Purification and properties of the Escherichia coli host factor required for inversion of the G segment in bacteriophage Mu

G inversion in bacteriophage Mu requires the product of the DNA invertase gene gin and an Escherichia coli host factor termed FIS (factor for inversion stimulation). A recombination substrate must contain two recombination sites, arranged as inverted repeats, and a recombinational enhancer sequence termed sis. FIS has been purified to homogeneity. The purified protein has a relative molecular weight of 12,000 when analyzed under denaturing conditions. The intact protein behaves as a dimer of relative molecular weight 25,000 in gel filtration analysis. The purified protein does not possess any recombinogenic activity when assayed in the absence of the DNA-invertase Gin. In the presence of purified Gin FIS is the only additional protein required for efficient inversion. By performing gel retention assays, we show that FIS is a DNA-binding protein, which specifically binds to DNA fragments containing the recombinational enhancer sis.     

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.     

Mutational analysis of a prokaryotic recombinational enhancer element with two functions.

The site-specific DNA inversion system Cin encoded by the bacteriophage P1 consists of a recombinase, two inverted crossing-over sites and a recombinational enhancer. The latter approximately 75 bp long genetic element is bifunctional due to its location within the 5' part of the cin gene encoding the recombinase. In order to determine the essential nucleotides for each of its two biological functions we randomly mutated the recombinational enhancer sequence sis(P1) and analysed both functions of the mutants obtained. Three distinct regions of this sequence were found to be important for the enhancer activity. One of them occupies the middle third of the enhancer sequence and it can suffer a number of functionally neutral base substitutions, while others are detrimental. The other two regions occupy the two flanking thirds of the enhancer. They coincide with binding sites of the host-coded protein FIS (Factor for Inversion Stimulation) needed for efficient DNA inversion in vitro. These sequences appear to be highly evolved allowing only a few mutations without affecting either of the biological functions. Taking the effect of mutations within these FIS binding sites into account a consensus sequence for the interaction with FIS was compiled. This FIS consensus implies a palindromic structure for the recombinational enhancer. This is in line with the orientation independence of enhancer action with respect to the crossing-over sites.     

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.     

Isolation and characterization of unusual gin mutants.

Site-specific inversion of the G segment in phage Mu DNA is promoted by two proteins, the DNA invertase Gin and the host factor FIS. Recombination occurs if the recombination sites (IR) are arranged as inverted repeats and a recombinational enhancer sequence is present in cis. Intermolecular reactions as well as deletions between direct repeats of the IRs rarely occur. Making use of a fis- mutant of Escherichia coli we have devised a scheme to isolate gin mutants that have a FIS independent phenotype. This mutant phenotype is caused by single amino acid changes at five different positions of gin. The mutant proteins display a whole set of new properties in vivo: they promote inversions, deletions and intermolecular recombination in an enhancer- and FIS-independent manner. The mutants differ in recombination activity. The most active mutant protein was analysed in vitro. The loss of site orientation specificity was accompanied with the ability to recombine even linear substrates. We discuss these results in connection with the role of the enhancer and FIS protein in the wild-type situation.     

The recombinational enhancer for DNA inversion functions independent of its orientation as a consequence of dyad symmetry in the Fis-DNA complex.

The Escherichia coli Fis protein binds to specific DNA sequences whose base composition varies enormously. One known function of Fis is to stimulate site-specific DNA recombination. We used the Gin-mediated DNA inversion system of bacteriophage Mu to analyze Fis-DNA interaction. Efficient inversion requires an enhancer which consists of two Fis binding sites at a fixed distance from each other. Using mutant enhancers in which one of the Fis binding sites is replaced we show that Fis binds symmetrically to the DNA and we locate the center of symmetry. Furthermore, we show that one of the Fis binding sites can be replaced by a Fis binding site that normally functions in a process other than site-specific recombination.     

Stimulation of DNA inversion by FIS: evidence for enhancer-independent contacts with the Gin-gix complex.

Efficient DNA inversion catalysed by the invertase Gin requires the cis-acting recombinational enhancer and the Escherichia coliFIS protein. Binding of FIS bends the enhancer DNA and, on a negatively supercoiled DNA inversion substrate, facilitates the formation of a synaptic complex with specific topology. Previous studies have indicated that FIS-independent Gin mutants can be isolated which have lost the topological constraints imposed on the inversion reaction yet remain sensitive to the stimulatory effect of FIS. Whether the effect of FIS is purely architectural, or whether in addition direct protein contacts between Gin and FIS are required for efficient catalysis has remained an unresolved question. Here we show that FIS mutants impaired in DNA binding are capable of either positively or negatively affecting the inversion reaction both in vivo and in vitro. We further demonstrate that the mutant protein FIS K25E/V66A/M67T dramatically enhances the cleavage of recombination sites by FIS-independent Gin in an enhancer-independent manner. Our observations suggest that FIS plays a dual role in the inversion reaction and stimulates both the assembly of the synaptic complex as well as DNA strand cleavage.     

