Sequence of the site-specific recombinase gene cin and of its substrates serving in the inversion of the C segment of bacteriophage P1

The Role of O-antigen in P1 Transduction of Shigella flexneri and Escherichia coli with its Alternative S' Tail Fibre

Enterobacteria phage P1 expresses two types of tail fibre, S and S'. Despite the wide usage of phage P1 for transduction, the host range and the receptor for its alternative S' tail fibre was never determined. Here, a ΔS-cin Δpac E. coli P1 lysogenic strain was generated to allow packaging of phagemid DNA into P1 phage having either S or S' tail fibre. P1(S') could transduce phagemid DNA into Shigella flexneri 2a 2457O, Shigella flexneri 5a M90T and Escherichia coli O3 efficiently. Mutational analysis of the O-antigen assembly genes and LPS inhibition assays indicated that P1(S') transduction requires at least one O-antigen unit. E. coli O111:B4 LPS produced a high neutralising effect against P1(S') transduction, indicating that this E. coli strain could be susceptible to P1(S')-mediated transduction. Mutations in the O-antigen modification genes of S. flexneri 2a 2457O and S. flexneri 5a M90T did not cause significant changes to P1(S') transduction efficiency. A higher transduction efficiency of P1(S') improved the delivery of a cas9 antimicrobial phagemid into both S. flexneri 2457O and M90T. These findings provide novel insights into P1 tropism-switching, by identifying the bacterial strains which are susceptible to P1(S')-mediated transduction, as well as demonstrating its potential for delivering a DNA sequence-specific Cas9 antimicrobial into clinically relevant S. flexneri.

Bacteriophage P1 does not show spatial preference when infecting Escherichia coli

To begin its infection, a bacteriophage first needs to adsorb to cells. The adsorption site on the cell surface may influence viral DNA injection, gene expression and cell-fate development. Here, we study the early steps of the infection cycle of coliphage P1, focusing on their correlation with spatial locations at the single-cell level. By fluorescently labeling P1 virions, we found that P1 shows no spatial preference on cell surface adsorption. In addition, live-cell phage DNA imaging revealed that adsorption sites do not affect the success rate for P1 in injecting its DNA into the cell. Furthermore, the lysis-lysogeny decision of P1 does not depend on the adsorption site, based on fluorescence reporters for the lytic and lysogenic pathways. These findings highlight the different infection strategies used by the two paradigmatic coliphages differ from those found in the paradigmatic phage lambda, highlighting that different infection strategies are used by phages.

Site-specific DNA Inversion by Serine Recombinases

Reversible site-specific DNA inversion reactions are widely distributed in bacteria and their viruses. They control a range of biological reactions that most often involve alterations of molecules on the surface of cells or phage. These programmed DNA rearrangements usually occur at a low frequency, thereby preadapting a small subset of the population to a change in environmental conditions, or in the case of phages, an expanded host range. A dedicated recombinase, sometimes with the aid of additional regulatory or DNA architectural proteins, catalyzes the inversion of DNA. RecA or other components of the general recombination-repair machinery are not involved. This chapter discusses site-specific DNA inversion reactions mediated by the serine recombinase family of enzymes and focuses on the extensively studied serine DNA invertases that are stringently controlled by the Fis-bound enhancer regulatory system. The first section summarizes biological features and general properties of inversion reactions by the Fis/enhancer-dependent serine invertases and the recently described serine DNA invertases in Bacteroides. Mechanistic studies of reactions catalyzed by the Hin and Gin invertases are then discussed in more depth, particularly with regards to recent advances in our understanding of the function of the Fis/enhancer regulatory system, the assembly of the active recombination complex (invertasome) containing the Fis/enhancer, and the process of DNA strand exchange by rotation of synapsed subunit pairs within the invertasome. The role of DNA topological forces that function in concert with the Fis/enhancer controlling element in specifying the overwhelming bias for DNA inversion over deletion and intermolecular recombination is emphasized.

A structured annotation frame for the transposable phages: a new proposed family "Saltoviridae" within the Caudovirales

Enterobacteriophage Mu is the best studied and paradigm member of the transposable phages. Mu-encoded proteins have been annotated in detail in UniProtKB and linked to a controlled vocabulary describing the various steps involved in the phage lytic and lysogenic cycles. Transposable phages are ubiquitous temperate bacterial viruses with a dsDNA linear genome. Twenty-six of them, that infect α, β and γ-proteobacteria, have been sequenced. Their conserved properties are described. Based on these characteristics, we propose a reorganization of the Caudovirales, to allow for the inclusion of a "Saltoviridae" family and two newly proposed subfamilies, the "Myosaltovirinae" and "Siphosaltovirinae". The latter could temporarily be included in the existing Myoviridae and Siphoviridae families.

Scalable plasmid transfer using engineered P1-based phagemids

Dramatic improvements to computational, robotic, and biological tools have enabled genetic engineers to conduct increasingly sophisticated experiments. Further development of biological tools offers a route to bypass complex or expensive mechanical operations, thereby reducing the time and cost of highly parallelized experiments. Here, we engineer a system based on bacteriophage P1 to transfer DNA from one E. coli cell to another, bypassing the need for intermediate DNA isolation (e.g., minipreps). To initiate plasmid transfer, we refactored a native phage element into a DNA module capable of heterologously inducing phage lysis. After incorporating known cis-acting elements, we identified a novel cis-acting element that further improves transduction efficiency, exemplifying the ability of synthetic systems to offer insight into native ones. The system transfers DNAs up to 25 kilobases, the maximum assayed size, and operates well at microliter volumes, enabling manipulation of most routinely used DNAs. The system's large DNA capacity and physical coupling of phage particles to phagemid DNA suggest applicability to biosynthetic pathway evolution, functional proteomics, and ultimately, diverse molecular biology operations including DNA fabrication.

