Phospholipid Turnover in a Conditional Polyamine Auxotroph of Escherichia coli

Polyamines are required for rapid phospholipid turnover in Escherichia coli growing in media of low osmolarity.     

Polyamine Requirements of a Conditional Polyamine Auxotroph of Escherichia coli

Escherichia coli MA-159 is deficient in agmatine ureohydrolase. After addition of exogenous arginine, the cellular putrescine content declines immediately and exponentially; however, the spermidine content remains normal for 3 h. The growth rate of such cultures, measured turbidometrically, slows gradually over many hours. Putrescine-depleted cultures grow especially slowly in media of low osmolarity, whereas nondepleted cultures grow at similar and rapid rates in media of either normal or low osmolarity. External osmolarity also affects the ability of various exogenous polyamines to stimulate growth of putrescine-depleted cultures. In medium of normal osmolarity, putrescine and spermidine both allow sustained rapid growth for many hours. In low osmolarity medium, putrescine allows sustained rapid growth, whereas cultures containing spermidine grow more slowly; this result cannot be explained by conversion of putrescine to spermidine, for cultures grown with exogenous putrescine contain smaller spermidine pools than do cultures grown with exogenous spermidine. Spermine greatly stimulates growth in medium of normal osmolarity; however, in medium of low osmolarity, spermine is much less effective and can block the action of putrescine. Several other polyamines have been studied in this system. These results confirm and expand previous reports that polyamines are necessary for growth of E. coli and suggest that putrescine may have a specific function during growth in media of low osmolarity.     

Synthesis of Pyridoxine by a Pyridoxal Auxotroph of Escherichia coli

Dempsey, Walter B. (University of Florida, Gainesville). Synthesis of pyridoxine by a pyridoxal auxotroph of Escherichia coli. J. Bacteriol. 92:333-337. 1966.-A pyridoxal auxotroph of Escherichia coli B produced pyridoxol and pyridoxol 5'-phosphate during starvation for pyridoxal. The identification of these compounds was made both by bioassay and by ion-exchange chromatography. Pyridoxol 5'-phosphate oxidase activity was absent in extracts of the auxotroph. The rate of synthesis of total pyridoxine by a pyridoxal-starved culture of this auxotroph was 6.0 x 10(-6) moles per mg per hr. Cellular content of pyridoxine was constant at 4.0 x 10(-10) moles/mg.     

Growth of Ribonucleic Acid Bacteriophage f2 in a Conditional Putrescine Auxotroph of Escherichia coli: Evidence for a Polyamine Role in Translation

The ribonucleic acid (RNA) bacteriophage, f2, grows poorly in a conditional putrescine auxotroph during polyamine starvation. The addition of putrescine simultaneously with f2 enhances phage growth, shortens the latent period, and increases the burst size. The stimulation of f2 growth is reflected in higher rates of phage RNA and protein syntheses as measured by radioactive labeling of infected cells in the presence of rifampin. Putrescine does not affect f2 adsorption or the penetration of its RNA. Rather, in vitro assays demonstrate that in putrescine-supplemented cells more molecules of f2 replicase are made per incoming parental RNA than in polyamine-starved cultures. The ability of polyamines to stimulate the translation of a preformed messenger suggests a physiological role for these organic cations in normal protein synthesis.     

Regulation of Transaminase C Synthesis in Escherichia coli: Conditional Leucine Auxotrophy

The regulation of synthesis of the valine-alanine-alpha-aminobutyrate transaminase (transaminase C) was studied in Escherichia coli mutants lacking the branched-chain amino acid transaminase (transaminase B). An investigation was made of two strains, CU2 and CU2002, each carrying the same transaminase B lesion but exhibiting different growth responses on a medium supplemented with branched-chain amino acids. Both had the absolute isoleucine requirement characteristic of ilvE auxotrophs, but growth of strain CU2 was stimulated by valine, whereas that of strain CU2002 was markedly inhibited by valine. Strain CU2002 behaved like a conditional leucine auxotroph in that the inhibition by valine was reversed by leucine. Results of enzymatic studies showed that synthesis of transaminase C was repressed by valine in strain CU2002 but not in strain CU2. Inhibition by valine in strain CU2002 appears to be the combined effect of repression on transaminase C synthesis and valine-dependent feedback inhibition of alpha-acetohydroxy acid synthase activity, causing alpha-ketoisovalerate (and hence leucine) limitation. The ilvE markers of strains CU2 and CU2002 were each transferred by transduction to a wild-type genetical background. All ilvE recombinants from both crosses resembled strain CU2002 and were inhibited by valine in the presence of isoleucine. Thus, strain CU2 carries an additional lesion that allows it to grow on a medium containing isoleucine plus valine. It is concluded that conditional leucine auxotrophy is characteristic of mutants carrying an ilvE lesion alone.     

