Site-specific recombination events mediated by the DNA invertase Cin of bacteriophage P1 during transformation

Abstract Bacteriophage P1 encodes the site-specific recombinase Cin which promotes inversion of the C segment, thus controlling the P1 host range. Cin can also mediate inefficient inversion between the normal crossover site cixL and a quasi-crossover site cixQ 1 in inverted orientation. Inversion between cixL and cixQ 1 occurs more frequently in a short period of time after transformation with a plasmid carrying the cin gene, cixL and cixQ 1 than in an established transformant of the plasmid. This is also the case for Cin-mediated deletion on a plasmid containing the cin gene and directly repeated cix sites.     

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.     

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.     

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

Summary The crossover sites for Cin-mediated inversion consist of imperfect 12 bp inverted repeats with non-palindomic 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 tubsequent 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.     

A site-specific, conservative recombination system carried by bacteriophage P1. Mapping the recombinase gene cin and the cross-over sites cix for the inversion of the C segment.

The bacteriophage P1 genome carries an invertible C segment consisting of 3-kb unique sequences flanked by 0.6-kb inverted repeats. With insertion and deletion mutants of P1 derivatives the site-specific recombinase gene cin for C inversion) has been mapped adjacent to the C segment and the cix sites (for C inversion cross-over) have been located at the outside ends of the inverted repeats. Inversion of the C segment functions as a biological switch and controls expression of the gene(s) responsible for phage infectivity carried on the C segment. The cin gene product can promote recombination between a 'quasi- cix ' site on plasmid pBR322 and a cix site on P1 DNA. The junctions formed on the resulting co-integrate can also serve as cix sites. This observation implies a potential evolutionary process to bring genes under the control of a biological switch acting by DNA inversion.     

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

Inversion of the 4.2-kb C segment flanked by 0.6-kb inverted repeats on the bacteriophage P1 genome is mediated by the P1-encoded site-specific cin recombinase. The cin gene lies adjacent to the C segment and the C inversion cross-over sites cixL and cixR are at the external ends of the inverted repeats. We have sequenced the DNA containing the cin gene and these cix sites. The cin structural gene consists of 561 nucleotides and terminates at the inverted repeat end where the cixL site is located. Only two nucleotides in the cixL region differ from those in the cixR and they are within the cin TAA stop codon. The cin promoter was localized by transposon mutagenesis within a 0.1-kb segment, which contains probable promoter sequences overlapping with a 'pseudo-cix' sequence cixPp. In a particular mutant, integration of an IS1-flanked transposon into the cin control region promoted weak expression of the cin gene. The cin and cix sequences show homology with corresponding, functionally related sequences for H inversion in Salmonella and with cross-over sites for G inversion in phage Mu. Based on a comparison of the DNA sequences and of the gene organizations, a possible evolutionary relationship between these three inversion systems and the possible significance of the cixPp sequence in the cin promoter are discussed.     

The Min DNA inversion enzyme of plasmid p15B of Escherichia coli 15T−: a new member of the Din family of site-specific recombinases

Plasmid p15B is a bacteriophage P1-related resident of Escherichia coli 15T-. Both genomes contain a segment in which DNA inversion occurs, although this part of their genomes is not identical. This DNA segment of p15B was cloned in a multicopy vector plasmid. Like its parent, the resulting plasmid, pAW800, undergoes complex multiple DNA inversions: this DNA inversion system is therefore called Min. The min gene, which codes for the p15B Min DNA invertase, can complement the P1 cin recombinase gene. The Min inversion system is thus a new member of the Din family of site-specific recombinases to which Cin belongs. The DNA sequence of the min gene revealed that Min is most closely related to the Pin recombinase of the e14 defective viral element on the E. coli K12 chromosome. Like other members of the Din family, the min gene contains a recombinational enhancer element which stimulates site-specific DNA inversion 300-fold.     

