Inactivation of the Serratia marcescens gene for the lipoprotein in Escherichia coli by insertion sequences, IS1 and IS5; sequence analysis of junction points

Investigating How Genomic Contexts Impact IS5 Transposition Within the Escherichia coli Genome

Insertions of the transposable element IS5 into its target sites in response to stressful environmental conditions, DNA structures, and DNA-binding proteins are well studied, but how the genomic contexts near IS5's native loci impact its transpositions is largely unknown. Here, by examining the roles of all 11 copies of IS5 within the genome of E. coli strain BW25113 in transposition, we reveal that the most significant copy of IS5 is one nested within and oriented in the same direction as the nmpC gene, while two other copies of IS5 harboring point mutations are hardly transposed. Transposition activity is heavily reliant on the upstream nmpC promoter that drives IS5 transposase gene ins5A, with more transpositions resulting from greater promoter activity. The IS5 element at nmpC but not at other loci transcribed detectable amounts of ins5A mRNA. By increasing expression of the ins5CB operon harbored in IS5, we demonstrate that Ins5B and Ins5C appear to exert a stimulatory role in IS5 transposition, suggesting that the downstream genomic regions near the native loci are involved in overall IS5 transposition as well. Using a strain that carries IS5 only at the nmpC locus, we confirm that IS5 primarily uses a copy/paste mechanism for transposition, although we cannot rule out the cut/paste mechanism.

Exploring the Potential of a Genome-Reduced Escherichia coli Strain for Plasmid DNA Production

The global demand for nucleic acid-based vaccines, including plasmid DNA (pDNA) and mRNA vaccines, needs efficient production platforms. However, conventional hosts for plasmid production have encountered challenges related to sequence integrity due to the presence of insertion sequences (ISs). In this study, we explored the potential of a genome-reduced Escherichia coli as a host for pDNA production. This strain had been constructed by removing approximately 23% of the genome which were unessential genes, including the genomic unstable elements. Moreover, the strain exhibits an elevated level of NADPH, a coenzyme known to increase plasmid production according to a mathematical model. We hypothesized that the combination of genome reduction and the abundance of NADPH would significantly enhance pDNA production capabilities. Remarkably, our results confirmed a three-fold increase in pDNA production compared to the widely employed DH5α strain. Furthermore, the genome-reduced strain exhibited heightened sensitivity to various antibiotics, bolstering its potential for large scale industrial pDNA production. These findings suggest the genome-reduced E. coli as an exciting candidate for revolutionizing the pDNA industry, offering unprecedented efficiency and productivity.

Frequency, composition and mobility of Escherichia coli-derived transposable elements in holdings of plasmid repositories

By providing the scientific community with uniform and standardized resources of consistent quality, plasmid repositories play an important role in enabling scientific reproducibility. Plasmids containing insertion sequence elements (IS elements) represent a challenge from this perspective, as they can change the plasmid structure and function. In this study, we conducted a systematic analysis of a subset of plasmid stocks distributed by plasmid repositories (The Arabidopsis Biological Resource Center and Addgene) which carry unintended integrations of bacterial mobile genetic elements. The integration of insertion sequences was most often found in, but not limited to, pBR322-derived vectors, and did not affect the function of the specific plasmids. In certain cases, the entire stock was affected, but the majority of the stocks tested contained a mixture of the wild-type and the mutated plasmids, suggesting that the acquisition of IS elements likely occurred after the plasmids were acquired by the repositories. However, comparison of the sequencing results of the original samples revealed that some plasmids already carried insertion mutations at the time of donation. While an extensive BLAST analysis of 47 877 plasmids sequenced from the Addgene repository uncovered IS elements in only 1.12%, suggesting that IS contamination is not widespread, further tests showed that plasmid integration of IS elements can propagate in conventional Escherichia coli hosts over a few tens of generations. Use of IS-free E. coli hosts prevented the emergence of IS insertions as well as that of small indels, suggesting that the use of IS-free hosts by donors and repositories could help limit unexpected and unwanted IS integrations into plasmids.

