Site-specific relaxation and recombination by the Tn3 resolvase: recognition of the DNA path between oriented res sites

We studied the dynamics of site-specific recombination by the resolvase encoded by the Escherichia coli transposon Tn3. The pure enzyme recombined supercoiled plasmids containing two directly repeated recombination sites, called res sites. Resolvase is the first strictly site-specific topoisomerase. It relaxed only plasmids containing directly repeated res sites; substrates with zero, one or two inverted sites were inert. Even when the proximity of res sites was ensured by catenation of plasmids with a single site, neither relaxation nor recombination occurred. The two circular products of recombination were catenanes interlinked only once. These properties of resolvase require that the path of the DNA between res sites be clearly defined and that strand exchange occur with a unique geometry. A model in which one subunit of a dimeric resolvase is bound at one res site, while the other searches along adjacent DNA until it encounters the second site, would account for the ability of resolvase to distinguish intramolecular from intermolecular sites, to sense the relative orientation of sites and to produce singly interlinked catenanes. Because resolvase is a type 1 topoisomerase, we infer that it makes the required duplex bDNA breaks of recombination one strand at a time.     

Directionality in FLP protein-promoted site-specific recombination is mediated by DNA-DNA pairing

The 2 mu plasmid of the yeast Saccharomyces cerevisiae encodes a site-specific recombination system consisting of plasmid-encoded FLP protein and two recombination sites on the plasmid. The recombination site possesses a specific orientation, which is determined by an asymmetric 8-base pair spacer sequence separating two 13-base pair inverted repeats. The outcome or directionality of site-specific recombination is defined by the alignment of two sites in the same orientation during the reaction. Sites containing point mutations or 1-base pair insertions or deletions within the spacer generally undergo recombination with unaltered sites at reduced levels. In contrast, recombination between the two identical mutant sites (where homology is restored) proceeds efficiently in all cases. Sites containing spacer sequences of 10 base pairs or more are nonfunctional under all conditions. A recombination site in which 5 base pairs are changed to yield an entirely symmetrical spacer sequence again recombines efficiently, but only with an identical site. This reaction, in addition, produces a variety of new products which can only result from random alignment of the two sites undergoing recombination, i.e. the reaction no longer exhibits directionality. These and other results demonstrate that both the efficiency and directionality of site-specific recombination is dependent upon homology between spacer sequences of the two recombining sites. This further implies that critical DNA-DNA interactions between the spacer region of the two sites involved in the reaction occur at some stage during site-specific recombination in this system. The specific spacer sequence itself appears to be unimportant as long as homology is maintained; thus, these sequences are probably not involved in recognition by FLP protein.     

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.     

Sequence analysis of the inversion region containing the pilin genes of Moraxella bovis.

Moraxella bovis EPP63 is able to produce two antigenically distinct pili called Q and I pili (previously called beta and alpha pili). Hybridization studies have shown that the transition between the types is due to inversion of a 2.1-kilobase segment of chromosomal DNA. We present the sequence of a 4.1-kilobase region of cloned DNA spanning the entire inversion region in orientation 1 (Q pilin expressed). Comparison of this sequence with the sequence of the polymerase chain reaction-amplified genomic DNA from orientation 2 (I pilin expressed) allows the site-specific region of recombination to be localized to a 26-base-pair region in which sequence similarity to the left inverted repeat of the Salmonella typhimurium hin system was previously noted. In addition, 50% sequence similarity was seen in a 60-base-pair segment of our sequence to the recombinational enhancer of bacteriophage P1, an inversion system related to the hin system of S. typhimurium. Finally, two open reading frames representing potential genes were identified.     

Location and analysis of nucleotide sequences at one end of a putative lac transposon in the Escherichia coli chromosome.

