their ratio the ribosomal proteins can be classified as follows: Many of the proteins have a ratio of 1, i. e. they are present in the same amount in both preparations. The ratios for about 30% of the proteins differ only slightly from 1 whereas three proteins namely S6, S21 and L12 have ratios of 2.5 and 3.1 respectively. This means that ribosomal populations isolated from cells grown in rich medium contain these three proteins in two to three fold greater amounts compared to those synthesized in minimal medium.The relevance of these results with respect to the occurrence of heterogeneous ribosomal populations in vivo is discussed.Paper Nr. 36 on Ribosomal Proteins. Preceding paper is by H. J. Weber, Mol. Gen. Genetics 119, 233–248 (1972).     

Survival of Escherichia coli K12 in seawater

Abstract The fate of an auxotrophic Escherichia coli K12 strain (NF1830) in coastal water was investigated. The E. coli K12 were enumerated after incubation for varying times in seawater. Incubated in raw seawater at 15 and 20°C, the NF1830 decreased from 10⁶ cfu/ml to below detection within six days of incubation, but when incubated at 7°C it persisted longer. The NF1830 was capable of cell division in sterile seawater. Growth was also shown to occur in raw seawater in the presence of autoclaved sediment. The E. coli K12 decreased in number at a much lower rate when incubated in seawater treated with eukaryotic inhibitors. These findings suggest that the die-off of the auxotrophic E. coli K12 strain seen in the raw seawater was caused by grazing of bacterial predators in the seawater.     

Alkaline phosphatase activity of Escherichia coli starved in sterile lake water microcosms

Escherichia coli grown in high or low phosphate medium was inoculated into a lake water starvation medium. The viable count decreased at 37°C but not at the lower temperatures over 70 d. Alkaline phosphatase was monitored using a colorimetric assay with pNPP as the substrate. Derepression of the enzyme occurred in cultures starved for > 30 d in the lake water and within 5 d in lake water microcosms supplemented with carbon and nitrogen sources where there was rarely an increase in viable count. Chloramphenicol prevented the synthesis of alkaline phosphatase suggesting that, even under starvation conditions, de novo synthesis of the enzyme occurs.     

Changes in the electro-orientation of Escherichia coli cells exposed to disinfectants

Various disinfectants were shown to influence the frequency dependence of Escherichia coli electro-orientation. Cell inactivation by different agents was found to decrease the effect at high frequencies (5 X 10(5)-5 X 10(6) Hz). The decrease should be attributed to the fact that the barrier properties of membranes are disorganized and the equivalent electric conductivity of cells drops down. The microbiological control of the bactericidal action produced by disinfectants fits in well with changes in the electro-orientation of bacterial cells at these frequencies.     

Changes in levels of amino acid acceptors in tRNA from Escherichia coli grown under various conditions

Active enzyme sedimentation of five asparaginase and glutaminase-asparaginase enzymes with antitumor activity was studied. The catalytically active species of each enzyme appeared to have a molecular weight greater than 100,000 g/mole. Gel filtration and disc gel electrophoresis confirmed the absence of catalytically active smaller species.