IS2-43 and IS2-44: New alleles of the insertion sequence IS2 which have promoter activity

Summary The sequence of two new IS2 alleles with promoter activity (IS2-43 and IS2-44) is reported. The alleles are identical and are formed by a 17 bp tandem duplication in an AT-rich region of IS2. This created a new RNA polymerase binding site. A mutation was found that increased the frequency of formation of these 17 bp duplications but not of another class of duplications, the mini-insertions. This suggested that the mechanisms of formation of the two classes of duplications are different.     

Characterization of the metabolic burden on Escherichia coli DH1 cells imposed by the presence of a plasmid containing a gene therapy sequence

The presence of a plasmid, containing gene sequences for DNA immunotherapy that are not expressed in microbial culture, imposed a degradation in bioreactor performance in cultures of the host E. coli strain. Significant decreases in growth rate (24%) and biomass yield (7%) and a corresponding increase in overflow metabolism were observed in a strain containing a therapeutic sequence (a hepatitis B antigen under the control of a CMV promotor). The observed increase in overflow metabolism was incorporated into a Metabolic Flux Analysis (MFA) model (as acetate secretion). Metabolic flux analysis revealed an increase in TCA cycle flux, consistent with an increased respiration rate observed in plasmid-containing cells. These effects are thought to result from increased ATP synthesis requirements (24%) arising from the expression of the Kanr plasmid marker gene whose product accounted for 18% of the cell protein of the plasmid-containing strain. These factors will necessitate significantly higher aeration and agitation rates or lower nutrient feed rates in high-density cultures than would be expected for plasmid-free cultures.     

Influence of plasmid origin and promoter strength in fermentations of recombinant yeast

The effects of plasmid promoter strength and origin of replication on cloned gene expression in recombinant Saccharomyces cerevisiae have been studied in batch and continuous culture. The plasmids employed contain the Escherichia coli lacZ gene under the control of yeast promoters regulated by the galactose regulatory circuit. The synthesis of beta-galactosidase was therefore induced by the addition of galactose. The initial induction transients in batch culture were compared for strains containing plasmids with 2mu and ARS1 origins. As expected, cloned gene product synthesis was much lower with the ARS1 plasmid: average beta-galactosidase specific activity was an order of magnitude below that with the 2mu-based plasmid. This was primarily due to the low plasmid stability of 7.5% when the plasmid origin of replication was the ARS1 element. The influence of plasmid promoter strength was studied using the yeast GAL1, GAL10, and hybrid GAL10-CYC1 promoters. The rate of increase in beta-galactosidase specific activity after induction in batch culture was 3-5 times higher with the GAL1 promoter. Growth rate under induced conditions, however, was 15% lower than in the absence of lacZ expression for this promoter system. The influence of plasmid promoter strength on induction behavior and cloned gene expression was also studied in continuous fermentations. Higher beta-galactosidase production and lower biomass concentration and plasmid stability were observed for the strain bearing the plasmid with the stronger GAL1 promoter. Despite the decrease in biomass concentration and plasmid stability, overall productivity in continuous culture using the GAL1 promoter was three times that obtained with the GAL10-CYC1 promoter.     

Characterization of the new insertion sequence IS91 from an alpha-hemolysin plasmid of Escherichia coli

Summary IS91 is a 1.85 kb insertion sequence originally resident in the -hemolytic plasmid pSU233. The element was transposed sequentially from this plasmid to pA-CYC184, to R388, and to pBR322. Both cointegrates and simple insertions of the element were obtained. A detailed restriction enzyme map of the element is presented. This does not bear any relationship to the maps of previously described insertion sequences. Furthermore, hybridization between these sequences and IS91 could not be demonstrated.Deletion derivatives of IS91 were constructed which are unable to transpose. However, their transposition can be complemented in Trans by wild-type elements. One of these deletion derivatives has been genetically labeled with a kanamycin resistance marker from Tn5. When this new element was complemented for transposition, only about 2% of the transposition products were cointegrates. Thus, the behavior of IS91 is better explained by transposition models that allow direct transposition.Part of this work was carried out by E. Diaz-Aroca as a requirement for her degree in Sciences. The work is published (Esmeralda Diaz-Aroca, Tesina de Licenciatura, Universidad Autónoma de Madrid, 1983) and it contains the complete details of procedures and results of the cloning experiments and the restriction maps of the plasmids shown in this work. It is available from the authors upon request     

Analysis of IS21-mediated mobilization of plasmid pACYC184 by R68.45 in Escherichia coli

Escherichia coli plasmids like pACYC184 or pBR325 can be mobilized by the P-type plasmid R68.45, which carries a tandem duplication of insertion element IS21, at a frequency of 10^?3–10^?5 per donor cell. Analysis of exconjugant cells revealed that plasmid mobilization occurs via cointegrate formation involving transposition of IS21. No resolution of cointegrates of pACYC184 and the P-type plasmid could be found in recA recipient cells. In the cointegrate, the E. coli plasmid is flanked by single copies of IS21 in direct orientation. After resolution of the cointegrate in recA⁺ recipients, the mobilizing plasmid R68.45 lost one copy of IS21 becoming indistinguishable from plasmid R68. It was shown that during mobilization, insertion element IS21 transposes to the mobilized plasmid. Insertion sites and orientations of IS21 in 33 pACYC184::IS21 insertion mutants have been determined: IS21 was found to be integrated in plasmid pACYC184 in different regions but only in one orientation. The IS21 tandem structure of plasmid R68.45 and its role in the mobilization process is discussed.     