Haloarchaeal myovirus φCh1 harbours a phase variation system for the production of protein variants with distinct cell surface adhesion specificities

The φCh1 myovirus, which infects the haloalkaliphilic archaeon Natrialba magadii, contains an invertible region that comprises the convergent open reading frames (ORFs) 34 and 36, which code for the putative tail fibre proteins gp34 and gp36 respectively. The inversion leads to an exchange of the C-termini of these proteins, thereby creating different types of tail fibres. Gene expression experiments revealed that only ORF34 is transcribed, indicating that φCh1 produces tail fibre proteins exclusively from this particular ORF. Only one of the two types of tail fibres encoded by ORF34 is able to bind to Nab. magadii in vitro. This is reflected by the observation that during the early phases of the infection cycle, the lysogenic strain L11 carries its invertible region exclusively in the orientation that produces that specific type of tail fibre. Obviously, Nab. magadii can only be infected by viruses carrying this particular type of tail fibre. By mutational analysis, the binding domain of gp34 was localized to the C-terminal part of the protein, particularly to a galactose-binding domain. The involvement of galactose residues in cell adhesion was supported by the observation that the addition of α-D-galactose to purified gp34 or whole virions prevented their attachment to Nab. magadii.

Genomic analysis and relatedness of P2-like phages of the Burkholderia cepacia complex

Background

The Burkholderia cepacia complex (BCC) is comprised of at least seventeen Gram-negative species that cause infections in cystic fibrosis patients. Because BCC bacteria are broadly antibiotic resistant, phage therapy is currently being investigated as a possible alternative treatment for these infections. The purpose of our study was to sequence and characterize three novel BCC-specific phages: KS5 (vB_BceM-KS5 or vB_BmuZ-ATCC 17616), KS14 (vB_BceM-KS14) and KL3 (vB_BamM-KL3 or vB_BceZ-CEP511).

Results

KS5, KS14 and KL3 are myoviruses with the A1 morphotype. The genomes of these phages are between 32317 and 40555 base pairs in length and are predicted to encode between 44 and 52 proteins. These phages have over 50% of their proteins in common with enterobacteria phage P2 and so can be classified as members of the Peduovirinae subfamily and the "P2-like viruses" genus. The BCC phage proteins similar to those encoded by P2 are predominantly structural components involved in virion morphogenesis. As prophages, KS5 and KL3 integrate into an AMP nucleosidase gene and a threonine tRNA gene, respectively. Unlike other P2-like viruses, the KS14 prophage is maintained as a plasmid. The P2 E+E' translational frameshift site is conserved among these three phages and so they are predicted to use frameshifting for expression of two of their tail proteins. The lysBC genes of KS14 and KL3 are similar to those of P2, but in KS5 the organization of these genes suggests that they may have been acquired via horizontal transfer from a phage similar to λ. KS5 contains two sequence elements that are unique among these three phages: an ISBmu2-like insertion sequence and a reverse transcriptase gene. KL3 encodes an EcoRII-C endonuclease/methylase pair and Vsr endonuclease that are predicted to function during the lytic cycle to cleave non-self DNA, protect the phage genome and repair methylation-induced mutations.

Conclusions

KS5, KS14 and KL3 are the first BCC-specific phages to be identified as P2-like. As KS14 has previously been shown to be active against Burkholderia cenocepacia in vivo, genomic characterization of these phages is a crucial first step in the development of these and similar phages for clinical use against the BCC.

CTX-M-10 linked to a phage-related element is widely disseminated among Enterobacteriaceae in a Spanish hospital

CTX-M-10 has been widely disseminated among multiple clones of several species of Enterobacteriaceae, harboring seemingly different plasmids, for over a decade in Ramón y Cajal University Hospital, Madrid, Spain. Cloning and sequencing of a 12.2-kb DNA fragment from plasmid pRYCE21 from Klebsiella pneumoniae strain KP4aC revealed a novel phage-related element immediately upstream of bla(CTX-M-10) conserved among different CTX-M-10-producing strains. This is the first report showing an extended-spectrum-beta-lactamase gene linked to a phage-related element.

Genome of bacteriophage P1

P1 is a bacteriophage of Escherichia coli and other enteric bacteria. It lysogenizes its hosts as a circular, low-copy-number plasmid. We have determined the complete nucleotide sequences of two strains of a P1 thermoinducible mutant, P1 c1-100. The P1 genome (93,601 bp) contains at least 117 genes, of which almost two-thirds had not been sequenced previously and 49 have no homologs in other organisms. Protein-coding genes occupy 92% of the genome and are organized in 45 operons, of which four are decisive for the choice between lysis and lysogeny. Four others ensure plasmid maintenance. The majority of the remaining 37 operons are involved in lytic development. Seventeen operons are transcribed from sigma(70) promoters directly controlled by the master phage repressor C1. Late operons are transcribed from promoters recognized by the E. coli RNA polymerase holoenzyme in the presence of the Lpa protein, the product of a C1-controlled P1 gene. Three species of P1-encoded tRNAs provide differential controls of translation, and a P1-encoded DNA methyltransferase with putative bifunctionality influences transcription, replication, and DNA packaging. The genome is particularly rich in Chi recombinogenic sites. The base content and distribution in P1 DNA indicate that replication of P1 from its plasmid origin had more impact on the base compositional asymmetries of the P1 genome than replication from the lytic origin of replication.

Inversion within the haloalkaliphilic virus φCh1 DNA results in differential expression of structural proteins

The sequence of phi Ch1 contains an open reading frame (int1) in the central part of its genome that belongs to the lambda integrase family of site-specific recombinases. Sequence similarities to known integrases include the highly conserved tetrad R-H-R-Y. The flanking sequences of int1 contain several direct repeats of 30 bp in length (IR-L and IR-R), which are orientated in an inverted direction. Here, we show that a recombination active region exists in the genome of phi Ch1: the number of those repeats, non-homologous regions within the repeat clusters IR-L and IR-R and the orientation of the int1 gene vary in a given virus population. Within this study, we identified circular intermediates, composed of the int1 gene and the inwards orientated repeat regions IR-L and IR-R, which could be involved in the recombination process itself. IR-L and IR-R are embedded within ORF34 and ORF36 respectively. As a consequence of the inversion within this region of phi Ch1, the C-terminal parts of the proteins encoded by ORF34 and 36 are exchanged. Both proteins, expressed in Escherichia coli, interact with specific antisera against whole virus particles, indicating that they could be parts of phi Ch1 virions. Expression of the protein(s) in Natrialba magadii could be detected 98 h after inoculation, which is similar to other structural proteins of phi Ch1. Taken together, the data show that the genome of phi Ch1 contains an invertible region that codes for a recombinase and structural proteins. Inversion of this segment results in a variation of these structural proteins.

