Cyclic changes in the affinity of protein-DNA interactions drive the progression and regulate the outcome of the Tn10 transposition reaction

Transposons Tn 10 and Tn 5

The study of the bacterial transposons Tn 10 and Tn 5 has provided a wealth of information regarding steps in nonreplicative DNA transposition, transpososome dynamics and structure, as well as mechanisms employed to regulate transposition. The focus of ongoing research on these transposons is mainly on host regulation and the use of the Tn 10 antisense system as a platform to develop riboregulators for applications in synthetic biology. Over the past decade two new regulators of both Tn 10 and Tn 5 transposition have been identified, namely H-NS and Hfq proteins. These are both global regulators of gene expression in enteric bacteria with functions linked to stress-response pathways and virulence and potentially could link the Tn 10 and Tn 5 systems (and thus the transfer of antibiotic resistance genes) to environmental cues. Work summarized here is consistent with the H-NS protein working directly on transposition complexes to upregulate both Tn 10 and Tn 5 transposition. In contrast, evidence is discussed that is consistent with Hfq working at the level of transposase expression to downregulate both systems. With regard to Tn 10 and synthetic biology, some recent work that incorporates the Tn 10 antisense RNA into both transcriptional and translational riboswitches is summarized.

Bacterial stationary-state mutagenesis and Mammalian tumorigenesis as stress-induced cellular adaptations and the role of epigenetics

Mechanisms of cellular adaptation may have some commonalities across different organisms. Revealing these common mechanisms may provide insight in the organismal level of adaptation and suggest solutions to important problems related to the adaptation. An increased rate of mutations, referred as the mutator phenotype, and beneficial nature of these mutations are common features of the bacterial stationary-state mutagenesis and of the tumorigenic transformations in mammalian cells. We argue that these commonalities of mammalian and bacterial cells result from their stress-induced adaptation that may be described in terms of a common model. Specifically, in both organisms the mutator phenotype is activated in a subpopulation of proliferating stressed cells as a strategy to survival. This strategy is an alternative to other survival strategies, such as senescence and programmed cell death, which are also activated in the stressed cells by different subpopulations. Sustained stress-related proliferative signalling and epigenetic mechanisms play a decisive role in the choice of the mutator phenotype survival strategy in the cells. They reprogram cellular functions by epigenetic silencing of cell-cycle inhibitors, DNA repair, programmed cell death, and by activation of repetitive DNA elements. This reprogramming leads to the mutator phenotype that is implemented by error-prone cell divisions with the involvement of Y family polymerases. Studies supporting the proposed model of stress-induced cellular adaptation are discussed. Cellular mechanisms involved in the bacterial stress-induced adaptation are considered in more detail.

H-NS mediates the dissociation of a refractory protein-DNA complex during Tn10/IS10 transposition

Tn10/IS10 transposition takes place in the context of a protein–DNA complex called a transpososome. During the reaction, the transpososome undergoes several conformational changes. The host proteins IHF and H-NS, which also are global regulators of gene expression, play important roles in directing these architectural changes. IHF binds tightly to only one of two transposon ends within the transpososome, folding this end into a DNA loop structure. Unfolding this DNA loop is necessary for excising the transposon from flanking donor DNA and preventing integration of the transposon into itself. We show here that efficient DNA loop unfolding relies on the continuity of the flanking donor DNA on the side of the transpososome opposite to the folded transposon end. We also show this same donor DNA is a preferred binding site for H-NS, which promotes opening of the IHF-loop, which is required for productive target interactions. This is counter to the usual mode of H-NS action, which is repressive due to its propensity to coat DNA. The interplay between IHF and H-NS likely serves to couple the rate of transposition to the host cell physiology as both of these proteins are integrated into cellular stress response pathways.

A simple topological filter in a eukaryotic transposon as a mechanism to suppress genome instability

DNA transposition takes place within a higher-order complex known as the transpososome. Almost everything known about its assembly has been gleaned from bacterial transposons. Here we present a detailed analysis of transpososome assembly in the human Hsmar1 element. The transpososome is nominally symmetrical, consisting of two identical transposon ends and a dimer of transposase. However, after the transposase dimer has captured the first transposon end, an asymmetry is introduced, raising a barrier against recruitment of the second end. The barrier can be overcome by right-handed plectonemic intertwining of the transposon ends. This likely occurs mainly during transcription and episodes of nucleosome remodeling. Plectonemic intertwining favors only synapsis of closely linked transposon ends in the inverted-repeat configuration and therefore suppresses the promiscuous synapsis of distant transposon ends, which initiate McClintock's chromosomal breakage-fusion-bridge cycles in maize. We also show that synapsis of the transposon ends is a prerequisite for the first catalytic step. This provides constraints on the enzymatic mechanism of the double-strand breaks in mariner transposition, excluding the most prevalent of the current models.

