Mutational analysis of a site-specific recombinase: characterization of the catalytic and dimerization domains of the β recombinase of pSM19035

The β recombinase encoded by the streptococcal plasmid pSM19035, which shows 28 to 34% identity with DNA resolvases and DNA invertases, can catalyze formation of deletions or inversions between properly oriented target sites. We have constructed a number of site-directed mutations at residues that are conserved between the β protein and other DNA recombinases of the resolvase/invertase family. The analysis of the recombination and DNA-binding ability of each mutant protein shows that the mutations affect the catalytic activity and, in two cases, the dimerization of the protein. The results suggest that the β protein probably mediates recombination by a catalytic mechanism similar to that proposed for the resolvase/invertase family. Since the β recombinase differs from DNA resolvases and DNA invertases in its lack of bias towards either of these reactions, the results presented support the hypothesis that its unique properties might depend on details of the architecture or assembly of the recombination complex. In addition, two β protein mutants that can no longer form dimers in solution have provided new insights into the way the protein binds to DNA     

Diversity in the serine recombinases

Most site-specific recombinases fall into one of two families, based on evolutionary and mechanistic relatedness. These are the tyrosine recombinases or lambda integrase family and the serine recombinases or resolvase/invertase family. The tyrosine recombinases are structurally diverse and functionally versatile and include integrases, resolvases, invertases and transposases. Recent studies have revealed that the serine recombinase family is equally versatile and members have a variety of structural forms. The archetypal resolvase/invertases are highly regulated, only affect resolution or inversion and they have an N-terminal catalytic domain and a C-terminal DNA binding domain. Phage-encoded serine recombinases (e.g. phiC31 integrase) cause integration and excision with strictly controlled directionality, and have an N-terminal catalytic domain but much longer C-terminal domains compared with the resolvase/invertases. This high molecular weight group also contains transposases (e.g. TnpX from Tn4451). Other transposases, which belong to a third structurally different group, are similar in size to the resolvase/invertases but have the DNA binding domain N-terminal to the catalytic domain (e.g. IS607 transposase). These three structural groups represented by the resolvase/invertases, the large serine recombinases and relatives of IS607 transposase correlate with three major groupings seen in a phylogeny of the catalytic domains. These observations indicate that the serine recombinases are modular and that fusion of the catalytic domain to unrelated sequences has generated structural and functional diversity.     

A DNA-binding domain swap converts the invertase gin into a resolvase

DNA resolvases and invertases are closely related, yet catalyze recombination within two distinct nucleoprotein structures termed synaptosomes and invertasomes, respectively. Different protein-protein and protein-DNA interactions guide the assembly of each type of recombinogenic complex, as well as the subsequent activation of DNA strand exchange. Here we show that invertase Gin catalyzes factor for inversion stimulation dependent inversion on isolated copies of sites I from ISXc5 res, which is typically utilized by the corresponding resolvase. The concomitant binding of Gin to sites I and III in res, however, inhibits recombination. A chimeric recombinase, composed of the catalytic domain of Gin and the DNA-binding domain of ISXc5 resolvase, recombines two res with high efficiency. Gin must therefore contain residues proficient for both synaptosome formation and activation of strand exchange. Surprisingly, this chimera is unable to assemble a productive invertasome; a result which implies a role for the C-terminal domain in invertasome formation that goes beyond DNA binding.     

The beta recombinase of plasmid pSM19035 binds to two adjacent sites, making different contacts at each of them.

The beta recombinase from plasmid pSM19035 catalyzes intramolecular site-specific recombination between two directly or inversely oriented six sites in the presence of a chromatin-associated protein (Hbsu, HU or HMG-1). The six site is a DNA segment containing two binding sites (I and II) for beta protein dimers. We show that beta recombinase binds sequentially to both sites, having a different affinity for each one. Hydroxyl radical footprints show a different protection pattern at each site. Positions critical for beta protein binding have been identified by methylation interference and missing nucleoside assays. The results indicate that the protein recognizes each site in a different way. Comparison of the beta protein recombination site with that of DNA resolvases and DNA invertases of the Tn3 family, to which it belongs, shows that these sequences can be divided into two regions. One corresponds to the crossover point and is similar for all recombinases of the family. The other region differs in the different subfamilies and seems to have an architectural role in aligning the crossover sites at the synaptic complex. The different ways to assemble this complex could explain why each system leads to a particular recombination event: DNA resolution (resolvases), inversion (invertases) or both (beta recombinase).     

