Site-specific Recombination System Research Articles

In vivo recombination efficiency of two site-specific recombination systems, VCre/VloxP and SCre/SloxP, inmedaka (Oryzias latipes).

The present study delineates the invivo efficiency of two site-specific recombination systems, VCre/VloxP and SCre/SloxP, in medaka (Oryzias latipes). VCre, SCre, and Cre RNA was microinjected into fertilized medaka eggs belonging to three transgenic lines harboring VloxP, SloxP, and loxP cassette. VCre induced site-specific recombination specifically at VloxP sequence and SCre at SloxP sequence without any cross-reactivity. These findings provide two novel alternative recombination systems invivo in addition to the existing Cre/loxP and Flp/FRT systems, thus enabling sophisticated gene expression in model organisms.

Construction of an environmental safe Bacillus thuringiensis engineered strain against Coleoptera.

Cloning of new toxic genes from Bacillus thuringiensis (Bt) and construction of Bt engineered strains are two key strategies for bio-control of coleopteran pests in agriculture and forestry. In this study, we cloned a new cry3Aa-type gene, cry3Aa8, from wild Bt strain YC-03 against coleopteran, and constructed a Bt engineered strain, ACE-38, containing insecticidal protein-encoding gene cry3Aa8. The engineered strain, with almost four times of Cry3Aa yield compared with strain YC-03, was an antibiotic marker-free strain. Though no selective pressure was presented in the medium, cry3Aa8 in the engineered strain ACE-38 remained stable. The yield of Cry3Aa by strain ACE-38 reached 2.09mg/ml in the optimized fermentation medium. The activity of strain ACE-38 against Plagiodera versicolora was tested, and the LC50 of ACE-38 cultures in the optimized fermentation medium was 1.13μl/ml. Strain ACE-38 is a non-antibiotic Bt engineered strain with high Chrysomelidae toxicity and exhibits good fermentation property. The modified indigenous site-specific recombination system constructed in this study might be useful for the construction of Bt engineered strains containing genes that cannot be expressed in the indigenous site-specific recombination system using plasmid pBMB1205R.

Abstract B053: Designing chimeric antigen receptors for personalized immunotherapy: Rapid assembly of CARs from principal components using “EZ-CAR” platform

