The effect of growth rate and other growth conditions on the lipid composition of Escherichia coli

Escherichia coli was grown as a continuous culture at various defined conditions of temperature, pH, aeration rate and dilution rate. The lipids were extracted from disrupted cells and the relative fatty acid content of the individual and total phospholipids was determined. The lipid composition of E. coli was shown to change with the fermentation conditions. Interestingly, E. coli adapted to high growth rates and to low oxygen tension by changing the lipid composition of the membrane in exactly the same way, thus indicating a common effect.     

Construction of lac fusions to the inducible arginine-and lysine decarboxylase genes of Escherichia coli K12

The induction of several amino acid decarboxylases under anaerobic conditions at low pH has been known for many years, but the mechanism associated with this type of regulation has not been elucidated. To study the regulation of the biodegradative arginine and lysine decarboxylases of Escherichia coli K12, Mudlac fusions to these genes were isolated. Mudlac fusion strains deficient for lysine decarboxylase or arginine decarboxylase were identified using decarboxylase indicator media and analysed for their regulation of beta-galactosidase expression. The position of the Mudlac fusion in lysine decarboxylase-deficient strains has been mapped to the cadA gene at 93.7 minutes, while the Mudlac fusions exhibiting a deficiency in the inducible arginine decarboxylase have been mapped to 93.4 minutes.     

Lysine decarboxylase activity as a factor of fluoroquinolone resistance in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Exposure of E. coli cells to sublethal concentrations of fluoroquinolones induced synthesis of lysine decarboxylase LdcC, which was previously considered to be a constitutive enzyme. Under these conditions, a key role in this process is played by RNA polymerase σ ^S subunit (RpoS); its quantity increased substantially in the presence of antibiotics. Fluoroquinolones of the second and third generations had a more pronounced effect on rpoS expression and LdcC activity than the first-generation antibiotics. A direct correlation was shown between the level of cadaverine, the product of lysine decarboxylase reaction in E. coli cells, and their resistance to fluoroquinolones. An increase in endogenous cadaverine reduced effectiveness of the second and third-generation fluoroquinolones, but had no effect on antimicrobial activity of the first-generation antibiotics. This is in good agreement with the hydrophilic properties of antibiotics of different generations and, consequently, with different mechanisms of their penetration into bacterial cells.     

Regulation of polyamine biosynthesis by antizyme and some recent developments relating the induction of polyamine biosynthesis to cell growth

This review considers the role of antizyme, of amino acids and of protein synthesis in the regulation of polyamine biosynthesis.The ornithine decarboxylase of eukaryotic ceils and ofEscherichia coli coli can be non-competitively inhibited by proteins, termed antizymes, which are induced by di-and poly- amines. Some antizymes have been purified to homogeneity and have been shown to be structurally unique to the cell of origin. Yet, the E. c o l i antizyme and the rat liver antizyme cross react and inhibit each other's biosynthetic decarboxylases. These results indicate that aspects of the control of polyamine biosynthesis have been highly conserved throughout evolution.Evidence for the physiological role of the antizyme in mammalian cells rests upon its identification in normal uninduced cells, upon the inverse relationship that exists between antizyme and ornithine decarboxylase as well as upon the existence of the complex of ornithine decarboxylase and antizyme in vivo. Furthermore, the antizyme has been shown to be highly specific; its Keq for ornithine decarboxylase is 1.4 x 1011 M-1. In addition, mammalian ceils contain an anti-antizyme, a protein that specifically binds to the antizyme of an ornithine decarboxylase-antizyme complex and liberates free ornithine decarboxylase from the complex. In B. coli , in which polyamine biosynthesis is mediated both by ornithine decarboxylase and by arginine decarboxylase, three proteins (one acidic and two basic) have been purified, each of which inhibits both these enzymes. They do not inhibit the biodegradative ornithine and arginine decarboxylases nor lysine decarboxylase. The two basic inhibitors have been shown to correspond to the ribosomal proteins S₂₀/L₂₆ and L₃₄, respectively. The relationship of the acidic antizyme to other known B. coli proteins remains to be determined.     