Cre-loxP recombination system for large genome rearrangements in Lactococcus lactis

We have used a new genetic strategy based on the Cre-loxP recombination system to generate large chromosomal rearrangements in Lactococcus lactis. Two loxP sites were sequentially integrated in inverse order into the chromosome either at random locations by transposition or at fixed points by homologous recombination. The recombination between the two chromosomal loxP sites was highly efficient (approximately 1 x 10(-1)/cell) when the Cre recombinase was provided in trans, and parental- or inverted-type chromosomal structures were isolated after removal of the Cre recombinase. The usefulness of this approach was demonstrated by creating three large inversions of 500, 1,115, and 1,160 kb in size that modified the lactococcal genome organization to different extents. The Cre-loxP recombination system described can potentially be used for other gram-positive bacteria without further modification.     

Inversions over the terminus region in Salmonella and Escherichia coli: IS200s as the sites of homologous recombination inverting the chromosome of Salmonella enterica serovar typhi

Genomic rearrangements (duplications and inversions) in enteric bacteria such as Salmonella enterica serovar Typhimurium LT2 and Escherichia coli K12 are frequent (10(-3) to 10(-5)) in culture, but in wild-type strains these genomic rearrangements seldom survive. However, inversions commonly survive in the terminus of replication (TER) region, where bidirectional DNA replication terminates; nucleotide sequences from S. enterica serovar Typhimurium LT2, S. enterica serovar Typhi CT18, E. coli K12, and E. coli O157:H7 revealed genomic inversions spanning the TER region. Assuming that S. enterica serovar Typhimurium LT2 represents the ancestral genome structure, we found an inversion of 556 kb in serovar Typhi CT18 between two of the 25 IS200 elements and an inversion of about 700 kb in E. coli K12 and E. coli O157:H7. In addition, there is another inversion of 500 kb in E. coli O157:H7 compared with E. coli K12. PCR analysis confirmed that all S. enterica serovar Typhi strains tested, but not strains of other Salmonella serovars, have an inversion at the exact site of the IS200 insertions. We conclude that inversions of the TER region survive because they do not significantly change replication balance or because they are part of the compensating mechanisms to regain chromosome balance after it is disrupted by insertions, deletions, or other inversions.     

High-frequency flp recombinase-mediated inversions of the oriC-containing region of the Pseudomonas aeruginosa genome

The genomes of the two clonally derived Pseudomonas aeruginosa prototypic strains PAO1 and DSM-1707 differ by the presence of a 2. 19-Mb inversion including oriC. Integration of two Flp recombinase target sites near the rrn operons containing the inversion endpoints in PAO1 led to Flp-catalyzed inversion of the intervening 1.59-Mb fragment, including oriC, at high frequencies (83%), favoring the chromosome configuration found in DSM-1707. The results indicate that the oriC-containing region of the P. aeruginosa chromosome can readily undergo and tolerate large inversions.     

Role of arginine-43 and arginine-69 of the Hin recombinase catalytic domain in the binding of Hin to the hix DNA recombination sites

The Hin recombinase mediates the site-specific inversion of a segment of the Salmonella chromosome between two flanking 26 bp hix DNA recombination sites. Mutations in two amino acid residues, R43 and R69 of the catalytic domain of the Hin recombinase, were identified that can compensate for loss of binding resulting from elimination of certain major and minor groove contacts within the hix recombination sites. With one exception, the R43 and R69 mutants were also able to bind a hix sequence with an additional 4 bp added to the centre of the site, unlike wild-type Hin. Purified Hin mutants R43H and R69C had both partial cleavage and inversion activities in vitro while mutants R43L, R43C, R69S, and R69P had no detectable cleavage and inversion activities. These data support a model in which the catalytic domain plays a role in DNA-binding specificity, and suggest that the arginine residues at positions 43 and 69 function to position the Hin recombinase on the DNA for a step in the recombination reaction which occurs either at and/or prior to DNA cleavage.     

Construction of Chromosomal Rearrangements in Salmonella by Transduction: Inversions of Non-Permissive Segments Are Not Lethal