Abstract Clinical data demonstrates that one chimeric antigen receptor (CAR) design targeting T cells to a given tumor-associated antigen (TAA) will have varying therapeutic potential in different patients. For example, second generation CD19-specific CARs activated via chimeric CD28/CD3ζ or CD137/CD3ζ exhibit superior clinical responses when autologous genetically modified T cells are administered to patients with acute versus chronic B-lineage leukemias. Therefore, we investigated whether CAR species can be designed to improve the anti-tumor effect for a given tumor. This is particularly appealing as our clinical approach to gene therapy based on the electro-transfer of DNA plasmids from the Sleeping Beauty (SB) transposon system reduces the cost and complexity to manufacture individual CAR designs for small subsets of patients. Our approach to personalizing CAR+ T cells is based on the generation of a large number of CAR molecules that can be screened and assessed for their ability to benefit a given patient. We have developed an approach for high throughput assembly of CARs using triple site-specific recombination system termed “EZ-CAR platform”. This technology allows the rapid combination of 3 components of a prototypical CAR from (i) the single chain variable fragment (scFv) that defines specificity, (ii) the scaffold/hinge that appends the scFv from the cell surface, and (iii) one or more intracellular signaling domains. As proof-of-concept we generated a CD19-specific CAR using the EZ-CAR platform in parallel with CD19 CAR control CAR+ T cells (CG CAR). Both CD19 CAR sequences were inserted into Sleeping Beauty transposon vectors and electroporated into T cells. After electroporation the T cells were cultivated in presence of CD19+ Activating and Propagating Cells (AaPCs) for antigen specific expansion of the T cells. The expression of the CARs in the T cells surface was measured every week by flow cytometry (Fc+ expression), showing similar CAR expression in both groups. We also performed a Chromium Release Assay (CRA) to evaluate the killing function of CD19 CAR+ T cells generated by EZ-CAR platform against tumor cells. After 4 hours of incubation the percentage of specific cell lysis was 52% by the EZ- CAR T cells and 49% by the CG CAR T cells. These results showed that using this technology we were able to generate functional CAR+ T cells. Then we started a rapid production of CARs using a library of plasmids containing the three components of a CAR molecule: (i) anti-CD19 scFv (ii) 5 hinges with different sizes and (iii) different combinations of 7 signaling domains with the CD3ζ domain. The EZ-CAR platform is in a dynamic process where new CAR components are been added to our library. Transfection of HEK 293 cells with plasmid containing the CAR transgene were used to screen 30 different CAR constructs to ensure the expression of the CAR protein on the cell surface. The high throughput testing of individual CAR molecules has been undertaken using the iQue Screener (Intellicyt), a high throughput flow cytometer, where cytotoxic assays are performed using engineered target cells expressing a fluorescent granzyme B reporter. The release of IL-2, IFN-γ and TNF-α by the CAR+ T cells and the cytotoxic activity are concurrently evaluated. The CAR designs that result in superior killing will be further tested using tumor cells from patients. Citation Format: Ana Beatriz Korngold, Brian Rabinovich, Helen Huls, Laurence Cooper. Designing chimeric antigen receptors for personalized immunotherapy: Rapid assembly of CARs from principal components using “EZ-CAR” platform. [abstract]. In: Proceedings of the CRI-CIMT-EATI-AACR Inaugural International Cancer Immunotherapy Conference: Translating Science into Survival; September 16-19, 2015; New York, NY. Philadelphia (PA): AACR; Cancer Immunol Res 2016;4(1 Suppl):Abstract nr B053.

Gene stacking in plant cell using recombinases for gene integration and nucleases for marker gene deletion

BackgroundPractical approaches for multigene transformation and gene stacking are extremely important for engineering complex traits and adding new traits in transgenic crops. Trait deployment by gene stacking would greatly simplify downstream plant breeding and trait introgression into cultivars. Gene stacking into pre-determined genomic sites depends on mechanisms of targeted DNA integration and recycling of selectable marker genes. Targeted integrations into chromosomal breaks, created by nucleases, require large transformation efforts. Recombinases such as Cre-lox, on the other hand, efficiently drive site-specific integrations in plants. However, the reversibility of Cre-lox recombination, due to the incorporation of two cis-positioned lox sites, presents a major bottleneck in its application in gene stacking. Here, we describe a strategy of resolving this bottleneck through excision of one of the cis-positioned lox, embedded in the marker gene, by nuclease activity.MethodsAll transgenic lines were developed by particle bombardment of rice callus with plasmid constructs. Standard molecular approach was used for building the constructs. Transgene loci were analyzed by PCR, Southern hybridization, and DNA sequencing.ResultsWe developed a highly efficient gene stacking method by utilizing powerful recombinases such as Cre-lox and FLP-FRT, for site-specific gene integrations, and nucleases for marker gene excisions. We generated Cre-mediated site-specific integration locus in rice and showed excision of marker gene by I-SceI at ~20 % efficiency, seamlessly connecting genes in the locus. Next, we showed ZFN could be used for marker excision, and the locus can be targeted again by recombinases. Hence, we extended the power of recombinases to gene stacking application in plants. Finally, we show that heat-inducible I-SceI is also suitable for marker excision, and therefore could serve as an important tool in streamlining this gene stacking platform.ConclusionsA practical approach for gene stacking in plant cell was developed that allows targeted gene insertions through rounds of transformation, a method needed for introducing new traits into transgenic lines for their rapid deployment in the field. By using Cre-lox, a powerful site-specific recombination system, this method greatly improves gene stacking efficiency, and through the application of nucleases develops marker-free, seamless stack of genes at pre-determined chromosomal sites.

