Marker removal from actinomycetes genome using Flp recombinase

We report here a system for the functional expression of the Flp recombinase in several actinomycetes: Streptomyces coelicolor, S. lividans, and Saccharotrix espanaensis. We have constructed a synthetic gene encoding the Flp recombinase with a GC content of 60.6% optimized for expression in high-GC bacteria. Using the synthetic flp(a) gene, we have removed an apramycin resistance gene flanked by FRT sites from the chromosome of actinomycetes with an efficiency of 40%. Sequencing the region of chromosome showed that excision of the apramycin cassette by Flp recombinase was specific.     

Molecular Characterization of Low-Molecular-Weight Component Protein,Flp, in Actinobacillus actinomycetemcomitans Fimbriae

Fimbriae preparation from Actinobacillus actinomycetemcomitans was found to contain an abundant low-molecular-weight protein (termed Flp) with an apparent molecular mass of approximately 6.5 kDa, in addition to a small amount of 54-kDa protein. Immunogold electron microscopy localized the Flp protein at the bacterial fimbriae but not at the cell surface. The DNA fragment including the flp gene was cloned from A. actinomycetemcomitans 304-a and its nucleotide sequence was determined. An open reading frame of the flp gene was composed of 225 bp encoding a protein of 75 amino acids. Comparison of the translated amino acid sequence with the sequence of native Flp determined by Edman degradation indicated that the N-terminal part of 26 amino acids is leader peptide. The N-terminal sequence of mature Flp exhibited some similarity to type-IV pilin. Furthermore, the processing site of premature Flp is also similar to that of type-IV prepilin, and a gene encoding a protein homologous to type-IV prepilin-like protein leader peptidase was found downstream of the flp gene. These findings indicate that Flp is the major component protein of A. actinomycetemcomitans fimbriae.     

Functional expression of the Flp recombinase in Mycobacterium bovis BCG

Mycobacteria contain a large number of redundant genes whose functions are difficult to analyze in mutants because there are only two efficient antibiotic resistance genes available for allelic exchange experiments. Sequence-specific recombinbases such as the Flp recombinase can be used to excise resistance markers. Expression of the flp(e) gene from Saccharomyces cerevisiae is functional for this purpose in fast-growing Mycobacterium smegmatis but not in slow-growing mycobacteria such as M. bovis BCG or M. tuberculosis. We synthesized the flp(m) gene by adapting the codon usage to that preferred by M. tuberculosis. This increased the G+C content from 38% to 61%. Using the synthetic flp(m) gene, the frequency of removal of FRT-hyg-FRT cassette from the chromosome by the Flp recombinase was increased by more than 100-fold in M. smegmatis. In addition, 40% of all clones of M. bovis BCG had lost the hyg resistance cassette after transient expression of the flp(m) gene. Sequencing of the chromosomal DNA showed that excision of the FRT-hyg-FRT cassette by Flp was specific. These results show that the flp(m) encoded Flp recombinase is not only an improved genetic tool for M. smegmatis, but can also be used in slow growing mycobacteria such as M. tuberculosis for constructing unmarked mutations. Other more sophisticated applications in mycobacterial genetics would also profit from the improved Flp/FRT system.     

Flp recombinase transgenic mice of C57BL/6 strain for conditional gene targeting

We constructed an expression vector of Flp recombinase modified by adding a nuclear localization signal. Injection of the expression vector into fertilized eggs of the C57BL/6 strain yielded transgenic mouse lines expressing the Flp recombinase transgene in the testis. We crossed the transgenic mice to reporter mice carrying the neomycin phosphotransferase gene flanked by target sites of Flp recombinase. Examination of the deletion of the neomycin phosphotransferase gene in the progeny showed that Flp-mediated recombination took place efficiently in vivo in FLP66 transgenic mouse line. These results suggest that the Flp recombinase system is effective in mice and in combination with the Cre recombinase system extends the potentials of gene manipulation in mice. One of the useful applications of FLP66 transgenic mouse line is the removal of marker genes from mice manipulated for the conditional gene targeting with the Cre/loxP system in the pure C57BL/6 genetic background.     

