Two distinct regions of the large serine recombinase TnpX are required for DNA binding and biological function

High fidelity one-pot DNA assembly using orthogonal serine integrases

BACKGROUND

Large serine integrases (LSIs, derived from temperate phages) have been adapted for use in a multipart DNA assembly process in vitro, called serine integrase recombinational assembly (SIRA). The versatility, efficiency, and fidelity of SIRA is limited by lack of a sufficient number of LSIs whose activities have been characterized in vitro.

METHODS AND MAJOR RESULTS

In this report, we compared the activities in vitro of 10 orthogonal LSIs to explore their suitability for multiplex SIRA reactions. We found that Bxb1, ϕR4, and TG1 integrases were the most active among the set we studied, but several others were also usable. As proof of principle, we demonstrated high-efficiency one-pot assembly of six DNA fragments (made by PCR) into a 7.5 kb plasmid that expresses the enzymes of the β-carotenoid pathway in Escherichia coli, using six different LSIs. We further showed that a combined approach using a few highly active LSIs, each acting on multiple pairs of att sites with distinct central dinucleotides, can be used to scale up "poly-part" gene assembly and editing.

CONCLUSIONS AND IMPLICATIONS

We conclude that use of multiple orthogonal integrases may be the most predictable, efficient, and programmable approach for SIRA and other in vitro applications.

Solution structure and DNA binding of the catalytic domain of the large serine resolvase TnpX

The transfer of antibiotic resistance between bacteria is mediated by mobile genetic elements such as plasmids and transposons. TnpX is a member of the large serine recombinase subgroup of site-specific recombinases and is responsible for the excision and insertion of mobile genetic elements that encode chloramphenicol resistance in the pathogens Clostridium perfringens and Clostridium difficile. TnpX consists of three structural domains: domain I contains the catalytic site, whereas domains II and III contain DNA-binding motifs. We have solved the solution structure of residues 1-120 of the catalytic domain I of TnpX. The TnpX catalytic domain shares the same overall fold as other serine recombinases; however, differences are evident in the identity of the proposed hydrogen donor and in the size, amino acid composition, conformation, and dynamics of the TnpX active site loops. To obtain the interaction surface of TnpX1-120 , we titrated a DNA oligonucleotide containing the circular intermediate joint attCI recombination site into (15) N-labeled TnpX1-120 and observed progressive nuclear magnetic resonance chemical shift perturbations using (15) N HSQC spectra. Perturbations were largely confined to a region surrounding the catalytic serine and encompassed residues of the active site loops. Utilizing the perturbation map and the data-driven docking program, HADDOCK, we have generated a model of the DNA interaction complex for the TnpX catalytic domain.

Utility of the clostridial site-specific recombinase TnpX to clone toxic-product-encoding genes and selectively remove genomic DNA fragments

TnpX is a site-specific recombinase responsible for the excision and insertion of the transposons Tn4451 and Tn4453 in Clostridium perfringens and Clostridium difficile, respectively. Here, we exploit phenotypic features of TnpX to facilitate genetic mutagenesis and complementation studies. Genetic manipulation of bacteria often relies on the use of antibiotic resistance genes; however, a limited number are available for use in the clostridia. The ability of TnpX to recognize and excise specific DNA fragments was exploited here as the basis of an antibiotic resistance marker recycling system, specifically to remove antibiotic resistance genes from plasmids in Escherichia coli and from marked chromosomal C. perfringens mutants. This methodology enabled the construction of a C. perfringens plc virR double mutant by allowing the removal and subsequent reuse of the same resistance gene to construct a second mutation. Genetic complementation can be challenging when the gene of interest encodes a product toxic to E. coli. We show that TnpX represses expression from its own promoter, PattCI, which can be exploited to facilitate the cloning of recalcitrant genes in E. coli for subsequent expression in the heterologous host C. perfringens. Importantly, this technology expands the repertoire of tools available for the genetic manipulation of the clostridia.

