Synthesis of unique proteins at the onset of carbon starvation inEscherichia coli

Summary Escherichia coli bulk protein synthesis continued during the first 3–4 h of carbon starvation at 50–75% that of non-starved (growing) cells. Two-dimensional gel electrophoresis analysis of in vivo pulse-labelled proteins resolved at least 30 polypeptides with new or increased synthesis, relative to total protein synthesis, during this time. Among these polypeptides were several that were also synthesized by ethanol-treatedE. coli (heat-shock proteins). In addition, a number of unique polypeptides were synthesized by carbon-starved cells. These starvation proteins may be involved in survival of the starving bacteria.     

Expression of cGMP-dependent protein kinase inEscherichia coli

Cyclic GMP-dependent protein kinase (cGMP kinase) is involved in the relaxation of smooth muscle. The enzyme has been cloned and expressed in eukaryotic cell lines but so far not in prokaryotic cells. Three vectors were constructed for the expression of I cGMP kinase inEscherichia coli. Transformation with the pET3a/cgk vector which uses the T7 RNA polymerase/promotor system resulted in efficient accumulation of cGMP kinase. Most of the protein was in an insoluble and catalytic inactive form. Various solubilization and refolding conditions did not yield an active enzyme. A small fraction of the cGMP kinase was present in the soluble cell extract. This fraction bound cGMP with high affinity but had no cGMP stimulated kinase activity. To prevent aggregation two additional vectors were constructed. (I) A bacterial leader sequence, which directs the export of proteins into the periplasmic space, was fused to the aminoterminus of the cGMP kinase. (II) A gram/gram⁺ shuttle vector for expression under the control of the tac promotor was used. Both constructs directed the synthesis of an isoluble and inactive cGMP kinase. These results suggest that large amounts of cGMP kinase can be expressed inE. coli, but mainly in an isoluble and inactive form. In contrast to eukaryotic cells, bacteria may lack systems for correct protein folding and/or posttranslational modification that are crucial for the productive folding and/or activation of cGMP kinase.     

Nitrate reductases inEscherichia coli

Escherichia coli expresses two different membrane-bound respiratory nitrate reductases, nitrate reductase A (NRA) and nitrate reductase Z (NRZ). In this review, we compare the genetic control, biochemical properties and regulation of these two closely related enzyme systems. The two enzymes are encoded by distinct operons located within two different loci on theE. coli chromosome. ThenarGHJI operon, encoding nitrate reductaseA, is located in thechlC locus at 27 minutes, along with several functionally related genes:narK, encoding a nitrate/nitrite antiporter, and thenarXL operon, encoding a nitrate-activated, two component regulatory system. ThenarZYWV operon, encoding nitrate reductase Z, is located in thechlZ locus located at 32.5 minutes, a region which includes anarK homologue,narU, but no apparent homologue to thenarXL operon. The two membrane-bound enzymes have similar structures and biochemical properties and are capable of reducing nitrate using normal physiological substrates. The homology of the amino acid sequences of the peptides encoded by the two operons is extremely high but the intergenic regions share no related sequences. The expression of both thenarGHJI operon and thenarK gene are positively regulated by two transacting factors Fnr and NarL-Phosphate, activated respectively by anaerobiosis and nitrate, while thenarZYWV operon and thenarU gene are constitutively expressed. Nitrate reductase A, which accounts for 98% of the nitrate reductase activity when fully induced, is clearly the major respiratory nitrate reductase inE. coli while the physiological role of the constitutively expressed nitrate reductase Z remains to be defined.Abbreviations NR nitrate reductaseOn leave from Department of Biochemistry and Molecular Biology, The University of Texas Medical school at Houston, Houston, Texas, 77225, USA     

Enhanced production of recombinant protein inEscherichia coli using silkworm hemolymph

The effect of silkworm hemolymph on the expression of recombinant protein inEscherichia coli was investigated. The addition of silkworm hemolymph to the culture medium increased the production of recombinant β-galactosidase inE. coli. The production was dependent on the concentration of the added silkworm hemolymph, which increased 2-, 5-, and 8-fold in media supplemented with 1,3, and 5% silkworm hemolymph, respectively. To identify the effective component, the silkworm hemolymph was fractionated by gel filtration column chromatography. A fraction, with a molecular weight of about 30 K was identified as the effective component.     

