The circle is broken: telomere resolution in linear replicons.

Linear DNA molecules with covalently closed hairpin ends (telomeres) exist in a wide variety of organisms. Telomere resolution, a DNA breakage and reunion reaction in which replicated telomeres are processed into hairpin ends, is now known to be a common theme in poxviruses, Borrelia burgdorferi and Escherichia coli phage N15. Candidate proteins that may perform this reaction have recently been identified in poxviruses. Moreover, the first purification and definitive identification of a telomere resolvase has been reported for phage N15. This protein is the prototype for a new class of DNA enzyme that performs a unique reaction. Advances in the study of telomere resolution in poxviruses, B. burgdorferi and E. coli phage N15 are discussed.

Telomere resolution in the Lyme disease spirochete.

The genus Borrelia includes the causative agents of Lyme disease and relapsing fever. An unusual feature of these bacteria is a genome that includes linear DNA molecules with covalently closed hairpin ends referred to as telomeres. We have investigated the mechanism by which the hairpin telomeres are processed during replication. A synthetic 140 bp sequence having the predicted structure of a replicated telomere was shown to function as a viable substrate for telomere resolution in vivo, and was sufficient to convert a circular replicon to a linear form. Our results suggest that the final step in the replication of linear Borrelia replicons is a site-specific DNA breakage and reunion event to regenerate covalently closed hairpin ends. The telomere substrate described here will be valuable both for in vivo manipulation of linear DNA in Borrelia and for in vitro studies to identify and characterize the telomere resolvase.

Effect of mutations in the Mu-host junction region on transpososome assembly.

Mu transposition occurs through a series of higher-order nucleoprotein complexes called transpososomes. The region where the Mu DNA joins the host DNA plays an integral role in the assembly of these transpososomes. We have created a series of point mutations at the Mu-host junction and characterized their effect on the Mu in vitro strand transfer reaction. Analysis of these mutant constructs revealed an inhibition in transpososome assembly at the point in the reaction pathway when the junction region is engaged by the transposase active site (i.e. the transition from LER to type 0). We found that the degree of inhibition was dependent upon the particular base-pair change at each position and whether the substitution occurred at the left or right transposon end. The MuB transposition protein, an allosteric effector of MuA, was shown to suppress all of the inhibitory Mu-host junction mutants. Most of the mutant constructs were also suppressed, to varying degrees, by the substitution of Mg(2+) with Mn(2+). Analysis of the mutant constructs has revealed hierarchical nucleotide preferences at positions -1 through +3 for transpososome assembly and suggests the possibility that specific metal ion-DNA base interactions are involved in DNA recognition and transpososome assembly.

The solution structure of the C-terminal domain of the Mu B transposition protein.

Mu B is one of four proteins required for the strand transfer step of bacteriophage Mu DNA transposition and the only one where no high resolution structural data is available. Structural work on Mu B has been hampered primarily by solubility problems and its tendency to aggregate. We have overcome this problem by determination of the three-dimensional structure of the C-terminal domain of Mu B (B(223-312)) in 1.5 M NaCl using NMR spectroscopic methods. The structure of Mu B(223-312) comprises four helices (backbone r.m.s.d. 0.46 A) arranged in a loosely packed bundle and resembles that of the N-terminal region of the replication helicase, DnaB. This structural motif is likely to be involved in the inter-domainal regulation of ATPase activity for both Mu A and DnaB. The approach described here for structural determination in high salt may be generally applicable for proteins that do not crystallize and that are plagued by solubility problems at low ionic strength.

Site-specific DNA binding and bending by the Borrelia burgdorferi Hbb protein.