Characterization of the temperate phage vB_RleM_PPF1 and its site-specific integration into the Rhizobium leguminosarum F1 genome.

Bacteriophages may play an important role in regulating population size and diversity of the root nodule symbiont Rhizobium leguminosarum, as well as participating in horizontal gene transfer. Although phages that infect this species have been isolated in the past, our knowledge of their molecular biology, and especially of genome composition, is extremely limited, and this lack of information impacts on the ability to assess phage population dynamics and limits potential agricultural applications of rhizobiophages. To help address this deficit in available sequence and biological information, the complete genome sequence of the Myoviridae temperate phage PPF1 that infects R. leguminosarum biovar viciae strain F1 was determined. The genome is 54,506bp in length with an average G+C content of 61.9%. The genome contains 94 putative open reading frames (ORFs) and 74.5% of these predicted ORFs share homology at the protein level with previously reported sequences in the database. However, putative functions could only be assigned to 25.5% (24 ORFs) of the predicted genes. PPF1 was capable of efficiently lysogenizing its rhizobial host R. leguminosarum F1. The site-specific recombination system of the phage targets an integration site that lies within a putative tRNA-Pro (CGG) gene in R. leguminosarum F1. Upon integration, the phage is capable of restoring the disrupted tRNA gene, owing to the 50bp homologous sequence (att core region) it shares with its rhizobial host genome. Phage PPF1 is the first temperate phage infecting members of the genus Rhizobium for which a complete genome sequence, as well as other biological data such as the integration site, is available.

Conditional Gene Expression/Deletion Systems for Marchantia polymorpha Using its Own Heat-Shock Promoter and Cre/loxP-Mediated Site-Specific Recombination.

The liverwort Marchantia polymorpha is an emerging model plant suitable for addressing, using genetic approaches, various evolutionary questions in the land plant lineage. Haploid dominancy in its life cycle facilitates genetic analyses, but conversely limits the ability to isolate mutants of essential genes. To overcome this issue and to be employed in cell lineage, mosaic and cell autonomy analyses, we developed a system that allows conditional gene expression and deletion using a promoter of a heat-shock protein (HSP) gene and the Cre/loxP site-specific recombination system. Because the widely used promoter of the Arabidopsis HSP18.2 gene did not operate in M. polymorpha, we identified a promoter of an endogenous HSP gene, MpHSP17.8A1, which exhibited a highly inducible transient expression level upon heat shock with a low basal activity level. Reporter genes fused to this promoter were induced globally in thalli under whole-plant heat treatment and also locally using a laser-assisted targeted heating technique. By expressing Cre fused to the glucocorticoid receptor under the control of the MpHSP17.8A1 promoter, a low background, sufficiently inducible control for loxP-mediated recombination could be achieved in M. polymorpha. Based on these findings, we developed a Gateway technology-based binary vector for the conditional induction of gene deletions.

Application of the Cre/loxP Site-Specific Recombination System for Gene Transformation in Aurantiochytrium limacinum.

The Cre/loxP site-specific recombination system was applied to Aurantiochytrium limacinum to obtain a transformant without the antibiotic resistance marker gene. First, the enhanced green fluorescent protein gene (egfp) and chloramphenicol resistance gene (Cmr), along with the two loxP loci, were integrated into the genome of A. limacinum OUC88 using 18S rDNA sequences as the homologous recombination sites. Then plasmid pSH65, containing a zeocin resistance gene (Bler) was transferred into A. limacinum OUC_CG. After induction with galactose, repeated passage in culture and PCR-based assessment, the pSH65 plasmid was lost and A. limacinum OUC_EG host was shown to no longer have resistance to 100 mg chloramphenicol/L or 5 mg zeocin/L. Through southern blotting and fluorescence detection, egfp was found to be integrated into the genome of A. limacinum OUC_EG, and EGFP was successfully expressed in the cells. The successful application of the Cre/loxP system demonstrates an experimental basis for genetic modification of A. limacinum so as to obtain transformed strains with no antibiotic resistance marker genes.