Nucleotide sequence of the transposable DNA-element IS2.

The complete sequence of the transposable DNA element IS2 in gal OP-308:: IS2 (I) has been determined. This element is 1.327 bp long. The integrated element is flanked by a five base pair long sequence duplication. The termini of IS2 are not perfect inverted repeats, but a close approximation.     

Insertion sequence IS2 in the cyanobacterium Chlorogloeopsis fritschii

A cloned DNA fragment, previously demonstrated to encode ribulose bisphosphate carboxylase/oxygenase (RuBisCO) of Chlorogloeopsis fritschii strain CCAP1411/1b, is shown also to include the entire transposable element, IS2, normally a resident in the Escherichia coli genome. Southern-blot hybridisation experiments confirm the presence of IS2 in the C. fritschii genome. This finding adds a new and unrelated species to the known host range of this element and provides evidence of genetic transfer between the Gram-negative E. coli and cyanobacteria. This may also have significance in relation to the nucleotide sequence rearrangements known to occur adjacent to RuBisCO and nif genes in other nitrogen-fixing cyanobacteria.     

Integration of IS3 into IS2 generates a short sequence duplication.

Summary The Gal⁺ allele IS2-43 is known to segregate Gal^- clones. Among 11 Gal^- segregants, one was shown to be due to the integration of IS3 into IS2-43. Precise excision of the integrated IS3 element occured at a rate of 5x10^-9/cell/generation. DNA sequence analysis revealed that the termini of the IS3 element have the relation of imperfect inverted repeats and it is now flanked by a 3bp or 4bp duplication, a size which has not been seen before with other elements.     

IS1-mediated tandem duplication of plasmid pBR322. Dependence on recA and on DNA polymerase I

Transposable-element-mediated fusion of the conjugal plasmid pOX38::Tn9 with pBR322 results in the appearance of cointegrates composed of a single copy of each plasmid, and cointegrates which carry a single copy of pOX38 but multiple tandem copies of pBR322. These plasmids are separated by directly repeated copies of the transposable element. We demonstrate here that such multimers can be generated from monomeric cointegrates, probably by unequal crossing over between the flanking Tn9(IS1) elements. Their appearance is thus not necessarily associated with the original transposition (fusion) event. Our study demonstrates that the process of duplication is strongly dependent on the homologous recombination system of Escherichia coli, since it is undetectable by our methods in recA- strains. It is also strongly dependent on the presence of a functional DNA polymerase I in the cell. The major pathway(s) for this duplication thus appears to rely on both the homologous recombination system and the replication of the duplicated segment.     

Occurrence of insertion sequence (IS) regions on plasmid deoxyribonucleic acid as direct and inverted nucleotide sequence duplications.

Insertion sequence (IS) regions have been identified previously as a cause of strongly polar mutations in Escherichia coli and several bacteriophages. The present experiments indicate that genetically characterized IS regions occur on bacterial plasmid deoxyribonucleic acid (DNA) as both direct and inverted DNA sequence duplications. The DNA insertion which has been shown previously (Sharp et al., 1973) to control expression of tetracycline resistance in the R6-5 plasmid, and which occurs as directly and inversely repeated DNA sequences adjacent to the region believed to contain the tetracycline resistance gene, has been identified as IS3. A second genetically characterized insertion sequence (IS1) has been identified as a direct DNA duplication occurring at both junctions of the resistance transfer factor and R-determinant components of R6-5 and related plasmids. A model is presented for the reversible dissociation of resistance transfer factor and R-determinant components of co-integrate R plasmids at the sites of DNA sequence homology provided by the repeated IS regions.     

Plasmid-encoded protein: the principal factor in the "metabolic burden" associated with recombinant bacteria

Experimental elucidation of the metabolic load placed on bacteria by the expression of foreign protein is presented. The host/vector system is Escherichia coli RR1/pBR329 (amp(r), cam(r), and let(r)). Plasmid content results, which indicate that the plasmid copy number monotonically increases with decreasing growth rate, are consistent with the literature on ColE1-like plasmids. More significantly, we have experimentally quantified the reduction in growth rate brought about by the expression of chloramphenicol-acetyl-transferase (CAT) and beta-lactamase. Results indicate a nearly linear decrease in growth rate with increasing foreign protein content. Also, the change in growth rate due to foreign protein expression depends on the growth rate of the cells. The observed linear relationship is media independent and, to our knowledge, previously undocumented. Furthermore, the induction of CAT, mediated by the presence of chloramphenicol, is shown to occur only at low growth rates, which further increases the metabolic load.Results are vdelineated with the aid of a structured kinetic model representing the metabolism of recombinant E. coli. In this article, several previous hypotheses and model predictions are justified and validated. This work provides an important step in the development of comprehensive, methabolically-structured, kinetic models capable of prediciting optimal conditions for maximizing product yield.