Escherichia coli DNA Topoisomerase I and Suppression of Killing by Tn5 Transposase Overproduction: Topoisomerase I Modulates Tn5 Transposition

Tn5 transposase (Tnp) overproduction is lethal to Escherichia coli. The overproduction causes cell filamentation and abnormal chromosome segregation. Here we present three lines of evidence strongly suggesting that Tnp overproduction killing is due to titration of topoisomerase I. First, a suppressor mutation of transposase overproduction killing, stkD10, is localized in topA (the gene for topoisomerase I). The stkD10 mutant has the following characteristics: first, it has an increased abundance of topoisomerase I protein, the topoisomerase I is defective for the DNA relaxation activity, and DNA gyrase activity is reduced; second, the suppressor phenotype of a second mutation localized in rpoH, stkA14 (H. Yigit and W. S. Reznikoff, J. Bacteriol. 179:1704–1713, 1997), can be explained by an increase in topA expression; and third, overexpression of wild-type topA partially suppresses the killing. Finally, topoisomerase I was found to enhance Tn5 transposition up to 30-fold in vivo.     

Tn5 Transposase with an Altered Specificity for Transposon Ends

Tn5 is a composite bacterial transposon that encodes a protein, transposase (Tnp), required for movement of the transposon. The initial step in the transposition pathway involves specific binding of Tnp to 19-bp end recognition sequences. Tn5 contains two different specific end sequences, termed outside end (OE) and inside end (IE). In Escherichia coli, IE is methylated by Dam methylase (IE(ME)). This methylation greatly inhibits recognition by Tnp and greatly reduces the ability of transposase to facilitate movement of IE defined transposons. Through use of a combinatorial random mutagenesis technique (DNA shuffling), we have isolated an IE(ME)-specific hyperactive form of Tnp, Tnp sC7v.2.0, that is able to promote high levels of transposition of IE(ME) defined transposons in vivo and in vitro while functioning at wild-type levels with OE transposons. This protein contains a critical glutamate-to-valine mutation at amino acid 58 that is responsible for this change in end specificity.     

Characterization of the Tn5 transposase and inhibitor proteins: a model for the inhibition of transposition.

Tn5 is a composite transposon consisting of two IS50 sequences in inverted orientation with respect to a unique, central region encoding several antibiotic resistances. The IS50R element encodes two proteins in the same reading frame which regulate the transposition reaction: the transposase (Tnp), which is required for transposition, and an inhibitor of transposition (Inh). The inhibitor is a naturally occurring deletion variant of Tnp which lacks the N-terminal 55 amino acids. In this report, we present the purification of both the Tnp and Inh proteins and an analysis of their DNA binding properties. Purified Tnp, but not Inh, was found to bind specifically to the outside end of Tn5. Inh, however, stimulated the binding activity of Tnp to outside-end DNA and was shown to be present with Tnp in these bound complexes. Inh was also found to exist as a dimer in solution. These results indicate that the N-terminal 55 amino acids of Tnp are required for sequence-specific binding. They also suggest that Inh inhibits transposition by forming mixed oligomers with Tnp which still bind to the ends of the transposon but are defective for later stages of the transposition reaction.     

Characterization of two hypertransposing Tn5 mutants.

Transposition of Tn5 in Escherichia coli is regulated by two transposon-encoded proteins: transposase (Tnp), promoting transposition preferentially in cis, and the trans-acting inhibitor (Inh). Two separate transposase mutants were isolated that replace glutamate with lysine at position 110 (EK110) and at position 345 (EK345). The EK transposase proteins increase the Tn5 transposition frequency 6- to 16-fold in cis and enhance the ability of transposase to act in trans. The purified mutant transposase proteins interact with transposon outside end DNA differently from the wild-type protein, resulting in the formation of a novel complex in gel retardation assays. During characterization of the transposase proteins in the absence of inhibitor, we found that wild-type transposase itself has a transposition-inhibiting function and that this inhibition is reduced for the mutant proteins. We present a model for the regulation of Tn5 transposition, which proposes the existence of two transposase species, one cis-activating and the other trans-inhibiting. The phenotype of the EK transposase mutants can be explained by a shift in the ratio of these two species.     