FppA, a novel Pseudomonas aeruginosa prepilin peptidase involved in assembly of type IVb pili

Several subclasses of type IV pili have been described according to the characteristics of the structural prepilin subunit. Whereas molecular mechanisms of type IVa pilus assembly have been well documented for Pseudomonas aeruginosa and involve the PilD prepilin peptidase, no type IVb pili have been described in this microorganism. One subclass of type IVb prepilins has been identified as the Flp prepilin subfamily. Long and bundled Flp pili involved in tight adherence have been identified in Actinobacillus actinomycetemcomitans, for which assembly was due to a dedicated machinery encoded by the tad-rcp locus. A similar flp-tad-rcp locus containing flp, tad, and rcp gene homologues was identified in the P. aeruginosa genome. The function of these genes has been investigated, which revealed their involvement in the formation of extracellular Flp appendages. We also identified a gene (designated by open reading frame PA4295) outside the flp-tad-rcp locus, that we named fppA, encoding a novel prepilin peptidase. This is the second enzyme of this kind found in P. aeruginosa; however, it appears to be truncated and is similar to the C-terminal domain of the previously characterized PilD peptidase. In this study, we show that FppA is responsible for the maturation of the Flp prepilin and belongs to the aspartic acid protease family. We also demonstrate that FppA is required for the assembly of cell surface appendages that we called Flp pili. Finally, we observed an Flp-dependent bacterial aggregation process on the epithelial cell surface and an increased biofilm phenotype linked to Flp pilus assembly.     

Consecutive gene deletions in Mycobacterium smegmatis using the yeast FLP recombinase

Mycobacteria contain a large number of redundant genes whose functions are difficult to analyze in mutants, because there are only two efficient resistance markers available for allelic exchange experiments. We have established a system based on the Flp recombinase of the yeast Saccharomyces cerevisiae for use in the nonpathogenic model organism Mycobacterium smegmatis. This system consists of a hygromycin resistance cassette flanked by two Flp recognition targets (FRT) in direct orientation and a curable plasmid for expression of the flp gene. The FRT-hyg-FRT cassette was used on a suicide plasmid and on a conditionally replicating plasmid to delete two of the four known porin genes of M. smegmatis, mspA and mspC, respectively, by homologous recombination. The hyg gene was specifically removed from the chromosome of both mutants upon expression of the flp gene. Based on the marker-less mspC mutant strain, a double knock-out mutant lacking also mspA was obtained using the same strategy. Thus, by a fast and efficient two-step procedure, each of the porin genes was replaced by a single FRT site, which can be further used for site-specific integration. These results show that the Flp/FRT system is a suitable genetic tool for constructing unmarked mutations and for the analysis of redundant genes by consecutive gene deletions in M. smegmatis.     

A dual reporter screening system identifies the amino acid at position 82 in Flp site-specific recombinase as a determinant for target specificity

We have developed a dual reporter screen in Escherichia coli for identifying variants of the Flp site-specific recombinase that have acquired reactivity at an altered target site (mFRT). In one reporter, the lacZα gene segment is flanked by mFRTs in direct orientation. In the other, the red fluorescence protein (RFP) gene is flanked by the native FRTs. Hence, the color of a colony on an X-gal indicator plate indicates the recombination potential of the variant Flp protein expressed in it: blue if no recombination or only FRT recombination occurs, red if only mFRT recombination occurs and white if both FRT and mFRT recombinations occur. The scheme was validated by identification and in vivo characterization of Flp variants that show either relaxed specificity (active on FRT and mFRT) or moderately shifted specificity toward mFRT. We find that alteration of Lys-82 to Met, Thr, Arg or His enables the corresponding Flp variants to recombine FRT sites as well as altered FRT sites containing a substitution of G-C by C-G at position 1 of the Flp binding element (mFRT11). In contrast, wild-type Flp has no detectable activity on mFRT11. When Lys-82 is replaced by Tyr, the resulting Flp variant shows a small but reproducible preference for mFRT11 over FRT. However, this preference for mFRT11 is nearly lost when Tyr-82 is substituted by Phe.     