Yeast recombination-based cloning as an efficient way of constructing vectors for Zymoseptoria tritici

Many pathogenic fungi are genetically tractable. Analysis of their cellular organization and invasion mechanisms underpinning virulence determinants profits from exploiting such molecular tools as fluorescent fusion proteins or conditional mutant protein alleles. Generation of these tools requires efficient cloning methods, as vector construction is often a rate-limiting step. Here, we introduce an efficient yeast recombination-based cloning (YRBC) method to construct vectors for the fungus Zymoseptoria tritici. This method is of low cost and avoids dependency on the availability of restriction enzyme sites in the DNA sequence, as needed in more conventional restriction/ligation-based cloning procedures. Furthermore, YRBC avoids modification of the DNA of interest, indeed this potential risk limits the use of site-specific recombination systems, such as Gateway cloning. Instead, in YRBC, multiple DNA fragments, with 30bp overlap sequences, are transformed into Saccharomyces cerevisiae, whereupon homologous recombination generates the vector in a single step. Here, we provide a detailed experimental protocol and four vectors, each encoding a different dominant selectable marker cassette, that enable YRBC of constructs to be used in the wheat pathogen Z. tritici.

IncI shufflons: Assembly issues in the next-generation sequencing era

The shufflon is a site-specific recombination system first identified in the IncI1 plasmid R64. The R64 shufflon consists of four segments, separated by short repeats, which are rearranged and inverted by the recombinase protein Rci, generating diversity in the C-terminal end of the PilV protein. PilV is the tip adhesin of the thin pilus structure involved in bacterial conjugation and may play a role in determining recipient cell specificity during liquid mating. The variable arrangements of the shufflon region would be expected to make plasmid assembly difficult, particularly with short-read sequencing technology, but this is not usually mentioned in recent publications reporting IncI plasmid sequences. Here we discuss the issues we encountered with assembly of IncI1 sequence data obtained from the Roche-454 and Illumina platforms and make some suggestions for assembly of the shufflon region. Comparison of shufflon segments from a collection of IncI1 plasmids from The Netherlands and Australia, together with sequences available in GenBank, suggests that the number of shufflon segments present is conserved among plasmids grouped together by plasmid multi-locus sequencing typing but the different reported arrangements of shufflon segments may not be meaningful. This analysis also indicated that the sequences of the shufflon segments are highly conserved, with very few nucleotide changes.

Global dissemination patterns of common gene cassette arrays in class 1 integrons.

Integrons are genetic elements that contain a site-specific recombination system able to capture, express and exchange gene cassettes. Mobile integrons are widespread and often confer resistance to multiple antibiotics, due to the expression of the arrays of gene cassettes they carry. Although >300 cassette arrays have been described, < 10 array compositions prevail in the reports related to class 1 integrons. These common arrays are found in a broad variety of hosts and environments, highlighting the high level of horizontal dissemination of these elements amongst bacterial populations and species. Clonal expansion also contributes to the current prevalence and inter-regional spread of integron-carrying bacterial species. Here, we review the dissemination pattern of common cassette arrays with a focus on the bacterial species, the geographical dispersal pattern and the environments in which they reside. Conserved arrays of gene cassettes are found in at least 74 countries and 72 species present in different environments. The factors governing the further spread and population dynamics of these cassette arrays remain to be determined.

An efficient strategy for producing a stable, replaceable, highly efficient transgene expression system in silkworm, Bombyx mori.