A segment of Escherichia coli DNA that contained a discontinuity of homology with Salmonella typhimurium DNA was isolated. The segment, 1,430 base pairs long, was derived from one end of the lac "loop," a region of about 12 kilobase pairs of E. coli DNA, including the lac operon which has no detectable homology with S. typhimurium DNA (K. Lampel and M. Riley, Mol. Gen. Genet. 186:82-86, 1982). The nucleotide sequence of the 1,430-base-pair segment of DNA was determined. The location of the junction of discontinuity of homology within the segment was established by hybridization experiments. Nucleotide sequences at or near the junction were determined to be similar to sequences that are involved in site-specific inversion in S. typhimurium, E. coli, phage P1, and phage Mu. Similar sequences are also present within the terminal inverted repeat sequences of transposon Tn5 and at the V-D-J joining sequences of eucaryotic immunoglobulin genes. Therefore, the lac operon, together with flanking DNA, may have been inserted into the E. coli chromosome at one time via a site-specific recombination event. Rearrangement events of this kind undoubtedly have played a significant role in the evolutionary divergence of chromosomal DNAs.     

Structure of the chromosomal insertion site for pSAM2: functional analysis in Escherichia coli

The element pSAM2 from Streptomyces ambofaciens integrates into the chromosome through site-specific recombination between the element ( att  P) and the chromosomal ( att  B) sites. These regions share an identity segment of 58 bp extending from the anti-codon loop through the 3' end of a tRNA^Pro gene. To facilitate the study of the att  B site, the int and xis genes, expressed from an inducible promoter, and att  P from pSAM2 were cloned on plasmids in Escherichia coli . Compatible plasmids carrying the different att  B regions to be tested were introduced in these E . coli strains. Under these conditions, Int alone could promote site-specific integration; Int and Xis were both required for site-specific excision. This experimental system was used to study the sequences required in att  B for efficient site-specific recombination. A 26 bp sequence, centred on the anti-codon loop region and not completely included in the identity segment, retained all the functionality of att  B; shorter sequences allowed integration with lower efficiencies. By comparing the 26-bp-long att  B with att  P, according to the Lambda model, we propose that B and B', C and C' core-type Int binding sites consist of 9 bp imperfect inverted repeats separated by a 5 bp overlap region.     

Recombination within the yeast plasmid 2mu circle is site-specific

The multicopy yeast plasmid, 2mu circle, encodes a specialized recombination system. It contains two regions, each 599 bp in length, that are precise inverted repeats of each other and between which recombination occurs readily. In addition, this recombination requires the product of a 2mu circle gene, designated FLP. By examining the products of FLP-mediated recombination of plasmids containing single insertions within one of the repeated regions, we show that this recombination occurs only at a specific site within the repeat. This result was confirmed from analysis of the ability of plasmids containing various deletions within one of the repeated regions to serve as substrates for FLP-mediated recombination. These experiments limit the recombination site to a sequence of less than 65 bp. In addition, by mutational analysis of the recombination potential of a hybrid plasmid containing the entire 2mu circle genome, we have shown that FLP is only the 2mu circle gene necessary for this site-specific recombination. Finally, we describe a sensitive assay for recombination between the repeated sequences of 2mu circle; using it, we demonstrate that even in the absence of FLP gene product, recombination between the repeats occurs at a low but detectable level during meiosis.     

Site-specific recombination between ColE1 tcer and NTP16 nmr sites in vivo

The site-specific recombination system used by multicopy plasmids of the ColE1 family uses two identical plasmid-encoded recombination sites and four bacterial proteins to catalyze the recombination reaction. In the case of the Escherichia coli plasmid ColE1, the recombination site, cer, is a 280 by DNA sequence which is acted on by the products of the argR, pepA, xerC and xerD genes. We have constructed a model system to study this recombination system, using tandemly repeated recombination sites from the plasmids ColE1 and NTP16. These plasmids have allowed us precisely to define the region of strand exchange during site-specific recombination, and to derive a model for cer intramolecular site-specific recombination.     