The TadV protein of Actinobacillus actinomycetemcomitans is a novel aspartic acid prepilin peptidase required for maturation of the Flp1 pilin and TadE and TadF pseudopilins

The tad locus of Actinobacillus actinomycetemcomitans encodes genes for the biogenesis of Flp pili, which allow the bacterium to adhere tenaciously to surfaces and form strong biofilms. Although tad (tight adherence) loci are widespread among bacterial and archaeal species, very little is known about the functions of the individual components of the Tad secretion apparatus. Here we characterize the mechanism by which the pre-Flp1 prepilin is processed to the mature pilus subunit. We demonstrate that the tadV gene encodes a prepilin peptidase that is both necessary and sufficient for proteolytic maturation of Flp1. TadV was also found to be required for maturation of the TadE and TadF pilin-like proteins, which we term pseudopilins. Using site-directed mutagenesis, we show that processing of pre-Flp1, pre-TadE, and pre-TadF is required for biofilm formation. Mutation of a highly conserved glutamic acid residue at position +5 of Flp1, relative to the cleavage site, resulted in a processed pilin that was blocked in assembly. In contrast, identical mutations in TadE or TadF had no effect on biofilm formation, indicating that the mechanisms by which Flp1 pilin and the pseudopilins function are distinct. We also determined that two conserved aspartic acid residues in TadV are critical for function of the prepilin peptidase. Together, our results indicate that the A. actinomycetemcomitans TadV protein is a member of a novel subclass of nonmethylating aspartic acid prepilin peptidases.     

Generation of a conditional lima1a allele in zebrafish using the FLEx switch technology

Gene trapping has emerged as a valuable tool to create conditional alleles in various model organisms. Here we report the FLEx‐based gene trap vector SAGFLEx that allows the generation of conditional mutations in zebrafish by gene‐trap mutagenesis. The SAGFLEx gene‐trap cassette comprises the rabbit β‐globin splice acceptor and the coding sequence of GFP, flanked by pairs of inversely oriented heterotypic target sites for the site‐specific recombinases Cre and Flp. Insertion of the gene‐trap cassette into endogenous genes can result in conditional mutations that are stably inverted by Cre and Flp, respectively. To test the functionality of this system we performed a pilot screen and analyzed the insertion of the gene‐trap cassette into the lima1a gene locus. In this lima1a allele, GFP expression faithfully recapitulated the endogenous lima1a expression and resulted in a complete knockout of the gene in homozygosity. Application of either Cre or Flp was able to mediate the stable inversion of the gene trap cassette and showed the ability to conditionally rescue or reintroduce the gene inactivation. Combined with pharmacologically inducible site specific recombinases the SAGFLEx vector insertions will enable precise conditional knockout studies in a spatial‐ and temporal‐controlled manner. genesis 54:19–28, 2016. © 2015 Wiley Periodicals, Inc.     

flp-1, the first representative of a new pilin gene subfamily, is required for non-specific adherence of Actinobacillus actinomycetemcomitans