Homologous sequences placed in inverse order at particular separated sites in the bacterial chromosome (termed ``permissive') can recombine to form an inversion of the intervening chromosome segment. When the same repeated sequences flank other chromosome segments (``non-permissive'), recombination occurs but the expected inversion rearrangement is not found among the products. The failure to recover inversions of non-permissive chromosomal segments could be due to lethal effects of the final rearrangement. Alternatively, local chromosomal features might pose barriers to reciprocal exchanges between sequences at particular sites and could thereby prevent formation of inversions of the region between such sites. To distinguish between these two possibilities, we have constructed inversions of two non-permissive intervals by means of phage P22-mediated transduction crosses. These crosses generate inversions by simultaneous incorporation of two transduced fragments, each with a sequence that forms one join-point of the final inversion. We constructed inversions of the non-permissive intervals trp ('34) to his ('42) and his ('42) to cysA ('50). Strains with the constructed inversions are viable and grow normally. These results show that our previous failure to detect formation of these inversions by recombination between chromosomal sequences was not due to lethal effects of the final rearrangement. We infer that the ``non-permissive' character of some chromosomal segments reflects the inability of the recombination system to perform the needed exchanges between inverse order sequences at particular sites. Apparently these mechanistic problems were circumvented by the transductional method used here to direct inversion formation.     

Enhancer-independent mutants of the Cin recombinase have a relaxed topological specificity.

Cin is a member of the hin family of complementing site-specific recombinases which regulate the alternate expression of genes by inverting DNA segments. Common characteristics of this family of recombination systems are the requirement for an enhancer-like element in cis and the specificity for inversely oriented recombination sites on the same DNA molecule. We have isolated two mutants of the Cin recombinase which will efficiently recombine a substrate lacking the enhancer. In addition, these mutant proteins also catalyse efficient recombination between sites in direct orientation or on different DNA molecules. Both mutations are due to single amino acid substitutions at different positions in the protein and the two mutants have slightly different phenotypes. The finding that the loss of enhancer dependence is coupled to a change in topological specificity leads us to conclude that the enhancer determines the specificity of the system for DNA inversion.     

Ability of a Bacterial Chromosome Segment to Invert Is Dictated by Included Material Rather than Flanking Sequence

Homologous recombination between sequences present in inverse order within the same chromosome can result in inversion formation. We have previously shown that inverse order sequences at some sites (permissive) recombine to generate the expected inversion; no inversions are found when the same inverse order sequences flank other (nonpermissive) regions of the chromosome. In hopes of defining how permissive and nonpermissive intervals are determined, we have constructed a strain that carries a large chromosomal inversion. Using this inversion mutant as the parent strain, we have determined the "permissivity" of a series of chromosomal sites for secondary inversions. For the set of intervals tested, permissivity seems to be dictated by the nature of the genetic material present within the chromosomal interval being tested rather than the flanking sequences or orientation of this material in the chromosome. Almost all permissive intervals include the origin or terminus of replication. We suggest that the rules for recovery of inversions reflect mechanistic restrictions on the occurrence of inversions rather than lethal consequences of the completed rearrangement.     

Cre-loxP Recombination System for Large Genome Rearrangements in Lactococcus lactis

We have used a new genetic strategy based on the Cre-loxP recombination system to generate large chromosomal rearrangements in Lactococcus lactis. Two loxP sites were sequentially integrated in inverse order into the chromosome either at random locations by transposition or at fixed points by homologous recombination. The recombination between the two chromosomal loxP sites was highly efficient (approximately 1 × 10⁻¹/cell) when the Cre recombinase was provided in trans, and parental- or inverted-type chromosomal structures were isolated after removal of the Cre recombinase. The usefulness of this approach was demonstrated by creating three large inversions of 500, 1,115, and 1,160 kb in size that modified the lactococcal genome organization to different extents. The Cre-loxP recombination system described can potentially be used for other gram-positive bacteria without further modification.     

Analysis of secondary,integration sites for IS117 in Streptomyces lividans and their role in the generation of chromosomal deletions

IS117, the 2.6 kb mini-circle of Streptomyces coelicolor A3(2), is a transposable element previously shown to be integrated into two distant sites in the chromosome. When introduced into S. lividans, IS117 integrates into one preferred chromosomal site, but when this site was artificially deleted, IS117 integrated into many secondary sites. Nucleotide sequence analysis of several secondary integration sites revealed varying degrees of similarity with the preferred site, but no consensus sequence. Nevertheless, sites more similar to the preferred site tended to be occupied more often than those that are less similar. Insertion of IS117 into secondary sites in the chromosome of S. lividans sometimes mediated chromosomal rearrangements. It was shown that some strains containing IS117 integrated into secondary sites had suffered deletions of chromosomal DNA. Deletions were adjacent to the inserted element and were at least several kilobases long. The proposed model implicates homologous recombination between IS117 copies integrated into two different secondary sites in the same chromosome as a cause of the deletions.     