Chromosome-free bacterial cells are safe and programmable platforms for synthetic biology

A type of chromosome-free cell called SimCells (simple cells) has been generated from Escherichia coli, Pseudomonas putida, and Ralstonia eutropha. The removal of the native chromosomes of these bacteria was achieved by double-stranded breaks made by heterologous I-CeuI endonuclease and the degradation activity of endogenous nucleases. We have shown that the cellular machinery remained functional in these chromosome-free SimCells and was able to process various genetic circuits. This includes the glycolysis pathway (composed of 10 genes) and inducible genetic circuits. It was found that the glycolysis pathway significantly extended longevity of SimCells due to its ability to regenerate ATP and NADH/NADPH. The SimCells were able to continuously express synthetic genetic circuits for 10 d after chromosome removal. As a proof of principle, we demonstrated that SimCells can be used as a safe agent (as they cannot replicate) for bacterial therapy. SimCells were used to synthesize catechol (a potent anticancer drug) from salicylic acid to inhibit lung, brain, and soft-tissue cancer cells. SimCells represent a simplified synthetic biology chassis that can be programmed to manufacture and deliver products safely without interference from the host genome.

Defensive Function of Transposable Elements in Bacteria

It has been widely debated whether transposable elements have a positive or a negative effect on their host cells. This study demonstrated that transposable elements, specifically insertion sequences (ISs), can adopt a defensive role in Escherichia coli. In three different E. coli strains (S17, DH5α, and Nissle 1917), IS1 and IS10 rapidly disrupted the I-CeuI gene (encoding I-CeuI endonuclease) on the plasmid pLO11-ICeuI as early as the first generation, despite the gene-circuit being under control of an arabinose promoter. Proteomics analysis showed that the protein abundance profile of E. coli DH5α with pLO11-ICeuI in the fifth generation was nearly opposite to that of control strain (E. coli with pLO11, no I-CeuI). The DNA damage caused by the leaky expression of I-CeuI was enough to trigger a SOS response and alter lipid synthesis, ribosomal activity, RNA/DNA metabolism, central dogma and cell cycle processes in E. coli DH5α. After the ISs disrupted the expression of I-CeuI, cells fully recovered by the 31st generation had a protein abundance profile similar to that of the control strain. This study showed that ISs readily mutated a harmful gene which subsequently restored host fitness. These observations have implications for the stability of designed gene circuits in synthetic biology.

CRISPR-interference-based modulation of mobile genetic elements in bacteria

Spontaneous mutagenesis of synthetic genetic constructs by mobile genetic elements frequently results in the rapid loss of engineered functions. Previous efforts to minimize such mutations required the exceedingly time-consuming manipulation of bacterial chromosomes and the complete removal of insertional sequences (ISes). To this aim, we developed a single plasmid-based system (pCRIS) that applies CRISPR-interference to inhibit the transposition of bacterial ISes. pCRIS expresses multiple guide RNAs to direct inactivated Cas9 (dCas9) to simultaneously silence IS1, IS3, IS5 and IS150 at up to 38 chromosomal loci in Escherichia coli, in vivo. As a result, the transposition rate of all four targeted ISes dropped to negligible levels at both chromosomal and episomal targets. Most notably, pCRIS, while requiring only a single plasmid delivery performed within a single day, provided a reduction of IS-mobility comparable to that seen in genome-scale chromosome engineering projects. The fitness cost of multiple IS-knockdown, detectable in flask-and-shaker systems was readily outweighed by the less frequent inactivation of the transgene, as observed in green fluorescent protein (GFP)-overexpression experiments. In addition, global transcriptomics analysis revealed only minute alterations in the expression of untargeted genes. Finally, the transposition-silencing effect of pCRIS was easily transferable across multiple E. coli strains. The plasticity and robustness of our IS-silencing system make it a promising tool to stabilize bacterial genomes for synthetic biology and industrial biotechnology applications.

