Division of labor among monomers within the Mu transposase tetramer

An efficient and accurate integration of mini-Mu transposons in vitro: a general methodology for functional genetic analysis and molecular biology applications

Transposons are mobile genetic elements and have been utilized as essential tools in genetics over the years. Though highly useful, many of the current transposon-based applications suffer from various limitations, the most notable of which are: (i) transposition is performed in vivo, typically species specifically, and as a multistep process; (ii) accuracy and/or efficiency of the in vivo or in vitro transposition reaction is not optimal; (iii) a limited set of target sites is used. We describe here a genetic analysis methodology that is based on bacteriophage Mu DNA transposition and circumvents such limitations. The Mu transposon tool is composed of only a few components and utilizes a highly efficient and accurate in vitro DNA transposition reaction with a low stringency of target preference. The utility of the Mu system in functional genetic analysis is demonstrated using restriction analysis and genetic footprinting strategies. The Mu methodology is readily applicable in a variety of current and emerging transposon-based techniques and is expected to generate novel approaches to functional analysis of genes, genomes and proteins.

Supercoiling-dependent site-specific binding of HU to naked Mu DNA

Using HU chemical nucleases to probe HU-DNA interactions, we report here for the first time site-specific binding of HU to naked DNA. An unique feature of this interaction is the absolute requirement for negative DNA supercoiling for detectable levels of site-specific DNA binding. The HU binding site is the Mu spacer between the L1 and L2 transposase binding sites. Our results suggest recognition of an altered DNA structure which is induced by DNA supercoiling. We propose that recruitment of HU to this naked DNA site induces the DNA bending required for productive synapsis and transpososome assembly. Implications of HU as a supercoiling sensor with a potential in vivo regulatory role are discussed. Finally, using HU nucleases we have also shown that non-specific DNA binding by HU is stimulated by increasing levels of supercoiling.

The three-dimensional structure of a Tn5 transposase-related protein determined to 2.9-A resolution

Transposon Tn5 employs a unique means of self-regulation by expressing a truncated version of the transposase enzyme that acts as an inhibitor. The inhibitor protein differs from the full-length transposase only by the absence of the first 55 N-terminal amino acid residues. It contains the catalytic active site of transposase and a C-terminal domain involved in protein-protein interactions. The three-dimensional structure of Tn5 inhibitor determined to 2.9-A resolution is reported here. A portion of the protein fold of the catalytic core domain is similar to the folds of human immunodeficiency virus-1 integrase, avian sarcoma virus integrase, and bacteriophage Mu transposase. The Tn5 inhibitor contains an insertion that extends the beta-sheet of the catalytic core from 5 to 9 strands. All three of the conserved residues that make up the "DDE" motif of the active site are visible in the structure. An arginine residue that is strictly conserved among the IS4 family of bacterial transposases is present at the center of the active site, suggesting a catalytic motif of "DDRE." A novel C-terminal domain forms a dimer interface across a crystallographic 2-fold axis. Although this dimer represents the structure of the inhibited complex, it provides insight into the structure of the synaptic complex.

An Efficient DNA Sequencing Strategy Based on the Bacteriophage Mu in Vitro DNA Transposition Reaction

A highly efficient DNA sequencing strategy was developed on the basis of the bacteriophage Mu in vitro DNA transposition reaction. In the reaction, an artificial transposon with a chloramphenicol acetyltransferase (cat) gene as a selectable marker integrated into the target plasmid DNA containing a 10.3-kb mouse genomic insert to be sequenced. Bacterial clones carrying plasmids with the transposon insertions in different positions were produced by transforming transposition reaction products into Escherichia coli cells that were then selected on appropriate selection plates. Plasmids from individual clones were isolated and used as templates for DNA sequencing, each with two primers specific for the transposon sequence but reading the sequence into opposite directions, thus creating a minicontig. By combining the information from overlapping minicontigs, the sequence of the entire 10,288-bp region of mouse genome including six exons of mouse Kcc2 gene was obtained. The results indicated that the described methodology is extremely well suited for DNA sequencing projects in which considerable sequence information is on demand. In addition, massive DNA sequencing projects, including those of full genomes, are expected to benefit substantially from the Mu strategy.

[The sequence data reported in this paper have been submitted to the GenBank data library under accession no. AJ011033.]