Actinobacillus actinomycetemcomitans, a Gram-negative bacterium responsible for localized juvenile periodontitis and other infections such as endocarditis, produces long fibrils of bundled pili that are believed to mediate non-specific, tenacious adherence to surfaces. Previous investigations have implicated an abundant, small ( approximately 6.5 kDa), fibril-associated protein (Flp/Fap) as the primary fibril subunit. Here, we report studies on fibril structure and on the function and evolution of Flp. High-resolution electron microscopy of adherent clinical strain CU1000N revealed long bundles of 5- to 7-nm-diameter pili, whose subunits appear to be arranged in a helical array similar to that observed for type IV pili in other bacteria. Fibrils were found to be associated with the bacterial cell surface and smaller structures thought to be membrane vesicles. A modified version of the CU1000N Flp1 polypeptide with the T7-TAG epitope fused to its C-terminus was expressed in the wild-type strain, and the presence of the modified Flp1 in fibrils was confirmed by immunogold electron microscopy with monoclonal antibody to T7-TAG. To determine the importance of Flp1 in fibril formation and cell adherence, we used transposon IS903phikan to isolate insertion mutations in the flp-1 gene (formerly designated flp). Mutants with insertions early in flp-1 fail to produce fibrils and do not adhere to surfaces. Both fibril production and adherence were restored by cloned flp-1 in trans, thus providing the first evidence that flp-1 is required for fibril formation and tight, non-specific adherence. One mutant was found to have an insertion near the 3' end of flp-1 that results in the expression of a truncated and altered C-terminus of Flp1. This mutant produced short, unbundled pili, and its adherence to surfaces was significantly less than that of wild-type bacteria. These findings and related observations with the Flp1-T7-TAG protein indicate that the C-terminus of Flp1 is important for the bundling and adherence properties of pili. Extensive sequence comparisons and phylogenetic analysis of 61 predicted prepilin genes of bacteria revealed flp-1 to be a member of a novel and widespread subfamily of type IV prepilin genes. Thus, Flp pili are likely to be expressed by diverse bacterial species. Furthermore, we found that it is common for bacterial genomes to contain multiple alleles of flp-like genes, including the open reading frame (flp-2, previously designated orfA) immediately downstream of flp-1 in A. actinomycetemcomitans. The duplication and divergence of flp genes in bacteria may be important to the diversification of the colonization properties of these organisms.     

Expression of ferritin-like protein in Listeria monocytogenes after cold and freezing stress

The cold shock protein family consists of the transfer of the foodborne pathogen Listeria monocytogenes from 37 to 4 and ?20?°C and was characterized by the sharp induction of a low molecular mass protein. This major cold shock protein ferritin-like protein (Flp) has an important role in regulation of various microbial physiological processes. Flp have a molecular mass of about 18?kDa, as observed on SDS?CPAGE. The purification procedure including ammonium sulfate fractionation was used. Monospecific polyclonal antibodies raised in rabbits against the purified new Flp immunostained a single 18-kDa Flp band in extracts from different cytoplasmic proteins blotted onto nitrocellulose. A 411-bp cDNA fragment that corresponds to an internal region of an flp gene was obtained by RT-PCR. Our result indicated a surexpression of major cold shock protein and an important increase in flp mRNA amount after a downshift temperature especially at ?20?°C.     

Genetic analysis of the requirement for flp-2, tadV, and rcpB in Actinobacillus actinomycetemcomitans biofilm formation

The tad locus of Actinobacillus actinomycetemcomitans encodes a molecular transport system required for tenacious, nonspecific adherence to surfaces and formation of extremely strong biofilms. This locus is dedicated to the biogenesis of Flp pili, which are required for colonization and virulence. We have previously shown that 11 of the 14 tad locus genes are required for adherence and Flp pilus production. Here, we present genetic and phylogenetic analyses of flp-2, tadV, and rcpB genes in biofilm formation. We show that tadV, predicted to encode prepilin peptidase, is required for adherence. In contrast, targeted insertional inactivation of flp-2, a gene closely related to the prepillin gene flp-1, did not abrogate biofilm formation. Expression studies did not detect Flp2-T7 protein under standard laboratory conditions. We present phylogenetic data showing that there is no significant evidence for natural selection in the available flp-2 sequences from A. actinomycetemcomitans, suggesting that flp-2 does not play a significant role in the biology of this organism. Mutants with insertions at the 3' end of rcpB formed biofilms equivalent to wild-type A. actinomycetemcomitans. Surprisingly, 5' end chromosomal insertion mutants in rcpB were obtained only when a wild-type copy of the rcpB gene was provided in trans or when the Tad secretion system was inactivated. Together, our results strongly suggest that A. actinomycetemcomitans rcpB is essential in the context of a functional tad locus. These data show three different phenotypes for the three genes.     