Site-specific recombination between ColE1 tcer and NTP16 nmr sites in vivo

The site-specific recombination system used by multicopy plasmids of the ColE1 family uses two identical plasmid-encoded recombination sites and four bacterial proteins to catalyze the recombination reaction. In the case of the Escherichia coli plasmid ColE1, the recombination site, cer, is a 280 by DNA sequence which is acted on by the products of the argR, pepA, xerC and xerD genes. We have constructed a model system to study this recombination system, using tandemly repeated recombination sites from the plasmids ColE1 and NTP16. These plasmids have allowed us precisely to define the region of strand exchange during site-specific recombination, and to derive a model for cer intramolecular site-specific recombination.     

Characterization of a circular plasmid from the yeast Kluyveromyces waltii.

A new plasmid was found in the yeast Kluyveromyces waltii. This high-copy-number plasmid, named pKW1, is a double-stranded circular DNA plasmid of 5619 bp. It has several features characteristic of the 2 mu-type plasmids: presence of two inverted repeats and four open reading frames, as well as the interconversion of two isomeric forms. However, the nucleotide sequence shows little homology with known yeast plasmids. An ARS function was localized within a segment of 545 bp near one of the inverted repeats. Chimeric plasmids carrying this segment efficiently transformed K. waltii. A strain of K. waltii cured of the plasmid (cir degree) was also obtained. In the pKW1 sequence, a functionally neutral region was found at which foreign DNA can be inserted with little effect on plasmid stability. Such constructions carrying the full sequence of pKW1 replicated autonomously in a cir degree host and were particularly stable. pKW1-derived full-sequence plasmids also transformed K. thermotolerans, but not K. lactis.     

A site-specific recombination function in Staphylococcus aureus plasmids.

All known small staphylococcal plasmids possess one or two recombination sites at which site-specific cointegrate formation occurs. One of these sites, RSA, is present on two small multicopy plasmids, pT181 and pE194; it consists of 24 base pairs of identity in the two plasmids, the "core," flanked by some 50 base pairs of decreasing homology. Here we show that recombination at RSA is recA independent and is mediated by a plasmid-encoded, trans-acting protein, Pre (plasmid recombination). Pre-mediated recombination is site specific in that it occurs within the core sequence of RSA in a recA1 host. Recombination also occurs between two intramolecular RSA sites. Unlike site-specific recombination systems encoded by other plasmids, Pre-RSA is not involved in plasmid maintenance.     

Direct and inverted DNA repeats associated with P-glycoprotein gene amplification in drug resistant Leishmania.

The H circle of Leishmania species contains a 30 kb inverted duplication separated by two unique DNA segments, a and b. The corresponding H region of chromosomal DNA has only one copy of the duplicated DNA. We show here that the chromosomal segments a and b are flanked by inverted repeats (198 and 1241 bp) and we discuss how these repeats could lead to formation of H circles from chromosomal DNA. Selection of Leishmania tarentolae for methotrexate resistance indeed resulted in the de novo formation of circles with long inverted duplication, but two mutants selected for arsenite resistance contained new H region plasmids without such duplications. One of these plasmids appears due to a homologous recombination between two P-glycoprotein genes with a high degree of sequence homology. Our results show how the same DNA region in Leishmania may be amplified to give plasmids with or without long inverted duplications and apparently by different mechanisms.     

Physical mapping and expression of hybrid plasmids carrying chromosomal beta-lactamase genes of Escherichia coli K-12.

