Linker insertion mutagenesis based on IS21 transposition: isolation of an AMP-insensitive variant of catabolic ornithine carbamoyltransferase from Pseudomonas aeruginosa

inPOSE: A Flexible Toolbox for Chromosomal Cloning and Amplification of Bacterial Transgenes

Cloning the genes and operons encoding heterologous functions in bacterial hosts is now almost exclusively carried out using plasmid vectors. This has multiple drawbacks, including the need for constant selection and variation in copy numbers. The chromosomal integration of transgenes has always offered a viable alternative; however, to date, it has been of limited use due to its tedious nature and often being limited to a single copy. We introduce here a strategy that uses bacterial insertion sequences, which are the simplest autonomous transposable elements to insert and amplify genetic cargo into a bacterial chromosome. Transgene insertion can take place either as transposition or homologous recombination, and copy number amplification is achieved using controlled copy-paste transposition. We display the successful use of IS1 and IS3 for this purpose in Escherichia coli cells using various selection markers. We demonstrate the insertion of selectable genes, an unselectable gene and a five-gene operon in up to two copies in a single step. We continue with the amplification of the inserted cassette to double-digit copy numbers within two rounds of transposase induction and selection. Finally, we analyze the stability of the cloned genetic constructs in the lack of selection and find it to be superior to all investigated plasmid-based systems. Due to the ubiquitous nature of transposable elements, we believe that with proper design, this strategy can be adapted to numerous other bacterial species.

Construction of random transposition mutagenesis system in Rhodococcuserythropolis using IS1415

Recent studies on the metabolic activities of genus Rhodococcus have shown rhodococci to be of important use in industrial, pharmaceutical and environmental biotechnology. The increasing economic significance of Rhodococcus encourages renewed efforts to characterize their genetic systems, as Rhodococcus genetics are still poorly understood. The goal of this study is to adapt a transposon system for use in creating random mutagenesis in Rhodococcus erythropolis. A plasmid carrying IS1415, a member of IS21 family identified from Rerythropolis, has been constructed and designated as pTNR. pTNR is a non-replicating transposon tool introduced into target cells by electroporation. During its transposition, the transposable-marker gene is separated from the open reading frames (istAB) of IS1415, which should avoid secondary transposition. Transposition of pTNR into wild-type R. erythropolis created mutagenesis with a high efficiency of 1.23x10(6)mutants per microgram plasmid DNA. However, it could also be transposed into other Rhodococcus spp. at lower frequencies in comparison with that of R. erythropolis. It has been indicated by Southern hybridization that the generated kanamycin-resistant mutants were resulted from single transposition event of pTNR. The results also revealed that the transposable-marker gene of pTNR was randomly inserted into the chromosomal DNA of R. erythropolis. The affected DNA regions carrying the transposed DNA element could be conveniently recovered for further characterization using a plasmid rescue procedure. Sequence data of the insertion sites of 40 random mutants analyzed indicated that transposition of pTNR generated 6-bp direct target duplications in 36 cases, while in the remaining four mutants; it generated 5- or 7-bp target duplications (two cases each). This study concluded that pTNR could be served as an efficient genetic tool for construction of random mutagenesis system in Rhodococcus species.

Transposon-based strategies for microbial functional genomics and proteomics

Transposons are mobile genetic elements that can relocate from one genomic location to another. As well as modulating gene expression and contributing to genome plasticity and evolution, transposons are remarkably diverse molecular tools for both whole-genome and single-gene studies in bacteria, yeast, and other microorganisms. Efficient but simple in vitro transposition reactions now allow the mutational analysis of previously recalcitrant microorganisms. Transposon-based signature-tagged mutagenesis and genetic footprinting strategies have pinpointed essential genes and genes that are crucial for the infectivity of a variety of human and other pathogens. Individual proteins and protein complexes can be dissected by transposon-mediated scanning linker mutagenesis. These and other transposon-based approaches have reaffirmed the usefulness of these elements as simple yet highly effective mutagens for both functional genomic and proteomic studies of microorganisms.

Probing the α-complementing domain of E. coli β-galactosidase with use of an insertional pentapeptide mutagenesis strategy based on Mu in vitro DNA transposition

Protein structure-function relationships can be studied by using linker insertion mutagenesis, which efficiently identifies essential regions in target proteins. Bacteriophage Mu in vitro DNA transposition was used to generate an extensive library of pentapeptide insertion mutants within the alpha-complementing domain 1 of Escherichia coli beta-galactosidase, yielding mutants at 100% efficiency. Each mutant contained an accurate 15-bp insertion that translated to five additional amino acids within the protein, and the insertions were distributed essentially randomly along the target sequence. Individual mutants (alpha-donors) were analyzed for their ability to restore (by alpha-complementation) beta-galactosidase activity of the M15 deletion mutant (alpha-acceptor), and the data were correlated to the structure of the beta-galactosidase tetramer. Most of the insertions were well tolerated, including many of those disrupting secondary structural elements even within the protein's interior. Nevertheless, certain sites were sensitive to mutations, indicating both known and previously unknown regions of functional importance. Inhibitory insertions within the N-terminus and loop regions most likely influenced protein tetramerization via direct local effects on protein-protein interactions. Within the domain 1 core, the insertions probably caused either lateral shifting of the polypeptide chain toward the protein's exterior or produced more pronounced structural distortions. Six percent of the mutant proteins exhibited temperature sensitivity, in general suggesting the method's usefulness for generation of conditional phenotypes. The method should be applicable to any cloned protein-encoding gene.

Structure-function studies of Escherichia coli RpoH (sigma32) by in vitro linker insertion mutagenesis

The sigma factor RpoH (sigma(32)) is the key regulator of the heat shock response in Escherichia coli. Many structural and functional properties of the sigma factor are poorly understood. To gain further insight into RpoH regions that are either important or dispensable for its cellular activity, we generated a collection of tetrapeptide insertion variants by a recently established in vitro linker insertion mutagenesis technique. Thirty-one distinct insertions were obtained, and their sigma factor activity was analyzed by using a groE-lacZ reporter fusion in an rpoH-negative background. Our study provides a map of permissive sites which tolerate linker insertions and of functionally important regions at which a linker insertion impairs sigma factor activity. Selected linker insertion mutants will be discussed in the light of known sigma factor properties and in relation to a modeled structure of an RpoH fragment containing region 2.

Pentapeptide scanning mutagenesis: encouraging old proteins to execute unusual tricks

Pentapeptide scanning mutagenesis is a facile transposon-based procedure for the random insertion of a variable five amino acid cassette into a target protein. The analysis of a library of proteins harbouring pentapeptide insertions can provide invaluable information on the essential and inessential regions of a target protein, as well as revealing surprising aspects of target protein function and activity.