Bacteriophage recombineering in the lytic state using the lambda red recombinases

Bacteriophages, the historic model organisms facilitating the initiation of molecular biology, are still important candidates of numerous useful or promising biotechnological applications. Development of generally applicable, simple and rapid techniques for their genetic engineering is therefore a validated goal. In this article, we report the use of bacteriophage recombineering with electroporated DNA (BRED), for the first time in a coliphage. With the help of BRED, we removed a copy of mobile element IS1, shown to be active, from the genome of P1vir, a coliphage frequently used in genome engineering procedures. The engineered, IS-free coliphage, P1virdeltaIS, displayed normal plaque morphology, phage titre, burst size and capacity for generalized transduction. When performing head-to-head competition experiments, P1vir could not outperform P1virdeltaIS, further indicating that the specific copy of IS1 plays no direct role in lytic replication. Overall, P1virdeltaIS provides a genome engineering vehicle free of IS contamination, and BRED is likely to serve as a generally applicable tool for engineering bacteriophage genomes in a wide range of taxa.

Novel miniature transposable elements in thermophilic Synechococcus strains and their impact on an environmental population

The genomes of the two closely related freshwater thermophilic cyanobacteria Synechococcus sp. strain JA-3-3Ab and Synechococcus sp. strain JA-2-3B'a(2-13) each host several families of insertion sequences (ISSoc families) at various copy numbers, resulting in an overall high abundance of insertion sequences in the genomes. In addition to full-length copies, a large number of internal deletion variants have been identified. ISSoc2 has two variants (ISSoc2∂-1 and ISSoc2∂-2) that are observed to have multiple near-exact copies. Comparison of environmental metagenomic sequences to the Synechococcus genomes reveals novel placement of copies of ISSoc2, ISSoc2∂-1, and ISSoc2∂-2. Thus, ISSoc2∂-1 and ISSoc2∂-2 appear to be active nonautonomous mobile elements derived by internal deletion from ISSoc2. Insertion sites interrupting genes that are likely critical for cell viability were detected; however, most insertions either were intergenic or were within genes of unknown function. Most novel insertions detected in the metagenome were rare, suggesting a stringent selective environment. Evidence for mobility of internal deletion variants of other insertion sequences in these isolates suggests that this is a general mechanism for the formation of miniature insertion sequences.

Analysis of insertion sequences in thermophilic cyanobacteria: exploring the mechanisms of establishing, maintaining, and withstanding high insertion sequence abundance

Insertion sequences (ISs) are simple mobile genetic elements capable of relocating within a genome. Through this transposition activity, they are known to create mutations which are mostly deleterious to the cell, although occasionally they are beneficial. Two closely related isolates of thermophilic Synechococcus species from hot spring microbial mats are known to harbor a large number of diverse ISs. To explore the mechanism of IS acquisition within natural populations and survival in the face of high IS abundance, we examined IS content and location in natural populations of Synechococcus by comparing metagenomic data to the genomes of fully sequenced cultured isolates. The observed IS distribution in the metagenome was equivalent to the distribution in the isolates, indicating that the cultured isolates are appropriate models for the environmental population. High sequence conservation between IS families shared between the two isolates suggests that ISs are able to move between individuals within populations and between species via lateral gene transfer, consistent with models for IS family accumulation. Most IS families show evidence of recent activity, and interruption of critical genes in some individuals was observed, demonstrating that transposition is an ongoing mutational force in the populations.

Reduced evolvability of Escherichia coli MDS42, an IS-less cellular chassis for molecular and synthetic biology applications

Background

Evolvability is an intrinsic feature of all living cells. However, newly emerging, evolved features can be undesirable when genetic circuits, designed and fabricated by rational, synthetic biological approaches, are installed in the cell. Streamlined-genome E. coli MDS42 is free of mutation-generating IS elements, and can serve as a host with reduced evolutionary potential.

Results

We analyze an extreme case of toxic plasmid clone instability, and show that random host IS element hopping, causing inactivation of the toxic cloned sequences, followed by automatic selection of the fast-growing mutants, can prevent the maintenance of a clone developed for vaccine production. Analyzing the molecular details, we identify a hydrophobic protein as the toxic byproduct of the clone, and show that IS elements spontaneously landing in the cloned fragment relieve the cell from the stress by blocking transcription of the toxic gene. Bioinformatics analysis of sequence reads from early shotgun genome sequencing projects, where clone libraries were constructed and maintained in E. coli, suggests that such IS-mediated inactivation of ectopic genes inhibiting the growth of the E. coli cloning host might happen more frequently than generally anticipated, leading to genomic instability and selection of altered clones.