Mutational analysis of the Mu transposase. Contributions of two distinct regions of domain II to recombination

Mu transposase is a member of a protein family that includes many transposases and the retroviral integrases. These recombinases catalyze the DNA cleavage and joining reactions essential for transpositional recombination. Here we demonstrate that, consistent with structural predictions, aspartate 336 of Mu transposase is required for catalysis of both DNA cleavage and DNA joining. This residue, although located 55 rather than 35 residues NH2-terminal of the essential glutamate, is undoubtedly the analog of the second aspartate of the Asp-Asp-35-Glu motif found in other family members. The core domain of Mu transposase consists of two subdomains: the NH2-terminal subdomain (IIA) contains the conserved Asp-Asp-Glu motif residues, whereas the smaller COOH-terminal subdomain (IIB) contains a large positively charged region exposed on its surface. To probe the function of domain IIB, we constructed mutant proteins carrying deletion or substitution mutations within this region. The activity of the deletion proteins revealed that domains IIA and IIB can be provided by different subunits in the transposase tetramer. Substitution mutations at two pairs of exposed lysine residues within the positively charged surface of domain IIB render transposase defective in transposition at a reaction step after DNA cleavage but prior to DNA joining. The severity of this defect depends on the structure of the DNA flanking the cleavage site. Thus, these data suggest that domain IIB is involved in manipulating the DNA near the cleavage site and that this function is important during the transition between the DNA cleavage and the DNA joining steps of recombination.

Mutations in domain III alpha of the Mu transposase: evidence suggesting an active site component which interacts with the Mu-host junction

A series of point mutations was constructed in domain IIIalpha of the Mu A protein. The mutant transposases were purified and assayed for their ability to promote various aspects of the in vitro Mu DNA strand transfer reaction. All mutants with discernable phenotypes were inhibited in stable synapsis (Type 0 or Type 1 complex formation). In contrast, these mutant proteins were capable of LER formation (a transient early reaction intermediate in which the Mu left and right ends have been synapsed with the enhancer), at levels comparable to wild-type transposase. These proteins therefore comprise a novel class of transposase mutants, which are specifically inhibited in stable transpososome assembly. The defect in these proteins was also uniformly suppressed by either Mn2+, or the Mu B protein in the presence of ATP and target DNA. Striking phenotypic similarities were recognized between the domain IIIalpha transposase mutant characteristics noted above, and those for substrate mutants carrying a terminal base-pair substitution at the point of cleavage on the donor molecule. This phenotypic congruence suggests that the alterations in either protein or DNA are exerting an effect on the same step of the reaction i.e., engagement of the terminal nucleotide by the active site. We suggest that domain IIIalpha of the transposase comprises the substrate binding pocket of the active site which interacts with the Mu-host junction.

An ATP-ADP switch in MuB controls progression of the Mu transposition pathway

MuB protein, an ATP-dependent DNA-binding protein, collaborates with Mu transposase to promote efficient transposition. MuB binds target DNA, delivers this target DNA segment to transposase and activates transposase's catalytic functions. Using ATP-bound, ADP-bound and ATPase-defective MuB proteins we investigated how nucleotide binding and hydrolysis control the activities of MuB protein, important for transposition. We found that both MuB-ADP and MuB-ATP stimulate transposase, whereas only MuB-ATP binds with high affinity to DNA. Four different ATPase-defective MuB mutants fail to activate the normal transposition pathway, further indicating that ATP plays critical regulatory roles during transposition. These mutant proteins fall into two classes: class I mutants are defective in target DNA binding, whereas class II mutants bind target DNA, deliver it to transposase, but fail to promote recombination with this DNA. Based on these studies, we propose that the switch from the ATP- to ADP-bound form allows MuB to release the target DNA while maintaining its stimulatory interaction with transposase. Thus, ATP-hydrolysis by MuB appears to function as a molecular switch controlling how target DNA is delivered to the core transposition machinery.

DNA excision by the Sfi I restriction endonuclease

A mechanism for the precise excision of DNA between two target sites was elucidated by analysing the individual steps during the reactions of the SfiI endonuclease on a plasmid with two SfiI sites. Previous studies had indicated that SfiI is a tetrameric protein that binds to two copies of its recognition site before cleaving both sites in both strands. In this study, the concerted cleavage of four phosphodiester bonds was shown to arise from four consecutive reactions that had similar values for their intrinsic rate constants. Each reaction is presumably mediated by one of the four active sites in the tetramer and all four were generally completed within the life-time of the complex between the protein and two recognition sites, though products cleaved in one or two phosphodiester bonds were also detected following premature dissociation of the enzyme-substrate complex at elevated temperatures. At the physiological temperature for this enzyme, all four bonds were cleaved within one minute but the subsequent dissociation of the enzyme-product complex, liberating the excised segment of DNA, took about one hour. The tetrameric structure for SfiI was confirmed by equilibrium centrifugation.