Expression of Flp Protein in a Baculovirus/Insect Cell System for Biotechnological Applications

The Saccharomyces cerevisiae Flp protein is a site-specific recombinase that recognizes and binds to the Flp recognition target (FRT) site, a specific sequence comprised of at least two inverted repeats separated by a spacer. Binding of four monomers of Flp is required to mediate recombination between two FRT sites. Because of its site-specific cleavage characteristics, Flp has been established as a genome engineering tool. Amongst others, Flp is used to direct insertion of genes of interest into eukaryotic cells based on single and double FRT sites. A Flp-encoding plasmid is thereby typically cotransfected with an FRT-harboring donor plasmid. Moreover, Flp can be used to excise DNA sequences that are flanked by FRT sites. Therefore, the aim of this study was to determine whether Flp protein and its step-arrest mutant, FlpH305L, recombinantly expressed in insect cells, can be used for biotechnological applications. Using a baculovirus system, the proteins were expressed as C-terminally 3?×?FLAG-tagged proteins and were purified by anti-FLAG affinity selection. As demonstrated by electrophoretic mobility shift assays (EMSAs), purified Flp and FlpH305L bind to FRT-containing DNA. Furthermore, using a cell assay, purified Flp was shown to be active in recombination and to mediate efficient insertion of a donor plasmid into the genome of target cells. Thus, these proteins can be used for applications such as DNA-binding assays, in vitro recombination, or genome engineering.     

Establishment of a pig fibroblast-derived cell line for locus-directed transgene expression in cell cultures and blastocysts

We report the establishment of a spontaneously immortalized pig cell line designated Pig Flip-in Visualize (PFV) for locus-directed transgene expression in pig cells and blastocysts. The PFV cell line was isolated from pig ear fibroblasts transfected with a Sleeping Beauty DNA transposon-based docking vector harbouring a selection gene, an eGFP reporter gene, and an Flp recombinase site for locus-directed gene insertion. PFV cells have insertion of a single docking vector with stable eGFP expression and generated phenotypic normal blastocysts with transgene expression after somatic cell nuclear transfer. PFV cells supported Flp mediated cassette exchange for transgene substitution of eGFP with dsRED, and the dsRED transgenic PFV cells generated blastocysts with transgene expression. Hence, the PFV cell line constitutes a valuable pig equivalent to transformed cell lines from other mammalian species suitable for locus-directed transgene expression in cell cultures and, in addition, for transgene analyses in the very early embryonic stages.     

Bending-incompetent variants of Flp recombinase mediate strand transfer in half-site recombinations: role of DNA bending in recombination.

One key feature of the interaction of Flp recombinase with its target site (FRT) is the large bend introduced in the substrate as a result of protein binding. The extent of bending was found to depend on the phasing and spacing of the Flp monomers occupying the two Flp-binding elements (FBE) bordering the strand-exchange region (spacer) of the substrate. The relative mobilities of the Flp complexes formed by the two permuted substrate fragments, containing the FRT site near the end or in the middle, corresponded to a DNA bend of approx. 140 degrees when each of the two FBEs flanking the spacer was occupied by a protein monomer. The estimated bend angle was the same when the reference DNA fragment with the FRT site at the end was substituted by one with the site in the middle, but containing a 4-bp insertion within the spacer. We used a combination of wild-type Flp and Flp variants that were competent or incompetent in DNA bending, together with full, or half FRT sites, to ask whether bending is a conformational requirement for catalysis, namely cleavage and exchange of strands. We obtained the following results: in full-site (FRT) vs. full-site recombinations or in full-site vs. half-site (half FRT) recombinations, there was a large difference in the reactivity between Flp and a bending-incompetent Flp variant. This difference virtually disappeared when reactions were done with half-FRT sites. We conclude that bending is not a prerequisite for catalysis, but represents the manner in which the substrate accommodates the Flp protomer-protomer interactions that are pertinent to catalysis.     

Tyr60 variants of Flp recombinase generate conformationally altered protein-DNA complexes. Differential activity in full-site and half-site recombinations

