Functional analysis of Box II mutations in yeast site-specific recombinases Flp and R. Significance of amino acid conservation within the Int family and the yeast sub-family

Efficient Genome Manipulation by Variants of Site-Specific Recombinases R and TD

Genome engineering benefits from the availability of DNA modifying enzymes that have different target specificities and have optimized performance in different cell types. This variety of site-specific enzymes can be used to develop complex genome engineering applications at multiple loci. Although eight yeast site-specific tyrosine recombinases are known, only Flp is actively used in genome engineering. To expand the pool of the yeast site-specific tyrosine recombinases capable of mediating genome manipulations in mammalian cells, we engineered and analyzed variants of two tyrosine recombinases: R and TD. The activity of the evolved variants, unlike the activity of the native R and TD recombinases, is suitable for genome engineering in Escherichia coli and mammalian cells. Unexpectedly, we found that R recombinase benefits from the shortening of its C-terminus. We also found that the activity of wild-type R can be modulated by its non-consensus "head" sequence but this modulation became not apparent in the evolved R variants. The engineered recombinase variants were found to be active in all recombination reactions tested: excision, integration, and dual recombinase-mediated cassette exchange. The analysis of the latter reaction catalyzed by the R/TD recombinase pair shows that the condition supporting the most efficient replacement reaction favors efficient TD-mediated integration reaction while favoring efficient R-mediated integration and deletion reactions.

Functional domains of the IS1 transposase: analysis in vivo and in vitro

The IS1 bacterial insertion sequence family, considered to be restricted to Enterobacteria, has now been extended to other Eubacteria and to Archaebacteria, reviving interest in its study. To analyse the functional domains of the InsAB' transposase of IS1A, a representative of this family, we used an in vivo system which measures IS1-promoted rescue of a temperature-sensitive pSC101 plasmid by fusion with a pBR322::IS1 derivative. We also describe the partial purification of the IS1 transposase and the development of several in vitro assays for transposase activity. These included a DNA band shift assay, a transposase-mediated cleavage assay and an integration assay. Alignments of IS family members (http://www-is.biotoul.fr) not only confirmed the presence of an N-terminal helix-turn-helix and a C-terminal DDE motif in InsAB', but also revealed a putative N-terminal zinc finger. We have combined the in vitro and in vivo tests to carry out a functional analysis of InsAB' using a series of site-directed InsAB' mutants based on these alignments. The results demonstrate that appropriate mutations in the zinc finger and helix-turn-helix motifs result in loss of binding activity to the ends of IS1 whereas mutations in the DDE domain are affected in subsequent transposition steps but not in end binding.

Mutational analysis of the archaeal tyrosine recombinase SSV1 integrase suggests a mechanism of DNA cleavage in trans

The only tyrosine recombinase so far studied in archaea, the SSV1 integrase, harbors several changes in the canonical residues forming the catalytic pocket of this family of recombinases. This raised the possibility of a different mechanism for archaeal tyrosine recombinase. The residues of Int(SSV) tentatively involved in catalysis were modified by site-directed mutagenesis, and the properties of the corresponding mutants were studied. The results show that all of the targeted residues are important for activity, suggesting that the archaeal integrase uses a mechanism similar to that of bacterial or eukaryotic tyrosine recombinases. In addition, we show that Int(SSV) exhibits a type IB topoisomerase activity because it is able to relax both positive and negative supercoils. Interestingly, in vitro complementation experiments between the inactive integrase mutant Y314F and all other inactive mutants restore in all cases enzymatic activity. This suggests that, as for the yeast Flp recombinase, the active site is assembled by the interaction of the tyrosine from one monomer with the other residues from another monomer. The shared active site paradigm of the eukaryotic Flp protein may therefore be extended to the archaeal tyrosine recombinase Int(SSV).

Gamma integrase complementation at the level of DNA binding and complex formation

Site-specific recombinases of the gamma Int family carry out two single-strand exchanges by binding as head-to-head dimers on inverted core-type DNA sites. Each protomer may cleave its own site as a monomer in cis (as for Cre recombinase), or it may recruit the tyrosine from its partner in trans to form a composite active site (as for Flp recombinase). The crystal structure of the gamma Int catalytic domain is compatible with both cleavage mechanisms, but two previous biochemical studies on gamma integrase (Int) generated data that were not in agreement. Support for cis and trans cleavage came from assays with bispecific DNA substrates for gamma and HK022 Ints and from functional complementation between recombination-deficient mutants, respectively. The data presented here do not provide new evidence for cis cleavage, but they strongly suggest that the previously described complementation results cannot be used in support of a trans-cleavage mechanism. We show here that IntR212Q retains some residual catalytic function but is impaired in binding to core-type DNA on linear substrates and in forming higher-order attL intasome structures. The binding-proficient mutant IntY342F can stabilize IntR212Q binding to core-type DNA through protein-protein interactions. Similarly, the formation of higher-order Int complexes with arm- and core-type DNA is boosted with both mutants present. This complementation precedes cleavage and thus precludes any conclusions about the mechanism of catalysis. Cross-core stimulation of wild-type HK022-Int cleavage on its cognate site (in cis) by mutant gamma Ints on bispecific core DNA suicide substrates is shown to be independent of the catalytic tyrosine but appears to be proportional to the respective core-binding affinities of the gamma Int mutants.