Multiple inverted DNA repeats of Bacteroides fragilis that control polysaccharide antigenic variation are similar to the hin region inverted repeats of Salmonella typhimurium

The important opportunistic pathogen Bacteroides fragilis is a strictly anaerobic Gram-negative bacterium and a member of the normal resident human gastrointestinal microbiota. Our earlier studies indicated that there is considerable within-strain variation in polysaccharide expression, as detected by mAb labelling. Analysis of the genome sequence has revealed multiple invertible DNA regions, designated fragilis invertible (fin) regions, seven of which are upstream of polysaccharide biosynthesis loci and are approximately 226 bp in size. Using orientation-specific PCR primers and sequence analysis with populations enriched for one antigenic type, two of these invertible regions were assigned to heteropolymeric polysaccharides with different sizes of repeating units, as determined by PAGE pattern. The implication of these findings is that inversion of the fin regions switches biosynthesis of these polysaccharides off and on. The invertible regions are bound by inverted repeats of 30 or 32 bp with striking similarity to the Salmonella typhimurium H flagellar antigen inversion cross-over (hix) recombination sites of the invertible hin region. It has been demonstrated that a plasmid-encoded Hin invertase homologue (FinB), present in B. fragilis NCTC 9343, binds specifically to the invertible regions and the recombination sites have been designated as fragilis inversion cross-over (fix) sites.

DNA inversion in the tail fiber gene alters the host range specificity of carotovoricin Er, a phage-tail-like bacteriocin of phytopathogenic Erwinia carotovora subsp. carotovora Er

Carotovoricin Er is a phage-tail-like bacteriocin produced by Erwinia carotovora subsp. carotovora strain Er, a causative agent for soft rot disease in plants. Here we studied binding and killing spectra of carotovoricin Er preparations for various strains of the bacterium (strains 645Ar, EC-2, N786, and P7) and found that the preparations contain two types of carotovoricin Er with different host specificities; carotovoricin Era possessing a tail fiber protein of 68 kDa killed strains 645Ar and EC-2, while carotovoricin Erb with a tail fiber protein of 76 kDa killed strains N786 and P7. The tail fiber proteins of 68 and 76 kDa had identical N-terminal amino acid sequences for at least 11 residues. A search of the carotovoricin Er region in the chromosome of strain Er indicated the occurrence of a DNA inversion system for the tail fiber protein consisting of (i) two 26-bp inverted repeats inside and downstream of the tail fiber gene that flank a 790-bp fragment and (ii) a putative DNA invertase gene with a 90-bp recombinational enhancer sequence. In fact, when a 1,400-bp region containing the 790-bp fragment was amplified by a PCR using the chromosomal DNA of strain Er as the template, both the forward and the reverse nucleotide sequences of the 790-bp fragment were detected. DNA inversion of the 790-bp fragment also occurred in Escherichia coli DH5alpha when two compatible plasmids carrying either the 790-bp fragment or the invertase gene were cotransformed into the bacterium. Furthermore, hybrid carotovoricin CGE possessing the tail fiber protein of 68 or 76 kDa exhibited a host range specificity corresponding to that of carotovoricin Era or Erb, respectively. Thus, a DNA inversion altered the C-terminal part of the tail fiber protein of carotovoricin Er, altering the host range specificity of the bacteriocin.

Campylobacter fetus uses multiple loci for DNA inversion within the 5' conserved regions of sap homologs

Campylobacter fetus cells possess multiple promoterless sap homologs, each capable of expressing a surface layer protein (SLP) by utilizing a unique promoter present on a 6.2-kb invertible element. Each sap homolog includes a 626-bp 5' conserved region (FCR) with 74 bp upstream and 552 bp within the open reading frame. After DNA inversion, the splice is seamless because the FCRs are identical. In mutant strain 23D:ACA2K101, in which sapA and sapA2 flanking the invertible element in opposite orientations were disrupted by promoterless chloramphenicol resistance (Cm(r)) and kanamycin resistance (Km(r)) cassettes, respectively, the frequency of DNA inversion is 100-fold lower than that of wild-type strain 23D. To define the roles of a 15-bp inverted repeat (IR) and a Chi-like site (CLS) in the FCR, we mutagenized each upstream of sapA2 in 23D:ACA2K101 by introducing NotI and KpnI sites to create strains 23D:ACA2K101N and 23D:ACA2K101K, respectively. Alternatively selecting colonies for Cm(r) or Km(r) showed that mutagenizing the IR or CLS had no apparent effect on the frequency of the DNA inversion. However, mapping the unique NotI or KpnI site in relation to the Cm(r) or Km(r) cassette in the cells that changed phenotype showed that splices occurred both upstream and downstream of the mutated sites. PCR and sequence analyses also showed that the splice could occur in the 425-bp portion of the FCR downstream of the cassettes. In total, these data indicate that C. fetus can use multiple sites within the FCR for its sap-related DNA inversion.

Accessory genes in the darA operon of bacteriophage P1 affect antirestriction function, generalized transduction, head morphogenesis, and host cell lysis

Bacteriophage P1 mutants with the 8.86-kb region between the invertible C-segment and the residential IS1 element deleted from their genome are still able to grow vegetatively and to lysogenize stably, but they show several phenotypic changes. These include the formation of minute plaques due to delayed cell lysis, the abundant production of small-headed particles, a lack of specific internal head proteins, sensitivity to type I host restriction systems, and altered properties to mediate generalized transduction. In the wild-type P1 genome, the accessory genes encoding the functions responsible for these characters are localized in the darA operon that is transcribed late during phage production. We determined the relevant DNA sequence that is located between the C-segment and the IS1 element and contains the cin gene for C-inversion and the accessory genes in the darA operon. The darA operon carries eight open reading frames that could encode polypeptides containing >100 amino acids. Genetic studies indicate that some of these open reading frames, in particular those residing in the 5' part of the darA operon, are responsible for the phenotypic traits identified. The study may contribute to a better comprehension of phage morphogenesis, of the mobilization of host DNA into phage particles mediating generalized transduction, of the defense against type I restriction systems, and of the control of host lysis.