Delivering the goods: viral and non-viral gene therapy systems and the inherent limits on cargo DNA and internal sequences

Viruses have long been considered to be the most promising tools for human gene therapy. However, the initial enthusiasm for the use of viruses has been tarnished in the light of potentially fatal side effects. Transposons have a long history of use with bacteria in the laboratory and are now routinely applied to eukaryotic model organisms. Transposons show promise for applications in human genetic modification and should prove a useful addition to the gene therapy tool kit. Here we review the use of viruses and the limitations of current approaches to gene therapy, followed by a more detailed analysis of transposon length and the physical properties of internal sequences, which both affect transposition efficiency. As transposon length increases, transposition decreases: this phenomenon is known as length-dependence, and has implications for vector cargo capacity. Disruption of internal sequences, either via deletion of native DNA or insertion of exogenous DNA, may reduce or enhance genetic mobility. These effects may be related to host factor binding, essential spacer requirements or other influences yet to be elucidated. Length-dependence is a complex phenomenon driven not simply by the distance between the transposon ends, but by host proteins, the transposase and the properties of the DNA sequences encoded within the transposon.

Base flipping in V(D)J recombination: insights into the mechanism of hairpin formation, the 12/23 rule, and the coordination of double-strand breaks

Tn5 transposase cleaves the transposon end using a hairpin intermediate on the transposon end. This involves a flipped base that is stacked against a tryptophan residue in the protein. However, many other members of the cut-and-paste transposase family, including the RAG1 protein, produce a hairpin on the flanking DNA. We have investigated the reversed polarity of the reaction for RAG recombination. Although the RAG proteins appear to employ a base-flipping mechanism using aromatic residues, the putatively flipped base is not at the expected location and does not appear to stack against any of the said aromatic residues. We propose an alternative model in which a flipped base is accommodated in a nonspecific pocket or cleft within the recombinase. This is consistent with the location of the flipped base at position -1 in the coding flank, which can be occupied by purine or pyrimidine bases that would be difficult to stabilize using a single, highly specific, interaction. Finally, during this work we noticed that the putative base-flipping events on either side of the 12/23 recombination signal sequence paired complex are coupled to the nicking steps and serve to coordinate the double-strand breaks on either side of the complex.

Base flipping in tn10 transposition: an active flip and capture mechanism

The bacterial Tn5 and Tn10 transposases have a single active site that cuts both strands of DNA at their respective transposon ends. This is achieved using a hairpin intermediate that requires the DNA to change conformation during the reaction. In Tn5 these changes are controlled in part by a flipped nucleoside that is stacked on a tryptophan residue in a hydrophobic pocket of the transposase. Here we have investigated the base flipping mechanism in Tn10 transposition. As in Tn5 transposition, we find that base flipping takes place after the first nick and is required for efficient hairpin formation and resolution. Experiments with an abasic substrate show that the role of base flipping in hairpin formation is to remove the base from the DNA helix. Specific interactions between the flipped base and the stacking tryptophan residue are required for hairpin resolution later in the reaction. We show that base flipping in Tn10 transposition is not a passive reaction in which a spontaneously flipped base is captured and retained by the protein. Rather, it is driven in part by a methionine probe residue that helps to force the flipped base from the base stack. Overall, it appears that base flipping in Tn10 transposition is similar to that in Tn5 transposition.

The global regulator H-NS binds to two distinct classes of sites within the Tn10 transpososome to promote transposition

The histone-like nucleoid structuring protein (H-NS) is a global transcriptional regulator that influences stress response and virulence pathways in Gram-negative bacteria. H-NS also promotes Tn10 transposition by binding directly to the transpososome and inducing a conformational change in the transpososome that favours intermolecular transposition events. H-NS binds preferentially to curved DNA and can bend non-curved DNA, it self-oligomerizes and can interact with other proteins. To determine what functions of H-NS are important in promoting Tn10 transposition, we have examined the ability of two mutant forms of H-NS, P116S and 1-64, to act in Tn10 transposition. We provide evidence that the initial interaction of H-NS with the transpososome is dependent on H-NS binding to a specific structure in DNA flanking the transposon end. Additional molecules of H-NS then bind within the transposon end. This latter event appears to be directed by H-NS binding to the Tn10 transposase protein, and is important in maintaining the transpososome in a conformation that promotes intermolecular transposition. The binding of H-NS to a transposase protein is a novel function for this important regulatory molecule.