Large serine recombinase domain structure and attachment site binding

Large serine recombinases (LSRs) catalyze the movement of DNA elements into and out of bacterial chromosomes using site-specific recombination between short DNA "attachment sites". The LSRs that function as bacteriophage integrases carry out integration between attachment sites in the phage (attP) and in the host (attB). This process is highly directional; the reverse excision reaction between the product attL and attR sites does not occur in the absence of a phage-encoded recombination directionality factor, nor does recombination typically occur between other pairings of attachment sites. Although the mechanics of strand exchange are reasonably well understood through studies of the closely related resolvase and invertase serine recombinases, many of the fundamental aspects of the LSR reactions have until recently remained poorly understood on a structural level. In this review, we discuss the results of several years worth of biochemical and molecular genetic studies of LSRs in light of recently described structural models of LSR-DNA complexes. The focus is understanding LSR domain structure, how LSRs bind to the attP and attB attachment sites, and the differences between attP-binding and attB-binding modes. The simplicity, site-selectivity and strong directionality of the LSRs has led to their use as important tools in a number of genetic engineering applications in a wide variety of organisms. Given the important potential role of LSR enzymes in genetic engineering and gene therapy, understanding the structure and DNA-binding properties of LSRs is of fundamental importance for those seeking to enhance or alter specificity and functionality in these systems.

The site-specific integration reaction of Listeria phage A118 integrase, a serine recombinase

Background

A large subfamily of serine recombinases contains long polypeptide segments appended to the C-terminal end of the conserved catalytic domain. Members of this subfamily often function as phage integrases but also mediate transposition and regulate terminal differentiation processes in eubacteria. Although a few members of this subfamily have been studied in purified in vitro systems, key mechanistic aspects of reactions promoted by these recombinases remain to be determined, particularly with respect to the functions of the large C-terminal domain.

Results

We have developed and characterized a robust in vitro recombination reaction by the Listeria phage A118 integrase, a member of the subfamily of serine recombinases containing a large C-terminal domain. The reaction occurs in a simple buffered salt solution and exhibits a modest stimulation by divalent cations or spermidine and DNA supercoiling. Recombination with purified A118 integrase is unidirectional, being efficient only between attP and attB DNA sites to either join separate DNA molecules (intermolecular recombination) or to generate deletions or inversions depending on the relative orientation of att sites in cis (intramolecular recombination). The minimal attP site is 50 bp but requires only 44 bp of base sequence information, whereas the minimal attB site is 42 bp and requires 38 bp of base sequence information. DNA exchange occurs between the central 2 bp of attP and attB. Identity between these two base pairs is required for recombination, and they solely determine the orientation of recombination sites. The integrase dimer binds efficiently to full att sites, including the attL and attR integration products, but poorly and differentially to each half-site. The large C-terminal domain can be separated from the N-terminal catalytic by partial proteolysis and mediates non-cooperative DNA binding to att sites.

Conclusions

The basic properties of the phage A118 integrase reaction and its substrate requirements have been elucidated. A118 integrase thus joins the handful of biochemically characterized serine integrases that are serving as models for mechanistic studies on this important class of recombinases. Information reported here will also be useful in exploiting this recombinase for genetic engineering.

Zinc is essential for high-affinity DNA binding and recombinase activity of ΦC31 integrase

The mechanism through which the large serine recombinases bind DNA is poorly understood. Alignments of ϕC31 integrase (Int) and its relatives indicate the presence of a conserved motif containing four cysteines resembling a zinc finger. Inductively coupled plasma–mass spectrometry (ICP–MS) confirmed that an Int monomer contains one atom of zinc. Pre-incubation of Int with ethylenediaminetetraacetic acid (EDTA) was detrimental for both recombination activity and DNA binding affinities but full activity could be restored by adding back Zn²⁺. Mutations in the cysteines and other highly conserved residues yielded proteins that were hypersensitive to proteases, suggesting that without zinc the domain is unfolded. Substitutions in the highly charged region between the conserved cysteines led to lowered DNA binding affinities while circular dichroism revealed that these variant Ints were not greatly affected in overall folding. Int was protected from inhibition by EDTA when DNA containing an attachment site was present suggesting that the zinc finger and the DNA are in close proximity. A truncated mutant of Int, hInt V371S^UGA, lacking the putative zinc finger could bind DNA with low affinity. The data are consistent with there being at least two DNA binding motifs in Int one of which is the zinc finger-like motif.

