Purification of the integration host factor homolog of Rhodobacter capsulatus: cloning and sequencing of the hip gene, which encodes the beta subunit.

We describe a method for rapid purification of the integration host factor (IHF) homolog of Rhodobacter capsulatus that has allowed us to obtain microgram quantities of highly purified protein. R. capsulatus IHF is an alpha beta heterodimer similar to IHF of Escherichia coli. We have cloned and sequenced the hip gene, which encodes the beta subunit. The deduced amino acid sequence (10.7 kDa) has 46% identity with the beta subunit of IHF from E. coli. In gel electrophoretic mobility shift DNA binding assays, R. capsulatus IHF was able to form a stable complex in a site-specific manner with a DNA fragment isolated from the promoter of the structural hupSL operon, which contains the IHF-binding site. The mutated IHF protein isolated from the Hup- mutant IR4, which is mutated in the himA gene (coding for the alpha subunit), gave a shifted band of greater mobility, and DNase I footprinting analysis has shown that the mutated IHF interacts with the DNA fragment from the hupSL promoter region differently from the way that the wild-type IHF does.     

The HimA and HimD subunits of integration host factor can specifically bind to DNA as homodimers.

Integration host factor (IHF) is a heterodimeric protein from Escherichia coli which specifically binds to an asymmetric consensus sequence. We have isolated the individual subunits of IHF, HimA and HimD, and show that an active IHF protein can be reconstituted from these subunits. The HimA and HimD polypeptides alone are capable of specifically recognizing the same ihf sequence. The mobilities of the protein-DNA complexes in a gel-retardation assay suggest that the proteins bind as homodimers. The stability of the HimD-DNA complex is approximately 100-fold lower than that of the IHF-DNA complex. The HimA-DNA complex is even less stable and is only observed when a large excess of HimA is used. This instability is possibly due to the inability of HimA to form stable homodimers. By domain swapping between HimA and HimD, we have constructed an IHF fusion protein which has the putative DNA-binding domains of only HimA. This fusion protein forms stable dimers and makes specific protein-DNA complexes with a high efficiency. A comparable fusion protein with only the DNA-binding domains of HimD forms less stable complexes, suggesting that sequence-specific contacts between IHF and the ihf consensus are mainly provided by the HimA subunit.     

Single-chain integration host factors as probes for high-precision nucleoprotein complex formation

Integration host factor (IHF) is a heterodimeric, site-specific DNA-binding and DNA-bending protein from Escherichia coli. It is involved in high-precision DNA transactions where it serves as a key architectural component of specialized nucleoprotein structures (snups). We described recently a novel approach for protein engineering using a single polypeptide chain IHF, termed scIHF2, as a first example. ScIHF2 is made up of the alpha subunit of IHF which was inserted into the beta subunit at peptide bond Q39/G40 via two short linkers. The monomer behaves very similarly to the heterodimeric, parental IHF in biochemical and functional assays. Here, we describe an extension of this approach in which we shortened either one or both linkers by one amino acid, thereby generating three new variants termed scIHF1, 3, and 4. These variants exhibit distinct DNA-binding properties, different phenotypes in site-specific integrative and excisive recombination by phage lambda integrase in vitro, as well as in pSC101 replication assays in a DeltaIHF E. coli host. We also introduced a K45E substitution within the alpha domain of scIHF3 and based on electrophoretic mobility shift assays (EMSAs), argue that it significantly changes the DNA trajectory within the protein-DNA complex. Our results indicate that IHF's pleiotropic roles in DNA transactions inside E. coli require different types of high-precision DNA architectural activities. The scIHF variants described here will help to explore further how flexible these requirements are.     

The isolation and characterization of mutants of the integration host factor (IHF) of Escherichia coli with altered, expanded DNA-binding specificities.

The integration host factor (IHF) of Escherichia coli is a small, basic protein that is required for lambda site-specific recombination and a variety of cellular processes. It is composed of two subunits, alpha and beta, that are encoded by the himA and hip (himD) genes, respectively. IHF is a sequence-specific DNA-binding protein and bends the DNA when it binds. We have used the bacteriophage P22-based challenge phage selection to isolate suppressor mutants with altered, expanded DNA binding specificities. The suppressors were isolated by selecting mutants that recognize variants of the phage lambda H'IHF recognition site. Two of the mutants recognize both the wild-type and a single variant site and contain amino acid substitutions at positions 64 (Pro to Leu) or 65 (Lys to Ser) of the alpha subunit. These substitutions are in a region of the protein that is predicted to contain a flexible arm that interacts with DNA. Three other mutants, which recognize the wild-type and a different variant site, contain amino acid substitutions at position 44 (Glu to Lys, Val or Gly) of the beta subunit. These substitutions are in the middle of a predicted beta-strand of the subunit. We discuss the possible mechanisms of suppression by the mutants in terms of a model of the IHF-DNA complex proposed by Yang and Nash [Cell, 57, 869-880 (1989)].     

Interaction of integration host factor from Escherichia coli with the integration region of the Haemophilus influenzae bacteriophage HP1.