Hydrogenase-3 Contributes to Anaerobic Acid Resistance of Escherichia coli

Background

Hydrogen production by fermenting bacteria such as Escherichia coli offers a potential source of hydrogen biofuel. Because H₂ production involves consumption of 2H⁺, hydrogenase expression is likely to involve pH response and regulation. Hydrogenase consumption of protons in E. coli has been implicated in acid resistance, the ability to survive exposure to acid levels (pH 2–2.5) that are three pH units lower than the pH limit of growth (pH 5–6). Enhanced survival in acid enables a larger infective inoculum to pass through the stomach and colonize the intestine. Most acid resistance mechanisms have been defined using aerobic cultures, but the use of anaerobic cultures will reveal novel acid resistance mechanisms.

Methods and Principal Findings

We analyzed the pH regulation of bacterial hydrogenases in live cultures of E. coli K-12 W3110. During anaerobic growth in the range of pH 5 to 6.5, E. coli expresses three hydrogenase isoenzymes that reversibly oxidize H₂ to 2H⁺. Anoxic conditions were used to determine which of the hydrogenase complexes contribute to acid resistance, measured as the survival of cultures grown at pH 5.5 without aeration and exposed for 2 hours at pH 2 or at pH 2.5. Survival of all strains in extreme acid was significantly lower in low oxygen than for aerated cultures. Deletion of hyc (Hyd-3) decreased anoxic acid survival 3-fold at pH 2.5, and 20-fold at pH 2, but had no effect on acid survival with aeration. Deletion of hyb (Hyd-2) did not significantly affect acid survival. The pH-dependence of H₂ production and consumption was tested using a H₂-specific Clark-type electrode. Hyd-3-dependent H₂ production was increased 70-fold from pH 6.5 to 5.5, whereas Hyd-2-dependent H₂ consumption was maximal at alkaline pH. H₂ production, was unaffected by a shift in external or internal pH. H₂ production was associated with hycE expression levels as a function of external pH.

Conclusions

Anaerobic growing cultures of E. coli generate H₂ via Hyd-3 at low external pH, and consume H₂ via Hyd-2 at high external pH. Hyd-3 proton conversion to H₂ is required for acid resistance in anaerobic cultures of E. coli.     

Cloning and expression of the soybean DapA gene encoding dihydrodipicolinate synthase

The rate-limiting step in the pathway for lysine synthesis in plants is catalyzed by the enzyme dihydrodipicolinate synthase (DS). We have cloned the portion of the soybean (Glycine max cv. Century) DapA cDNA that encodes the mature DS protein. Expression of the cloned soybean cDNA as a lacZ fusion protein was selected in a dapA ^- Escherichia coli auxotroph. The DS activity of the fusion protein was characterized in E. coli extracts. The DS activity of the fusion protein was inhibited by lysine concentrations that also inhibited native soybean DS, while E. coli DS activity was much less sensitive to inhibition by lysine.     

木糖异构酶基因xylA表达载体构建

以大肠埃希菌MG1655的基因组为模板,通过PCR扩增获得木糖异构酶基因xylA。利用敲除编码对基因转录起负调控作用的lacIq基因的大肠埃希菌/谷氨酸棒杆菌穿梭质粒pEC-XK99E,酶连后转化大肠埃希菌BL21和谷氨酸棒杆菌ATCC 13032。成功构建出了具有大肠埃希菌BL21表达活性的木糖异构酶表达载体pEC(lacI-)-xylA。     

Cloning and expression of the structural gene for pyruvate decarboxylase of Zymomonas mobilis in Escherichia coli

A genomic library of Zymomonas mobilis DNA was constructed in Escherichia coli using cosmid vector pHC79. Immunological screening of 483 individual E. coli strains revealed two clones expressing pyruvate decarboxylase, the key enzyme for efficient ethanol production of Z. mobilis. The two plasmids, pZM1 and pZM2, isolated from both E. coli strains were found to be related and to exhibit a common 4.6 kb SphI fragment on which the gene coding for pyruvate decarboxylase, pdc, was located.The pdc gene was similarily well expressed in both aerobically and anaerobically grown E. coli cells, and exerted a considerable effect on the amount of fermentation products formed. During fermentative growth on 25 mM glucose, plasmid-free E. coli lacking a pdc gene produced 6.5 mM ethanol, 8.2 mM acetate, 6.5 mM lactate, 0.5 mM succinate, and about 1 mM formate leaving 10.4 mM residual glucose. In contrast, recombinant E. coli harbouring a cloned pdc gene from Z. mobilis completely converted 25 mM glucose to up to 41.5 mM ethanol while almost no acids were formed.     