Genetic Methods for Analysis and Manipulation of Inversion Mutations in Bacteria

A number of genetic methods for the isolation, characterization and manipulation of large chromosomal inversions in Salmonella typhimurium are described. One inversion-carrying mutant is characterized in detail and used to demonstrate a number of unique genetic properties of bacterial inversions.—Contrary to expectation, it was found that large inversion mutations can be repaired by generalized transduction. The repair results from the simultaneous introduction of two wild-type transduced fragments into a single recipient cell. Homologous recombination between the two transduced fragments and the two inversion breakpoints causes the inverted segment to be reinverted. This results in regeneration of the wild-type orientation of this chromosome segment. Similar recombination events allow a large inversion mutation to be introduced into a wild-type strain; two transduced fragments from an inversion strain cause recombination events resulting in inversion of a large chromosome segment.—Genetic methods for mapping the extent of a large inversion mutation by generalized transduction are described and tested. The methods are operationally simple and allow good resolution of the two inversion breakpoints.     

A region flanking H-2K is duplicated to a distant site in most mouse t haplotypes

Mouse t haplotypes contain at least one inversion, which encompasses the major histocompatibility complex, relative to their wild-type counterparts. A DNA probe for a single copy sequence which flanks the H-2K region in inbred strains was found to have undergone further rearrangements in the t haplotypes. In most t haplotypes, this sequence is duplicated at a distant site, and the two regions show 1 % recombination. The length of homology shared by the two sites is likely to be at least 10–15 kb. Three different alleles, as defined by restriction fragment length polymorphisms, were found for each of the two sites among different t haplotypes. These may reveal evolutionary relationships among these chromosomes.     

Approaches to Half-Tetrad Analysis in Bacteria: Recombination between Repeated, Inverse-Order Chromosomal Sequences

In standard bacterial recombination assays, a linear fragment of DNA is transferred to a recipient cell and, at most, a single selected recombinant type is recovered from each merozygote. This contrasts with fungal systems, for which tetrads allow recovery of all meiotic products, including both ultimate recombinant products of an apparent single act of recombination. We have developed a bacterial recombination system in which two recombining sequences are placed in inverse order at widely separated sites in the circular chromosome of Salmonella typhimurium. Recombination can reassort markers between these repeated sequences (double recombination and apparent gene conversion), or can exchange flanking sequences, leading to inversion of the chromosome segment between the recombining sequences. Since two recombinant products remain in the chromosome of a recombinant with an inversion, one can, in principle, approach the capability of tetrad analysis. Using this system, the following observations have been made. (a) When long sequences (40 kb) recombine, conversion frequently accompanies exchange of flanking sequences. (b) When short sequences (5 kb) recombine, conversion rarely accompanies exchange of flanks. (c) Both recA and recB mutations eliminate inversion formation. (d) The frequency of exchanges between short repeats is more sensitive to the distance separating the recombining sequences in the chromosome. The results are presented with the assumption that inversions occur by simple interaction of two sequences in the same circular chromosome. In an appendix we discuss mechanistically more complex possibilities, some of which could also apply to standard fungal systems.     

Analysis of secondary, integration sites for IS117 in Streptomyces lividans and their role in the generation of chromosomal deletions

IS117, the 2.6 kb mini-circle of Streptomyces coelicolor A3(2), is a transposable element previously shown to be integrated into two distant sites in the chromosome. When introduced into S. lividans, IS117 integrates into one preferred chromosomal site, but when this site was artificially deleted, IS117 integrated into many secondary sites. Nucleotide sequence analysis of several secondary integration sites revealed varying degrees of similarity with the preferred site, but no consensus sequence. Nevertheless, sites more similar to the preferred site tended to be occupied more often than those that are less similar. Insertion of IS117 into secondary sites in the chromosome of S. lividans sometimes mediated chromosomal rearrangements. It was shown that some strains containing IS117 integrated into secondary sites had suffered deletions of chromosomal DNA. Deletions were adjacent to the inserted element and were at least several kilobases long. The proposed model implicates homologous recombination between IS117 copies integrated into two different secondary sites in the same chromosome as a cause of the deletions.