The tyrosine at position 60 of the Flp recombinase of the Saccharomyces cerevisiae plasmid, 2 mu circle, is invariant among site-specific recombinases of the "yeast plasmid family". Alterations of this residue give rise to Flp variants that show no recombination activity when assayed in vivo in Escherichia coli. Upon purification, they bind substrate, execute DNA cleavage and catalyze recombination. The efficiency of strand cleavage follows the order: Flp(Y60F) greater than Flp greater than Flp(Y60S) greater than Flp(Y60D); efficiency of recombination between Flp sites on a linear substrate and a circular one follows the order: Flp greater than Flp(Y60F) greater than Flp(Y60S) greater than Flp(Y60D). Methylation footprints of the DNA-protein complexes formed by two of the Flp variants, Flp(Y60S) and Flp(Y60D), do not show hypermethylation of the G residues within the substrate core that is characteristic of complexes formed by wild-type Flp. The third variant, Flp(Y60F), causes significant distortion (although less than wild-type Flp) of the substrate core, as indicated by enhanced G-methylation. Binding profiles with circularly permuted substrates indicate that Flp(Y60S) and Flp(Y60D), but not Flp(Y60F), are defective in bending substrate DNA. In recombination between two Flp half-sites, the variant proteins are significantly more active than in normal full-site recombination.     

Recombination of hybrid target sites by binary combinations of Flp variants: mutations that foster interprotomer collaboration and enlarge substrate tolerance

Strategies of directed evolution and combinatorial mutagenesis applied to the Flp site-specific recombinase have yielded recombination systems that utilize bi-specific hybrid target sites. A hybrid site is assembled from two half-sites, each harboring a distinct binding specificity. Satisfying the two specificities by a binary combination of Flp variants, while necessary, may not be sufficient to elicit recombination. We have identified amino acid substitutions that foster interprotomer collaboration between partner Flp variants to potentiate strand exchange in hybrid sites. One such substitution, A35T, acts specifically in cis with one of the two partners of a variant pair, Flp(K82M) and Flp(A35T, R281V). The same A35T mutation is also present within a group of mutations that rescue a Flp variant, Flp(Y60S), that is defective in establishing monomer-monomer interactions on the native Flp target site. Strikingly, these mutations are localized to peptide regions involved in interdomain and interprotomer interactions within the recombination complex. The same group of mutations, when transferred to the context of wild-type Flp, can relax its specificity to include non-native target sites. The hybrid Flp systems described here mimic the naturally occurring XerC/XerD recombination system that utilizes two recombinases with distinct DNA binding specificities. The ability to overcome the constraints of binding site symmetry in Flp recombination has important implications in the targeted manipulations of genomes.     

Functional analysis of Arg-308 mutants of Flp recombinase. Possible role of Arg-308 in coupling substrate binding to catalysis

The arginine residue at position 308 in the Flp recombinase corresponds to the only invariant arginine within the Int family of recombinases. Alterations of this residue result in Flp variants that retain substrate recognition, but form weaker protein-DNA complexes than wild type Flp. Furthermore, their DNA cleavage activity is significantly diminished. A conservative change of R308K results in a functional Flp variant; however, this protein has a lowered temperature optimum for recombination. The Arg-308 mutants can be stabilized on the DNA substrate through cooperativity with a partner Flp mutant that is tight binding. Thus, interactions between Flp monomers must be a relevant feature of the normal recombination reaction.     

The Flp recombinase cleaves Holliday junctions in trans

The Flp site-specific recombinase is encoded by the 2 µm plasmid of Saccharomyces cerevisiae and is a member of the integrase family of recombinases. Like all members of the integrase family studied, Flp mediates recombination in two steps. First, a pair of strand exchanges creates a Holliday-like intermediate; second, this intermediate is resolved to recombinant products by a second pair of strand exchanges.
Evidence derived from experiments using linear substrates indicates that Flp's active site is composed of two Flp protomers. One binds to the Flp recognition target site (FRT site) and activates the scissile phosphodiester bond for cleavage. Another molecule of Flp bound elsewhere in the synaptic complex ( in trans ) donates the nucleophilic tyrosine that executes cleavage and thereby becomes covalently attached to the 3' phosphoryl group at the cleavage site.
It has previously been shown that Flp efficiently resolves synthetic, Holliday-like (χ) structures to linear products. In this paper, we examined whether resolution of χ structures by Flp also occurs via the trans cleavage mechanism. We used in vitro complementation studies of mutant Flp proteins as well as nicked χ structures to show that Flp resolves χ structures by trans cleavage. We propose a model for Flp-mediated recombination that incorporates trans cleavage at both the initial and resolution steps of strand exchange.