Effect of chelating agents and respiratory inhibitors on regulation of the cadA gene in Escherichia coli

The cadA gene that encodes lysine decarboxylase in Escherichia coli is induced by low pH and – during anaerobic growth – by the substrate, lysine. We used operon fusions of cadA to lacZ to investigate the effects of aeration on cadA regulation. When an insertion mutation in osmZ (= hns) was introduced, a cadA-lacZ fusion was derepressed in the presence of air to approximately the same level as seen during anaerobic growth. However, the pH-dependent regulation of cadA was not affected by osmZ. Introduction of mutations in rpoS, fur, or fnr had no significant effect on cadA expression. However, defects in arcB or arcA largely abolished expression of cadA during anaerobic growth. Nonetheless, strains defective in both arcB and osmZ showed the same high cadA-lac expression in air as seen in the single osmZ derivatives. Blocking the respiratory chain with mutations or chemical inhibitors also caused derepression of a cadA-lacZ fusion in air, while agents affecting the proton gradient had no effect. Derepression of cadA in air was also mediated by several chelating agents, in particular by methoxyindole carboxylic acid. Addition of Fe²⁺ overcame this effect. Chelating agents also abolished the expression during aerobic growth of several genes known to be under arcAB control and which are normally repressed during anaerobic growth but induced in the presence of air. This implies that the effect of chelating agents on cadA expression is mediated via the arcAB regulatory system. Received: 16 August 1996 / Accepted: 12 November 1996     

Improved cadaverine production from mutant Klebsiella oxytoca lysine decarboxylase

Cadaverine has the potential to become an important platform chemical for the production of nylon. Previously, a system that overexpresses the Klebsiella oxytoca lysine decarboxylase in Escherichia coli was engineered. The system was optimized by codon optimization, and tuning the expression level of the gene by testing various promoters and inducer concentrations. Here, we further improved the system by optimizing the sequence located in the region of the ribosome‐binding site in order to enhance translation efficiency. We also identified mutant lysine decarboxylase enzymes that demonstrated enhanced cadaverine‐production ability. Together, these modifications increased cadaverine production in the system by 50%, and the system has a yield of 80% from lysine‐HCl under the conditions we tested. This is the first time that a system to produce cadaverine using the lysine decarboxylase from K. oxytoca performed at a level that is competitive with the traditional systems using the E. coli lysine decarboxylases in both lab‐scale and batch fermentation conditions.     

Regulation of Aspartate Family Amino Acid Biosynthesis in Brevibacterium flavum

Dihydrodipicolinate (DDP)* synthetase and DDP-reductase were partially purified about 30 and 15 folds, respectively, from sonic extracts of Brevibacterium flavum.

In contrast with DDP-synthetase from Escherichia coli, the B. flavum enzyme was only slightly inhibited by α, ε-diaminopimelate, a precursor of lysine, but not by lysine itself. Single or simultaneous addition of any other amino acid(s) of aspartate family did not affect the activity significantly. Optimum pH for DDP-synthetase was 8.4 with Tris-HCl buffer. Kms for aspartic-β-semialdehyde and pyruvate at pH 7.5 were 2×10^?4m and 1×10^?4m, respectively. The formation of DDP-synthetase was not significantly repressed by lysine.

DDP-reductase of B. flavum required NADH or NADPH as the cofactor. This enzyme was not inhibited by single or simultaneous addition of aspartate family amino acid(s).

From the above results, the regulation mechanism of lysine biosynthesis in B. flavum was discussed.     

Participation of RNase I in MS2 Phage Growth

Participation of RNase I in the growth of phage on infection with bacteriophage MS2 was studied.

Some strains of uracil-requiring E. coli were isolated, grown in MS broth, and transferred to a minimal medium to exhaust the pool of nucleotides. The phage was then added to the cells grown in uracil-deficient medium. The growth of phage was observed to occur at the burst size of two hundreds in strains of E. coli K12S (F⁺) U^? and C600 (F⁺) U^?, which possessed RNase I, but not in strains, A19 (Hfr) U^? and Q13 (Hfr) U^?, which lacked RNase I.