DNA sequence bias during Tn5 transposition

Transposition is one of the primary mechanisms causing genome instability. This phenomenon is mechanistically related to other DNA rearrangements such as V(D)J recombination and retroviral DNA integration. In the Tn5 system, only one protein, the transposase (Tnp), is required for all of the catalytic steps involved in transposon movement. The complexity involved in moving multiple DNA strands within one active site suggests that, in addition to the specific contacts maintained between Tnp and its recognition sequence, Tnp also interacts with the flanking DNA sequence. Here, we demonstrate that Tnp interacts with the donor DNA region. Tnp protects the donor DNA from DNase I digestion, suggesting that Tnp is in contact with, or otherwise distorts, the donor DNA during synapsis. In addition, changes in the donor DNA sequence within this region alter the affinity of Tnp for DNA by eightfold during synapsis. In vitro selection for more stable synaptic complexes reveals an A/T sequence bias for this region. We further show that certain donor DNA sequences, which favor synapsis, also appear to serve as hot spots for strand transfer. The TTATA donor sequence represents the best site. Most surprising is the fact that this sequence is found within the Tnp recognition sequence. Preference for insertion into a site within the Tnp recognition sequence would effectively inactivate one copy of the element and form clusters of the Tn5 transposon. In addition, the fact that several donor DNA sequences, which favor synapsis, appear to serve as hot spots for transposon insertion suggest that similar criteria may exist for Tnp-donor DNA and Tnp-target DNA interactions.     

The phosphoCTD-interacting domain of Topoisomerase I

The N-terminal domain (NTD) of Drosophila melanogaster (Dm) Topoisomerase I has been shown to bind to RNA polymerase II, but the domain of RNAPII with which it interacts is not known. Using bacterially-expressed fusion proteins carrying all or half of the NTDs of Dm and human (Homo sapiens, Hs) Topo I, we demonstrate that the N-terminal half of each NTD binds directly to the hyperphosphorylated C-terminal repeat domain (phosphoCTD) of the largest RNAPII subunit, Rpb1. Thus, the amino terminal segment of metazoan Topo I (1-157 for Dm and 1-114 for Hs) contains a novel phosphoCTD-interacting domain that we designate the Topo I-Rpb1 interacting (TRI) domain. The long-known in vivo association of Topo I with active genes presumably can be attributed, wholly or in part, to the TRI domain-mediated binding of Topo I to the phosphoCTD of transcribing RNAPII.     

Tn5 transposase active site mutants

Tn5 transposase (Tnp) is a 53.3-kDa protein that is encoded by and facilitates movement of transposon Tn5. Tnp monomers contain a single active site that is responsible for catalyzing a series of four DNA breaking/joining reactions at one transposon end. Based on primary sequence homology and protein structural information, we designed and constructed a series of plasmids that encode for Tnps containing active site mutations. Following Tnp expression and purification, the active site mutants were tested for their ability to form protein-DNA complexes and perform each of the four catalytic steps in the transposition pathway in vitro. The results demonstrate that Asp-97, Asp-188, and Glu-326, visible in the active site of Tn5 crystal structures, are absolutely required for all catalytic steps. Mutations within a series of amino acid residues that are conserved in the IS4 family of transposases and retroviral integrases also impair Tnp catalytic activity. Mutations at either Tyr-319 or Arg-322 reduce both hairpin resolution and strand transfer activity within protein-DNA complexes. Mutations at Lys-333 reduce the ability of Tnps to form protein-DNA complexes, whereas mutations at the less strongly conserved Lys-330 have less of an effect on both synaptic complex formation and catalytic activity.     

A high-throughput assay for Tn5 Tnp-induced DNA cleavage

Transposition causes genomic instability by mobilizing DNA elements. This phenomenon is mechanistically related to other DNA rearrangements, such as V(D)J recombination and retroviral DNA integration. A conserved active site architecture within the transposase/integrase superfamily catalyzes these distinct phenomena. The Tn5 transposase (Tnp) falls within this protein class, and many intermediates of the Tn5 transposition reaction have been characterized. Here, we describe a method for the rapid identification of Tn5 Tnp small molecule effectors. This high-throughput screening strategy will aid in the identification of compounds that perturb Tnp-induced DNA cleavage. This method is advantageous, since it identifies effectors that specifically inhibit catalysis without inhibiting Tnp-DNA binding interactions. Effectors identified using this method will serve as a valuable aid both in the isolation and characterization of metal-bound reaction intermediates and in co-crystallization studies involving the effector, Tnp and DNA, to identify the structural basis of the interaction. Furthermore, since Tn5 Tnp shares a similar active site architecture to other transposase/integrase superfamily members, this strategy and any effectors identified using this method will be readily applicable to these other systems.     

