Induction threshold of the Q - mutant of bacteriophage λ in Escherichia coli

Temperature induction of bacteriophage in Escherichia coli depends on bacterial population density. The lowest rate of viability loss at the temperature threshold results in maximal gene expression of . -Infection causes bacterial cells to lose cell viability and thus decrease temperature induction efficiency. In addition, shifting-up in temperature increases the probability of progeny ; thus, the mortality of bacterial hosts increases and the expression of recombinant proteins by naked significantly decrease.     

Uptake of bacteriophage λ DNA in Escherichia coli by electroporation: An alternative to in vitro packaging

Summary By using a high field strength DC pulse of 15 kV/cm and a pulse duration of 5 ms for the transfection of E. coli by bacteriophage DNA, we obtained efficiencies of 1.1 × 10⁶ (pfu/g bacteriophage , DNA). This represents a 100-fold improvement over the traditional CaCl₂/heat shock method and is a viable alternative to the more costly in vitro packaging of recombinant bacteriophage DNA for the production of cDNA and genomic libraries.     

The Bacteriophage λ Attachment Site in Wild Strains of Escherichia coli

The attachment site (attlambda) of bacteriophage lambda was examined in wild strains of Escherichia coli. Although the att region is non-coding, the DNA sequence was invariant in the 13 strains examined. Two other non-coding regions showed nine changes, all associated with a single strain. In four of 33 strains, sequences were inserted in or near the attlambda site and in two of these the insert was related to lambda. Among strains that can be lysogenized by lambda, integration was via the attlambda site in all cases. Some resistant strains can be lysogenized, and these have been termed "lenient." Most of these fail to give normal phage yield after induction. In some cases rare lysogens have been formed in cells that belong to a mutant subpopulation.     

Repressor and int synthesis of bacteriophage λ in the E. coli host mutant ER437

Molecular Genetics and Genomics - Analysis of λ phage infection of the host mutant ER437 by SDS polyacrylamide gel electrophoresis and autoradiography has revealed altered expression of...     

Enhancement of bacteriophage λ stability using a λQ − S − mutant in the continuous culture of Escherichia coli

In this study, we used a bacteriophage λQ ⁻ S ⁻ mutant that increased the stability of recombinant Escherichia coli during continuous culture. The operation was conducted in two stages: the first stage was carried out to promote cell growth, and the second stage was performed for product formation. The productivity of recombinant proteins depends on the substrate concentration of the fresh medium supplied to the second stage (S ₃) and dilution rate of the second stage (D ₂). With the optimal value of S ₃ and D ₂, the first and second stages were stably maintained for 170 and 80 h, respectively. To further improve this process, a three-stage continuous process was conducted with an additional induction stage between the growth and production stages. Compared with the two-stage operation, the stable production period was extended by 1.7 fold, and the recombinant protein production increased by 1.3 fold.     

The Escherichia coli genome sequence: the end of an era or the start of the FUN?

Our dream of determining the entire Escherichia coli K12 genome sequence has been realized. This calls for new approaches for the analysis of gene expression and function in biology's best-understood organism. Comparison of the E. coli genome sequence with others will provide important taxonomic insights and have implications for the study of bacterial virulence. Approximately 20% of E. coli genes have been designated FUN genes, because they have no known function or homologies to sequence databases. FUN genes promise to have an exciting impact on bacterial research. The post-genome era requires novel strategies that address gene regulation at the level of the entire cell. These strategies need to supersede the reductionist approach to genetic analysis. Only then will the genome sequence lead us to an understanding of how a bacterial cell really works.     

lamB mutations in E. coli K12: Growth of λ host range mutants and effect of nonsense suppressors

Summary Over sixty EMS induced mutations affecting gene lamB, presumably the structural gene for the receptor in Escherichia coli K12, were examined for growth of host range mutants and effect of nonsense suppressors. By the first criterion the mutations could be grouped in three classes. Bacteria with class I mutations allow growth of mutants with extended host range (noted h) of the type already described (Appleyard, Mac Gregor and Baird, 1956). Bacteria with class II mutations allow growth of h mutants with still more extended host range (noted hh ^*). No host range mutants of could be found which would grow on bacteria with class III mutations. Using nonsense suppressors it was found that class I and II consist of missense mutations, while class III consists of nonsense mutations. Exceptions are likely to exist (especially in class III) but were not found among the mutations tested. These observations are briefly discussed in terms of outer membrane protein integration and of phage receptor interaction.     

Isolation of superoxide dismutase mutants in Escherichia coli: is superoxide dismutase necessary for aerobic life?

Mu transposons carrying the chloramphenicol resistance marker have been inserted into the cloned Escherichia coli genes sodA and sodB coding for manganese superoxide dismutase (MnSOD) and iron superoxide dismutase (FeSOD) respectively, creating mutations and gene fusions. The mutated sodA or sodB genes were introduced into the bacterial chromosome by allelic exchange. The resulting mutants were shown to lack the corresponding SOD by activity measurements and immunoblot analysis. Aerobically, in rich medium, the absence of FeSOD or MnSOD had no major effect on growth or sensitivity to the superoxide generator, paraquat. In minimal medium aerobic growth was not affected, but the sensitivity to paraquat was increased, especially in the sodA mutant. A sodA sodB double mutant completely devoid of SOD was also obtained. It was able to grow aerobically in rich medium, its catalase level was unaffected and it was highly sensitive to paraquat and hydrogen peroxide; the double mutant was unable to grow aerobically on minimal glucose medium. Growth could be restored by removing oxygen, by providing an SOD-overproducing plasmid or by supplementing the medium with the 20 amino acids. It is concluded that the total absence of SOD in E. coli creates a conditional sensitivity to oxygen.     

The effect of α-mating factor secretion signal mutations on recombinant protein expression in Pichia pastoris

The methylotrophic yeast, Pichia pastoris, has been genetically engineered to produce many heterologous proteins for industrial and research purposes. In order to secrete proteins for easier purification from the extracellular medium, the coding sequence of recombinant proteins is initially fused to the Saccharomyces cerevisiae α-mating factor secretion signal leader. Extensive site-directed mutagenesis of the prepro-region of the α-mating factor secretion signal sequence was performed in order to determine the effects of various deletions and substitutions on expression. Though some mutations clearly dampened protein expression, deletion of amino acids 57–70, corresponding to the predicted 3rd alpha helix of α-mating factor secretion signal, increased secretion of reporter proteins horseradish peroxidase and lipase at least 50% in small-scale cultures. These findings raise the possibility that the secretory efficiency of the leader can be further enhanced in the future.     

Effects of mutations in genesfadR,fabB, fadE,andenvC ofEscherichia coli on the action of the lysis gene of bacteriophageϕX174

The lytic effect of the expression of the cloned geneE of bacteriophage X174 inEscherichia coli is considerably amplified by a mutation in thefadR gene, which primarily affects the regulation of fatty acid degradation. In contrast, reduction of the fluidity of the cell membranes by use of thefabB andfadE mutations, which interfere with the synthesis and the oxidation of unsaturated fatty acids, severely inhibits the action of the X174 lysis gene product. A chain-forming mutant carrying a pleiotropic mutation in theenvC locus is also refractory to the X174 lysis protein. As shown by reversion and complementation of theenvC mutatation, a defect in at least one additional gene (rle) is involved in the generation of this refractoriness.