We developed an efficient strategy that combines a method for the post-integration elimination of all transposon sequences, a site-specific recombination system, and an optimized fibroin H-chain expression system to produce a stable, replaceable, highly efficient transgene expression system in the silkworm (Bombyx mori) that overcomes the disadvantages of random insertion and post-integration instability of transposons. Here, we generated four different transgenic silkworm strains, and of one the transgenic strains, designated TS1-RgG2, with up to 16% (w/w) of the target protein in the cocoons, was selected. The subsequent elimination of all the transposon sequences from TS1-RgG2 was completed by the heat-shock-induced expression of the transposase in vivo. The resulting transgenic silkworm strain was designated TS3-g2 and contained only the attP-flanked optimized fibroin H-chain expression cassette in its genome. A phiC31/att-system-based recombinase-mediated cassette exchange (RMCE) method could be used to integrate other genes of interest into the same genome locus between the attP sites in TS3-g2. Controlling for position effects with phiC31-mediated RMCE will also allow the optimization of exogenous protein expression and fine gene function analyses in the silkworm. The strategy developed here is also applicable to other lepidopteran insects, to improve the ecological safety of transgenic strains in biocontrol programs.

Genome engineering and direct cloning of antibiotic gene clusters via phage ϕBT1 integrase-mediated site-specific recombination in Streptomyces.

Several strategies have been used to clone large DNA fragments directly from bacterial genome. Most of these approaches are based on different site-specific recombination systems consisting of a specialized recombinase and its target sites. In this study, a novel strategy based on phage ϕBT1 integrase-mediated site-specific recombination was developed, and used for simultaneous Streptomyces genome engineering and cloning of antibiotic gene clusters. This method has been proved successful for the cloning of actinorhodin gene cluster from Streptomyces coelicolor M145, napsamycin gene cluster and daptomycin gene cluster from Streptomyces roseosporus NRRL 15998 at a frequency higher than 80%. Furthermore, the system could be used to increase the titer of antibiotics as we demonstrated with actinorhodin and daptomycin, and it will be broadly applicable in many Streptomyces.

Reversibility of the Snail-induced epithelial–mesenchymal transition revealed by the Cre–loxP system

The epithelial–mesenchymal transition (EMT), a key process in the tumor metastatic cascade, is characterized by the loss of cell–cell junctions and cell polarity, as well as the acquisition of migratory and invasive properties. Snail is an EMT-inducer whose expression in several different epithelial cells, e.g., Madin–Darby canine kidney (MDCK), leads to EMT. To further understand EMT induced by Snail expression, the Cre–loxP site-specific recombination system was used to investigate its reversibility. Transfection of MDCK cells with loxP-flanked Snail (Snail-loxP) resulted in EMT induction, which included the acquisition of a spindle-shaped fibroblastic morphology, the downregulation of epithelial markers, and the upregulation of mesenchymal markers. DNA methylation of the E-cadherin promoter, which often occurs during E-cadherin downregulation, was not observed in Snail+ cells. After Cre-mediated excision of Snail-loxP, the cells reacquired an epithelial morphology, upregulated epithelial markers, and downregulated mesenchymal markers. Thus, EMT induced by Snail expression was reversible.

The expression profile of Arabidopsis thaliana β-1,3-glucanase promoter in tobacco

Well characterized promoters with specific activity only during male gametophyte development of transgenic organism are widely utilized in strategies aimed at the elimination of unwanted transgene escape from the transgenic to the non-transgenic plant population. Since the specificity and timing of the applied promoter in the original and transgenic organism don't have to be consistent, here we have tested by promoter-GUS fusion analysis the APRS promoter isolated from Arabidopsis thaliana in transgenic tobacco plants. Unlike of A. thaliana transcriptomic microarray data that identified gene expression from this promoter in late stages of pollen development, in tobacco plants the APRS promoter was active in the developing microspores during a short period of time before the microspores are released from the tetrads. Despite these discrepancies, the APRS promoter remains strictly pollen specific in tobacco plants. However, verification of its specificity in other important crops should precede the use of the APRS promoter in the engineered male sterility or in production of transgene-free pollen via site-specific recombination systems.

Engineered Minichromosomes in Plants: Structure, Function, and Applications.