Altering the DNA-binding specificity of Mu transposase in vitro

We describe the isolation of a variant of Mu transposase (MuA protein) which can recognize altered att sites at the ends of Mu DNA. No prior knowledge of the structure of the DNA binding domain or its mode of interaction with att DNA was necessary to obtain this variant. Protein secondary structure programs initially helped target mutations to predicted helical regions within a subdomain of MuA demonstrated to harbor att DNA binding activity. Of the 54 mutant positions examined, only two showed decreased affinity for att DNA, while eight others affected assembly of the Mu transpososome. A variant impaired in DNA binding [MuA(R146V)], and predicted to be in the recognition helix of an HTH motif, was challenged with altered att sites created from degenerate oligonucleotides to select for novel DNA binding specificity. DNA sequences bound to MuA(R146V) were detected by gel-retardation, and following several steps of PCR amplification/enrichment, were identified by cloning and sequencing. The strategy allowed recovery of an altered att site for which MuA(R146V) showed higher affinity than for the wild-type site, although this site was bound by wild-type MuA as well. The altered association between MuA(R146V) and an altered att site target was competent in transposition. We discuss the strengths and limitations of this methodology, which has applications in dissecting the functional role of specific protein-DNA associations.

Disruption of target DNA binding in Mu DNA transposition by alteration of position 99 in the Mu B protein

Target DNA binding by the Mu B protein is an important step in phage Mu transposition; however, the region of Mu B involved in target binding and the mechanism of the interaction are unknown. Previous studies have demonstrated that modification of Mu B with the sulfhydryl-specific reagent N-ethylmaleimide can selectively inhibit target DNA binding. We now show that individual mutation of the three cysteines in Mu B to serine results in proteins which are active in intermolecular strand transfer, but demonstrate variable levels of N-ethylmaleimide resistance. The data indicate that cysteine 99 is the primary site of modification affecting target DNA binding, with a minor contribution resulting from the derivatization of cysteine 129. These findings are confirmed by the construction of Mu B mutants containing a bulky side-chain at the individual cysteine to mimic the N-ethylmaleimide modified protein. The C99Y protein shows a complete loss in target-dependent strand transfer activity under standard reaction conditions and C129Y displays partial activity. The effect of the tyrosine substitutions is specific for target interaction as both mutants show wild-type activity in their ability to stimulate the Mu transposase to perform donor cleavage and intramolecular strand transfer. Finally, a target dissociation assay has shown that the C99Y-DNA complex generated in the presence of ATP-gamma-S has a drastically reduced half-life as previously found for N-ethylmaleimide treated wild-type Mu B. Modification of cysteine 99 is proposed to block target DNA binding by causing steric interference near the DNA binding pocket.

PDZ-like domains mediate binding specificity in the Clp/Hsp100 family of chaperones and protease regulatory subunits

ClpX, a molecular chaperone and the regulatory subunit of the ClpXP protease, is shown to contain tandem modular domains that bind to the C-terminal sequences of target proteins in a manner that parallels functional specificity. Nuclear magnetic resonance studies show that these C-terminal sequences are displayed as disordered peptides on the surface of otherwise folded proteins. The ClpX substrate-binding domains are homologous to sequences in other Clp/Hsp100 proteins and are related more distantly to PDZ domains, which also mediate C-terminal specific protein-protein interactions. Conservation of these binding domains indicates that the mode of substrate recognition characterized here for ClpX will be a conserved feature among Clp/Hsp100 family members and a distinguishing characteristic between this chaperone family and the Hsp70 chaperones.

A large nucleoprotein assembly at the ends of the viral DNA mediates retroviral DNA integration

We have probed the nucleoprotein organization of Moloney murine leukemia virus (MLV) pre-integration complexes using a novel footprinting technique that utilizes a simplified in vitro phage Mu transposition system. We find that several hundred base pairs at each end of the viral DNA are organized in a large nucleoprotein complex, which we call the intasome. This structure is not formed when pre-integration complexes are made by infecting cells with integrase-minus virus, demonstrating a requirement for integrase. In contrast, footprinting of internal regions of the viral DNA did not reveal significant differences between pre-integration complexes with and without integrase. Treatment with high salt disrupts the intasome in parallel with loss of intermolecular integration activity. We show that a cellular factor is required for reconstitution of the intasome. Finally, we demonstrate that DNA-protein interactions involving extensive regions at the ends of the viral DNA are functionally important for retroviral DNA integration activity. Current in vitro integration systems utilizing purified integrase lack the full fidelity of the in vivo reaction. Our results indicate that both host factors and long viral DNA substrates may be required to reconstitute an in vitro system with all the hallmarks of DNA integration in vivo.