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.     

Analysis of strand exchange and DNA binding of enhancer-independent Gin recombinase mutants.

The Gin recombination system of phage Mu mediates inversion of the DNA sequence between two sites (gix). In addition to Gin protein and gix sites, recombination requires an enhancer bound by the host factor FIS. We analyzed mutants of Gin that function in the absence of the enhancer and FIS and mediate deletion and intermolecular fusion in addition to inversion. The linking number changes caused by inversion imply that mutant Gin alone can form the same synaptic complex and can use the same strand exchange mechanism as the complete wild-type system. However, the linking number changes also reveal that unlike wild-type Gin, mutant Gin can recombine through more than one synaptic complex and can relax DNA in the absence of synapsis. This expanded repertoire allows mutant Gin to mediate DNA rearrangements not performed by wild-type Gin. Because mutant Gin, but not wild-type Gin, unwinds gix site DNA upon binding, we postulate that FIS and the enhancer function with (-) supercoiling to promote this unwinding with wild-type Gin. The analysis of the topological changes during DNA fusion shows that both the parallel gix site configuration and the right-handed rotation of the sites during exchange of wild-type Gin are a result of the (-) supercoiling of the substrate and the number of entrapped supercoils in the synaptic complex.     

The DNA invertase Gin of phage Mu: formation of a covalent complex with DNA via a phosphoserine at amino acid position 9.

The DNA invertase Gin encoded by bacteriophage Mu catalyses efficient site-specific recombination between inverted repeat sequences (IR) in vivo and in vitro in the presence of the host factor FIS and the recombinational enhancer. We demonstrate that Gin alone is able to introduce single strand breaks into duplex DNA fragments which contain the IR sequence. Strand cleavage is site-specific and can occur on either strand within the IR. Cleaved molecules contain Gin covalently attached to DNA. The covalent complex is formed through linkage of Gin to the 5' DNA phosphate at the site of the break via a phosphoserine. Extensive site-directed mutational analysis showed that all mutants altered at serine position 9 were completely recombination deficient in vivo and in vitro. The mutant proteins bind to DNA but lack topoisomerase activity and are unable to introduce nicks. This holds true even for a conservative amino acid substitution at position 9. We conclude that serine at position 9 is part of the catalytic domain of Gin. The intriguing finding that the DNA invertase Gin has the same catalytic center as the DNA resolvases that promote deletions without recombinational enhancer and host factor FIS is discussed.     

Potential binding sites of the trans-activator FIS are present upstream of all rRNA operons and of many but not all tRNA operons

FIS, the Escherichia coli protein that stimulates the inversion of various DNA segments by binding to a recombinational enhancer, trans-activates a number of stable RNA operons and binds to the upstream activator sequence (UAS) of these operons (Nilsson et al. (1990) EMBO J. 9, 727). In a search for potential FIS-binding sites we have compared UASs of other stable RNA operons with a consensus FIS-binding sequence, compiled by comparing recombinational enhancers. Such sites can thus be recognized upstream of all rRNA and 13 tRNA operons. Matching with the consensus sequence varied, suggesting that the affinity of FIS for the sites differed. Accordingly, FIS binding to an upstream sequence of the metY(nusA) operon was found to be weaker than that to the UAS of the thrU(tufB) operon. No FIS binding sites were found upstream three tRNA operons.     

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 properties of the DNA invertase gin encoded by bacteriophage Mu

The host range of bacteriophage Mu is regulated through an invertible segment. Inversion requires the presence of two properly oriented recombination sites and a recombinational enhancer sis. The reaction is catalyzed by the Mu-encoded DNA invertase Gin and a host factor termed factors for inversion stimulation (FISs). We present a novel purification scheme for Gin. Purified Gin alone catalyzes the inversion reaction at very low efficiency recombining less than 0.8% of substrate molecules. When supplemented with FIS substrates containing the recombinational enhancer are recombined efficiently. Stoichiometric amounts of Gin are required for recombination.     

Site-specific recombination in bacteriophage Mu: characterization of binding sites for the DNA invertase Gin.