Genome plasticity in the distal tail fiber locus of the T-even bacteriophage: recombination between conserved motifs swaps adhesin specificity

The adsorption specificity of the T-even phages is determined by the protein sequence near the tip of the long tail fibers. These adhesin sequences are highly variable in both their sequence and specificity for bacterial receptors. The tail fiber adhesin domains are located in different genes in closely related phages of the T-even type. In phage T4, the adhesin sequence is encoded by the C-terminal domain of the large tail fiber gene (gene 37), but in T2, the adhesin is a separate gene product (gene 38) that binds to the tip of T2 tail fibers. Analysis of phage T6 and Ac3 sequences reveals additional variant forms of this locus. The tail fiber host specificity determinants can be exchanged, although the different loci have only limited homology. Chimeric fibers can be created by crossovers either between small homologies within the structural part of the fiber gene or in conserved motifs of the adhesin domain. For example, the T2 adhesin determinants are flanked by G-rich DNA motifs and exchanges involving these sequences can replace the specificity determinants. These features of the distal tail fiber loci genetically link their different forms and can mediate acquisition of diverse host range determinants, including those that allow it to cross species boundaries and infect taxonomically distant hosts.

Nested DNA inversion of Campylobacter fetus S-layer genes is recA dependent

Wild-type strains of Campylobacter fetus are covered by a monomolecular array of surface layer proteins (SLPs) critical for virulence. Each cell possesses eight SLP gene cassettes, tightly clustered in the genome, that encode SLPs of 97 to 149 kDa. Variation of SLP expression occurs by a mechanism of nested DNA rearrangement that involves the inversion of a 6.2-kb sapA promoter-containing element alone or together with one or more flanking SLP gene cassettes. The presence of extensive regions of identity flanking the 5' and 3' ends of each SLP gene cassette and of a Chi-like recognition sequence within the 5' region of identity suggests that rearrangement of SLP gene cassettes may occur by a generalized (RecA-dependent) homologous recombination pathway. To explore this possibility, we cloned C. fetus recA and created mutant strains by marker rescue, in which recA is disrupted in either S+ or S- strains. These mutants then were assessed for their abilities to alter SLP expression either in the presence or absence of a complementary shuttle plasmid harboring native recA. In contrast to all previously reported programmed DNA inversion systems, inversion in C. fetus is recA dependent.

The resolvase/invertase domain of the site-specific recombinase TnpX is functional and recognizes a target sequence that resembles the junction of the circular form of the Clostridium perfringens transposon Tn4451

Tn4451 is a 6.3-kb chloramphenicol resistance transposon from Clostridium perfringens and is found on the conjugative plasmid pIP401. The element undergoes spontaneous excision from multicopy plasmids in Escherichia coli and C. perfringens and conjugative excision from pIP401 in C. perfringens. Tn4451 is excised as a circular molecule which is probably the transposition intermediate. Excision of Tn4451 is dependent upon the site-specific recombinase TnpX, which contains potential motifs associated with both the resolvase/invertase and integrase families of recombinases. Site-directed mutagenesis of conserved amino acid residues within these domains was used to show that the resolvase/invertase domain was essential for TnpX-mediated excision of Tn4451 from multicopy plasmids in E. coli. An analysis of Tn4451 target sites revealed that the transposition process showed target site specificity. The Tn4451 target sequence resembled the junction of the circular form, and insertion occurred at a GA dinucleotide. Tn4451 insertions were flanked by directly repeated GA dinucleotides, and there was also a GA at the junction of the circular form, where the left and right termini of Tn4451 were fused. We propose a model for Tn4451 excision and insertion in which the resolvase/invertase domain of TnpX introduces 2-bp staggered cuts at these GA dinucleotides. Analysis of Tn4451 derivatives with altered GA dinucleotides provided experimental evidence to support the model.

The site-specific recombinase encoded by pinD in Shigella dysenteriae is due to the presence of a defective Mu prophage

The DNA inversion systems are made up of an invertible DNA segment and a site-specific recombinase gene. Five systems are known in prokaryotes: the Salmonella typhimurium H segment and hin gene (H-hin), phage Mu G-gin, phage P1 C-cin, Escherichia coli e14 P-pin, and Shigella sonnei B-pinB systems. In this report a site-specific recombinase (pinD) gene of Shigella dysenteriae was cloned and sequenced. pinD mediated inversion of five known segments at the same extent in E. coli. Although one inv sequence was identified, no invertible region was detected in a cloned fragment. The predicted amino acid sequences of PinD and three ORFs showed high homology to those of Gin and its flanking gene products. An ORF homologous to Mom of Mu conserved a functional activity to modify intracellular plasmid DNA. Southern analysis showed that the cloned fragment contains two homologous regions corresponding to the left and right ends of the Mu genome. Together these results indicated that the pinD gene in S. dysenteriae is derived from a Mu-like prophage.

Integration of bacteriophage Mx8 into the Myxococcus xanthus chromosome causes a structural alteration at the C-terminal region of the IntP protein

Mx8 is a generalized transducing phage that infects Myxococcus xanthus cells. This phage is lysogenized in M. xanthus cells by the integration of its DNA into the host chromosome through site-specific recombination. Here, we characterize the mechanism of Mx8 integration into the M. xanthus chromosome. The Mx8 attachment site, attP, the M. xanthus chromosome attachment site, attB, and two phage-host junctions, attL and attR, were cloned and sequenced. Sequence alignments of attP, attB, attL, and attR sites revealed a 29-bp segment that is absolutely conserved in all four sequences. The intP gene of Mx8 was found to encode a basic protein that has 533 amino acids and that carries two domains conserved in site-specific recombinases of the integrase family. Surprisingly, the attP site was located within the coding sequence of the intP gene. Hence, the integration of Mx8 into the M. xanthus chromosome results in the conversion of the intP gene to a new gene designated intR. As a result of this conversion, the 112-residue C-terminal sequence of the intP protein is replaced with a 13-residue sequence. A 3-base deletion within the C-terminal region had no effect on Mx8 integration into the chromosome, while a frameshift mutation with the addition of 1 base at the same site blocked integration activity. This result indicates that the C-terminal region is required for the enzymatic function of the intP product.