Conclusions

Delayed genetic adaptation of clean-genome, IS-free MDS42 host improves maintenance of unstable genetic constructs, and is suggested to be beneficial in both laboratory and industrial settings.

Identification and characterization of IS1 transposition in plasmid amplification mutants of E. coli clones producing DNA vaccines

Merck Research Laboratories has developed a highly productive Escherichia coli fermentation process to produce plasmid DNA for use as vaccines. The process consists of a fed-batch fermentation in a chemically defined medium. Initiation of the feed stream precedes a growth-limited phase in which plasmid DNA is amplified. The fermentation is only maximally productive for a small fraction of E. coli transformants designated as high-producers, while the predominant low-producer population does not amplify plasmid DNA. In experiments undertaken to probe this phenomenon, transposition of the 768-bp E. coli insertion sequence IS1 into an HIV DNA vaccine vector was observed in several low-producer clones. IS1 was found to insert in or near the neomycin resistance gene in nearly a dozen unique sites from within a single population of plasmid molecules. The fraction of IS1-containing plasmids within several clones was determined by quantitative polymerase chain reaction and was found to increase with increasing cultivation time in the chemically defined medium. Because transposition into an antibiotic-resistance gene is unlikely to affect plasmid amplification, the genomes of high- and low-producers of three different HIV DNA vaccine vectors were subsequently profiled by restriction fragment length polymorphism analysis. In all three cases, IS1 insertional mutations were found in the genomes of the predominant low-producers, while the genomes of the high-producers were indistinguishable from untransformed cells. The insertions reside on similarly sized fragments for two of the low-producer clones, and the fragment size is smaller for the third clone. The third clone also produces much less plasmid DNA than a typical low-producer. The results suggest the presence of an IS1 insertional mutation that affects plasmid replication and amplification, possibly in a position-dependent manner.

Plasmid instabilities of single and three-plasmid systems in Escherichia coli during continuous cultivation

Plasmid instabilities in E. coli JM103 carrying three plasmids (pRK248cI, pMTC48, pEcoR4) and a single plasmid system (pTG206) for the production of fusion EcoRI (SPA::EcoRI) and catechol 2,3-dioxygenase, respectively, were investigated in continuous cultures under selective and non-selective conditions. In a three-plasmid system, pRK248cI was lost gradually together with pMTC48 from the host under non-selective conditions. The selective pressure against pRK248cI stabilized the pMTC48. This indicates that the loss of pMTC48 under non-selective conditions was caused by the loss of cI857 gene (coded by pRK248cI) which resulted in the overproduction of the toxic gene product (coded by pMTC48). In the case of single plasmid (pTG206) system, the plasmid lost from the host under non-selective conditions. This plasmid was stabilized in the host growing under selective conditions. During this period we obtained some ampicillin resistant colonies which gave low levels of enzyme activities compared to the normal plasmid bearing cells. Plasmid analysis from the above cells showed that the plasmid has undergone structural instability. Further, restriction analysis of this plasmid exhibited an additional PvuII site in a 0.9 kbp fragment that was integrated near the tet promoter which controls the expression of the xyl E gene, thereby resulting low levels of enzyme activities. Our results indicate that some of the IS elements which are present in the host chromosome were responsible for such instabilities to turn off the synthesis by inserting into the tet promoter region to lower the protein formation during the bioprocess.

Mapping of insertion element IS5 in the Escherichia coli K-12 chromosome. Chromosomal rearrangements mediated by IS5

We identified phage clones containing insertion element IS5 in a set of 476 lambda phage clones carrying chromosomal segments that cover almost the entire chromosome of Escherichia coli K-12 W3110. Precise locations and orientations of IS5 were then determined by cleavage analysis of phage DNAs containing them. We mapped 23 copies of IS5 (named is5A to is5W) on the W3110 chromosome. Among them, ten were identified as the common elements present at the same locations in both chromosomes of W3110 and another E. coli K-12 strain, JE5519. While most of the mapped IS5 elements were scattered over the W3110 chromosome, four copies of IS5 (designated is5L, is5M, is5N and is5O) were in a region representing tandem duplication of a DNA segment flanked by two copies of IS5. Interestingly, one unit of this DNA segment as well as a portion of it was seen also in a tandem array in a different region where two copies of IS5 (designated is5P and is5Q) were present. In particular two pairs of the mapped IS5 elements may have been involved in inversion of the chromosomal segments in two of the E. coli K-12 derivatives.