Effect of Trimethoprim on Macromolecular Synthesis in Escherichia coli

Trimethoprim is a specific inhibitor of dihydrofolate reductase. When added to amino acid supplemented cultures of Escherichia coli, protein, ribonucleic acid (RNA), and deoxyribonucleic acid synthesis are rapidly inhibited. It is shown that thymidylate and purine synthesis must continuously occur if the inhibition is to be maintained. These results are interpreted as demonstrating that in vivo trimethoprim can reduce but not totally inhibit the action of dihydrofolate reductase and therefore reduce the amount of tetrahydrofolate derivatives available for formylmethionyl transfer RNA formylation, purine, and thymidylate synthesis.     

Urea Production and Putrescine Biosynthesis by Escherichia coli

Cultures of Escherichia coli B and K-12 produce urea during growth in minimal medium. Results of isotopic labeling experiments were consistent with the sole source of urea being from the conversion of arginine to putrescine. Since E. coli itself has no demonstrable urease activity, the rate of urea production is a measure of the flux through the arginine to putrescine pathway.     

Fatty Acid Replacements in a Fatty Acid Auxotroph of Escherichia coli

Unsaturated fatty acids having structural features which are different from those of the monoenoic acids normally synthesized by Escherichia coli can serve as growth factors for an auxotroph requiring unsaturated fatty acids. These analogues were incorporated into the phospholipids, as shown by gas-liquid and thin-layer chromatographic analysis of the phospholipid fatty acid composition. Some of these fatty acids were cisDelta(5)- and cis-Delta(9)-tetradecenoic, cis-Delta(11)-eicosenoic, cis,cis-Delta(11,14)-eicosadienoic, cis,cis,cis-Delta(11,14,17)-eicosatrienoic, trans-Delta(9)- and trans-Delta(11)-octadecenoic acids. Although partial degradation of some of these analogues to shorter even-chain homologues occurred, chain elongation of the exogenous fatty acids was not detected. Trans-olefinic acids were utilized without stereochemical or positional isomerization. These studies provide a basis for exploring the properties of the fatty acids and phospholipids required for the formation, structure, and function of membranes.     

Effects of Mitomycin C on Macromolecular Synthesis in Escherichia coli

When cells of Escherichia coli B growing in a glucose-synthetic medium were treated with mitomycin C, the effects produced by the antibiotic varied, depending on the concentration. When the concentration was reduced to less than 0.1 mug/ml, the action of the antibiotic was bacteriostatic; cell elongation resulted, but no effect on the synthesis of cellular macromolecules was apparent. At higher levels (more than 5 mug/ml), mitomycin C was highly bactericidal and inhibited deoxyribonucleic acid synthesis almost completely. The exposure of growing cells to a bactericidal level of mitomycin C resulted also in a delayed inhibition of the synthesis of ribonucleic acid (RNA) and protein. The capacity of the treated cells to synthesize beta-galactosidase inducibly in a medium free from a carbon source remained constant for the first 30 min and then was destroyed progressively with time. Prolonged incubation with the bactericidal level of mitomycin C caused a degradation of cellular nucleic acids, particularly RNA. The degraded nucleic acid components were eventually released into the medium.     

Isolation and Characterization of a Mutant of Escherichia coli Blocked in the Synthesis of Putrescine

A mutant of Escherichia coli is described which is defective in the conversion of arginine to putrescine. The activity of the enzyme agmatine ureohydrolase is greatly reduced, whereas the activity of the other two enzymes of the pathway, the constitutive arginine decarboxylase and the inducible arginine decarboxylase, are within the normal range. The growth behavior of the mutant reflects the enzymatic block. It grows well in the absence of arginine, but only poorly in the presence of arginine. Under the former conditions, putrescine can be formed from ornithine as well as arginine, whereas under the latter conditions, because of feedback control, it can be formed only from arginine.     

Multiple Transport Components for Putrescine in Escherichia coli

Putrescine uptake was studied in cultures of Escherichia coli K-12 grown in media of high or low osmolarity. When grown in high osmolarity medium, a transport system of low K(m) and low V(max) was found. For cultures grown in a medium of low osmolarity, the kinetics of putrescine uptake was more complex and consistent with the existence of an additional transport system of higher K(m) and V(max). This conclusion is supported by the isolation of mutants in which one or the other system appears to be defective and by the ability of chloramphenicol to block the expression of the second transport system. Both systems appear to prefer putrescine over other compounds, since several basic amino acids and other polyamines competed only weakly for transport. The action of both uptake systems was shown to cause significant displacement of intracellular putrescine. Both systems also are at least partially energy dependent.     