The Borrelia burgdorferi Hbb protein shows sequence similarity to members of the Escherichia coli HU/integration host factor (IHF) family of DNA accessory factors. We have overexpressed the hbb gene product in E. coli and purified the protein to near homogeneity. Biochemical analyses have revealed that Hbb has unique properties and is neither a strict HU nor IHF analogue. Hbb was found to bind specifically to a site in the putative origin of DNA replication between dnaA and dnaN. DNA footprinting studies have shown that this site is unrelated to the consensus sequence recognized by IHF proteins. Hbb induces a dramatic bend (> 126 degrees ) at this site and was also shown to restrain negative supercoils efficiently upon DNA binding. These features of the protein suggest that Hbb may act as a DNA accessory factor that facilitates the assembly of higher order protein-DNA complexes, such as those involved in DNA replication, transcription, recombination, packaging and perhaps other DNA metabolic processes unique to Borrelia.

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.

Studies on a "jumping gene machine": higher-order nucleoprotein complexes in Mu DNA transposition.

Studies in my lab have focused on DNA transposition in the bacterial virus, Mu. In vitro studies have shown that Mu DNA transposition is a three-step process involving DNA breakage, strand transfer and DNA replication. In the first step, a nick is introduced at each end of the transposon. The liberated 3'-OH groups subsequently attack a target DNA molecule resulting in strand transfer. The transposon DNA, now covalently linked to the target, is finally replicated to generate the transposition end-product, referred to as a cointegrate. The DNA cleavage and strand transfer reactions are mediated by a "jumping gene machine" or transpososomes, which we discovered in 1987. They are assembled by bringing together three different DNA regions via a process involving multiple protein-DNA and protein-protein interactions. The action of four different proteins is required in addition to protein-induced DNA bending or wrapping to overcome the intrinsic stiffness of DNA, which would ordinarily prohibit the assembly of such a structure. Transpososome assembly is a gradual process involving multiple steps with an inherent flexibility whereby alternate pathways can be used in the assembly process, biasing the reaction towards completion under different conditions.

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.

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.

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.

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.

DNA transposition: jumping gene machine, some assembly required.

Transposition of the mobile DNA element Mu is stringently controlled by the assembly of an elaborate jumping gene machine, which is inactive until all the pieces are in place.

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.

A novel DNA binding and nuclease activity in domain III of Mu transposase: evidence for a catalytic region involved in donor cleavage.

The Mu A protein is a 75 kDa transposase organized into three structural domains. By severing the C-terminal region (domain III) from the remainder of the protein, we unmasked a novel non-specific DNA binding and nuclease activity in this region. Deletion analysis localized both activities to a 26 amino acid stretch (aa 575-600) which remarkably remained active in DNA binding and cleavage. The two activities were shown to be tightly linked by site-directed mutagenesis. To study the importance of these activities in the transposition process, an intact mutant transposase lacking the DNA binding and nuclease activity of domain III was constructed and purified. The mutant transposase was indistinguishable from wild-type Mu A in binding affinity for both the Mu ends and the enhancer, and in strand transfer activity when the cleavage step was bypassed. In contrast, the mutant transposase displayed defects in both synapsis and donor cleavage. Our results strongly suggest that the 26 amino acid region in domain III carries catalytic residues required for donor DNA cleavage by Mu A protein. Furthermore, our data suggest that an active site for donor cleavage activity in the Mu tetramer is assembled from domain II (metal ion binding) in one A monomer and domain III (DNA cleavage) in a separate A monomer. This proposal for active site assembly is in agreement with the recently proposed domain sharing model by Yang et al. (Yang, J.Y., Kim, K., Jayaram, M. and Harshey, R.M. [1995] EMBO J., 14, 2374-2384).

Characterization of a region in phage Mu transposase that is involved in interaction with the Mu B protein.