Determinants of selectivity in Xer site-specific recombination

A remarkable property of some DNA-binding proteins that can interact with and pair distant DNA segments is that they mediate their biological function only when their binding sites are arranged in a specific configuration. Xer site-specific recombination at natural plasmid recombination sites (e.g., cer in ColE1) is preferentially intramolecular, converting dimers to monomers. In contrast, Xer recombination at the Escherichia coli chromosomal site dif can occur intermolecularly and intramolecularly. Recombination at both types of site requires the cooperative interactions of two related recombinases, XerC and XerD, with a 30-bp recombination core site. The dif core site is sufficient for recombination when XerC and XerD are present, whereas recombination at plasmid sites requires approximately 200 bp of adjacent accessory sequences and accessory proteins. These accessory factors ensure that recombination is intramolecular. Here we use a model system to show that selectivity for intramolecular recombination, and the consequent requirement for accessory factors, can arise by increasing the spacing between XerC- and XerD-binding sites from 6 to 8 bp. This reduces the affinity of the recombinases for the core site and changes the geometry of the recombinase/DNA complex. These changes are correlated with altered interactions of the recombinases with the core site and a reduced efficiency of XerC-mediated cleavage. We propose that the accessory sequences and proteins compensate for these changes and provide a nucleoprotein structure of fixed geometry that can only form and function effectively on circular molecules containing directly repeated sites.

Identification of a gene encoding a DNA invertase-like enzyme adjacent to the PaeR7I restriction-modification system

A gene encoding a DNA invertase-like enzyme was identified adjacent to the PaeR7I restriction-modification system (R-M), and was named paeR7IN (N for iNvertase). Sequence analysis revealed that this gene has the same polarity as the PaeR7IRM operon, and would encode a polypeptide of 21,506 Da. An amino-acid sequence similarity of 45-49% was found between the deduced protein product and various DNA invertases.

Cin-mediated recombination at secondary crossover sites on the Escherichia coli chromosome

The Cin recombinase is known to mediate DNA inversion between two wild-type cix sites flanking genetic determinants for the host range of bacteriophage P1. Cin can also act with low frequency at secondary (or quasi) sites (designated cixQ) that have lower homology to either wild-type site. An inversion tester sequence able to reveal novel operon fusions was integrated into the Escherichia coli chromosome, and the Cin recombinase was provided in trans. Among a total of 13 Cin-mediated inversions studied, three different cixQ sites had been used. In two rearranged chromosomes, the breakpoints of the inversions were mapped to cixQ sites in supB and ompA, representing inversions of 109 and 210 kb, respectively. In the third case, a 2.1-kb inversion was identified at a cixQ site within the integrated sequences. This derivative itself was a substrate for a second inversion of 1.5 kb between the remaining wild-type cix and still another cixQ site, thus resembling a reversion. In analogy to that which is known from DNA inversion on plasmids, homology of secondary cix sites to wild-type recombination sites is not a strict requirement for inversion to occur on the chromosome. The chromosomal rearrangements which resulted from these Cin-mediated inversions were quite stable and suffered no growth disadvantage compared with the noninverted parental strain. The mechanistic implications and evolutionary relevance of these findings are discussed.

DNA inversions in phages and bacteria

In certain phages and bacteria, there is a recombination system that specifically promotes the inversion of a DNA fragment. These inversion events appear to act as genetic switches allowing the alternate expression of different sets of genes which in general code for surface proteins. The mechanism of inversion in one class of inversion systems (Gin/Hin) has been studied in detail. It involves the formation of a highly specific nucleoprotein complex in which not only the two recombination sites and the DNA invertase participate but also a recombinational enhancer to which the DNA-bending protein Fis is bound.

DNA inversion regions Min of plasmid p15B and Cin of bacteriophage P1: evolution of bacteriophage tail fiber genes

Plasmid p15B and the genome of bacteriophage P1 are closely related, but their site-specific DNA inversion systems, Min and Cin, respectively, do not have strict structural homology. Rather, the complex Min system represents a substitution of a Cin-like system into an ancestral p15B genome. The substituting sequences of both the min recombinase gene and the multiple invertible DNA segments of p15B are, respectively, homologous to the pin recombinase gene and to part of the invertible DNA of the Pin system on the defective viral element e14 of Escherichia coli K-12. To map the sites of this substitution, the DNA sequence of a segment adjacent to the invertible segment in the P1 genome was determined. This, together with already available sequence data, indicated that both P1 and p15B had suffered various sequence acquisitions or deletions and sequence amplifications giving rise to mosaics of partially related repeated elements. Data base searches revealed segments of homology in the DNA inversion regions of p15B, e14, and P1 and in tail fiber genes of phages Mu, T4, P2, and lambda. This result suggest that the evolution of phage tail fiber genes involves horizontal gene transfer and that the Min and Pin regions encode tail fiber genes. A functional test proved that the p15B Min region carries a tail fiber operon and suggests that the alternative expression of six different gene variants by Min inversion offers extensive host range variation.

DNA sequences of the tail fiber genes of bacteriophage P2: evidence for horizontal transfer of tail fiber genes among unrelated bacteriophages

We have determined the DNA sequence of the bacteriophage P2 tail genes G and H, which code for polypeptides of 175 and 669 residues, respectively. Gene H probably codes for the distal part of the P2 tail fiber, since the deduced sequence of its product contains regions similar to tail fiber proteins from phages Mu, P1, lambda, K3, and T2. The similarities of the carboxy-terminal portions of the P2, Mu, ann P1 tail fiber proteins may explain the observation that these phages in general have the same host range. The P2 H gene product is similar to the products of both lambda open reading frame (ORF) 401 (stf, side tail fiber) and its downstream ORF, ORF 314. If 1 bp is inserted near the end of ORF 401, this reading frame becomes fused with ORF 314, creating an ORF that may represent the complete stf gene that encodes a 774-amino-acid-long side tail fiber protein. Thus, a frameshift mutation seems to be present in the common laboratory strain of lambda. Gene G of P2 probably codes for a protein required for assembly of the tail fibers of the virion. The entire G gene product is very similar to the products of genes U and U' of phage Mu; a region of these proteins is also found in the tail fiber assembly proteins of phages TuIa, TuIb, T4, and lambda. The similarities in the tail fiber genes of phages of different families provide evidence that illegitimate recombination occurs at previously unappreciated levels and that phages are taking advantage of the gene pool available to them to alter their host ranges under selective pressures.