Survival and Macromolecular Synthesis During Incubation of Escherichia coli in Limiting Thymine

Survival and the synthesis of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein were measured during incubation of a thymine auxotroph of Escherichia coli in a series of media containing thymine concentrations below the optimal level of 2 mug/ml. The rate of increase in viable count gradually diminishes to no net growth with 0.2 mug/ml. With lower concentrations of thymine, the rate of cell death gradually increases, resulting in a typical thymineless death curve with 0.02 mug/ml. Both the rate of cell growth and the rate of cell inactivation vary linearly with the thymine concentration. Thirty minutes of incubation in media containing limiting concentrations of thymine before a shift to complete thymine starvation results in a progressive decrease in the length of the lag period preceding thymineless death. These data suggest that only one type of cellular damage occurs during the various degrees of thymine limitation. Prolonged preincubation in media containing 0.1 to 0.2 mug/ml of thymine results in an immunity to thymineless death. This immunity differs from that observed with amino acid-starved cells in its kinetics; ultraviolet irradiation of preincubated cells indicates that the cells are inactivated at the same rate as log-phase cells. These results suggest that the immunity is not associated with chromosome alignment. Thymine concentrations between 2 mug/ml and 0.2 mug/ml permit essentially the same amount of protein and RNA synthesis. The total amount of synthesis then decreases linearly to 40 to 50% of the control level with further reduction in the amount of thymine present. Protein and RNA synthesis are first affected at the same thymine concentration at which lethality is first detectable, and this correlation suggests that the synthesis of these macromolecules is involved in the mechanism of thymineless death. DNA synthesis, on the other hand, is directly dependent on the thymine concentration for levels of 0.5 mug/ml or less. There are no critical changes in DNA synthesis associated with lethality, and DNA synthesis is still occurring under conditions of thymine limitation which result in immunity. These observations suggest that DNA synthesis is not directly involved in thymineless death.     

Diaminopimelic Acid Synthesis in Cultures of an Escherichia coli Double Auxotroph: Effects of Cultural Conditions

The metabolic response to L-lysine of Escherichia coli ATCC 13002, a lysine-histidine double auxotroph, has been examined in a synthetic medium containing sucrose. In shaken cultures largest amounts of extracellular DAP were produced with an initial lysine concentration of 7·5 mg/1 and in static cultures of 2·5 mg/1. Considerably smaller amounts of DAP accumulated under stationary conditions. In cultures shaken for 20 and 43 h there was an overall decrease in the yields of DAP, expressed in terms of cell biomass and of sucrose consumed, as the initial concentration of lysine was increased from 0·75 mg/1 in steps up to 25 mg/1. The regulatory effect of lysine on DAP production was also observed when lysine was supplied to cultures at a constant rate employing diffusion capsules.     

Effects of Oleate Starvation in a Fatty Acid Auxotroph of Escherichia coli K-12

The effects of oleate starvation on an oleate auxotroph of Escherichia coli K-12 were investigated. Following removal of oleate from the mutant growing in a minimal glycerol-peptone medium, the cells stopped making deoxyribonucleic acid, ribonucleic acid, protein, and phospholipids; they began to die exponentially and finally lysed. During oleate starvation in minimal medium minus peptone, inhibition of macromolecular syntheses and death occurred; however, lysis did not follow. When growth ceased, no further dying was observed. It is shown that none of the early effects (inhibition of macromolecular syntheses and death) can be due to leakiness of the cells, induction of a prophage or a colicin, or lack of energy sources. The cause of inhibition of macromolecular syntheses remained unknown. Since the rate of death was the same as the generation time under different conditions, it appears that death is due to the defective synthesis of some cellular structure (quite possibly, cytoplasmic membrane) during phospholipid deficiency. Lysis was found to require protein synthesis; electron microscopy revealed a peculiar type of "lysis from within"; i.e., the shape of the cells did not change but fragmentation of the inner layer of the cell envelope occurred. The murein was found to be unaltered. Most likely, lysis was a consequence of the cell's attempt to synthesize cytoplasmic membrane with altered phospholipid composition or during phospholipid deficiency. Several membrane functions (respiration, adenosine triphosphate formation, permeability) existing before oleate removal were not lost during starvation. Therefore, general damage to the membrane did not occur, and it could be that most, if not all, described effects were due to defective de novo membrane synthesis.