DNA recombination and RNA cleavage activities of the Flp protein: roles of two histidine residues in the orientation and activation of the nucleophile for strand cleavage

Using a combination of DNA and hybrid DNA-RNA substrates, we have analyzed the mechanism of phosphoryl transfer by the Flp site-specific recombinase in three different reactions: DNA strand breakage and joining, and two types of RNA cleavage activities. These reactions were then used to characterize Flp variants altered at His309 and His345, amino acid residues that are in close proximity to two key catalytic residues (Arg308 and Tyr343). These histidine residues are important for strand cutting by Tyr343, the active-site nucleophile of Flp, but neither residue contributes to the type II RNA cleavage activity or to the strand-joining reaction in a pre-cleaved substrate. Strand cleavage reactions using small, diffusible nucleophiles indicate that this histidine pair contributes to the correct positioning and activation of Tyr343 within the shared active site of Flp. The implications of these results are evaluated against the recently solved crystal structure of Flp in association with a Holliday junction.

The two active-site tyrosine residues of the a protein play non-equivalent roles during initiation of rolling circle replication of bacteriophage p2

The A protein of bacteriophage P2 initiates rolling circle DNA replication by a single-stranded cut at the origin. Two well-conserved tyrosine residues, interspaced by three amino acid residues, are required for the cleavage-joining activity of the protein. The functional relationship between these tyrosine residues was investigated by site-directed mutagenesis. We found that the two tyrosine residues located in the presumed catalytic site of P2 A play non-equivalent functional roles. Tyrosine residue 454 is superior in nicking single-stranded DNA compared to tyrosine residue 450, while both could promote joining at equal efficiency. Specific peptide-oligonucleotide adducts after cleavage reaction and protease digestion could be observed for both tyrosine residues. We propose that tyrosine 454 initiates replication and that tyrosine 450 is able to cleave the DNA only when tyrosine 454 is covalently joined to DNA, thereby reinitiating replication. Also, the involvement of divalent cations in the catalytic activity of P2 A was investigated. While the cleavage reaction was strongly discriminating between different divalent cations, primarily prefering magnesium, the joining reaction showed the same efficiency independently of what divalent cation was provided. This phenomenon could reflect conformational changes of the protein upon binding to DNA. Finally, we found that a large part of the C terminus but not the N terminus is dispensable for initiation of replication both in vivo and in vitro.

Genomic exploration of the hemiascomycetous yeasts: 8. Zygosaccharomyces rouxii

This paper reports the genomic analysis of strain CBS732 of Zygosaccharomyces rouxii, a homothallic diploid yeast. We explored the sequences of 4934 random sequencing tags of about 1 kb in size and compared them to the Saccharomyces cerevisiae gene products. Approximately 2250 nuclear genes, 57 tRNAs, the rDNA locus, the endogenous pSR1 plasmid and 15 mitochondrial genes were identified. According to 18S and 25S rRNA cladograms and to synteny analysis, Z. rouxii could be placed among the S. cerevisiae sensu lato yeasts.

Functional analysis of the FimE integrase of Escherichia coli K-12: isolation of mutant derivatives with altered DNA inversion preferences

Phase variable expression of type 1 fimbriae in Escherichia coli arises from a site-specific recombination event that inverts a short segment of chromosomal DNA carrying the promoter for transcription of the gene encoding the fimbrial subunit protein. Two integrase-like recombinases are involved in switching. The FimB recombinase inverts the DNA segment in either orientation, whereas the FimE protein inverts it predominantly in the ON-to-OFF direction. In this paper, we report the isolation of a FimE mutant protein that has enhanced bidirectional switching activity. This protein has an arginine-to-lysine substitution at position 59, and this confers a FimB-like switching character on FimE without altering its ability to bind to DNA. The arginine was not a member of the arginine-histidine-arginine-tyrosine catalytic tetrad that is common to all integrase-like recombinases. The catalytic tetrad members of FimE were identified at positions 41, 136, 139 and 171 and shown to be essential for FimE function. In addition, other amino acid residues that make important contributions to the DNA binding activity of FimE or its ON-to-OFF inversion efficiency were identified.