Hybrid plasmids carrying the ampC gene of Escherichia coli K-12 that codes for the chromosomal beta-lactamase were physically studied. The ampC gene was mapped to a deoxyribonucleic acid segment encompassing 1,370 base pairs. The mapping was facilitated by the isolation of a plasmid carrying an insertion of the transposable element gamma delta (gamma delta) close to ampC. The ampA1 mutation, which increases the expression of ampC by a factor of about 20, was localized to a 370-base pair segment of the 1,370-base pair deoxyribonucleic acid segment that contains the ampC gene. Using a minicell protein labeling system, it was seen that plasmids carrying either ampA+, ampC, or ampA1 and ampC coded for a 36,000-dalton protein which comigrated with purified chromosomal beta-lactamase. In cells carrying plasmids that bore the ampA1 allele, the production of this protein was greater. In addition, a protein with a slightly higher molecular weight (38,000) was expressed by both ampA+ ampC and ampA1 ampC plasmids in this protein labeling system. This protein might represent a precursor form of chromosomal beta-lactamasee. From E. coli K-12 strains carrying the ampA1 allele, second-step mutants were isolated that hyperproduced chromosomal beta-lactamase. By reciprocal recombination, plasmid derivatives were isolated that carried these mutations. Two second-step regulatory mutations mapped within the same 370-base pair region as ampA1. This piece of deoxyribonucleic acid therefore contains ampA, a control sequence region for ampC.     

Nucleotide sequence and expression of the gene for the site-specific integration protein from bacteriophage HP1 of Haemophilus influenzae.

The nucleotide sequence of the leftmost 2,363 base pairs of the HP1 genome, which includes the attachment site (attP) and the integration region, was determined. This sequence contained an open reading frame encoding a 337-residue polypeptide, which is a member of the integrase family of site-specific recombination proteins as judged by sequence comparison. The open reading frame was located immediately adjacent to the att site and was oriented so that initiation of translation would begin distal to the att site and end in its immediate vicinity. Expression of this DNA segment in Escherichia coli provided extracts which promoted site-specific recombination between plasmids containing cloned HP1 attP and Haemophilus influenzae attB sites. This recombination was directional, since no reaction was observed between plasmids containing attR and attL sites. The reaction was stimulated by the accessory protein integration host factor of E. coli. Evidence was also obtained that the integration host factor influenced the levels of HP1 integrase expression. The deduced amino acid sequence of HP1 integrase has remarkable similarity to that deduced for the integrase of coliphage 186.     

Changes in the DNase I sensitivity of DNA sequences within the yeast 2 micron plasmid nucleoprotein complex effected by plasmid-encoded products

We examined the effect of plasmid-encoded gene products on two DNase-I-sensitive regions of DNA in the yeast 2 micron plasmid nucleoprotein complex. For these studies, each sensitive region was cloned into an appropriate vector, and the chimeric plasmids were transformed into yeast. Nucleoprotein complexes of the chimeric plasmids were partially purified and tested for sensitivity to DNase I digestion. One sensitive region is between the 3' end of the 2 micron plasmid coding region D and the plasmid REP3 locus. This region was more sensitive and exhibited a different cleavage pattern when purified from a yeast strain containing endogenous 2 micron plasmid copies than when purified from a yeast strain lacking plasmid copies. Examination of the effect of individual gene products and combinations of the various gene products revealed that the plasmid's REP1, REP2 and D loci were all necessary to restore the pattern to that found in the preparation containing endogenous 2 micron plasmid copies. The other sensitive region studied brackets the binding site of the plasmid-encoded FLP protein, which catalyzes site-specific recombination between the 2 micron plasmid's inverted repeated sequences. In contrast to the first sensitive region examined, the sensitive region in the inverted repeat was less sensitive in chimeric plasmids isolated from a yeast strain containing endogenous 2 micron plasmid copies than from one lacking endogenous copies. Presumably, this protection results from the binding of the FLP protein.     

oriT sequence of the antibiotic resistance plasmid R100.

We present the nucleotide sequence of the oriT region from plasmid R100. Comparison to other IncF plasmids revealed homology around the proposed nick sites as well as conservation of inverted repeated sequences in the nonhomologous region. Three areas showed strong homology (eight of nine nucleotides) to the consensus sequence for binding of integration host factor, suggesting a role for this DNA-binding protein in nicking at oriT.     