A site-specific DNA inversion in Bacteroides plasmid pBF4 is influenced by the presence of the conjugal tetracycline resistance element

pBF4 is a 42-kb R plasmid from Bacteroides fragilis which transfers clindamycin resistance (Clr) independently of the chromosomal tetracycline resistance (Tcr) transfer element. We have found that this plasmid exists in two nonequimolar conformations, A and B. These forms differ by an inversion of approximately 11.5 kb which does not involve the repeated DNA sequences previously mapped on the plasmid. The presence of chromosomal tetracycline resistance conjugal elements influences the relative amounts of the two conformations: induction with tetracycline shifts the dominant form from B to A.

Site-specific recombinase genes in three Shigella subgroups and nucleotide sequences of a pinB gene and an invertible B segment from Shigella boydii

Inversional switching systems in procaryotes are composed of an invertible DNA segment and a site-specific recombinase gene adjacent to or contained in the segment. Four related but functionally distinct systems have previously been characterized in detail: the Salmonella typhimurium H segment-hin gene (H-hin), phage Mu G-gin, phage P1 C-cin, and Escherichia coli e14 P-pin. In this article we report the isolation and characterization of three new recombinase genes: pinB, pinD, and defective pinF from Shigella boydii, Shigella dysenteriae, and Shigella flexneri, respectively. The genes pinB and pinD were detected by the complementation of a hin mutation of Salmonella and were able to mediate inversion of the H, P, and C segments. pinB mediated H inversion as efficiently as the hin gene did and mediated C inversion with a frequency three orders of magnitude lower than that of the cin gene. pinD mediated inversion of H and P segments with frequencies ten times as high as those for the genes intrinsic to each segment and mediated C inversion with a frequency ten times lower than that for cin. Therefore, the pinB and pinD genes were inferred to be different from each other. The invertible B segment-pinB gene cloned from S. boydii is highly homologous to the G-gin in size, organization, and nucleotide sequence of open reading frames, but the 5' constant region outside the segment is quite different in size and predicted amino acid sequence. The B segment underwent inversion in the presence of hin, pin, or cin. The defective pinF gene is suggested to hae the same origin as P-pin on e14 by the restriction map of the fragment cloned from a Pin+ transductant that was obtained in transduction from S. flexneri to E. coli delta pin.

Characterization of the C operon transcript of bacteriophage Mu

Mu transcription occurs in three phases: early, middle, and late. Middle transcription occurs in the region of the C gene, which encodes the transactivator for late transcription. A middle promoter, Pm, was previously localized between 0.28 and 1.2 kilobase pairs upstream of C. We used S1 nuclease mapping with both unlabeled and radiolabeled capped RNAs from induced lysogens to characterize C transcription and identify its promoter. The C transcription initiation site was localized to a 4-base-pair region, approximately 740 base pairs upstream of C within the region containing Pm. Transcription of C was activated between 4 and 8 min after induction of cts and Cam lysogens and increased throughout the lytic cycle. Significant C transcription did not occur in replication-defective Aam lysogens. These kinetic and regulatory characteristics identify the C transcript as a middle RNA species and demonstrate that Pm is the C promoter. DNA sequence analysis of the Pm region showed a good -10, but poor -35, site homology to the Escherichia coli RNA polymerase consensus sequence. In addition, the sequence demonstrated that C is the distal gene in a middle operon containing several open reading frames. S1 mapping also showed an upstream transcript with a 3' end in the Pm region at a sequence strongly resembling a Rho-independent terminator. The regulatory characteristics of this RNA are consistent with this terminator, t9.2, being the early operon terminator.

Site-specific recombinations between direct and inverted res sites of Tn2501

The resolvase gene and the putative res site of Tn2501 are not closely related to any of the previously described resolution functions. In view of this divergence, we designed genetic experiments to confirm the localization of the res site. We analyzed the activity of the Tn2501-encoded resolvase on substrates containing either directly or invertedly repeated res sites. These experiments confirm the localization of the res site that was predicted from nucleotide sequence data and show that the Tn2501 resolvase promotes site-specific inversions in vivo.

Bacteriophage P1 tail-fibre and dar operons are expressed from homologous phage-specific late promoter sequences

Two plasmid systems, containing the easily assayable galK and lacZ functions, were employed to study the regulation of the bacteriophage P1 tail-fibre and dar operons. Various P1 DNA fragments carrying either the 5' end of lydA (the 1st gene in the dar operon) or the tail-fibre gene 19 precede the promoterless coding region of galK or were fused, in-frame, to the lacZ gene. In the presence of an induced P1 prophage, GalK and LacZ activities were both detected after a 20 to 30 minute lag period, indicating that the dar and tail-fibre operons are expressed from positively regulated, late promoters. The corresponding DNA operons are expressed from positively regulated, late promoters. The corresponding DNA region of the closely related p15B plasmid exhibits comparable promoter properties. Deletion analysis mapped the promoter of a gene 19-lacZ fusion to a DNA region upstream from gene R, an open reading frame that precedes the coding frame of gene 19. The tail-fibre gene thus forms the second gene in a three gene operon (genes R, 19 (S) and U). Sequence comparison between this promoter region, upstream sequences of the lydA gene and the corresponding portions of the p15B genome allowed the identification of a highly conserved 38 base-pair sequence, which most likely represents a P1-specific late promoter. This was confirmed by 5' mapping of P1 mRNA. Transcription of both the tail-fibre and dar operons is initiated at sites five and six base-pairs, respectively, downstream from the first conserved nucleotide of this sequence. The conserved motif consists of a standard Escherichia coli -10 region followed by a nine base-pair palindromic sequence located centrally about position -22.

Organization of the bacteriophage P1 tail-fibre operon

The revised sequence of a bacteriophage P1 DNA fragment containing the 5' end of the tail-fibre gene, gene 19, revealed that this gene is closely preceded by another open reading frame (ORF) of 432 bp. We have designated this ORF as gene R. The tail-fibre gene and gene R are transcriptionally and translationally coupled. Thus, the tail-fibre operon of bacteriophage P1 consists of three genes: gene R, gene 19 (or gene S) and gene U.

