Construction of an IS-Free Corynebacterium glutamicum ATCC 13 032 Chassis Strain and Random Mutagenesis Using the Endogenous ISCg1 Transposase

Mobile genetic elements (MGEs) contribute to instability of the host genome and plasmids. Previously, removal of the prophages in the industrial amino acid producer Corynebacterium glutamicum ATCC 13 032 resulted in strain MB001 which showed better survival under stress conditions and increased transformability. Still, eight families of Insertion Sequence (IS) elements with 27 potentially active members remain in MB001, two of which were demonstrated to be detrimental in biotechnological processes. In this study, systematical deletion of all complete IS elements in MB001 resulted in the MGE-free strain CR101. CR101 shows growth characteristics identical to the wildtype and the increased transformability of MB001. Due to its improved genome stability, we consider this strain to be an optimal host for basic research and biotechnology. As a “zero-background” host, it is also an ideal basis to study C. glutamicum IS elements. Re-sequencing of CR101 revealed that only five spontaneous point mutations had occurred during the construction process, highlighting the low mutation rate of C. glutamicum on the nucleotide level. In a second step, we developed an easily applicable ISCg1-based transposon mutagenesis system to randomly transpose a selectable marker. For optimal plasmid stability during cloning in Escherichia coli, the system utilizes a genetic switch based on the phage integrase Bxb1. Use of this integrase revealed the presence of a functional attB site in the C. glutamicum genome. To avoid cross-talk with our system and increase ease-of-use, we removed the attB site and also inserted the Bxb1 encoding gene into the chromosome of CR101. Successful insertion of single markers was verified by sequencing randomly selected mutants. Sequencing pooled mutant libraries revealed only a weak target site specificity, seemingly random distribution of insertion sites and no general strand bias. The resulting strain, ML103, together with plasmid pML10 provides a easily customizable system for random mutagenesis in an otherwise genomically stable C. glutamicum. Taken together, the MGE-free C. glutamicum strain CR101, the derivative ML103, and the plasmid pML10 provide a useful set of tools to study C. glutamicum in the future.

Plasmids as donors of Insertion Sequence elements mediating colistin resistance in Klebsiella pneumoniae

Colistin is a last resort antibiotic for the treatment of carbapenemase producing Klebsiella pneumoniae (CRKP) and other extensively drug resistant (XDR) gram-negative bacterial isolates. In line with rising colistin use worldwide, colistin resistant Klebsiella pneumoniae (K. pneumoniae) isolates have emerged. Insertion sequences (IS) integrating into the mgrB gene represents a significant mechanism mediating the emergence of colistin resistance in clinical settings. The disruption of mgrB by ISs has been widely reported worldwide. Evidence suggests plasmids encode mobilizable IS elements which preferentially integrate into the mgrB gene in K. pneumoniae causing gene inactivation and colistin resistance. Recognised IS elements targeting mgrB include ISL3 (ISKpn25), IS5 (ISKpn26), ISKpn14 and IS903B-like elements. K. pneumoniae represents the single largest species carrying plasmids encoding each IS element. The nucleotide reference sequence for ISKpn25, ISKpn26, ISKpn14 and IS903B were downloaded from IS finder. The BLATSn tool from NCBI was used to retrieve sequences producing significant alignment. For IS presence among species, 1000 BLASTn hits were downloaded and filtered for plasmids. Additionally, the top 120 BLASTn non-duplicate circularised plasmid contig hits for each IS element were typed for incompatibility (Inc) group and carbapenemase gene presence. Metadata pertaining to each sample was retrieved, including isolate source information to aid the understanding of the clinical threat posed by IS elements. IS903B was found in 28 unique Inc groups, while ISKpn25 was largely carried by IncFIB(pQil) plasmids. ISKpn26 and ISKpn14 were most often found associated with IncFII(pHN7A8) plasmids. Of the 34 unique countries which contained any of the IS elements, ISKpn25 was identified from 26. India, USA, and Italy were the isolation origin country for 16.6%, 13.3%, and 9.2%, respectively of the ISKpn25 insertions identified in plasmids. In contrast, ISKpn26, ISKpn14, and IS903B insertion sequences were identified from 89.3%, 44.9% and 23.9% plasmid samples from China. The stratification of carbapenemase genes presence and isolation source between ISKpn25, ISKpn26, ISKpn14 and IS903B bearing plasmids was markedly different. A significant difference between IS elements and the distribution of carbapenemase genes (χ2(3, N = 480) = 155.12, p = <.001) was detected. In addition, a significant difference between IS elements and source isolation distribution (χ2(3, N = 382) = 46.97, p = <.001) was also observed. Post hoc analysis revealed IS903B has a significantly different (p = <.001) carbapenemase and source isolation distribution relative to ISKpn26, ISKpn14 or ISKpn25. The odds ratio revealed plasmids carrying ISKpn25, ISKpn14, and ISKpn26 IS elements are 12.18, 27.0, and 44.43 times more likely to carry carbapenemase genes relative to plasmids carrying the IS element IS903B. Moreover, the odds ratio reveled ISKpn26, ISKpn25, and ISKpn14 were 6.10, 28.82, and 31.47 times more likely to be sourced from a clinical environmental setting than the environment relative to IS903B IS harboring plasmids. ISKpn25 present on IncFIB(pQil) sourced from clinical settings is established across multiple countries, while ISKpn26, ISKpn14, and IS903B appear most often in China. High carbapenemase presence in tandem with IS elements may help promote an extensively drug resistant profile in K. pneumoniae. IS element mobilisation into the mgrB gene has been linked to colistin treatment therapy, while carbapenemase gene presence has been associated with the epidemic success of K. pneumoniae in clinical settings. Plasmids which harbour both carbapenemases and IS elements may engender an extensively drug resistant phenotype during colistin therapy in hospitals.