A marked increase in acid-soluble fraction was observed with E. coli K12S (F⁺) U^? and C600 (F⁺) U^?, whereas the increase was little with E. coli A10 (Hfr) U^? and Q13 (Hfr) U^? Conditions for the growth of phage in uracil-deficient medium were investigated and the effect of antibiotics were also investigated.     

A requirement of TolC and MDR efflux pumps for acid adaptation and GadAB induction in Escherichia coli

Background

The TolC outer membrane channel is a key component of several multidrug resistance (MDR) efflux pumps driven by H⁺ transport in Escherichia coli. While tolC expression is under the regulation of the EvgA-Gad acid resistance regulon, the role of TolC in growth at low pH and extreme-acid survival is unknown.

Methods and Principal Findings

TolC was required for extreme-acid survival (pH 2) of strain W3110 grown aerobically to stationary phase. A tolC deletion decreased extreme-acid survival (acid resistance) of aerated pH 7.0-grown cells by 10⁵-fold and of pH 5.5-grown cells by 10-fold. The requirement was specific for acid resistance since a tolC defect had no effect on aerobic survival in extreme base (pH 10). TolC was required for expression of glutamate decarboxylase (GadA, GadB), a key component of glutamate-dependent acid resistance (Gad). TolC was also required for maximal exponential growth of E. coli K-12 W3110, in LBK medium buffered at pH 4.5–6.0, but not at pH 6.5–8.5. The TolC growth requirement in moderate acid was independent of Gad. TolC-associated pump components EmrB and MdtB contributed to survival in extreme acid (pH 2), but were not required for growth at pH 5. A mutant lacking the known TolC-associated efflux pumps (acrB, acrD, emrB, emrY, macB, mdtC, mdtF, acrEF) showed no growth defect at acidic pH and a relatively small decrease in extreme-acid survival when pre-grown at pH 5.5.

Conclusions

TolC and proton-driven MDR efflux pump components EmrB and MdtB contribute to E. coli survival in extreme acid and TolC is required for maximal growth rates below pH 6.5. The TolC enhancement of extreme-acid survival includes Gad induction, but TolC-dependent growth rates below pH 6.5 do not involve Gad. That MDR resistance can enhance growth and survival in acid is an important consideration for enteric organisms passing through the acidic stomach.     

Formation of Lysine from, α, ε-Diaminopimelic Acid Contained in Rumen Bacterial Cell Walls by Rumen Ciliate Protozoa

Cell walls containing α,ε-diaminopimelate-l,7-¹⁴C (DAP) was prepared from Escherichia coli isolated from the rumen. After incubation of ciliates with the cell walls, 22.0% of DAP contained in cell walls of E. coli was converted to lysine and pipecolate. Heat-treated mixed rumen bacteria and heat-treated cell walls of mixed rumen bacteria added to the culture medium of rumen ciliates increased 0.572 and 0.934 μmole/ml of sum of lysine and pipecolate, respectively.

From these results, it is clear that rumen ciliate protozoa can form lysine from DAP contained in the mucopeptide of bacterial cell walls. One of the nutritional significance of inhabitation of ciliates in the rumen was revealed.     

High‐level conversion of L‐lysine into 5‐aminovalerate that can be used for nylon 6,5 synthesis

L ‐Lysine is a potential feedstock for the production of bio‐based precursors for engineering plastics. In this study, we developed a microbial process for high‐level conversion of L ‐lysine into 5‐aminovalerate (5AVA) that can be used as a monomer in nylon 6,5 synthesis. Recombinant Escherichia coli WL3110 strain expressing Pseudomonas putida delta‐aminovaleramidase (DavA) and lysine 2‐monooxygenase (DavB) was grown to high density in fed‐batch culture and used as a whole cell catalyst. High‐density E. coli WL3110 expressing DavAB, grown to an optical density at 600 nm (OD₆₀₀) of 30, yielded 36.51 g/L 5AVA from 60 g/L L ‐lysine in 24 h. Doubling the cell density of E. coli WL3110 improved the conversion yield to 47.96 g/L 5AVA from 60 g/L of L ‐lysine in 24 h. 5AVA production was further improved by doubling the L ‐lysine concentration from 60 to 120 g/L. The highest 5AVA titer (90.59 g/L; molar yield 0.942) was obtained from 120 g/L L ‐lysine by E. coli WL3110 cells grown to OD₆₀₀ of 60. Finally, nylon 6,5 was synthesized by bulk polymerization of ?‐caprolactam and δ‐valerolactam prepared from microbially synthesized 5AVA. The hybrid system demonstrated here has promising possibilities for application in the development of industrial bio‐nylon production processes.     