Solution structure of the Mu end DNA-binding ibeta subdomain of phage Mu transposase: modular DNA recognition by two tethered domains

The phage Mu transposase (MuA) binds to the ends of the Mu genome during the assembly of higher order nucleoprotein complexes. We investigate the structure and function of the MuA end-binding domain (Ibetagamma). The three-dimensional solution structure of the Ibeta subdomain (residues 77-174) has been determined using multidimensional NMR spectroscopy. It comprises five alpha-helices, including a helix-turn-helix (HTH) DNA-binding motif formed by helices 3 and 4, and can be subdivided into two interacting structural elements. The structure has an elongated disc-like appearance from which protrudes the recognition helix of the HTH motif. The topology of helices 2-4 is very similar to that of helices 1-3 of the previously determined solution structure of the MuA Igamma subdomain and to that of the homeodomain family of HTH DNA-binding proteins. We show that each of the two subdomains binds to one half of the 22 bp recognition sequence, Ibeta to the more conserved Mu end distal half (beta subsite) and Igamma to the Mu end proximal half (gamma subsite) of the consensus Mu end-binding site. The complete Ibetagamma domain binds the recognition sequence with a 100- to 1000-fold higher affinity than the two subdomains independently, indicating a cooperative effect. Our results show that the Mu end DNA-binding domain of MuA has a modular organization, with each module acting on a specific part of the 22 bp binding site. Based on the present binding data and the structures of the Ibeta and Igamma subdomains, a model for the interaction of the complete Ibetagamma domain with DNA is proposed.

A new set of Mu DNA transposition intermediates: alternate pathways of target capture preceding strand transfer

Mu DNA transposition occurs within the context of higher order nucleoprotein structures or transpososomes. We describe a new set of transpososomes in which Mu B-bound target DNA interacts non-covalently with previously characterized intermediates prior to the actual strand transfer. This interaction can occur at several points along the reaction pathway: with the LER, the Type 0 or the Type 1 complexes. The formation of these target capture complexes, which rapidly undergo the strand transfer chemistry, is the rate-limiting step in the overall reaction. These complexes provide alternate pathways to strand transfer, thereby maximizing transposition potential. This versatility is in contrast to other characterized transposons, which normally capture target DNA only at a single point in their respective reaction pathways.

Human immunodeficiency virus type 1 preintegration complexes: studies of organization and composition

We have investigated the organization and function of human immunodeficiency virus type 1 (HIV-1) preintegration complexes (PICs), the large nucleoprotein particles that carry out cDNA integration in vivo. PICs can be isolated from HIV-1-infected cells, and such particles are capable of carrying out integration reactions in vitro. We find that although the PICs are large, the cDNA must be condensed to fit into the measured volume. The ends of the cDNA are probably linked by a protein bridge, since coordinated joining of the two ends is not disrupted by cleaving the cDNA internally with a restriction enzyme. cDNA ends in PICs were protected from digestion by added exonucleases, probably due to binding of proteins. The intervening cDNA, in contrast, was susceptible to attack by endonucleases. Previous work has established that the virus-encoded integrase protein is present in PICs, and we have reported recently that the host protein HMG I(Y) is also present. Here we report that the viral matrix and reverse transcriptase (RT) proteins also cofractionated with PICs through several steps whereas capsid and nucleocapsid proteins dissociated. These data support a model of PIC organization in which the cDNA is condensed in a partially disassembled remnant of the viral core, with proteins tightly associated at the apposed cDNA ends but loosely associated with the intervening cDNA. In characterizing the structure of the cDNA ends, we found that the U5 DNA ends created by RT were ragged, probably due to the terminal transferase activity of RT. Only molecules correctly cleaved by integrase protein at the 3' ends were competent to integrate, suggesting that one role for terminal cleavage by integrase may be to create a defined end at otherwise heterogeneous cDNA termini.

ClpX and MuB interact with overlapping regions of Mu transposase: implications for control of the transposition pathway

Transposition of phage Mu is catalyzed by an extremely stable transposase-DNA complex. Once recombination is complete, the Escherichia coli ClpX protein, a member of the Clp/Hsp100 chaperone family, initiates disassembly of the complex for phage DNA replication to commence. To understand how the transition between recombination and replication is controlled, we investigated how transposase-DNA complexes are recognized by ClpX. We find that a 10-amino-acid peptide from the carboxy-terminal domain of transposase is required for its recognition by ClpX. This short, positively charged peptide is also sufficient to convert a heterologous protein into a ClpX substrate. The region of transposase that interacts with the transposition activator, MuB protein, is also defined further and found to overlap with that recognized by ClpX. As a consequence, MuB inhibits disassembly of several transposase-DNA complexes that are intermediates in recombination. This ability of MuB to block access to transposase suggests a mechanism for restricting ClpX-mediated remodeling to the proper stage during replicative transposition. We propose that overlap of sequences involved in subunit interactions and those that target a protein for remodeling or destruction may be a useful design for proteins that function in pathways where remodeling or degradation must be regulated.