Comparison of protein quantification and extraction methods suitable for E. coli cultures

Many different extraction and analysis methods exist to determine the protein fraction of microbial cells. For metabolic engineering purposes it is important to have precise and accurate measurements. Therefore six different protein extraction protocols and seven protein quantification methods were tested and compared. Comparison was based on the reliability of the methods and boxplots of the normalized residuals. Some extraction techniques (SDS/chloroform and toluene) should never be used: the measurements are neither precise nor accurate. Bugbuster extraction combined with UV280 quantification gives the best results, followed by the combinations Sonication-UV280 and EasyLyse-UV280. However, if one does not want to use the quantification method UV280, one can opt to use Bugbuster, EasyLyse or sonication extraction combined with any quantification method with exception of the EasyLyse-BCA_P and Sonication-BCA_P combinations.     

Modulation of allele leakiness and adaptive mutability inEscherichia coli

It is shown that partial phenotypic suppression of two ochre mutations (argE3 andlacZU118) and an amber mutation (inargE) by sublethal concentrations of streptomycin in anrpsL ⁺ (streptomycin-sensitive) derivative of theEscherichia coli strain AB1157 greatly enhances their adaptive mutability under selection. Streptomycin also increases adaptive mutability brought about by theppm mutation described earlier. Inactivation ofrecA affects neither phenotypic suppression by streptomycin nor replication-associated mutagenesis but abolishes adaptive mutagenesis. These results indicate a causal relationship between allele leakiness and adaptive mutability.     

Characterization of pea chloroplastic carbonic anhydrase. Expression inEscherichia coli and site-directed mutagenesis

A cDNA encoding the mature, chloroplast-localized carbonic anhydrase in pea has been expressed inE. coli. The enzyme is fully active and yields of up to 20% of the total soluble protein can be obtained from the bacteria. This expression system was used to monitor the effects of site-directed mutagenesis of seven residues found within conserved regions in the pea carbonic anhydrase amino acid sequence. The effects of these modifications are discussed with respect to the potential of various amino acids to act as sites for zinc coordination or intramolecular proton shuttles.     

Amyloidogenic properties of transthyretin-like protein (TLP) from Escherichia coli

We report the amyloid-like properties of Escherichia coli transthyretin-like protein (TLP). TLP is 32% homologous to human transthyretin (hTTR), and is also tetrameric. In contrast to hTTR, TLP does not bind thyroxine. TLP orthologues are found in several prokaryotes, lower eukaryotes and vertebrates. TLP carries a signal peptide that targets the protein to the periplasmic space. We found that TLP and hTTR tetramers dissociate into monomers under similar conditions, although TLP monomers have different association properties. Like hTTR, TLP forms aggregates, small fibrillar structures of 8nm width, and annular structures of 8nm diameter which present amyloid-like properties and are toxic to cells.     

Glutamate excretion inEscherichia coli: dependency on thereIA andspoT genotype

Glutamate excretion due to amino acid starvation was investigated in “stringent” and “relaxed” strains ofEscherichia coli. The observed excretion process isrelA-dependent, carrier-mediated, and glutamate-specific. After induction, excretion was detected within less than 2 min and continued for more than 5h with a rate of 7–10 nmol (mg dry weight)⁻¹ min⁻¹. Using carbonyl cyanidem-chlorophenylhydrazone or polymyxin B nonapeptide, together with valinomycin, it was shown that glutamate excretion is driven by the membrane potential.     

Identification of the ferrioxamine B receptor,FoxB, inEscherichia coli K12

The photoreactivep-azidobenzoyl analog of ferrioxamine B was used to show that ferrioxamine-B-mediated iron transport is separate and distinct from coprogen-mediated iron transport inEscherichia coli. Photolysis of this analog inhibited uptake of [⁵⁹Fe]ferrioxamine B but not [⁵⁹Fe]coprogen or [⁵⁹Fe]ferrichrome. Conversely, photolysis of thep-azidobenzoyl analog of coprogen B inhibited uptake of [⁵⁹Fe]coprogen but not [⁵⁹Fe]ferrioxamine B or [⁵⁹Fe]ferrichrome. Photolabeling of outer membranes withp-azidobenzoyl-[⁵⁹Fe]ferrioxamine B resulted in the labeling of two iron-regulated peptides with molecular masses of about 66 and 26 kDa. Expression of these peptides was increased when ferrioxamine B was the sole iron source. Both peptides were present in outer membrane preparations of thefhuF mutant H1717, but the 66 kDa peptide was not inducible. These results are evidence for an outer membrane receptor inE. coli unique for linear ferrioxamines.     