Wild-type Flp recombinase cleaves DNA in trans

Site-specific recombinases of the Integrase family utilize a common chemical mechanism to break DNA strands during recombination. A conserved Arg-His-Arg triad activates the scissile phosphodiester bond, and an active-site tyrosine provides the nucleophile to effect DNA cleavage. Is the tyrosine residue for the cleavage event derived from the same recombinase monomer which provides the RHR triad (DNA cleavage in cis), or are the triad and tyrosine derived from two separate monomers (cleavage in trans)? Do all members of the family follow the same cleavage rule, cis or trans? Solution studies and available structural data have provided conflicting answers. Experimental results with the Flp recombinase which strongly support trans cleavage have been derived either by pairing two catalytic mutants of Flp or by pairing wild-type Flp and a catalytic mutant. The inclusion of the mutant has raised new concerns, especially because of the apparent contradictions in their cleavage modes posed by other Int family members. Here we test the cleavage mode of Flp using an experimental design which excludes the use of the mutant protein, and show that the outcome is still only trans DNA cleavage.

Expression and mutational analysis of the baculovirus very late factor 1 (vlf-1) gene

We have examined the expression and function of a gene, vlf-1, of Autographa californica nuclear polyhedrosis virus that is known to encode a regulator of very late gene transcription. Western blot analysis revealed that vlf-1 is expressed during the late phase of infection, primarily from 15 to 24 h postinfection. VLF-1 localized in the cell nucleus and was also present in the nucleocapsids of virus particles. Mapping of vlf-1 mRNA by primer extension showed that transcription initiates at a TAAG motif 71 bp upstream of the vlf-1 open reading frame. Disruption of this TAAG motif abolished the ability of vlf-1 to stimulate transcription from the very late polyhedrin gene (polh) promoter in transient expression assays, suggesting that vlf-1 expression is controlled by the TAAG motif. Using a highly efficient system to construct recombinant viruses with modifications in vlf-1, we confirmed that the TAAG motif was essential. Furthermore, efforts to construct null mutants of vlf-1 failed, suggesting that vlf-1 is an essential gene for virus replication. Computer-assisted sequence homology searches place vlf-1 in the lambda phage integrase family (McLachlin and Miller, 1994). None of the strictly conserved residues of this family which are found in vlf-1 could be changed in the viral genome, implying that the putative integrase activity of VLF-1 is associated with the essential function of vlf-1. However, mutation of a crucial active-site tyrosine did not affect the ability of vlf-1 to transactivate the polh promoter in transient expression assays, indicating that the very late transcriptional activity of VLF-1 does not require the integrase activity.

Site-directed mutagenesis of conserved aspartates, glutamates and arginines in the active site region of Escherichia coli DNA topoisomerase I

To catalyze relaxation of supercoiled DNA, DNA topoisomerases form a covalent enzyme-DNA intermediate via nucleophilic attack of a tyrosine hydroxyl group on the DNA phosphodiester backbone bond during the step of DNA cleavage. Strand passage then takes place to change the linking number. This is followed by DNA religation during which the displaced DNA hydroxyl group attacks the phosphotyrosine linkage to reform the DNA phosphodiester bond. Mg(II) is required for the relaxation activity of type IA and type II DNA topoisomerases. A number of conserved amino acids with acidic and basic side chains are present near Tyr-319 in the active site of the crystal structure of the 67-kDa N-terminal fragment of Escherichia coli DNA topoisomerase I. Their roles in enzyme catalysis were investigated by site-directed mutation to alanine. Mutation of Arg-136 abolished all the enzyme relaxation activity even though DNA cleavage activity was retained. The Glu-9, Asp-111, Asp-113, Glu-115, and Arg-321 mutants had partial loss of relaxation activity in vitro. All the mutants failed to complement chromosomal topA mutation in E. coli AS17 at 42 degreesC, possibly accounting for the conservation of these residues in evolution.

Unveiling two distinct ribonuclease activities and a topoisomerase activity in a site-specific DNA recombinase

The site-specific DNA recombinase Flp shows two types of RNA cleavage activities on hybrid DNA-RNA substrates. One targets the phosphodiester position involved in DNA recombination and follows a related mechanistic path. In this two-step reaction, first-strand scission is mediated by a nucleophilic attack of the scissile phosphodiester bond by the active site tyrosine of Flp. The resultant 3'-O-phosphoryl tyrosine bond is then attacked by the adjacent 2'-hydroxyl group. The second activity targets the immediately adjacent phosphodiester bond to the 3' side using a distinct mechanism. In this reaction, the vicinal 2'-hydroxyl directly attacks the phosphate group in a manner that is reminiscent of the pancreatic RNase mechanism. The Flp protein can also be shown to possess a topoisomerase-like activity.