Site-specific DNA inversion in phage Mu is catalysed by the phage-encoded DNA invertase Gin and a host factor FIS. We demonstrate that purified Gin protein binds specifically to 34-bp sequences that flank the G segment as inverted repeats. Each inverted repeat (IR) contains two binding sites for Gin which have to be arranged in a specific configuration to constitute a recombinogenic site. While one of these sites is bound when present alone, the other site is bound only in conjunction with the first one, suggesting cooperative binding. In addition to the sites within the IR, Gin binds with lower affinity to AT-rich sequences adjacent to the IR. We demonstrate that these sites do not participate in the inversion reaction. The IR itself can be shortened to 25 bp without effect on inversion frequency. Using gel mobility shift experiments on circular permuted fragments containing the IR we show that Gin bends DNA upon binding. We discuss the possibility that DNA bending is related to the formation of a productive synaptic complex.     

DNA looping and the helical repeat in vitro and in vivo: effect of HU protein and enhancer location on Hin invertasome assembly.

Site-specific DNA inversion by the Hin recombinase requires the formation of a multicomponent nucleo-protein structure called an invertasome. In this structure, the two recombination sites bound by Hin are assembled together at the Fis-bound recombinational enhancer with the requisite looping of the intervening DNA segments. We have analyzed the role of the HU protein in invertasome assembly when the enhancer is located at variable positions close to one of the recombination sites. In the absence of HU in vitro and in hupA hupB mutant cells in vivo, invertasome assembly is very inefficient when there is < 104 bp of DNA between the enhancer and recombination site. Invertasome assembly in the presence of HU in vitro or in vivo displayed a periodicity beginning with 60 bp of intervening DNA that reflected its helical repeat. The average helical repeat for this DNA region was calculated by autocorrelation and Fourier transformation to be 11.2 bp per turn for supercoiled DNA both in the presence of HU in vitro and in hup+ cells in vivo. HU is the only protein in Escherichia coli that can promote invertasome formation with short DNA lengths between the enhancer and recombination sites. However, the presence of certain polyamines and a protein activity present in HeLa nuclear extracts can efficiently substitute for HU in invertasome assembly. These data support a model in which HU binds non-specifically to the DNA between the enhancer and recombination site to facilitate DNA looping.     

Identification of two functional regions in Fis: the N-terminus is required to promote Hin-mediated DNA inversion but not lambda excision.

The Fis protein of E. coli binds to a recombinational enhancer sequence that is required to stimulate Hin-mediated DNA inversion. Fis is also required for efficient lambda prophase excision in vivo. The properties of mutant Fis proteins were examined in vivo and in vitro with respect to their stimulatory effects on these two different site-specific DNA recombination reactions. Both recombination reactions are dramatically affected by mutations altering a helix-turn-helix DNA binding motif located near the Fis C-terminus (residues 74-93). These mutations invariably decrease DNA binding affinity and some cause reduced DNA bending. Mutations in the Fis N-terminal region reduce or abolish the stimulation of Hin-mediated DNA recombination by Fis, but have little or no effect on DNA binding or lambda excision. We conclude that there are at least two functionally distinct domains in Fis: a C-terminal DNA binding region that is required for promoting both DNA recombination reactions and an N-terminal region that is uniquely required for Hin-mediated inversion.     

Purification and characterization of the R64 shufflon-specific recombinase

The shufflon, a multiple DNA inversion system in plasmid R64, consists of four invertible DNA segments which are separated and flanked by seven 19-bp repeat sequences. The product of a site-specific recombinase gene, rci, promotes site-specific recombination between any two of the inverted 19-bp repeat sequences of the shufflon. To analyze the molecular mechanism of this recombination reaction, Rci protein was overproduced and purified. The purified Rci protein promoted the in vitro recombination reaction between the inverted 19-bp repeats of supercoiled DNA of a plasmid carrying segment A of the R64 shufflon. The recombination reaction was enhanced by the bacterial host factor HU. Gel electrophoretic analysis indicated that the Rci protein specifically binds to the DNA segments carrying the 19-bp sequences. The binding affinity of the Rci protein to the four shufflon segments as well as four synthetic 19-bp sequences differed greatly: among the four 19-bp repeat sequences, the repeat-a and -d sequences displayed higher affinity to Rci protein. These results suggest that the differences in the affinity of Rci protein for the 19-bp repeat sequences determine the inversion frequencies of the four segments.     

Interaction of a protein from rat liver nuclei with cruciform DNA.

We constructed a synthetic cruciform DNA which closely resembles Holliday junctions, a DNA structure formed during recombination or following the transition from interstrand to intrastrand base pairing in palindromic DNA sequences. We identified and partially purified a protein from rat liver that specifically binds to this cruciform DNA molecule and does not bind to single-stranded or double-stranded DNAs of the same sequence. This protein also binds to the cruciform structure formed by a 70 bp palindromic sequence cloned in plasmid pUC18. No detectable nucleolytic activity is associated with the rat liver cruciform-binding protein, in contrast to all cruciform-recognizing proteins known so far.