The FIS protein fails to block the binding of DnaA protein to oriC, the Escherichia coli chromosomal origin.

The Escherichia coli chromosomal origin contains several bindings sites for factor for inversion stimulation (FIS), a protein originally identified to be required for DNA inversion by the Hin and Gin recombinases. The primary FIS binding site is close to two central DnaA boxes that are bound by DnaA protein to initiate chromosomal replication. Because of the close proximity of this FIS site to the two DnaA boxes, we performed in situ footprinting with 1, 10-phenanthroline-copper of complexes formed with FIS and DnaA protein that were separated by native gel electrophoresis. These studies show that the binding of FIS to the primary FIS site did not block the binding of DnaA protein to DnaA boxes R2 and R3. Also, FIS appeared to be bound more stably to oriC than DnaA protein, as deduced by its reduced rate of dissociation from a restriction fragment containing oriC . Under conditions in which FIS was stably bound to the primary FIS site, it did not inhibit oriC plasmid replication in reconstituted replication systems. Inhibition, observed only at high levels of FIS, was due to absorption by FIS binding of the negative superhelicity of the oriC plasmid that is essential for the initiation process.     

A truncated peptide model of the mutant P61A FIS forms a stable dimer

Factor for inversion stimulation (FIS) is a 98-residue homodimeric DNA-binding protein involved in several different cellular processes including DNA inversion and the regulation of multiple genes. FIS contains a flexible and functionally important N-terminus followed by four helices (A-D), the last two of which consist of the DNA-binding region. Helix B, which comprises the main dimerization interface has a 20 degrees kink at its center that was originally thought to be caused by the presence of a proline at position 61. However, it was later shown that the kink remained largely intact and that FIS retained its native-like function when the proline was mutated to an alanine. We previously showed that the P61A mutation increased the stability of FIS, but decreased its equilibrium denaturation cooperativity apparently due to preferential stabilization of the B-helix. Here we studied a peptide of P61A FIS, corresponding to residues 26-71 (26-71(A3) FIS), which encompasses the dimer interface (helices A and B). Circular dichroism (CD) and size-exclusion chromatography/multi-angle light scattering showed that the peptide was alpha-helical and dimeric, respectively, as expected based on the 3D structure of FIS. Urea-induced equilibrium denaturation experiments monitored by far-UV CD revealed a concentration-dependent transition, and data analysis based on a N2<-->2U model yielded a DeltaG of approximately -10 kcal/mol. Our results suggest that 26-71(A3) FIS can form a stable dimeric structure despite lacking the N- and C-terminus of native FIS.     

The location of an engineered inter-subunit disulfide bond in factor for inversion stimulation (FIS) affects the denaturation pathway and cooperativity

Two crossed-linked variants of the homodimeric DNA binding protein factor for inversion stimulation (FIS) were created via engineering of single intermolecular disulfide bonds. The conservative S30C and the nonconservative V58C FIS independent mutations resulted in FIS crossed-linked at the A helix (C30-C30) and at the middle of the B helix (C58-C58). This study sought to investigate how the location of an intermolecular disulfide bond may determine the effect on stability and its propagation through the structure to preserve or alter the denaturation cooperativity of FIS. The oxidized and reduced S30C and V58C FIS exhibited a far-UV CD spectrum and DNA binding affinities that were similar to WT FIS, indicating no significant changes in secondary and tertiary structure. However, the reduced and oxidized forms of the mutants revealed significant differences in the stability and equilibrium denaturation mechanism between the two mutants. In the reduced state, S30C FIS had very little effect on FIS stability, whereas V58C FIS was 2-3 kcal/mol less stable than WT FIS. Interestingly, while both disulfide bonds significantly increased the resistance to urea- and guanidine hydrochloride (GuHCl)-induced denaturation, oxidized V58C FIS exhibited a three-state GuHCl-induced transition. In contrast, oxidized S30C FIS displayed a highly cooperative WT-like transition with both denaturants. The three-state denaturation mechanism of oxidized V58C FIS induced by the GuHCl salt was reproduced by urea denaturation at pH 4, suggesting that disruption of a C-terminus salt-bridge network is responsible for the loss of denaturation cooperativity of V58C FIS in GuHCl or urea, pH 4. A second mutation on V58C FIS created to place a single tryptophan probe (Y95W) at the C-terminus further implies that the denaturation intermediate observed in disulfide crossed-linked V58C FIS results from a decoupling of the stabilities of the C-terminus and the rest of the protein. These results show that, unlike the C30-C30 intermolecular disulfide bond, the C58-C58 disulfide bond did not evenly stabilize the FIS structure, thereby highlighting the importance of the location of an engineered disulfide bond on the propagation of stability and the denaturation cooperativity of a protein.     