The Mu transposase tetramer is inactive in unassisted strand transfer: an auto-allosteric effect of Mu A promotes the reaction in the absence of Mu B

A tetramer of the Mu transposase is the structural and functional core in all three stable higher-order nucleoprotein complexes (Type 0, Type 1 and Type 2 transpososomes) generated in a defined in vitro strand transfer reaction. Although functional in donor cleavage, we report here that contrary to previous belief, the Mu A tetramer is incapable of unassisted strand transfer. The Mu B protein is required to stimulate the tetramer for intermolecular strand transfer. In the absence of Mu B protein we show that additional Mu A molecules must be added to the core tetramer to stimulate intramolecular strand transfer. Mapping experiments indicate that domain II of the assisting Mu A mediates functional interactions with the core tetramer. The recipient site for Mu A stimulated strand transfer on the A tetramer is likely in domain II and is clearly different from the domain IIIb site used by the Mu B protein. The Mu accessory end binding sites and the Mu enhancer are not required in the Mu A assisted strand transfer, suggesting that helper A molecules in solution can interact with the core tetramer to stimulate the reaction. Finally, we argue that the strand transfer activity and protein sites for target interaction reside within the core tetramer; hence the role of the stimulatory A molecules appears to be limited to that of an auto-allosteric effector.

Anatomy of a flexer-DNA complex inside a higher-order transposition intermediate

SUMMARY

Escherichia coli HU, a nonsequence-specific histone- and HMG-like DNA-binding protein, was chemically converted into a series of HU-nucleases with an iron-EDTA-based cleavage moiety positioned at 16 rationally selected sites. Specific DNA cleavage patterns from each of these HU-nucleases allowed us to determine the precise localization, stoichiometry, and orientation of HU binding in the Mu transpososome, a multiprotein structure that mediates the chemical reactions in DNA transposition. Correlation of the DNA cleavage data with the position of the cleavage moiety in the HU three-dimensional structure indicates the presence of a dramatic DNA bend, for which the bend center, direction, and magnitude were assessed. The data, which directly localize selected HU amino acids with respect to DNA in the transpososome, were used as constraints for computer-based molecular modeling to derive the first snapshot of an HU-DNA interaction.

Three-site synapsis during Mu DNA transposition: a critical intermediate preceding engagement of the active site

The chemical steps of bacteriophage Mu DNA transposition take place within a higher order nucleoprotein structure. We describe a novel intermediate that precedes the previously characterized transpososomes and directly demonstrates the interaction of a distant enhancer element with recombination regions. The transpositional enhancer interacts with the Mu left and right ends to form a three-site synaptic (LER) complex. Under normal reaction conditions, the LER complex is rapidly converted into the more stable Mu transpososomes. However, mutation of the Mu terminal nucleotides results in accumulation of the LER and a failure to form the type 0 transpososome. During the transition from LER to type 0, the Mu DNA termini and the active site of the transposase engage in a catalytically competent conformation.

The interwoven architecture of the Mu transposase couples DNA synapsis to catalysis

Mu transposition occurs exclusively using a pair of recombination sites found at the ends of the phage genome. To address the mechanistic basis of this specificity, we have determined both where the individual subunits of the tetrameric transposase bind on the DNA and where they catalyze DNA joining. We demonstrate that subunits do not catalyze recombination at the site adjacent to where they are bound, but rather on the opposite end of the phage genome. Furthermore, subunits bound to two different sites contribute to catalysis of one reaction step. This interwoven subunit arrangement suggests a molecular explanation for the precision with which recombination occurs using a pair of DNA signals and provides an example of the way in which the architecture of a protein-DNA complex can define the reaction products.

Mu transpositional recombination: donor DNA cleavage and strand transfer in trans by the Mu transposase

Central to the Mu transpositional recombination are the two chemical steps; donor DNA cleavage and strand transfer. These reactions occur within the Mu transpososome that contains two Mu DNA end segments bound to a tetramer of MuA, the transposase. To investigate which MuA monomer catalyzes which chemical reaction, we made transpososomes containing wild-type and active site mutant MuA. By pre-loading the MuA variants onto Mu end DNA fragments of different length prior to transpososome assembly, we could track the catalysis by MuA bound to each Mu end segment. The donor DNA end that underwent the chemical reaction was identified. Both the donor DNA cleavage and strand transfer were catalyzed in trans by the MuA monomers bound to the partner Mu end. This arrangement explains why the transpososome assembly is a prerequisite for the chemical steps.