Secondary and tertiary structural changes in gamma delta resolvase: comparison of the wild-type enzyme, the I110R mutant, and the C-terminal DNA binding domain in solution.

gamma delta Resolvase is a site-specific DNA recombinase (M(r) 20.5 kDa) in Escherichia coli that shares homology with a family of bacterial resolvases and invertases. We have characterized the secondary and tertiary structural behavior of the cloned DNA binding domain (DBD) and a dimerization defective mutant in solution. Low-salt conditions were found to destabilize the tertiary structure of the DBD dramatically, with concomitant changes in the secondary structure that were localized near the hinge regions between the helices. The molten tertiary fold appears to contribute significantly to productive DNA interactions and supports a mechanism of DNA-induced folding of the tertiary structure, a process that enables the DBD to adapt in conformation for each of the three imperfect palindromic sites. At high salt concentrations, the monomeric I110R resolvase shows a minimal perturbation to the three helices of the DBD structure and changes in the linker segment in comparison to the cloned DBD containing the linker. Comparative analysis of the NMR spectra suggest that the I110R mutant contains a folded catalytic core of approximately 60 residues and that the segment from residues 100 to 149 are devoid of regular structure in the I110R resolvase. No increase in the helicity of the linker region of I110R resolvase occurs on binding DNA. These results support a subunit rotation model of strand exchange that involves the partial unfolding of the catalytic domains.     

Tetrameric structure of a serine integrase catalytic domain

The serine integrases have recently emerged as powerful new chromosome engineering tools in various organisms and show promise for therapeutic use in human cells. The serine integrases are structurally and mechanistically unrelated to the bacteriophage lambda integrase but share a similar catalytic domain with the resolvase/invertase enzymes typified by the resolvase proteins from transposons Tn3 and gammadelta. Here we report the crystal structure and solution properties of the catalytic domain from bacteriophage TP901-1 integrase. The protein is a dimer in solution but crystallizes as a tetramer that is closely related in overall architecture to structures of activated gammadelta-resolvase mutants. The ability of the integrase tetramer to explain biochemical experiments performed in the resolvase and invertase systems suggests that the TP901 integrase tetramer represents a unique intermediate on the recombination pathway that is shared within the serine recombinase superfamily.     

Characterization of the staphylococcal beta-lactamase transposon Tn552.

The staphylococcal beta-lactamase transposon Tn552 is a member of a novel group of transposable elements. The organization of genes in Tn552 resembles that of members of the Tn21 sub-group of Tn3 family transposons, which transpose replicatively by cointegrate formation and resolution. Thus, a possible resolution site ('resL') and a resolvase gene (tnpR or 'binL') have been identified. However, consistent with the fact that Tn552 generates 6 bp (rather than 5 bp) flanking direct repeats of target DNA, neither the putative transposase protein, nor the terminal inverted repeats of Tn552 are homologous to those of Tn3 elements. Tn552, like phage Mu and retroelements, is defined by the terminal dinucleotides 5' TG .. CA 3'. A naturally occurring staphylococcal plasmid, pI9789, contains a Tn552-derived resolution system ('resR-binR') that acts as a 'hotspot' for Tn552 transposition; insertion creates a segment of DNA flanked by inversely repeated resolution sites, one (resR) on pI9789 and the other (resL) on Tn552. The putative Tn552 resolvase, the most closely related of known resolvases to the homologous DNA invertases, initially was identified as a DNA invertase ('Bin') as a result of its ability to mediate efficient inversion of this segment in vivo.     

Site-specific recombination systems for the genetic manipulation of eukaryotic genomes

Site-specific recombination systems, such as the bacteriophage Cre-lox and yeast FLP-FRT systems, have become valuable tools for the rearrangement of DNA in higher eukaryotes. As a first step to expanding the repertoire of recombination tools, we screened recombination systems derived from the resolvase/invertase family for site-specific recombinase activity in the fission yeast Schizosaccharomyces pombe. Here, we report that seven recombination systems, four from the small serine resolvase subfamily (CinH, ParA, Tn1721, and Tn5053) and three from the large serine resolvase subfamily (Bxb1, TP901-1, and U153), can catalyze site-specific deletion in S. pombe. Those from the large serine resolvase subfamily were also capable of site-specific integration and inversion. In all cases, the recombination events were precise. Functional operation of these recombination systems in the fission yeast holds promise that they may be further developed as recombination tools for the site-specific rearrangement of plant and animal genomes.     

The catalytic residues of Tn3 resolvase

To characterize the residues that participate in the catalysis of DNA cleavage and rejoining by the site-specific recombinase Tn3 resolvase, we mutated conserved polar or charged residues in the catalytic domain of an activated resolvase variant. We analysed the effects of mutations at 14 residues on proficiency in binding to the recombination site (‘site I’), formation of a synaptic complex between two site Is, DNA cleavage and recombination. Mutations of Y6, R8, S10, D36, R68 and R71 resulted in greatly reduced cleavage and recombination activity, suggesting crucial roles of these six residues in catalysis, whereas mutations of the other residues had less dramatic effects. No mutations strongly inhibited binding of resolvase to site I, but several caused conspicuous changes in the yield or stability of the synapse of two site Is observed by non-denaturing gel electrophoresis. The involvement of some residues in both synapsis and catalysis suggests that they contribute to a regulatory mechanism, in which engagement of catalytic residues with the substrate is coupled to correct assembly of the synapse.