Site-specific recombination by φC31 integrase and other large serine recombinases

Most temperate phages encode an integrase for integration and excision of the prophage. Integrases belong either to the λ Int family of tyrosine recombinases or to a subgroup of the serine recombinases, the large serine recombinases. Integration by purified serine integrases occurs efficiently in vitro in the presence of their cognate (~50 bp) phage and host attachment sites, attP and attB respectively. Serine integrases require an accessory protein, Xis, to promote excision, a reaction in which the products of the integration reaction, attL and attR, recombine to regenerate attP and attB. Unlike other directional recombinases, serine integrases are not controlled by proteins occupying accessory DNA-binding sites. Instead, it is thought that different integrase conformations, induced by binding to the DNA substrates, control protein–protein interactions, which in turn determine whether recombination proceeds. The present review brings together the evidence for this model derived from the studies on φC31 integrase, Bxb1 integrase and other related proteins.

Mutational analysis of highly conserved residues in the phage phiC31 integrase reveals key amino acids necessary for the DNA recombination

Background

Amino acid sequence alignment of phage phiC31 integrase with the serine recombinases family revealed highly conserved regions outside the catalytic domain. Until now, no system mutational or biochemical studies have been carried out to assess the roles of these conserved residues in the recombinaton of phiC31 integrase.

Methodology/Principal Findings

To determine the functional roles of these conserved residues, a series of conserved residues were targeted by site-directed mutagenesis. Out of the 17 mutants, 11 mutants showed impaired or no recombination ability, as analyzed by recombination assay both in vivo and in vitro. Results of DNA binding activity assays showed that mutants (R18A, I141A, L143A,E153A, I432A and V571A) exhibited a great decrease in DNA binding affinity, and mutants (G182A/F183A, C374A, C376A/G377A, Y393A and V566A) had completely lost their ability to bind to the specific target DNA attB as compared with wild-type protein. Further analysis of mutants (R18A, I141A, L143A and E153A) synapse and cleavage showed that these mutants were blocked in recombination at the stage of strand cleavage.

Conclusions/Significance

This data reveals that some of the highly conserved residues both in the N-terminus and C-terminus region of phiC31 integrase, play vital roles in the substrate binding and cleavage. The cysteine-rich motif and the C-tail val-rich region of phiC31 integrase may represent the major DNA binding domains of phiC31 integrase.

Revised nomenclature for transposable genetic elements

Transposable DNA elements occur naturally in the genomes of nearly all species of prokaryotes. A proposal for a uniform transposable element nomenclature was published prominently in the 1970s but is not, at present, available online even in abstract form, and many of the newly discovered elements have been named without reference to it. We propose here an updated version of the original nomenclature system for all of the various types of prokaryotic, autonomous, transposable elements excluding insertion sequences, for which a nomenclature system already exists. The use of this inclusive and sequential Tn numbering system for transposable elements, as described here, recognizes the ease of interspecies spread of individual elements, and allows for the naming of mosaic elements containing segments from two or more previously described types of transposons or plasmids. It will guard against any future need to rename elements following changes in bacterial nomenclature which occurs constantly with our increased understanding of bacterial phylogenies and taxonomic groupings. It also takes into account the increasing importance of metagenomic sequencing projects and the continued identification of new mobile elements from unknown hosts.

Sequences in attB that affect the ability of phiC31 integrase to synapse and to activate DNA cleavage

Phage integrases are required for recombination of the phage genome with the host chromosome either to establish or exit from the lysogenic state. C31 integrase is a member of the serine recombinase family of site-specific recombinases. In the absence of any accessory factors integrase is unidirectional, catalysing the integration reaction between the phage and host attachment sites, attP x attB to generate the hybrid sites, attL and attR. The basis for this directionality is due to selective synapsis of attP and attB sites. Here we show that mutations in attB can block the integration reaction at different stages. Mutations at positions distal to the crossover site inhibit recombination by destabilizing the synapse with attP without significantly affecting DNA-binding affinity. These data are consistent with the proposal that integrase adopts a specific conformation on binding to attB that permits synapsis with attP. Other attB mutants with changes close to the crossover site are able to form a stable synapse but cleavage of the substrates is prevented. These mutants indicate that there is a post-synaptic DNA recognition event that results in activation of DNA cleavage.