The RAG1 and RAG2 proteins establish the 12/23 rule in V(D)J recombination

V(D)J recombination requires a pair of signal sequences with spacer lengths of 12 and 23 base pairs. Cleavage by the RAG1 AND RAG2 proteins was previously shown to demand only a single signal sequence. Here, we established conditions where 12- and 23-spacer signal sequences are both necessary for cleavage. Coupled cutting at both sites requires only the RAG1 and RAG2 proteins, but depends on the metal ion. In Mn2+, a single signal sequence supports efficient double strand cleavage, but cutting in Mg2+ requires two signal sequences and is best with the canonical 12/23 pair. Thus, the RAG proteins determine both aspects of the specificity of V(D)J recombination, the recognition of a single signal sequence and the correct 12/23 coupling in a pair of signals.

The wing of the enhancer-binding domain of Mu phage transposase is flexible and is essential for efficient transposition

A tetramer of the Mu transposase (MuA) pairs the recombination sites, cleaves the donor DNA, and joins these ends to a target DNA by strand transfer. Juxtaposition of the recombination sites is accomplished by the assembly of a stable synaptic complex of MuA protein and Mu DNA. This initial critical step is facilitated by the transient binding of the N-terminal domain of MuA to an enhancer DNA element within the Mu genome (called the internal activation sequence, IAS). Recently we solved the three-dimensional solution structure of the enhancer-binding domain of Mu phage transposase (residues 1-76, MuA76) and proposed a model for its interaction with the IAS element. Site-directed mutagenesis coupled with an in vitro transposition assay has been used to assess the validity of the model. We have identified five residues on the surface of MuA that are crucial for stable synaptic complex formation but dispensable for subsequent events in transposition. These mutations are located in the loop (wing) structure and recognition helix of the MuA76 domain of the transposase and do not seriously perturb the structure of the domain. Furthermore, in order to understand the dynamic behavior of the MuA76 domain prior to stable synaptic complex formation, we have measured heteronuclear 15N relaxation rates for the unbound MuA76 domain. In the DNA free state the backbone atoms of the helix-turn-helix motif are generally immobilized whereas the residues in the wing are highly flexible on the pico- to nanosecond time scale. Together these studies define the surface of MuA required for enhancement of transposition in vitro and suggest that a flexible loop in the MuA protein required for DNA recognition may become structurally ordered only upon DNA binding.

The three chemical steps of Tn10/IS10 transposition involve repeated utilization of a single active site

Nonreplicative transposition by Tn10/IS10 involves three chemical steps at each transposon end: cleavage of the two strands plus joining of one strand to target DNA. These steps occur within a synaptic complex comprising two transposon ends and monomers of IS10 transposase. We report four transposase mutations that individually abolish each of the three chemical steps without affecting the synaptic complex. We conclude that a single constellation of residues, the "active site," directly catalyzes each of the three steps. Analyses of reactions containing mixtures of wild-type and catalysis-defective transposases indicate that a single transposase monomer at each end catalyzes the cleavage of two strands and that strand transfer is carried out by the same monomers that previously catalyzed cleavage. These and other data suggest that one active site unit carries out all three reactions in succession at one transposon end.

Assembly of phage Mu transpososomes: cooperative transitions assisted by protein and DNA scaffolds

Transposition of phage Mu takes place within higher order protein-DNA complexes called transpososomes. These complexes contain the two Mu genome ends synapsed by a tetramer of Mu transposase (MuA). Transpososome assembly is tightly controlled by multiple protein and DNA sequence cofactors. We find that assembly can occur through two distinct pathways. One previously described pathway depends on an enhancer-like sequence element, the internal activation sequence (IAS). The second pathway depends on a MuB protein-target DNA complex. For both pathways, all four MuA monomers in the tetramer need to interact with an assembly-assisting element, either the IAS or MuB. However, once assembled, not all MuA monomers within the transpososome need to interact with MuB to capture MuB-bound target DNA. The multiple layers of control likely are used in vivo to ensure efficient rounds of DNA replication when needed, while minimizing unwanted transposition products.