Ecological strategies and fitness tradeoffs inEscherichia coli mutants adapted to prolonged starvation

Many bacteria in nature are nutritionally deprived, and there has been heightened interest during the past decade in the properties of these bacteria. We subjected five populations ofEscherichia coli to prolonged starvation in a minimal salts medium, during which time the density of viable cells declined by several orders of magnitude. From each one, we isolated a surviving clone that showed some heritable difference in colony morphology. We then characterized these mutants in two ecologically relevant respects. First, we determined the nature of their selective advantage, if any, during prolonged starvation. (i) Three of the five mutants had significantly lower net death rate when progenitor and mutant clones were starved separately. (ii) Three mutants showed a significant reduction in death rate in mixed culture that was frequency dependent and manifest when the mutant clone was initially rare. This pattern suggests that these mutants fed on some byproduct of progenitor cells (living or dead). (iii) Two mutants caused the death rate of their progenitors to increase significantly relative to the rate measured in the absence of the mutant. This pattern suggests that these mutants had become allelopathic to their progenitors. Thus, three distinct ecological adaptations to prolonged starvation are evident. No advantage was detected for one mutant, whereas two mutants exhibited multiple advantages. Second, we asked whether the starvation-selected mutants were as fit in growth-supporting conditions as their progenitors. All five mutants were inferior to their progenitor during competition in fresh medium. Evidently, there is an evolutionary tradeoff between performance under growth and starvation conditions.     

Expression of genes from the marine bacteriumAlteromonas haloplanktis 214 inEscherichia coli K-12

DNA from the marine bacteriumAlteromonas haloplanktis 214 was partially digested withSau 3A and inserted into theBam HI site of the cloning vector pBR322. The ligation mixture was used to transformEscherichia coli HB101. The gene bank plasmid preparation obtained was used to transformEscherichia coli K-12 strain EO2717, an organism auxotrophic for histidine, arginine, adenine, uracil and thiamin. Prototrophic transformants for each of the five metabolites were isolated using appropriate minimal media for selection. Plasmids isolated from each of the transformants were shown by hybridization to containA. haloplanktis DNA and to be capable of complementing the appropriate mutation inE. coli EO2717. Restriction maps showed that each of the plasmids was different.     

Genetic engineering of Escherichia coli for production of tetrahydrobiopterin

Tetrahydrobiopterin (BH4) is an essential cofactor for various enzymes in mammals. In vivo, it is synthesized from GTP via the three-step pathway of GTP cyclohydrolase I (GCHI), 6-pyruvoyl-tetrahydropterin synthase (PTPS) and sepiapterin reductase (SPR). BH4 is a medicine used to treat atypical hyperphenylalaninemia. It is currently synthesized by chemical means, which consists of many steps, and requires costly materials and complicated procedures. To explore an alternative microbial method for BH4 production, we utilized recombinant DNA technology to construct recombinant Escherichia coli (E. coli) strains carrying genes expressing GCHI, PTPS and SPR enzymes. These strains successfully produced BH4, which was detected as dihydrobiopterin and biopterin, oxidation products of BH4. In order to increase BH4 productivity we made further improvements. First, to increase the de novo GTP supply, an 8-azaguanine resistant mutant was isolated and an additional guaBA operon was introduced. Second, to augment the activity of GCHI, the folE gene from E. coli was replaced by the mtrA gene from Bacillus subtilis. These modifications provided us with a strain showing significantly higher productivity, up to 4.0 g of biopterin/L of culture broth. The results suggest the possibility of commercial BH4 production by our method.     

Production inEscherichia coli of activeSorghum phosphoenolpyruvate carboxylase which can be phosphorylated

Phosphoenolpyruvate carboxylase (PEPC)-deficient mutants ofEscherichia coli have been complemented with a plasmid bearing a full-length cDNA encoding the C4-type form ofSorghum leaf PEPC. Transformed cells grew on minimal medium. Two clones were selected which produce a functional and full-sized enzyme protein as determined by activity assays, immunochemical behavior and SDS-PAGE. In addition, regulatory phosphorylation of immunopurified recombinant PEPC was observed when the enzyme was incubated with a partially purified plant PEPC kinase. These results establish thatE. coli cells produce a genuine, phosphate-free, higher-plant PEPC. Application of immunoadsorbtion chromatography to bacterial extracts makes it possible to prepare highly pure protein available for biochemical studies.     