Overexpression of the Tn5 transposase in Escherichia coli results in filamentation, aberrant nucleoid segregation, and cell death: analysis of E. coli and transposase suppressor mutations.

Overexpression of the Tn5 transposase (Tnp) was found to be lethal to Escherichia coli. This killing was not caused by transposition or dependent on the transpositional or DNA binding competence of Tnp. Instead, it was strictly correlated with the presence of a wild-type N terminus. Deletions removing just two N-terminal amino acids of Tnp resulted in partial suppression of this effect, and deletions of Tnp removing 3 or 11 N-terminal amino acids abolished the killing effect. This cytotoxic effect of Tnp overexpression is accompanied by extensive filament formation (i.e., a defect in cell division) and aberrant nucleoid segregation. Four E. coli mutants were isolated which allow survival upon Tnp overexpression, and the mutations are located at four discrete loci. These suppressor mutations map near essential genes involved in cell division and DNA segregation. One of these mutations maps to a 4.5-kb HindIII region containing the ftsYEX (cell division) locus at 76 min. A simple proposition which accounts for all of these observations is that Tnp interacts with an essential E. coli factor affecting cell division and/or chromosome segregation and that overexpression of Tnp titrates this factor below a level required for viability of the cell. Furthermore, the N terminus of Tnp is necessary for this interaction. The possible significance of this phenomenon for the transposition process is discussed.     

Purification and biochemical analyses of a monomeric form of Tn5 transposase.

The binding of transposase (Tnp) to the specific Tn5 end sequences is the first dedicated reaction during transposition. In this study, comparative DNA-binding analyses were performed using purified full-length Tnp and a C-terminal deletion variant (delta369) that lacks the putative dimerization domain. The shape of the binding curve of full-length Tnp is sigmoidal in contrast to the hyperbolic-shaped binding curve of delta369. This observation is consistent with previous observations as well as a rate of binding study presented here, which suggest that the full-length Tnp-end interaction, unlike that of the truncated protein, is a complex time-dependent reaction possibly involving a subunit exchange. Circular permutation assay results indicate that both proteins are capable of distorting the Tn5end sequences upon binding. Molecular weight determinations based on the migratory patterns of complexed DNA in polyacrylamide gels has shown that delta369 specifically binds the Tn5 end sequences as a monomer while full-length Tnp in complex represents a heterodimer.     

Mutational analysis of the base flipping event found in Tn5 transposition.

This work identifies novel structure-function relationships between Tn5 transposase (Tnp) and its DNA recognition sequence. The Tn5 Tnp-DNA co-crystal structure revealed the protein-DNA contacts of the post-cleavage complex (Davies, D. R., Goryshin, I. Y., Reznikoff, W. S., and Rayment, I. (2000) Science 289, 77-85). One of the most striking features of this complex is the rotation of thymine 2 (T2) away from the DNA helix and into a pocket within the Tnp. This interaction appears similar to the "base flipping" phenomenon found in many DNA repair enzymes such as T4 endonuclease V and uracil DNA glycosylase (Roberts, R. J., and Cheng, X. (1998) Annu. Rev. Biochem. 67, 181-198). To study the biochemical significance of this phenomenon, we mutated the Tnp residues proposed to be involved in stabilizing this interaction and removed the T2 nucleotide to examine which steps in the transposition reaction require T2-Tnp interactions. From this work, we have determined that stacking interactions between T2 and Tnp are critical for efficient transposition in vitro. In addition, our results suggested that T2-Tnp interactions facilitate hairpin formation and hairpin resolution primarily through base stacking and that T2 plays a role in the alignment of the transposon DNA for strand transfer.     

Examination of the Tn5 transposase overproduction phenotype in Escherichia coli and localization of a suppressor of transposase overproduction killing that is an allele of rpoH.

Tn5 transposase (Tnp) overproduction is lethal to Escherichia coli. Tnp overproduction causes cell filamentation, abnormal chromosome segregation, and an increase in anucleated cell formation. There are two simple explanations for the observed phenotype: induction of the SOS response or of the heat shock response. The data presented here show that overproduction of Tnp neither induces an SOS response nor a strong heat shock response. However, our experiments do indicate that induction of some sigma32-programmed function(s) (either due to an rpoH mutation, a deletion of dnaK, or overproduction of sigma32) suppresses Tnp overproduction killing. This effect is not due to overproduction of DnaK, DnaJ, or GroELS. In addition, Tnp but not deltall Tnp (whose overproduction does not kill the host cells) associates with the inner cell membrane, suggesting a possible correlation between cell killing and Tnp membrane association. These observations will be discussed in the context of a model proposing that Tnp overproduction titrates an essential host factor(s) involved in an early cell division step and/or chromosome segregation.     