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.     

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.     

The role of the local environment of engineered Tyr to Trp substitutions for probing the denaturation mechanism of FIS

Factor for inversion stimulation (FIS), a 98-residue homodimeric protein, does not contain tryptophan (Trp) residues but has four tyrosine (Tyr) residues located at positions 38, 51, 69, and 95. The equilibrium denaturation of a P61A mutant of FIS appears to occur via a three-state (N₂ ⇆ I₂ ⇆ 2U) process involving a dimeric intermediate (I₂). Although it was suggested that this intermediate had a denatured C-terminus, direct evidence was lacking. Therefore, three FIS double mutants, P61A/Y38W, P61A/Y69W, and P61A/Y95W were made, and their denaturation was monitored by circular dichroism and Trp fluorescence. Surprisingly, the P61A/Y38W mutant best monitored the N₂ ⇆ I₂ transition, even though Trp38 is buried within the dimer removed from the C-terminus. In addition, although Trp69 is located on the protein surface, the P61A/Y69W FIS mutant exhibited clearly biphasic denaturation curves. In contrast, P61A/Y95W FIS was the least effective in decoupling the two transitions, exhibiting a monophasic fluorescence transition with modest concentration-dependence. When considering the local environment of the Trp residues and the effect of each mutation on protein stability, these results not only confirm that P61A FIS denatures via a dimeric intermediate involving a disrupted C-terminus but also suggest the occurrence of conformational changes near Tyr38. Thus, the P61A mutation appears to compromise the denaturation cooperativity of FIS by failing to propagate stability to those regions involved mostly in intramolecular interactions. Furthermore, our results highlight the challenge of anticipating the optimal location to engineer a Trp residue for investigating the denaturation mechanism of even small proteins.     

Variable contributions of tyrosine residues to the structural and spectroscopic properties of the factor for inversion stimulation

The diverse roles of tyrosine residues in proteins may be attributed to their dual hydrophobic and polar nature, which can result in hydrophobic and ring stacking interactions, as well as hydrogen bonding. The small homodimeric DNA binding protein, factor for inversion stimulation (FIS), contains four tyrosine residues located at positions 38, 51, 69, and 95, each involved in specific intra- or intermolecular interactions. To investigate their contributions to the stability, flexibility, and spectroscopic properties of FIS, each one was independently mutated to phenylalanine. Equilibrium denaturation experiments show that Tyr95 and Tyr51 stabilize FIS by about 2 and 1 kcal/mol, respectively, as a result of their involvement in a hydrogen bond-salt bridge network. In contrast, Tyr38 destabilizes FIS by about 1 kcal/mol due to the placement of a hydroxyl group in a hydrophobic environment. The stability of FIS was not altered when the solvent-exposed Tyr69 was mutated. Limited proteolysis with trypsin and V8 proteases was used to monitor the flexibility of the C-terminus (residues 71-98) and the dimer core (residues 26-70), respectively. The results for Y95F and Y51F FIS revealed a different proteolytic susceptibility of the dimer core compared to the C-terminus, suggesting an increased flexibility of the latter. DNA binding affinity of the various FIS mutants was only modestly affected and correlated inversely with the C-terminal flexibility probed by trypsin proteolysis. Deconvolution of the fluorescence contribution of each mutant revealed that it varies in intensity and direction for each tyrosine in WT FIS, highlighting the role of specific interactions and the local environment in determining the fluorescence of tyrosine residues. The significant changes in stability, flexibility, and signals observed for the Y51F and Y95F mutations are attributed to their coupled participation in the hydrogen bond-salt bridge network. These results highlight the importance of tyrosine hydrogen-bonding and packing interactions for the stability of FIS and demonstrate the varying roles that tyrosine residues can play on the structural and spectroscopic properties of even small proteins.     

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.     

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.     

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.