Tn5: A molecular window on transposition

DNA transposition is an underlying process involved in the remodeling of genomes in all types of organisms. We analyze the multiple steps in cut-and-paste transposition using the bacterial transposon Tn5 as a model. This system is particularly illuminating because of the existence of structural, genetic, and biochemical information regarding the two participating specific macromolecules: the transposase and the 19-bp sequences that define the ends of the transposon. However, most of the insights should be of general interest because of similarities to other transposition-like systems such as HIV-1 DNA integration into the host genome.     

Simple and efficient generation in vitro of nested deletions and inversions: Tn5 intramolecular transposition.

We have exploited the intramolecular transposition preference of the Tn 5 in vitro transposition system to test its effectiveness as a tool for generation of nested families of deletions and inversions. A synthetic transposon was constructed containing an ori, an ampicillin resistance (Ampr) gene, a multi-cloning site (MCS) and two hyperactive end sequences. The donor DNA that adjoins the transposon contains a kanamycin resistance (Kanr) gene. Any Amprreplicating plasmid that has undergone a transposition event (Kans) will be targeted primarily to any insert in the MCS. Two different size targets were tested in the in vitro system. Synthetic transposon plasmids containing either target were incubated in the presence of purified transposase (Tnp) protein and transformed. Transposition frequencies (Ampr/Kans) for both targets were found to be 30-50%, of which >95% occur within the target sequence, in an apparently random manner. By a conservative estimate 10(5) or more deletions/inversions within a given segment of DNA can be expected from a single one-step 20 microl transposition reaction. These nested deletions can be used for structure-function analysis of proteins and for sequence analysis. The inversions provide nested sequencing templates of the opposite strand from the deletions.     

Composite transposons Tn5 and Tn10 in Escherichia coli K12: precise excision and recombination

The number of exconjugants having the transposon Tn5 excised precisely during the crosses of the Escherichia coli proA::Tn5 donor with the recipients F- rec+ or F- recA441 (tif) was 20-30 times higher for the crosses involving the latter recipient. The high recombinogenic activity is characteristic of the tif recipient. Precise excision from a tandem duplication is more efficient than from nonduplicated region of the genome. It is four orders higher, if a transposon is localized in an arm of a duplication. The effect is recA-dependent. The presented data permit us to suggest the participation of RecA protein (its synaptic function) in the formation of the intermediate "stem-loop" structure. The latter is predicted by the three mechanisms of transposon excision: "slippage", "correctional" and "recombinational". The latter two mechanisms were formulated in the paper. The experimental proof of the postexcision transposition presented in the paper, is a good support to the version of "recombinational" excision.     

Single-stranded conjugation in Escherichia coli K-12: characteristics of the formation of a heterogenous progeny]

During a single-stranded conjugation donor DNA, being a single-stranded form, takes part in the process of recombination. That is why a heteroduplex DNA must be an intermediate product of the recombination. The heteroduplex can be partially corrected as it was supposed for genetic transformation. The division of such a corrected heteroduplex gives the heterogenous progeny of exoconjugants. And this "correctional" heterogeneity must possess two following properties: 1) the mixed progeny must consist of only two recombinational genotypes; 2) the heterogeneity must be marker-specific. The experimental support to both predictions was obtained by the method of clonal analysis of conjugational merozygotes.     

Phosphate coordination and movement of DNA in the Tn5 synaptic complex: role of the (R)YREK motif

Bacterial DNA transposition is an important model system for studying DNA recombination events such as HIV-1 DNA integration and RAG-1-mediated V(D)J recombination. This communication focuses on the role of protein-phosphate contacts in manipulating DNA structure as a requirement for transposition catalysis. In particular, the participation of the nontransferred strand (NTS) 5' phosphate in Tn5 transposition strand transfer is analyzed. The 5' phosphate plays no direct catalytic role, nonetheless its presence stimulates strand transfer approximately 30-fold. X-ray crystallography indicates that transposase-DNA complexes formed with NTS 5' phosphorylated DNA have two properties that contrast with structures formed with complexes lacking the 5' phosphate or complexes generated from in-crystal hairpin cleavage. Transposase residues R210, Y319 and R322 of the (R)YREK motif coordinate the 5' phosphate rather than the subterminal NTS phosphate, and the 5' NTS end is moved away from the 3' transferred strand end. Mutation R210A impairs the 5' phosphate stimulation. It is posited that DNA phosphate coordination by R210, Y319 and R322 results in movement of the 5' NTS DNA away from the 3'-end thus allowing efficient target DNA binding. It is likely that this role for the newly identified RYR triad is utilized by other transposase-related proteins.     

Evidence for Campbell's mechanism for fine excision of Tn9 type transposons in Escherichia coli K12]

The plasmid-transposon Tn9-322 was constructed by inverted transposition from the pBR322::Tn9 plasmid. The precise excision of the Tn9-322 transposon from the proB gene site can proceed by the Campbell's model. This fact was demonstrated by appearance of the plasmid-transposons after their precise excision. They contain two IS1 elements flanking a short direct repeat of the target DNA. The recombinational mechanism of precise excision of Tn9 type transposons seems not to be alternative but looks as an additional one to a well-known slippage mechanism proved for Tn5 and Tn10.     

Impact of methionine oxidation as an initial event on the pathway of human prion protein conversion

Prion diseases comprise a group of fatal neurodegenerative disorders characterized by the autocatalytic conversion of the cellular prion protein PrP^C into the infectious misfolded isoform PrP^Sc. Increasing evidence supports a specific role of oxidative stress in the onset of pathogenesis. Although the associated molecular mechanisms remain to be elucidated in detail, several studies currently suggest that methionine oxidation already detected in misfolded PrP^Sc destabilizes the native PrP fold as an early event in the conversion pathway. To obtain more insights about the specific impact of surface-exposed methionine residues on the oxidative-induced conversion of human PrP we designed, produced, and comparatively investigated two new pseudosulfoxidation mutants of human PrP 121–231 that comprises the well-folded C-terminal domain. Applying circular dichroism spectroscopy and dynamic light scattering techniques we showed that pseudosulfoxidation of all surface exposed Met residues formed a monomeric molten globule-like species with striking similarities to misfolding intermediates recently reported by other groups. However, individual pseudosulfoxidation at the polymorphic M129 site did not significantly contribute to the structural destabilization. Further metal-induced oxidation of the partly unfolded pseudosulfoxidation mutant resulted in the formation of an oligomeric state that shares a comparable size and stability with PrP oligomers detected after the application of different other triggers for structural conversion, indicating a generic misfolding pathway of PrP. The obtained results highlight the specific importance of methionine oxidation at surface exposed residues for PrP misfolding, strongly supporting the hypothesis that increased oxidative stress could be one causative event for sporadic prion diseases and other neurodegenerative disorders.     

DNA duplications detect the hidden transposition of the Tn5 element in the Escherichia coli K12 genome

The frequency of Tn5 transposition localized in an arm of a tandem duplication was estimated as 1.3 X 10(-2) per cell per generation, two orders of magnitude higher than usual one. Approximately thirty per cent of all transpositions usually registered occur from the spontaneous duplications. The effect revealing latent transpositions is in good accordance with a conservative transposition model permitting some interesting predictions: 1. Composite transposons can be a reason for the double stranded cuts in DNA. 2. The transposition frequency in cis for composite elements seems to be many times higher than in trans. 3. Partially transpositions in cis can be recA dependent. 4. The estimation of Tn5 transposition in cis presented in the paper is a minimal one.