Participation of the hup gene product in site-specific DNA inversion in Escherichia coli

The closely related Escherichia coli genes hupA and hupB each encode a bacterial histone-like protein HU. We report here that DNA inversion mediated by hin, gin, pin and rci but not by cin is blocked in a hupA hupB double mutant, although inversions in these systems occur in the hupA or hupB single mutant as efficiently as in the wild-type strain. These findings show that HU protein participates in site-specific DNA inversion in E. coli and that only one subunit, either HU-1 or HU-2, is sufficient for this inversion.

A mutational analysis of the bacteriophage P1 cin recombinase gene: intragenic complementation

Bacteriophage P1 encodes a site-specific recombinase, Cin, which regulates the alternate expression of tail fibre genes by inverting a DNA segment. To define regions of Cin important for the recombination process, we have isolated and characterised 24 different mutations of the cin gene. Most of these mutations affected amino acids that are highly conserved in other related recombinases. Some of these mutants complement each other in vivo. This intragenic complementation could be due to the assembly of heteromers containing both mutant proteins, suggesting that the active enzyme is at least a dimer.

Random mutagenesis using degenerate oligodeoxyribonucleotides

An efficient method for random mutagenesis was applied to a 75-bp target sequence. The mutational changes in the target region are introduced by the technique of oligodeoxyribonucleotide(oligo)-directed, site-specific mutagenesis using mixtures of degenerate oligos. These are designed in such a way that they carry with a high probability randomly distributed substitutions, which are introduced into the oligos by utilizing appropriate concentrations of all four nucleotide precursors during each chain elongation step. These mixtures of degenerate oligos were hybridized to the appropriate M13-hybrid ss-template and then extended in vitro using PolIk. In order to avoid any bias artificially created by the Escherichia coli mismatch repair system, homoduplex molecules were synthesized in vitro according to the method of Taylor et al. [Nucleic Acids Res. 13 (1985) 8765-8785]. After transformation of the appropriate E. coli host, M13 plaques were randomly analysed by DNA sequencing. Using appropriate preparations of template DNA and oligos we attained mutagenesis efficiencies in the range of 20-50%. The analysis of 85 different mutants revealed that the distribution of the mutations is random and that all expected substitutions occur with about the same probability.

Nucleotide sequence of the rci gene encoding shufflon-specific DNA recombinase in the IncI1 plasmid R64: homology to the site-specific recombinases of integrase family

Shufflon is a novel type of DNA rearrangement in which four DNA segments are flanked by seven 19-bp repeat sequences. The site-specific recombination between any inverted repeats results in an inversion of the DNA segment(s) either independently or in groups. The recombination is mediated by a gene designated rci. We have determined the nucleotide sequence of the rci gene and found that it encodes a basic protein with 384 amino acid residues. The rci gene was fused with lacZ and its gene product was identified by Western blot analysis. The Rci protein shows regional homologies to the site-specific recombinases encoded by the bacteriophage genomes, including those of lambda, phi 80, P22, P2, 186, P4 and P1.

Pilin-gene phase variation of Moraxella bovis is caused by an inversion of the pilin genes

Moraxella bovis Epp63 can express either of two different pilin proteins, called alpha and beta. We have previously cloned and sequenced the beta-pilin gene and now report that DNAs isolated from bacteria expressing alpha pilin have hybridization patterns consistently different from those of bacteria expressing beta pilin. The phase variation between alpha- and beta-pilin gene expression appears to be associated with an inversion of about 2 kilobases of DNA, whose endpoints occur within the coding region of the expressed pilin gene. Comparisons of the beta-pilin gene sequence with those of well-studied bacterial inversion systems revealed a stretch of 58% sequence similarity (21 of 36 base pairs) between the left inverted repeat of the Salmonella typhimurium flagellar hin control region and the amino-terminal portion of the beta-pilin gene.

Purification and DNA-binding properties of FIS and Cin, two proteins required for the bacteriophage P1 site-specific recombination system, cin

An Escherichia coli chromosomally coded factor termed FIS (Factor for Inversion Stimulation) stimulates the Cin protein-mediated, site-specific DNA inversion system of bacteriophage P1 more than 500-fold. We have purified FIS and the recombinase Cin, and studied the inversion reaction in vitro. DNA footprinting studies with DNase I showed that Cin specifically binds to the recombination site, called cix. FIS does not bind to cix sites but does bind to a recombinational enhancer sequence that is required in cis for efficient recombination. FIS also binds specifically to sequences outside the enhancer, as well as to sequences unrelated to Cin inversion. On the basis of these data, we discuss the possibility of additional functions for FIS in E. coli.

Fis binding to the recombinational enhancer of the Hin DNA inversion system

The recombinational enhancer of the Hin inversion system in Salmonella stimulates recombination in vitro 150-fold in the presence of the Escherichia coli host factor Fis. To gain an understanding of the roles of the enhancer and Fis in stimulating the Hin-mediated inversion reaction, we have used nuclease and chemical protection/interference studies and gel retardation assays to examine the interactions between Fis and the recombinational enhancer. These studies combined with mutational analysis defined the enhancer sequences required for Fis binding and function. Fis binds with different affinities to two domains within the enhancer sequence. The binding of Fis at each domain is independent of the occupancy of the other domain and appears to be to opposite faces of the DNA helix. These results support a model for the role of the recombinational enhancer in Hin-mediated inversion in which the interaction between Hin bound at recombination sites and Fis bound to each domain of the recombinational enhancer results in a structure with the proper alignment and topology to promote DNA inversion.