The influence of pH and external H+ concentration on caesium toxicity and accumulation inEscherichia coli andBacillus subtilis

Summary Toxicity screening ofEscherichia coli NCIB 9484 andBacillus subtilis 007, NCIB 168 and NCIB 1650 has shown Cs⁺ to be the most toxic Group 1 metal cation. However, toxicity and accumulation of Cs⁺ by the bacteria was affected by two main external factors; pH and the presence of other monovalent cations, particularly K⁺. Over the pH range 6–9 bothE. coli andB. subtilis showed increasing sensitivity towards caesium as the pH was raised. The presence of K⁺ and Na⁺ in the laboratory media used lowered caesium toxicity and lowered acumulation of the metal. In order to assess accurately Cs⁺ toxicity towards the bacterial strains it was therefore necessary to define the K⁺:Cs⁺ ratio in the external medium. The minimum inhibitory K⁺:Cs⁺ concentration ratio for theBacillus strains tested was in the range 12–13 whileE. coli had a minimum inhibitory K⁺:Cs⁺ concentration ratio of 16.     

Low synonymous site variation at thelacY locus inEscherichia coli suggests the action of positive selection

We have determined the nucleotide sequences of sevenlacY alleles isolated from natural isolates ofEscherichia coli. Nucleotide heterozygosity estimates for this locus were compared to those obtained from previous studies of intraspecific variation at chromosomal loci, revealing thatlacY has unusually low synonymous site variation. The average pairwise heterozygosity of synonymous sites (Ks=0.0112+/-0.0100) is the second lowest reported and the lowest for loci that have an equivalent level of nonsynonymous variation. We consider several hypotheses to explain how different forces in evolution could act to create the observed pattern of polymorphism, including selection for translational efficiency and positive selection. Our analysis most strongly supports the hypothesis that positive selection has acted on thelacY locus inE. coli.     

Plasmid amplification in Escherichia coli after temperature upshift is impaired by induction of recombinant protein synthesis

Production of recombinant proteins often interferes with the physiology of the host organism by causing stress responses. In recombinant Escherichia coli, the cellular content of ColE1-derived plasmids and, consequently, the synthesis of the constitutively synthesized plasmid-encoded proteins generally increases after a temperature upshift. Simultaneous induction of inducible recombinant proteins that are synthesized at high levels and tend to form inclusion bodies, however, attenuates the plasmid amplification. This phenomenon was observed using temperature- as well as IPTG-inducible expression systems. Thus, high-level recombinant gene expression in connection with inclusion body formation does not only interfere with host cell but also with plasmid-related functions.     

Preparation and characterization of truncated human lipopolysaccharide-binding protein in Escherichia coli

Lipopolysaccharide (LPS) is a component of the outer membrane of Gram-negative bacteria, and is the causative agent of endotoxin shock. LPS induces signal transduction in immune cells when it is recognized by the cell surface complex of toll-like receptor 4 (TLR4) and MD-2. The complex recognizes the lipid A structure in LPS, which is buried in the membrane of the outer envelope. To present the Lipid A structure to the TLR4/MD-2, processing of LPS by LPS-binding protein (LBP) and CD14 is required. In previous studies, we expressed recombinant proteins of human MD-2 and CD14 as fusion proteins with thioredoxin in Escherichia coli, and demonstrated their specific binding abilities to LPS. In this study, we prepared a recombinant fusion protein containing 212 amino terminal residues of human LBP (HLB212) by using the same expression system. The recombinant protein expressed in E. coli was purified as a complex form with host LPS. The binding was not affected by high concentrations of salt, but was prevented by low concentrations of various detergents. Both rough-type LPS lacking the O antigen and smooth-type LPS with the antigen bound to HLBP212. Therefore, oligosaccharide repeats appeared to be unnecessary for the binding. A nonpathogenic penta-acylated LPS also bound to HLBP212, but the binding was weaker than that of the wild type. The hydrophobic interaction between the LBP and acyl chains of lipid A appears to be important for the binding. The recombinant proteins of LPS-binding molecules would be useful for analyzing the defense mechanism against infections.     

Alternative gene for biotin sulfoxide reduction inEscherichia coli K-12

A gene at 42 min on theEscherichia coli chromosome, identified as the locus of pseudoreversion of knockout mutations in the biotin sulfoxide reductase gene,bisC, has 64% base sequence identity withbisC. This makes it a member of a multigene family of molybdopterin enzymes that includes genes for anaerobic reduction of trimethylamine oxide (torA) and dimethylsulfoxide (dmsA). Disruption of this gene eliminates the background activity of biotin sulfoxide reduction observed inbisC mutants. Sequence comparison of the new gene (bisZ) withbisC indicates that certaints mutants ofbisC arise by gene conversion between the two loci.