Mu A protein, the 75-kDa phage transposase, consists of three domains: a 30-kDa NH2 terminus, a 35-kDa central domain, and a 10-kDa COOH terminus (Nakayama, C., Teplow, D. B., and Harshey, R. M. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 1809-1813). Genetic and biochemical experiments have demonstrated that the COOH-terminal domain must be present for functional interaction with Mu B protein. To further investigate the COOH-terminal domain of Mu A, we fused this 89-amino acid region to the glutathione S-transferase gene to facilitate subsequent expression and purification. We show that either the glutathione S-transferase-peptide fusion protein or the COOH-terminal peptide severed from glutathione S-transferase is active in Mu B interaction. Addition of the COOH-terminal domain to the in vitro strand transfer reaction inhibits intermolecular strand transfer by a mechanism previously characterized for intact Mu A protein (Baker, T. A., Mizuuchi, M., and Mizuuchi, K. (1991) Cell 65, 1003-1013), although the COOH-terminal domain is 70 times less effective than intact Mu A. The transient interaction between the COOH-terminal domain and Mu B does not inhibit Mu B stimulation of the strand cleavage and intramolecular strand transfer activity of Mu A. Deletion analysis has shown that the last 36 amino acids are sufficient for interaction with Mu B, but that removal of as few as 4 amino acids from the COOH terminus renders the peptide inactive. The recovery of an active COOH-terminal domain of Mu A will facilitate future structure/function studies of the Mu transposase.

A second high affinity HU binding site in the phage Mu transpososome.

The bacteriophage Mu in vitro transposition reaction proceeds through several higher order nucleoprotein intermediates (transpososomes). One of the requirements for complex assembly is the Escherichia coli sequence-independent DNA-binding protein, HU. This protein has an affinity for Mu transpososomes, which is at least 100 times greater than for supercoiled DNA (Lavoie and Chaconas, 1990). We have recently identified one such high affinity binding site at the Mu left end by converting HU into a chemical nuclease (Lavoie and Chaconas, 1993). Using immunoelectron microscopy, we now report high affinity HU binding to a region(s) distinct from the previously characterized left end site. HU can be removed from this region by a 0.5 M NaCl wash and subsequently reassembled into the complex with high efficiency. Furthermore, chemical modification of the Mu A protein in the Type 1 complex does not block HU reassembly into the transpososome; the high affinity HU binding observed is therefore unlikely to result from A-HU interactions. These findings are corroborated by the ability of eukaryotic HMG-1 to functionally replace HU in transpososome formation and to efficiently assemble into HU-depleted complexes. We propose that HU recognition of an altered DNA structure, rather than protein-protein interactions, mediates high affinity HU binding to Mu transpososomes.

Site-specific HU binding in the Mu transpososome: conversion of a sequence-independent DNA-binding protein into a chemical nuclease.

HU is a small, basic, sequence-independent DNA-binding protein capable of engineering DNA deformations required for the formation of higher order nucleoprotein structures. One such complex is the Mu Type 1 transpososome, where the ends of Mu are stably synapsed by a tetramer of Mu A and cleaved at their 3' ends. HU is believed to play a critical role in transpososome assembly, which requires the communication of the two Mu ends and the transpositional enhancer. Although footprinting studies have clearly defined the DNA regions bound by Mu A, no protection could be ascribed to the HU protein by DNAse I, MPE.Fe(II) or hydroxyl radical methods (Lavoie et al. 1991). To directly probe HU interactions with the transpososome DNA, we have coupled HU to a DNA cleavage reagent, iron-EDTA, and report here the first HU "footprint". HU-nuclease cleavage was detectable at specific sites within an 83-bp spacer DNA separating the left-end-most L1 site from its neighboring L2 site. This HU binding was specific since it could not be competed with 10-fold excess supercoiled DNA. We postulate that HU promotes the formation of a tight DNA bend or loop in this region which facilitates the communication of Mu A monomers during complex assembly. This method may prove generally useful for the localization of sequence-independent DNA-binding proteins on DNA and within higher oder nucleoprotein structures.

Mechanistic aspects of DNA transposition.

The past year has seen a number of important advances in our understanding of the mechanisms of DNA transposition. The molecular details of the protein-protein, protein-DNA and chemical-reaction steps in several transposition systems have been revealed and have highlighted remarkable uniformity in some areas, ranging from bacterial to retroviral mechanisms.