Enhancer-independent variants of phage Mu transposase: enhancer-specific stimulation of catalytic activity by a partner transposase

Assembly of the functional tetrameric form of phage Mu transposase (A protein) requires specific interactions between the Mu A monomer and its cognate sequences at the ends of the Mu genome (attL and attR) as well as those internal to it (the enhancer element). We describe here deletion variants of Mu A that show enhancer-independence in the assembly of the strand cleavage complex. These deletions remove the amino-terminal region of Mu A required for its interactions with the enhancer elements. The basal enhancer-independent activity of the variant proteins can be stimulated by a partner variant harboring an intact enhancer-binding domain. By exploiting the identical att-binding, and nonidentical enhancer-binding specificities of Mu A and D108 A (transposase of the Mu related phage D108), we show that the stimulation of activity is enhancer-specific. Taken together, these results suggest that the domain of Mu A that includes the enhancer-interacting region may exert negative as well as positive modulatory effects on the strand cleavage reaction. We discuss the implications of these results in the framework of a recent model for the assembly of shared active sites within the Mu A tetramer.

Disassembly of the Mu transposase tetramer by the ClpX chaperone

Mu transposition is promoted by an extremely stable complex containing a tetramer of the transposase (MuA) bound to the recombining DNA. Here we purify the Escherichia coli ClpX protein, a member of a family of multimeric ATPases present in prokaryotes and eukaryotes (the Clp family), on the basis of its ability to remove the transposase from the DNA after recombination. Previously, ClpX has been shown to function with the ClpP peptidase in protein turnover. However, neither ClpP nor any other protease is required for disassembly of the transposase. The released MuA is not modified extensively, degraded, or irreversibly denatured, and is able to perform another round of recombination in vitro. We conclude that ClpX catalyzes the ATP-dependent release of MuA by promoting a transient conformational change in the protein and, therefore, can be considered a molecular chaperone. ClpX is important at the transition between the recombination and DNA replication steps of transposition in vitro; this function probably corresponds to the essential contribution of ClpX for Mu growth. Deletion analysis reveals that the sequence at the carboxyl terminus of MuA is important for disassembly by ClpX and can target MuA for degradation by ClpXP in vitro. These data contribute to the emerging picture that members of the Clp family are chaperones specifically suited for disaggregating proteins and are able to function with or without a collaborating protease.

Disassembly of the bacteriophage Mu transposase for the initiation of Mu DNA replication

Upon catalyzing strand transfer, the Mu transposase (MuA) remains tightly bound to the resulting transposition intermediate, the strand transfer complex (STC), and poses an impediment to host replication proteins. Additional host factors, which can be resolved into two fractions (Mu Replication Factor alpha and beta; MRF alpha and MRF beta), are required to disassemble the MuA complex and initiate DNA synthesis. MRF alpha modifies the protein content of the STC, removing MuA from the DNA in the process. The MRF beta promotes initiation of the Mu DNA synthesis on the STC altered by the MRF alpha. These host factors cannot promote initiation of Mu DNA synthesis if the STC is damaged by partial proteolysis. Moreover, the mutant protein MuA211 cannot be removed from the STC by MRF alpha, blocking initiation of DNA synthesis. These results indicate that MuA in the STC plays a critical function in beginning a sequence of events leading to the establishment of a Mu replication fork.

Structure of the bacteriophage Mu transposase core: a common structural motif for DNA transposition and retroviral integration

The crystal structure of the core domain of bacteriophage Mu transposase, MuA, has been determined at 2.4 A resolution. The first of two subdomains contains the active site and, despite very limited sequence homology, exhibits a striking similarity to the core domain of HIV-1 integrase, which carries out a similar set of biochemical reactions. It also exhibits more limited similarity to other nucleases, RNase H and RuvC. The second, a beta barrel, connects to the first subdomain through several contacts. Three independent determinations of the monomer structure from two crystal forms all show the active site held in a similar, apparently inactive configuration. The enzymatic activity of MuA is known to be activated by formation of a DNA-bound tetramer of the protein. We propose that the connections between the two subdomains may be involved in the cross-talk between the active site and the other domains of the transposase that controls the activity of the protein.

Step-arrest mutants of phage Mu transposase. Implications in DNA-protein assembly, Mu end cleavage, and strand transfer

We describe the isolation and characterization of Mu A variants arrested at specific steps of transposition. Mutations at 13 residues within the Mu A protein were analyzed for precise excision of Mu DNA in vivo. A subset of the defective variants (altered at Asp269, Asp294, Gly348, and Glu392) were tested in specific steps of transposition in vitro. It is possible that at least some residues of the Asp269-Asp294-Glu392 triad may have functional similarities to those of the conserved Asp-Asp-Glu motif found in several transposases and retroviral integrases. Mu A(D269V) is defective in high-order DNA-protein assembly, Mu end cleavage, and strand transfer. The assembly defect, but not the catalytic defect, can be overcome by precleavage of Mu ends. Mu A(E392A) can assemble the synaptic complex, but cannot cleave Mu ends. A mutation of Gly348 to aspartic acid within Mu A permits the uncoupling of cleavage and strand transfer activities. This mutant is completely defective in synaptic assembly and Mu end cleavage in presence of Mg2+. The assembly defect is alleviated by replacing Mg2+ with Ca2+. Some Mu end cleavage is observed with this mutant in the presence of Mn2+. When presented with precleaved Mu ends, Mu A(G348D) exhibits efficient strand transfer activity.