digIS: towards detecting distant and putative novel insertion sequence elements in prokaryotic genomes

Background The insertion sequence elements (IS elements) represent the smallest and the most abundant mobile elements in prokaryotic genomes. It has been shown that they play a significant role in genome organization and evolution. To better understand their function in the host genome, it is desirable to have an effective detection and annotation tool. This need becomes even more crucial when considering rapid-growing genomic and metagenomic data. The existing tools for IS elements detection and annotation are usually based on comparing sequence similarity with a database of known IS families. Thus, they have limited ability to discover distant and putative novel IS elements. Results In this paper, we present digIS, a software tool based on profile hidden Markov models assembled from catalytic domains of transposases. It shows a very good performance in detecting known IS elements when tested on datasets with manually curated annotation. The main contribution of digIS is in its ability to detect distant and putative novel IS elements while maintaining a moderate level of false positives. In this category it outperforms existing tools, especially when tested on large datasets of archaeal and bacterial genomes. Conclusion We provide digIS, a software tool using a novel approach based on manually curated profile hidden Markov models, which is able to detect distant and putative novel IS elements. Although digIS can find known IS elements as well, we expect it to be used primarily by scientists interested in finding novel IS elements. The tool is available at https://github.com/janka2012/digIS.

Frequent Transposition of Multiple Insertion Sequences in Geobacillus kaustophilus HTA426

Geobacillus kaustophilus HTA426 is a thermophilic bacterium whose genome harbors numerous insertion sequences (IS). This study was initially conducted to generate mutant genes for thermostable T7 RNA polymerase in G. kaustophilus; however, relevant experiments unexpectedly identified that the organism transposed multiple IS elements and produced derivative cells that expressed a silent gene via transposition. The transposed elements were diverse and included members of the IS4, IS701, IS1634, and ISLre2 families. The transposition was relatively active at elevated temperatures and generated 4–9 bp of direct repeats at insertion sites. Transposition was more frequent in proliferative cells than in stationary cells but was comparable between both cells when sigX, which encodes an extra-cytoplasmic function sigma factor, was forcibly expressed. Southern blot analysis indicated that IS transposition occurred under growth inhibitory conditions by diverse stressors; however, IS transposition was not detected in cells that were cultured under growth non-inhibitory conditions. These observations suggest that G. kaustophilus enhances IS transposition via sigX-dependent stress responses when proliferative cells were prevented from active propagation. Considering Geobacillus spp. are highly adaptive bacteria that are remarkably distributed in diverse niches, it is possible that these organisms employ IS transposition for environmental adaptation via genetic diversification. Thus, this study provides new insights into adaptation strategies of Geobacillus spp. along with implications for strong codependence between mobile genetic elements and highly adaptive bacteria for stable persistence and evolutionary diversification, respectively. This is also the first report to reveal active IS elements at elevated temperatures in thermophiles and to suggest a sigma factor that governs IS transposition.