IS431, a staphylococcal insertion sequence-like element related to IS26 from Proteus vulgaris

We present the nucleotide sequence of IS431, a new staphylococcal insertion sequence-like element flanking the mercury-resistance determinant of pI524 and associated with the methicillin-resistance determinant. IS431 left is 800 bp long and has a perfect terminal inverted repeat (IR) of 22 bp; IS431 right is 786 bp long and has a terminal IR homologous to the IR of IS431 left except that the terminal 8 bp are absent. Both IRs share a 10-bp homology with the IR of IS26 from Proteus vulgaris. No directly repeated sequences were detected immediately adjacent to the IRs. An open reading frame (ORF) of 675 bp spans most of the IS431 sequence. Its deduced amino acid (aa) sequence shows 40% homology to the 234-aa-long putative transposase coded by ORFI of IS26.     

Insertion element IS102 resides in plasmid pSC101.

In vivo recombination was found to occur between plasmid pHS1, a temperature-sensitive replication mutant of pSC101 carrying tetracycline resistance, and plasmid ColE1 after selection for tetracycline resistance at the restrictive temperature, 42 degrees C. Extensive analysis of the physical structures of three of these recombinant plasmids, using restriction endonucleases and the electron microscope heteroduplex method, revealed that the plasmid pHS1 was integrated into different sites on ColE1. The recombinant plasmids contained a duplication of a unique 1-kilobase (kb) sequence of pHS1 in a direct orientation at the junctions between the two parental plasmid sequences. This was confirmed by comparing the nucleotide sequence of the recombinants and their parental plasmids. Nucleotide sequence analysis further revealed that nine nucleotides at the site of recombination of ColE1 were duplicated at the junction of each of the 1-kb sequences. The formation of recombinants was independent of RecA function. Based on our previous finding that a plasmid containing a deoxyribonucleic acid insertion (IS) element can recombine with a second plasmid to generate a duplication of the IS element, we conclude that the 1-kb sequence is an insertion sequence, which we named IS102. For convenience, we have also denoted the IS102 sequence as eta theta to assign the orientation of the sequence. Eighteen nucleotides at one end (eta end) were found to be repeated in an inverted orientation at the other end (theta end) of IS102. The nucleotide sequence of the eta end of the sequence was found to be identical to the sequence at the ends of the transposon Tn903, which is responsible for transposition of the kanamycin resistance gene.     

NBU1 integrase: evidence for an altered recombination mechanism

NBU1 is a 10.3 kbp Bacteroides mobilizable transposon. A previous study had identified a 2.7 kbp segment of the excised circular intermediate that was sufficient to mediate integration of the element after transfer. This segment contained an integrase gene, intN1, and a region spanning the ends of the circular form within which integration occurred (attN1). The integrase protein, IntN1, appeared to be a member of the tyrosine recombinase family because it contains the canonical C-terminal RKHRHY [RK(H/K)R(H/W)Y] motif that characterizes members of that family. In this study, we describe an Escherichia coli-based integration assay system that has allowed us to characterize attN1 in detail. We first localized attN1 to a 250 bp region. We then used site-directed mutations to identify directly repeated sequences within attN1 that were required for site-specific integration. The locus of NBU1 site-specific integration in the Bacteroides thetaiotaomicron chromosome, attBT1-1, contains a 14 bp sequence that is identical to a 14 bp sequence that spans the joined ends of the NBU1 attN1 site (common core sequences). The effects of mutations in the common core were different from the expected results if NBU1 integration was similar to lambda integration. In particular single base changes near one end of the common core region, which introduced heterology, actually increased the frequency of integration. By contrast, compensating changes that restored homology in the common core region reduced the integration frequency. The recombination mechanism also differs from the one used by conjugative transposons that have coupling sequences between the sites of strand cleavage and exchange. These results indicate that although NBU1 integrase is considered to be a member of the tyrosine recombinase family, it catalyses an integrative recombination reaction that occurs by a different crossover mechanism.