Functional coupling between the two active sites during Tn 10 transposition buffers the mutation of sequences critical for DNA hairpin processing

DNA processing reactions often involve multiple components acting in concert to achieve the desired outcome. However, it is usually difficult to know how the components communicate and cooperate to orchestrate an ordered series of events. We address this question in the context of the Tn 10 transposition reaction, in which the DNA cleavage and joining events occur within a higher-order complex containing a transposase dimer, two transposon ends and the DNA-bending host-factor IHF (Integration Host Factor). Previously it was shown that the complex is asymmetric. The a side consists of an IHF protomer initially immobilized by a DNA-loop, but subsequently used to promote conformational changes required for the cleavage steps. The beta side of the complex was considered to fulfil a more passive role. Here we show that the a side of the complex promotes coupled conformational changes at both transposon ends, while the a and beta sides communicate and cooperate to dominate different phases of the transposition reaction. Together, these effects provide for a robust response to critical changes in the transposon end. These findings also explain the intriguing genetic phenotypes of a series of previously reported Tn10 mutants and have consequences for the evolution of new elements.

Base-flipping dynamics in a DNA hairpin processing reaction

Many enzymes that repair or modify bases in double-stranded DNA gain access to their substrates by base flipping. Although crystal structures provide stunning snap shots, biochemical approaches addressing the dynamics have proven difficult, particularly in complicated multi-step reactions. Here, we use protein-DNA crosslinking and potassium permanganate reactivity to explore the base-flipping step in Tn5 transposition. We present a model to suggest that base flipping is driven by a combination of factors including DNA bending and the intrusion of a probe residue. The forces are postulated to act early in the reaction to create a state of tension, relieved by base flipping after cleavage of the first strand of DNA at the transposon end. Elimination of the probe residue retards the kinetics of nicking and reduces base flipping by 50%. Unexpectedly, the probe residue is even more important during the hairpin resolution step. Overall, base flipping is pivotal to the hairpin processing reaction because it performs two opposite but closely related functions. On one hand it disrupts the double helix, providing the necessary strand separation and steric freedom. While on the other, transposase appears to position the second DNA strand in the active site for cleavage using the flipped base as a handle.

Transpososome dynamics and regulation in Tn10 transposition

Tn10 is a bacterial transposon that transposes through a non-replicative mechanism. This mode of DNA transposition is widely used in bacteria and is also used by "DNA-based" transposons in eukaryotes. Tn10 has served as a paradigm for this mode of transposition and continues to provide novel insights into how steps in transposition reactions occur and how these steps are regulated. A common feature of transposition reactions is that they require the formation of a higher order protein-DNA complex called a transpososome. A major objective in the last few years has been to better understand the dynamics of transpososome assembly and progression through the course of transposition reactions. This problem is particularly interesting in the Tn10 system because two important host proteins, IHF and H-NS, have been implicated in regulating transpososome assembly and/or function. Interestingly, H-NS is an integral part of stress response pathways in bacteria, and its function is known to be sensitive to changes in environmental conditions. Consequently, H-NS may provide a means of allowing Tn10 to responed to changing environmental conditions. The current review focuses on the roles of both IHF and H-NS on Tn10 transposition.

Mutation of Tn5 transposase beta-loop residues affects all steps of Tn5 transposition: the role of conformational changes in Tn5 transposition

X-ray cocrystal structures of Tn5 transposase (Tnp) bound to its 19 base pair (bp) recognition end sequence (ES) reveal contacts between a beta-loop (amino acids 240-260) and positions 3, 4, 5, and 6 of the ES. Here, we show that mutations of residues in this loop affect both in vivo and in vitro transposition. Most mutations are detrimental, whereas some mutations at position 242 cause hyperactivity. More specifically, mutations to the beta-loop affect every individual step of transposition tested. Mutants performing in vivo and in vitro transposition less efficiently also form fewer synaptic complexes, whereas hyperactive Tnps form more synaptic complexes. Surprisingly, two hypoactive mutations, K244R and R253L, also affect the cleavage steps of transposition with a much more dramatic effect on the second double end break (DEB) complex formation step, indicating that the beta-loop likely plays an important roll in positioning the substrate DNA within the catalytic site. Finally, all mutants tested decrease efficiency of the final transposition step, strand transfer. A disparity in cleavage rate constants in vitro for mutants with changes to the proline at position 242 on transposons flanked by ESs differing in the orientation of the A-T base pair at position 4 allows us to postulate that P242 contacts the position 4 nucleotide pair. On the basis of these data, we propose a sequential model for end cleavage in Tn5 transposition in which the uncleaved PEC is not symmetrical, and conformational changes are necessary between the first and second cleavage events and also for the final strand transfer step of transposition.