Novel one-step cloning vector with a transposable element: application to the Myxococcus xanthus genome

A new strategy was developed for rapid cloning of genes with a transposon mutation library. We constructed a transposon designated TnV that was derived from Tn5 and consists of the gene coding for neomycin phosphotransferase II as well as the replication origin of an Escherichia coli plasmid, pSC101, flanked by Tn5 inverted repeats (IS50L and IS50R). TnV can transpose to many different sites of DNA in E. coli and Myxococcus xanthus and confers kanamycin resistance (Kmr) to the cells. From the Kmr cells, one-step cloning of a gene which is mutated as a result of TnV insertion can be achieved as follows. Chromosomal DNA isolated from TnV-mutagenized cells is digested with an appropriate restriction enzyme, ligated, and transformed into E. coli cells with selection for Kmr. The plasmids isolated contain TnV in the target gene. The plasmid DNA can then be used as a probe for characterization of the gene and screening of clones from a genomic library. We used this vector to clone DNA fragments containing genes involved in the development of M. xanthus.

Physical mapping of a 330 X 10(3)-base-pair region of the Myxococcus xanthus chromosome that is preferentially labeled during spore germination

Myxococcus xanthus was pulse-labeled with [3H]thymidine immediately after germination of dimethyl sulfoxide-induced spores. The restriction enzyme digests of the total chromosomal DNA from the pulse-labeled cells were analyzed by one-dimensional as well as two-dimensional agarose gel electrophoresis. Four PstI fragments preferentially labeled at a very early stage of germination were cloned into the unique PstI site of pBR322. By using these clones as probes, a restriction enzyme map was established covering approximately 6% of the total M. xanthus genome (330 X 10(3) base pairs). The distribution of the specific activities of the restriction fragments pulse-labeled after germination suggests a bidirectional mode of DNA replication from a fixed origin.

Mutations upstream of the ribosome-binding site affect translational efficiency

The DNA coding for the major outer membrane lipoprotein of Escherichia coli has been fused to the coding region of the beta-galactosidase gene to measure the effect of various mutations on the efficiency of translation initiation. The various mutants were made by either inserting or deleting a small number of nucleotides into or from a region just upstream of the ribosome-binding site. These small mutations dramatically affect translation initiation as measured by the production of beta-galactosidase. We postulate that these mutations affect translation initiation by altering the secondary structure of the messenger RNA. In one case, we predict that a stem and loop just upstream of the Shine-Dalgarno sequence sterically hinders the binding of the ribosome to the mRNA.

Escherichia coli K-12 F' plasmids carrying insertion sequences IS1 and IS5

A simple method is described for the detection of the insertion elements IS1 and IS5 in Escherichia coli F' plasmids. Several of these insertion elements are normal constituents of the E. coli chromosome and are located on chromosomal regions carried by the F' plasmids, while several others were probably acquired during the isolation or propagation of the F' plasmids. The F' plasmids carrying copies of IS1 or IS5 have been transferred into Salmonella (a host lacking chromosomal copies of IS1 and IS5) where individual copies can be examined for a variety of properties, including structural similarities and ability to transpose to new sites.

Mapping of chromosomal IS5 elements that mediate type II F-prime plasmid excision in Escherichia coli K-12

Three IS5 elements were mapped in overlapping chromosomal segments on a series of F-prime plasmids by restriction analysis and hybridization. IS5A was located clockwise of proA near 6 min, IS5B was located clockwise of purE near 12 min, and IS5C was tentatively located near 14 min on the Escherichia coli K-12 map. The physical structures of nine type II F-prime plasmids that contain chromosomal DNA from this region indicated that these plasmids were excised from the chromosome by recombination between pairs of IS5 elements.