The Kw recombinase, an integrase from Kluyveromyces waltii

Site-specific recombinases of the integrase family share limited amino-acid-sequence similarity, but use a common reaction mechanism to recombine distinct DNA target sites. Here we report the characterisation of the Kw site-specific recombinase, encoded on the 2 mu-like plasmid pKWS1 from the yeast Kluyveromyces waltii. Using in vitro-translated Kw recombinase, we show that the protein is able to bind and to recombine its putative DNA target site. Recombination is conservative and the Kw target site has a spacer of seven base pairs. We show that Kw recombinase is able to mediate recombination in a mammalian cell line, thus, it has potential for use as a tool for genomic manipulation in heterologous systems.

Crystal structure of the site-specific recombinase, XerD

The structure of the site-specific recombinase, XerD, that functions in circular chromosome separation, has been solved at 2.5 A resolution and reveals that the protein comprises two domains. The C-terminal domain contains two conserved sequence motifs that are located in similar positions in the structures of XerD, lambda and HP1 integrases. However, the extreme C-terminal regions of the three proteins, containing the active site tyrosine, are very different. In XerD, the arrangement of active site residues supports a cis cleavage mechanism. Biochemical evidence for DNA bending is encompassed in a model that accommodates extensive biochemical and genetic data, and in which the DNA is wrapped around an alpha-helix in a manner similar to that observed for CAP complexed with DNA.

Probing Flp: a new approach to analyze the structure of a DNA recognizing protein by combining the genetic algorithm, mutagenesis and non-canonical DNA target sites

A topological and functional overview of a DNA recognition protein with unknown structure can be achieved by combining three different, but complementary approaches: modeling by the genetic algorithm, functional analysis of mutated variants, and testing the target DNA using non-canonical oligonucleotides. As an example we choose the Flp protein, a site-specific recombinase from Saccharomyces cerevisiae. We derive the topological outline including the DNA binding cleft, examine DNA binding regions by deletional and mutational analysis, and analyze the DNA binding site using 7-deazaadenine, 7-deazaguanine, inosine and 4-O-methylthymine as probes. The combined data offer a comprehensive sketch of a plausible protein architecture for Flp. The structure is detailed enough to verify the prediction accuracy for different peptide regions from pre-existing data and by new experimental design.

Functional roles of individual recombinase monomers in strand breakage and strand union during site-specific DNA recombination

The site-specific recombinase Flp from Saccharomyces cerevisiae accomplishes recombination between two target DNA sites by executing a pair of strand exchanges at either end of the strand exchange region. One round of recombination requires the cooperative action of four recombinase monomers. We demonstrate here that, in the presence of the appropriate nucleophiles, a single Flp monomer associated with its binding element can mediate strand cleavage and strand joining at the exchange site phosphate adjacent to it. Our results support a model of recombination in which pairs of Flp monomers reverse catalytic roles to mediate the first and second sets of strand breakage/union reactions. They disfavor a model that involves a relay of recombinase monomers between binding elements to assemble separate active sites for strand cleavage and strand joining. Our data are consistent with the breakage and joining reactions being carried out by a single composite active site in which some residues contribute to both reactions while others contribute to one of the two reactions.

Mutagenesis of the IS1 transposase: importance of a His-Arg-Tyr triad for activity

Inspection of the primary sequence of the IS1 transposase suggested that it carries residues which are characteristic of the active site of integrases of the bacteriophage lambda family (Int). In particular, these include a highly conserved triad: His-Arg-Tyr. The properties of mutants made at each of these positions were investigated in vivo. The results of several different assays confirm that each is important for transposase activity. Moreover, as in the case of members of the Int family, different mutations of the His residue exhibited different effects. In a particular, His-to-Leu mutation resulted in complete inactivation whereas the equivalent His-to-Gln mutation retained low but significant levels of activity.

Two related recombinases are required for site-specific recombination at dif and cer in E. coli K12

The stable inheritance of ColE1-related plasmids and the normal partition of the E. coli chromosome require the function of the Xer site-specific recombination system. We show that in addition to the XerC recombinase, whose function has already been implicated in this system, a second chromosomally encoded recombinase, XerD, is required. The XerC and XerD proteins show 37% identity and bind to separate halves of the recombination site. Both proteins act catalytically in the recombination reaction. Recombination site asymmetry and the requirement of two recombinases ensure that only correctly aligned sites are recombined. We predict that normal partition of most circular chromosomes requires the participation of site-specific recombination to convert any multimers (arising by homologous recombination) to monomers.