Glutamate decarboxylase‐dependent acid resistance in orally acquired bacteria: function,distribution and biomedical implications of the gadBC operon

For successful colonization of the mammalian host, orally acquired bacteria must overcome the extreme acidic stress (pH < 2.5) encountered during transit through the host stomach. The glutamate‐dependent acid resistance (GDAR) system is by far the most potent acid resistance system in commensal and pathogenic Escherichia coli, Shigella flexneri, Listeria monocytogenes and Lactococcus lactis. GDAR requires the activity of glutamate decarboxylase (GadB), an intracellular PLP‐dependent enzyme which performs a proton‐consuming decarboxylation reaction, and of the cognate antiporter (GadC), which performs the glutamate_in/γ‐aminobutyrate_out (GABA) electrogenic antiport. Herein we review recent findings on the structural determinants responsible for pH‐dependent intracellular activation of E. coli GadB and GadC. A survey of genomes of bacteria (pathogenic and non‐pathogenic), having in common the ability to colonize or to transit through the host gut, shows that the gadB and gadC genes frequently lie next or near each other. This gene arrangement is likely to be important to ensure timely co‐regulation of the decarboxylase and the antiporter. Besides the involvement in acid resistance, GABA production and release were found to occur at very high levels in lactic acid bacteria originally isolated from traditionally fermented foods, supporting the evidence that GABA‐enriched foods possess health‐promoting properties.     

Zeta Potential of Selected Bacteria in Drinking Water When Dead, Starved, or Exposed to Minimal and Rich Culture Media

The zeta potentials of E. coli, GFP (green fluorescence protein)-labeled E. coli, Salmonella Newport, and Pseudomonas sp. in different states (nutrient-starved and dead) and grown in rich and minimal media were measured. Capillary electrophoresis experiments were conducted to measure the zeta potential of the different cells suspended in a drinking water sample. Salmonella Newport strain showed a lower zeta potential compared to E. coli, GFP-labeled E. coli, and Pseudomonas sp. Starved E. coli cells had a lower zeta potential compared to E. coli cells grown under rich media conditions. Salmonella Newport cells grown in minimal media also had a lower zeta potential compared to rich, starved, and dead cells. The different bacterial cell types exhibited differences in size as well. These results suggest that when bacterial cells are present in drinking water they can exhibit significant heterogeneity in the size and zeta potential, depending on their physiological state.     

The adaptive acid tolerance response in root nodule bacteria and Escherichia coli

Root nodule bacteria and Escherichia coli show an adaptive acid tolerance response when grown under mildly acidic conditions. This is defined in terms of the rate of cell death upon exposure to acid shock at pH 3.0 and expressed in terms of a decimal reduction time, D. The D values varied with the strain and the pH of the culture medium. Early exponential phase cells of three strains of Rhizobium leguminosarum (WU95, 3001 and WSM710) had D values of 1, 6 and 5 min respectively when grown at pH 7.0; and D values of 5, 20 and 12 min respectively when grown at pH 5.0. Exponential phase cells of Rhizobium tropici UMR1899, Bradyrhizobium japonicum USDA110 and peanut Bradyrhizobium sp. NC92 were more tolerant with D values of 31, 35 and 42 min when grown at pH 7.0; and 56, 86 and 68 min when grown at pH 5.0. Cells of E. coli UB1301 in early exponential phase at pH 7.0 had a D value of 16 min, whereas at pH 5.0 it was 76 min. Stationary phase cells of R. leguminosarum and E. coli were more tolerant (D values usually 2 to 5-fold higher) than those in exponential phase. Cells of R. leguminosarum bv. trifolii 3001 or E. coli UB1301 transferred from cultures at pH. 7.0 to medium at pH 5.0 grew immediately and induced the acid tolerance response within one generation. This was prevented by the addition of chloramphenicol. Acidadapted cells of Rhizobium leguminosarum bv. trifolii WU95 and 3001; or E. coli UB1301, M3503 and M3504 were as sensitive to UV light as those grown at neutral pH.