Engineered minichromosomes are small chromosomes that contain a transgene and selectable marker, as well as all of the necessary components required for maintenance in an organism separately from the standard chromosome set. The separation from endogenous chromosomes makes engineered minichromosomes useful in the production of transgenic plants. Introducing transgenes to minichromosomes does not have the risk of insertion within a native gene; additionally, transgenes on minichromosomes can be transferred between lines without the movement of linked genes. Of the two methods proposed for creating engineered minichromosomes, telomere-mediated truncation is more reliable in plant systems. Additionally, many plants contain a supernumerary, or B chromosome, which is an excellent starting material for minichromosome creation. The use of site-specific recombination systems in minichromosomes can increase their utility, allowing for the addition or subtraction of transgenes in vivo. The creation of minichromosomes with binary bacterial artificial chromosome vectors provides the ability to introduce many transgenes at one time. Furthermore, coupling minichromosomes with haploid induction systems can facilitate transfer between lines. Minichromosomes can be introduced to a haploid-inducing line and crossed to target lines. Haploids of the target line that then contain a minichromosome can then be doubled. These homozygous lines will contain the transgene without the need for repeated introgressions.

Conditional removal of selectable markers in Trypanosoma cruzi using a site-specific recombination tool: Proof of concept

The scarcity of molecular tools for genetic manipulation is a critical obstacle for functional genomics studies on Trypanosoma cruzi. The current study adapted an inducible site-specific recombination system based on Dimerizable CRE recombinase (DiCRE). Two vectors for stable transfection were created, a first one to express inactive portions of DiCRE recombinase, and a second plasmid containing the loxP sites to test DiCRE activity. After integrating both constructs into the T. cruzi genome, it was shown that DiCRE recombinase can be efficiently used to manipulate its genome by allowing the removal of selectable markers thus generating homogeneous populations. The DiCRE recombinase success allows conditional knockout and the removal of selectable markers without prior parasite modification, which also facilitate the transferring of DiCRE recombinase to different T. cruzi strains.

Antibiotic resistance correlates with transmission in plasmid evolution.

Conjugative (horizontally transmissible) plasmids are autonomous replicators, whose "self-interests" do not necessarily overlap with those of their hosts. This situation causes plasmids and bacteria to sometimes experience differing selection pressures. Escherichia coli plasmid pB15 contains genes for resistance to several antibiotics, including tetracycline. When plasmid-bearing cells were experimentally evolved in the laboratory, changes in resistance level in the unselected tetracycline marker coincided with changes in plasmid rates of vertical versus horizontal transmission. Here, we used minimum inhibitory assays that measure resistance levels as quantitative traits to determine phenotypic correlations among plasmid characters and to estimate divergence among plasmid lineages. Results suggested that plasmid-level evolution led to formation of two phenotypically dissimilar groups: virulent (highly infectious) and avirulent (weakly infectious) plasmids. In contrast, measures of carbon-source utilization, and fitness assays relative to a common competitor revealed that bacterial hosts generally converged in phenotypic performance, despite divergence among their associated plasmids. Preliminary sequence analyses suggested that divergence in plasmid conjugation was due to altered configurations of a shufflon region (a site-specific recombination system), where genetic rearrangements affect conjugative ability. Furthermore, we proposed that correlated resistance and transmission in pB15 derivatives were caused by a tetracycline-resistance transposon inserted into a transfer operon, allowing transcription from its promoter to simultaneously affect both plasmid resistance and transmission.

The partitioning and copy number control systems of the selfish yeast plasmid: an optimized molecular design for stable persistence in host cells.