Bacterial transposases and retroviral integrases

Transposable genetic elements have adopted two major strategies for their displacement from one site to another within and between genomes. One involves passage through an RNA intermediate prior to synthesis of a DNA copy while the other is limited uniquely to DNA intermediates. For both types of element, recombination reactions involved in integration are carried out by element-specific enzymes. These are called transposases in the case of DNA elements and integrases in the case of the best-characterized RNA elements, the retroviruses and retrotransposons. In spite of major differences between these two transposition strategies, one step in the process, that of insertion, appears to be chemically identical. Current evidence suggests that the similarities in integration mechanism are reflected in amino acid sequence similarities between the integrases and many transposases. These similarities are particularly marked in a region which is thought to form part of the active site, namely the DDE motif. In the light of these relationships, we attempt here to compare mechanistic aspects of retroviral integration with transposition of DNA elements and to summarize current understanding of the functional organization of integrases and transposases.

Crystal structure of the catalytic domain of HIV-1 integrase: similarity to other polynucleotidyl transferases

HIV integrase is the enzyme responsible for inserting the viral DNA into the host chromosome; it is essential for HIV replication. The crystal structure of the catalytically active core domain (residues 50 to 212) of HIV-1 integrase was determined at 2.5 A resolution. The central feature of the structure is a five-stranded beta sheet flanked by helical regions. The overall topology reveals that this domain of integrase belongs to a superfamily of polynucleotidyl transferases that includes ribonuclease H and the Holliday junction resolvase RuvC. The active site region is identified by the position of two of the conserved carboxylate residues essential for catalysis, which are located at similar positions in ribonuclease H. In the crystal, two molecules form a dimer with a extensive solvent-inaccessible interface of 1300 A2 per monomer.

Complete transposition requires four active monomers in the mu transposase tetramer

A tetramer of Mu transposase (MuA) cleaves and joins multiple DNA strands to promote transposition. Derivatives of MuA altered at two acidic residues that are conserved among transposases and retroviral integrases form tetramers but are defective in both cleavage and joining. These mutant proteins were used to analyze the contribution of individual monomers to the activity of the tetramer. The performance of different protein combinations demonstrates that not all monomers need to be catalytically competent for the complex to promote an individual cleavage or joining reaction. Furthermore, the results indicate that each pair of essential residues is probably donated to the active complex by a single monomer. Although stable, tetramers composed of a mixture of mutant and wild-type MuA generate products cleaved at only one end and with only one end joined to the target DNA. The abundance of these abortive products and the ratios of the two proteins in complexes stalled at different steps indicate that the complete reaction requires the activity of all four monomers. Thus, each subunit of MuA appears to use the conserved acidic amino acids to promote one DNA cleavage or one DNA joining reaction.

Identification of residues in the Mu transposase essential for catalysis

A tetramer of Mu transposase (MuA) cleaves the phage Mu DNA and joins these ends to a target DNA to catalyze transposition. Substitution mutations at Asp-269 or Glu-392 within MuA destroy both the DNA cleavage and joining activities without blocking tetramer assembly, indicating that the mutations specifically affect catalysis. Although inactive under standard reaction conditions (10 mM Mg2+), the mutant proteins are partially resuscitated by 10-20 mM Mn2+, concentrations 5- to 10-fold higher than optimal for wild-type MuA. Amino acid sequence alignment and the similar effects of mutations suggests that Asp-269 and Glu-392 of MuA may be analogs of the first Asp and final Glu of a conserved triad of acidic amino acids present in many transposases and the retroviral integrases (the D-D-35-E motif). The higher Mn2+ optima observed with MuA derivatives altered at these positions supports a role for the conserved acidic amino acids in coordinating divalent metal ions in the active sites of transposases.

Regulation of bacteriophage Mu transposition

Bacteriophage Mu is a transposon and a temperate phage which has become a paradigm for the study of the molecular mechanism of transposition. As a prophage, Mu has also been used to study some aspects of the influence of the host cell growth phase on the regulation of transposition. Through the years several host proteins have been identified which play a key role in the replication of the Mu genome by successive rounds of replicative transposition as well as in the maintenance of the repressed prophage state. In this review we have attempted to summarize all these findings with the purpose of emphasizing the benefit the virus and the host cell can gain from those phage-host interactions.