Role of the central dinucleotide at the crossover sites for the selection of quasi sites in DNA inversion mediated by the site-specific Cin recombinase of phage P1

The crossover sites for Cin-mediated inversion consist of imperfect 12 bp inverted repeats with non-palindromic dinucleotides at the center of symmetry. Inversion is believed to occur in vivo between the homologous central 2 bp crossover sequences at the inversely repeated crossover sites through introduction of 2 bp staggered cuts and subsequent reciprocal strand exchanges. The site-specific Cin recombinase acts not only on the normal crossover sites but also, less efficiently, on quasi crossover sites which have some homology with the normal sites. We identified 15 new quasi sites including 4 sites within the cin structural gene. Homology at the 2 bp crossover sequences between recombining sites favors selection as quasi crossover sites. The Cin enzyme can occasionally mediate inversion between nonidentical crossover sequences and such recombinations often result in localized mutations including base pair substitutions and deletions within the 2 bp crossover sequences. These mutations are explained as the consequences of heteroduplex molecules formed between the staggered dinucleotides and either their subsequent resolution by DNA replication or subsequent mismatch repair. Occasional utilization of quasi crossover sites and localized mutagenesis at the crossover sequences in enzyme-mediated inversion processes would be one of the mechanisms contributing to genetic diversity.

Synthesis of a site-specific DNA-binding peptide

The Hin recombinase binds to specific sites on DNA and mediates a recombination event that results in DNA inversion. In order to define the DNA-binding domain of the Hin protein two peptides 31 and 52 amino acids long were synthesized. Even though the 31mer encompassed the sequence encoding the putative helix-coil-helix-binding domain, it was not sufficient for binding to the 26-base pair DNA crossover site. However, the 52mer specifically interacted with the site and also effectively inhibited the Hin-mediated recombination reaction. The 52mer bound effectively to both the 26-base pair complete site and to a 14-base pair "half site." Nuclease and chemical protection studies with the 52mer helped to define the DNA base pairs that contributed to the specificity of binding. The synthetic peptide provides opportunities for new approaches to the study of the nature of protein-DNA interaction.

Magnesium-dependent plaque formation by bacteriophage P1cinC(-) on Escherichia coli C and Shigella sonnei

Phage P1C(-), in a state of the phage not infective to Escherichia coli K12, was able to form plaques on a wild-type strain of E. coli C and on Shigella sonnei in the presence of Mg2+. Citrobacter freundii, Enterobacter aerogenes, and a Salmonella typhimurium galE mutant were not lysed by, but were lysogenized with P1cinC(-), whereas Klebsiella pneumoniae, Proteus rettgeri, and S. typhimurium LT2 were not susceptible to either P1cinC(-) or P1cinC(+). The lipopolysaccharide structure of E. coli C and Sh. sonnei is discussed with reference to receptors for P1cinC(-) and P1cinC(+).

Sequence relations among the IncY plasmid p15B, P1, and P7 prophages

Electron microscopic analysis of heteroduplex molecules between the 94-kb plasmid p15B and the 92-kb phage P1 genome revealed nine regions of nonhomology, eight substitutions, and two neighboring insertions. Overall, the homologous segments correspond to 83% of the P1 genome and 81% of p15B. Heteroduplex molecules between p15B and the 99-kb phage P7 genome showed nonhomology in eight of the same nine regions; in addition, two new nonhomologous segments are present and P7 carries a 5-kb insertion representing Tn902. The DNA homology between those two genomes amounts to 79% of P7 DNA and 83% of p15B. Plasmid p15B contains two stem-loop structures. One of them has no equivalent structure on P1 and P7 DNA. The other substitutes the invertible C segments of P1 and P7 and their flanking sequences including cin, the gene for the site-specific recombinase mediating inversion.

Host protein requirements for in vitro site-specific DNA inversion

Flagellar phase variation is mediated by a recombination event that occurs at specific sites leading to inversion of a chromosomal segment of DNA. The presence of a 60 bp recombinational enhancer sequence on the DNA substrate molecule results in a 150-fold stimulation in the initial rate of inversion. The protein components required for inversion have been purified. They include the 21,000 dalton recombinase (Hin), a 12,000 dalton host protein (Factor II), and one of the major histone-like proteins of E. coli HU. The dependence of the initial rate of recombination on HU varies with respect to the location of the recombinational enhancer. The role of HU, Factor II, and the enhancer in facilitating site-specific recombination is discussed.

Site-specific and illegitimate recombination in the oriV1 region of the F factor. DNA sequences involved in recombination and resolution

We have defined some of the sequences involved in high frequency recA-independent recombination at the oriV1 region of the F factor. Using a mobilization assay, we determined that plasmid pMB080, a pBR322 derivative bearing the PvuII-BamHI (F factor co-ordinates 45.43 to 46.0) fragment from the oriV1 region of F, contained all sequences necessary to undergo efficient site-specific recombination with the F derivative pOX38, which retains the oriV1 region. We constructed a series of pMB080 deletions in vitro using exonucleases S1 and Bal31. Deletions removing a ten base-pair sequence, which forms part of an inverted repeat segment located 62 base-pairs to the left of the NcoI site (45.87) within the cloned fragment, totally eliminated the recA-independent recombination reaction. Other deletions differentially affected both the frequency and stability of cointegrate molecules formed by the site-specific recombination system. The F factor oriV1 region is involved also in low-frequency recombination with several sites on pBR322 and related plasmids. We have determined the precise location of these recombination sites within oriV1 by DNA sequencing. These studies revealed that recombination always took place within an eight base-pair spacer region between the ten base-pair inverted repeats found to be important for oriV1-oriV1 interactions. We propose that the low-efficiency recombination between pBR322 and pOX38 results from the ability of the F site-specific recombination apparatus to weakly recognize and interact with sequences that bear some resemblance to the normal oriV1 recognition elements. Furthermore, we suggest, by analogy with the lambda paradigm, that the nucleotide sequences at the junctions of secondary site recombinants define at least one crossover site used during the normal site-specific recombination process.

Localized conversion at the crossover sequences in the site-specific DNA inversion system of bacteriophage P1

The crossover sites for site-specific C inversion consist of imperfect 12 bp inverted repeats with the dinucleotide TT at the center of symmetry. The phage P1 Cin recombinase acts not only at these cix sites but also less efficiently at cix-related sequences called quasi-cix sites, cixQ. When cixQ contains a central dinucleotide TT, crossover occurs in vivo at the 2 bp sequence TT in the normal and the quasi-cix sites. If cixQ carries only one T residue, inversion-associated localized conversion can occur at the mismatched position within the 2 bp sequence. The results indicate that Cin generates 2 bp staggered cuts in vivo and that reciprocal strand exchanges occur at these 2 bp crossover sequences.