Insertion-sequence-mediated mutations both promote and constrain evolvability during a long-term experiment with bacteria

Insertion sequences (IS) are ubiquitous bacterial mobile genetic elements, and the mutations they cause can be deleterious, neutral, or beneficial. The long-term dynamics of IS elements and their effects on bacteria are poorly understood, including whether they are primarily genomic parasites or important drivers of adaptation by natural selection. Here, we investigate the dynamics of IS elements and their contribution to genomic evolution and fitness during a long-term experiment with Escherichia coli. IS elements account for ~35% of the mutations that reached high frequency through 50,000 generations in those populations that retained the ancestral point-mutation rate. In mutator populations, IS-mediated mutations are only half as frequent in absolute numbers. In one population, an exceptionally high ~8-fold increase in IS150 copy number is associated with the beneficial effects of early insertion mutations; however, this expansion later slowed down owing to reduced IS150 activity. This population also achieves the lowest fitness, suggesting that some avenues for further adaptation are precluded by the IS150-mediated mutations. More generally, across all populations, we find that higher IS activity becomes detrimental to adaptation over evolutionary time. Therefore, IS-mediated mutations can both promote and constrain evolvability.

Mobilization of antibiotic resistance genes differ by resistance mechanism

The degree to which antibiotic resistance genes (ARGs) are mobilized by insertion sequence (IS) elements, plasmids, and integrons has a strong association with their likelihood to function as resistance determinants. This stems from genetic decontextualization where strong promoters often present in IS elements and integrons and the copy number effect of plasmids contribute to high expression of accessory genes. Here, we screen all complete bacterial RefSeq genomes for ARGs. The genetic contexts of detected ARGs are investigated for IS elements, integrons, plasmids, and phylogenetic dispersion. The ARG-MOB scale is proposed which indicates how mobilized detected ARGs are in bacterial genomes. Antibiotic efflux genes are rarely mobilized and it is concluded that these are often housekeeping genes that are not decontextualized to confer resistance through overexpression. Even 80% of β-lactamases have never, or very rarely, been mobilized in the 15,790 studied genomes. However, some ARGs are indeed mobilized and co-occur with IS elements, plasmids, and integrons. These results have consequences for the design and interpretation of studies screening for resistance determinants, as mobilized ARGs pose a more concrete risk to human health, especially under heterologous expression, than groups of ARGs that have only been shown to confer resistance in cloning experiments.

Genomic characterization of IncpA1763-KPC: IncFIIK7 type plasmids p13294-KPC and pA1966-NR from Klebsiella pneumoniae

Aim: To characterize two plasmids p13294-KPC and pA1966-NR from clinical Klebsiella pneumoniae strains. Materials & methods: Plasmids p13294-KPC and pA1966-NR were fully sequenced and then detailed genomic analysis was performed in this work. The antimicrobial resistance phenotypes were determined. Results: p13294-KPC and pA1966-NR displayed IncpA1763-KPC:IncFIIK7 dual-replicon structures. The backbone of these two plasmids were closely related to each other. p13294-KPC contained two accessory modules, namely ΔIS Kpn25 and blaKPC-2 region, and the blaKPC-2 region carried a range of mobile elements and resistance gene blaKPC-2. while pA1966-NR contained four individual IS elements in its backbone and carried no resistance genes. Conclusion: This study provided a deeper insight into the genomic characterization of IncpA1763-KPC: IncFIIK7 type plasmids p13294-KPC and pA1966-NR.

Abundance of mobile genetic elements in an Acinetobacter lwoffii strain isolated from Transylvanian honey sample

Based on phylogenetic analyses, strain M2a isolated from honey, an unexpected source of acinetobacters, was classified as Acinetobacter lwoffii. The genome of this strain is strikingly crowded with mobile genetic elements. It harbours more than 250 IS elements of 15 IS-families, several unit and compound transposons and 15 different plasmids. These IS elements, including 30 newly identified ones, could be classified into at least 53 IS species. Regarding the plasmids, 13 of the 15 belong to the Rep-3 superfamily and only one plasmid, belonging to the “Low-GC” family, possesses a seemingly complete conjugative system. The other plasmids, with one exception, have a mobilization region of common pattern, consisting of the divergent mobA/mobL-family and mobS-, mobC- or traD-like genes separated by an oriT-like sequence. Although two plasmids of M2a are almost identical to those of A. lwoffi strains isolated from gold mine or Pleistocene sediments, most of them have no close relatives. The presence of numerous plasmid-borne and chromosomal metal resistance determinants suggests that M2a previously has also evolved in a metal-polluted environment. The numerous, possibly transferable, plasmids and the outstanding number of transposable elements may reflect the high potential of M2a for rapid evolution.