Membrane association of the Tnp and Inh proteins of IS50R.

Using a radioimmunoassay for the IS50R proteins Tnp and Inh, we found that both proteins were present primarily in the cytoplasm, but 3 to 11% of Tnp and 3 to 5% of Inh were found in association with the inner membrane. The fractions of total Tnp and Inh that became membrane bound were unaffected by the amount of Tnp and Inh synthesized in whole cells, provided that the ratio of total Tnp to total Inh was not changed. In addition, Inh was not found in the membrane fraction in Tnp- IS50R mutants, indicating that Tnp is required for Inh localization.     

Generation of Tn5 insertions in streptococcal conjugative transposon Tn916

A method has been developed for the introduction of Tn5 into Escherichia coli plasmid chimeras containing Streptococcus faecalis DNA. Tn5 could be introduced via a lambda::Tn5 delivery vehicle. The system proved to be particularly efficient and facilitated insertions at numerous sites on DNA containing the 16-kilobase conjugative transposon Tn916. It was possible to introduce some of the resulting Tn916::Tn5 derivatives back into S. faecalis by using a recently developed protoplast transformation procedure. A presumed zygotic induction resulted in insertion of the Tn916 derivatives at multiple sites in the S. faecalis chromosome.     

Transposition of the Tn5 and Tn10 elements and duplications in Escherichia coli K12 genome

The kinetics of accumulation of resident transposon copies in a dividing population has been defined using a special experimental system. Analysis of the kinetics made it possible to estimate the probability of transposition for Tn5 as 2.5 X 10(-4) and for Tn10 as 2.3 X 10(-6) per cell per generation. Transposition of the composite elements does not depend on RecBC or RecF pathways of recombination. The fraction of the bacterial population with tandem duplications in the proA region of the genome is permanent for Escherichia coli. It is independent of the recombination pathways (RecBC of RecF) and the integrity of DNA polymerase I.     

Generation of Tn5 insertions in streptococcal conjugative transposon Tn916.

A method has been developed for the introduction of Tn5 into Escherichia coli plasmid chimeras containing Streptococcus faecalis DNA. Tn5 could be introduced via a lambda::Tn5 delivery vehicle. The system proved to be particularly efficient and facilitated insertions at numerous sites on DNA containing the 16-kilobase conjugative transposon Tn916. It was possible to introduce some of the resulting Tn916::Tn5 derivatives back into S. faecalis by using a recently developed protoplast transformation procedure. A presumed zygotic induction resulted in insertion of the Tn916 derivatives at multiple sites in the S. faecalis chromosome.     

The inverted repeats of Tn5 are functionally different

The inverted repeats of Tn5, which have identical restriction endonuclease cleavage patterns, have different functional properties. They differ with respect to RNA polymerase binding, full promotion of neomycin resistance, the polypeptides coded for by the repeats and their function in the transposition process. There is a week RNA polymerase binding site present in one repeat and not in the other which seems to be important for neomycin resistance. The two inverted repeats code for polypeptides of different molecular weights, with each repeat appearing to encode two polypeptides. The polypeptides from only one of the repeats of Tn5 appear to be absolutely required for Tn5 transposition.     

Polarity of Tn5 insertion mutations in Escherichia coli.

We assessed the effect of insertions of the kanamycin resistance transposon Tn5 in the lac operon of Escherichia coli on the expression of distal genes lacY and lacA (melibiose fermentation at 41 degrees C and thiogalactoside transacetylase synthesis, respectively). Every insertion mutation tested (41 in lacZ and 23 in lacY) was strongly polar. However, approximately one-third of the insertion mutants expressed distal genes at low levels due to a promoter associated with Tn5. To localize this promoter, we (i) reversed the orientation of Tn5 at several sites and (ii) replaced wild-type Tn5 with several substitution derivatives which lack Tn5's central region. Neither alteration changed the expression of distal genes. Thus, in contrast to transposons IS2 and TnA. Tn5's ability to turn on distal gene expression is not due to a promoter in its central region and therefore is not dependent on the overall orientation of Tn5 in the operon. Our results suggest that the promoter is within 186 base pairs of the ends of Tn5. It is possible that the promoter is detected in only a fraction of insertions because it overlaps Tn5-target sequence boundary.