The multi-copy 2 micron plasmid of Saccharomyces cerevisiae, a resident of the nucleus, is remarkable for its high chromosome-like stability. The plasmid does not appear to contribute to the fitness of the host, nor does it impose a significant metabolic burden on the host at its steady state copy number. The plasmid may be viewed as a highly optimized selfish DNA element whose genome design is devoted entirely towards efficient replication, equal segregation and copy number maintenance. A partitioning system comprised of two plasmid coded proteins, Rep1 and Rep2, and a partitioning locus STB is responsible for equal or nearly equal segregation of plasmid molecules to mother and daughter cells. Current evidence supports a model in which the Rep-STB system promotes the physical association of the plasmid with chromosomes and thus plasmid segregation by a hitchhiking mechanism. The Flp site-specific recombination system housed by the plasmid plays a critical role in maintaining steady state plasmid copy number. A decrease in plasmid population due to rare missegregation events is rectified by plasmid amplification via a recombination induced rolling circle replication mechanism. Appropriate plasmid amplification, without runaway increase in copy number, is ensured by positive and negative regulation of FLP gene expression by plasmid coded proteins and by the control of Flp level/activity through host mediated post-translational modification(s) of Flp. The Flp system has been successfully utilized to understand mechanisms of site-specific recombination, to bring about directed genetic alterations for addressing fundamental problems in biology, and as a tool in biotechnological applications.

Single-copy vectors for integration at the SaPI1 attachment site for Staphylococcus aureus

We have previously reported the construction of Staphylococcus aureus integration vectors based on the staphylococcal pathogenicity island 1 (SaPI1) site-specific recombination system. These are shuttle vectors that can be propagated in Escherichia coli, which allows for standard DNA manipulations. In S. aureus, these vectors are temperature-sensitive and can only be maintained at non-permissive (42 °C) temperatures by integrating into the chromosome. However, most S. aureus strains are sensitive to prolonged incubations at higher temperatures and will rapidly accumulate mutations, making the use of temperature-sensitive integration vectors impractical for single-copy applications. Here we describe improved versions of these vectors, which are maintained only in single-copy at the SaPI1 attachment site. In addition, we introduce several additional cassettes containing resistance markers, expanding the versatility of integrant selection, especially in strains that are resistant to multiple antibiotics.

Mobility and generation of mosaic non-autonomous transposons by Tn3-derived inverted-repeat miniature elements (TIMEs).

Functional transposable elements (TEs) of several Pseudomonas spp. strains isolated from black shale ore of Lubin mine and from post-flotation tailings of Zelazny Most in Poland, were identified using a positive selection trap plasmid strategy. This approach led to the capture and characterization of (i) 13 insertion sequences from 5 IS families (IS3, IS5, ISL3, IS30 and IS1380), (ii) isoforms of two Tn3-family transposons – Tn5563a and Tn4662a (the latter contains a toxin-antitoxin system), as well as (iii) non-autonomous TEs of diverse structure, ranging in size from 262 to 3892 bp. The non-autonomous elements transposed into AT-rich DNA regions and generated 5- or 6-bp sequence duplications at the target site of transposition. Although these TEs lack a transposase gene, they contain homologous 38-bp-long terminal inverted repeat sequences (IRs), highly conserved in Tn5563a and many other Tn3-family transposons. The simplest elements of this type, designated TIMEs (Tn3 family-derived Inverted-repeat Miniature Elements) (262 bp), were identified within two natural plasmids (pZM1P1 and pLM8P2) of Pseudomonas spp. It was demonstrated that TIMEs are able to mobilize segments of plasmid DNA for transposition, which results in the generation of more complex non-autonomous elements, resembling IS-driven composite transposons in structure. Such transposon-like elements may contain different functional genetic modules in their core regions, including plasmid replication systems. Another non-autonomous element “captured” with a trap plasmid was a TIME derivative containing a predicted resolvase gene and a res site typical for many Tn3-family transposons. The identification of a portable site-specific recombination system is another intriguing example confirming the important role of non-autonomous TEs of the TIME family in shuffling genetic information in bacterial genomes. Transposition of such mosaic elements may have a significant impact on diversity and evolution, not only of transposons and plasmids, but also of other types of mobile genetic elements.