Selection of surfactants for cell lysis in chemical cytometry to study protein-DNA interactions

Protein-DNA interactions play a defining role in many cellular processes. Studying such interactions at the single-cell level is important and challenging. Here we make the first step toward achieving this goal with chemical cytometry. Chemical cytometry utilizes capillary separation for detailed chemical analyses of single cells. The cell is injected into a capillary, lysed, and its components are analyzed by CE or capillary chromatography with highly sensitive detection. In order to apply chemical cytometry to studies of protein-DNA interactions, cell lysis must not destroy protein-DNA complexes. Surfactants represent the most practical means of cell lysis inside the capillary. This work aimed at finding surfactants and lysis conditions that do not destroy protein-DNA complexes. We studied three groups of surfactants--ionic, zwitterionic, and nonionic--with respect to their ability to lyse the cell membrane without significantly influencing the stability of protein-DNA complexes. Nonequilibrium CE of equilibrium mixtures with surfactants in the equilibrium mixtures and in the run buffer was used to measure the equilibrium constant, K(d), and rate constant, k(off), of protein-DNA complex dissociation. We found that nonionic surfactants worked best: they lyse the plasma membrane without significantly influencing K(d), k(off), or the EOF. This work creates the foundation for studies of protein-DNA interactions in single cells by chemical cytometry.

DNA bending in the Sin recombination synapse: functional replacement of HU by IHF

The serine recombinase Sin requires a non-specific DNA-bending protein such as Hbsu for activity at its recombination site resH. Hbsu, and Sin subunits bound at site II of resH, together regulate recombination, ensuring selectivity for directly repeated resH sites by specifying assembly of an intertwined synapse. To investigate the role of the DNA-bending protein in defining the architecture of the synapse, we constructed a chimaeric recombination site (resF) which allows Hbsu to be substituted by IHF, binding specifically between site I (the crossover site) and site II. Two Sin dimers and one IHF dimer can bind together to the closely adjoining sites in resF, forming folded complexes. The precise position of the IHF site within the site I-site II spacer determines the conformation of these complexes, and also the reactivity of the resF sites in recombination assays. The data suggest that a sharp bend with a specific geometry is required in the spacer DNA, to bring the Sin dimers at sites I and II together in the correct relative orientation for synapse assembly and regulation, consistent with our model for a highly condensed synapse in which Hbsu/IHF has a purely architectural function.

The global regulator H-NS acts directly on the transpososome to promote Tn10 transposition

The histone-like nucleoid structuring (H-NS) protein is a global transcriptional regulator that is known to regulate stress response pathways and virulence genes in bacteria. It has also been implicated in the regulation of bacterial transposition systems, including Tn10. We demonstrate here that H-NS promotes Tn10 transposition by binding directly to the transposition complex (or transpososome). We present evidence that, upon binding, H-NS induces the unfolding of the Tn10 transpososome and helps to maintain the transpososome in an unfolded state. This ensures that intermolecular (as opposed to self-destructive intramolecular) transposition events are favored. We present evidence that H-NS binding to the flanking donor DNA of the transpososome is the initiating event in the unfolding process. We propose that by recruiting H-NS as a modulator of transposition, Tn10 has evolved a means of sensing changes in host physiology, as the amount of H-NS in the cell, as well its activity, are responsive to changes in environmental conditions. Sensing of environmental changes through H-NS would allow transposition to occur when it is most opportune for both the transposon and the host.

The transpososome: control of transposition at the level of catalysis

Studies of several transposable genetic elements have pinpointed the importance of the transpososome, a nucleoprotein complex involving the transposon ends and a transposon-encoded enzyme--the transposase--as a key in regulating transposition. Transpososomes provide a precise architecture within which the chemical reactions involved in transposon displacement occur. Data are accumulating that suggest they are dynamic and undergo staged conformational changes to accommodate different steps in the transposition pathway. This has been underpinned by recent results obtained particularly with Tn5, Tn10 and bacteriophage Mu.