The specific DNA-binding protein integration host factor (IHF) of Escherichia coli stimulates the site-specific recombination reaction between the attP site of bacteriophage HP1 and the attB site of its host, Haemophilus influenzae, in vitro and also appears to regulate the expression of HP1 integrase. IHF interacts specifically with DNA segments containing the att sites and the integrase regulatory region, as judged by IHF-dependent retardation of relevant DNA fragments during gel electrophoresis. The locations of the protein-binding sites were identified by DNase I protection experiments. Three sites in the HP1 attP region bound IHF, two binding sites were present in the vicinity of the attB region, and one region containing three partially overlapping sites was present in the HP1 integrase regulatory segment. The binding sites defined in these experiments all contained sequences which matched the consensus IHF binding sequences first identified in the lambda attP region. An activity which stimulated the HP1 site-specific integration reaction was found in extracts of H. influenzae, suggesting that an IHF-like protein is present in this organism.     

Characterization of the binding sites of two proteins involved in the bacteriophage P2 site-specific recombination system.

Integration of the bacteriophage P2 genome into the Escherichia coli host chromosome occurs by site-specific recombination between the phage attP and E. coli attB sites. The phage-encoded 38-kDa protein, integrase, is known to be necessary for both phage integration as well as excision. In order to begin the molecular characterization of this recombination event, we have cloned the int gene and overproduced and partially purified the Int protein and an N-terminal truncated form of Int. Both the wild-type Int protein and the integration host factor (IHF) of E. coli were required to mediate integrative recombination in vitro between a supercoiled attP plasmid and a linear attB substrate. Footprint experiments revealed one Int-protected region on both of the attP arms, each containing direct repeats of the consensus sequence TGTGGACA. The common core sequences at attP and attB were also protected by Int from nuclease digestion, and these contained a different consensus sequence, AA T/A T/A C/A T/G CCC, arranged as inverted repeats at each core. A single IHF-protected site was located on the P (left) arm, placed between the core- and P arm-binding site for Int. Cooperative binding by Int and IHF to the attP region was demonstrated with band-shift assays and footprinting studies. Our data support the existence of two DNA-binding domains on Int, having unrelated sequence specificities. We propose that P2 Int, IHF, attP, and attB assemble in a higher-order complex, or intasome, prior to site-specific integrative recombination analogous to that formed during lambda integration.     

Bacteriophage P2 integrase: another possible tool for site-specific recombination in eukaryotic cells

Aims:  To investigate if the site-specific tyrosine integrase (Int) from phage P2 has features that would make it interesting for use of gene transfer into eukaryotic cells. These include the possibility of promoting recombination with a nonphage sequence, abolishing the requirement for the bacterial DNA-binding and -bending protein integration host factor (IHF), and localization to the nucleus of eukaryotic cells.
Methods and Results:  We show that the Int protein catalyzes site-specific recombination using a human sequence in Escherichia coli and in vitro although not as efficiently as with the wild-type bacterial sequence, and that insertion of high mobility group recognition boxes in the phage attachment site substrate abolish the requirement of IHF and allows efficient recombination in vitro in a eukaryotic cell extract. Furthermore, we show by fluorescence that the Int protein contains a functional intrinsic nuclear localization signal, localizing it to the nucleus in both HeLa and 293 cells.
Conclusions:  We conclude that P2 Int may be a potential tool for site-specific integration of genes into the human chromosome.
Significance and Impact of the Study:  The study implies the possibility of using multiple prokaryotic Int proteins with different specific integration sites in human cells for future gene therapy programmes.     

Structure and function of the Pseudomonas putida integration host factor.

Integration host factor (IHF) is a DNA-binding and -bending protein that has been found in a number of gram-negative bacteria. Here we describe the cloning, sequencing, and functional analysis of the genes coding for the two subunits of IHF from Pseudomonas putida. Both the ihfA and ihfB genes of P. putida code for 100-amino-acid-residue polypeptides that are 1 and 6 residues longer than the Escherichia coli IHF subunits, respectively. The P. putida ihfA and ihfB genes can effectively complement E. coli ihf mutants, suggesting that the P. putida IHF subunits can form functional heterodimers with the IHF subunits of E. coli. Analysis of the amino acid differences between the E. coli and P. putida protein sequences suggests that in the evolution of IHF, amino acid changes were mainly restricted to the N-terminal domains and to the extreme C termini. These changes do not interfere with dimer formation or with DNA recognition. We constructed a P. putida mutant strain carrying an ihfA gene knockout and demonstrated that IHF is essential for the expression of the P(U) promoter of the xyl operon of the upper pathway of toluene degradation. It was further shown that the ihfA P. putida mutant strain carrying the TOL plasmid was defective in the degradation of the aromatic model compound benzyl alcohol, proving the unique role of IHF in xyl operon promoter regulation.     

The role of integration host factor In gene expression in Escherichia coli

Integration host factor is a sequence-specific, histone-like, multifunctional DNA-binding and -bending protein of Escherichia coli. The characterization and functional analysis of this protein has been done mainly in bacteriophage lambda and other mobile genetic elements. Less is known concerning the role of integration host factor (IHF) in E. coli, although it has been implicated in a number of processes in this organism including DNA replication, site-specific recombination, and gene expression. This review presents recent work which suggests that IHF alters the activity of an unusually large number of operons in E. coli. We discuss the possible physiological relevance of the involvement of IHF in gene expression and the hypothesis that IHF is a member of a class of functionally redundant proteins that participate in chromosome structure and multiple processes involving DNA.     

Integration host factor stimulates both FimB- and FimE-mediated site-specific DNA inversion that controls phase variation of type 1 fimbriae expression in Escherichia coli

The site-specific DNA inversion that controls phase variation of type 1 fimbriation in E. coli is catalysed by two recombinases, FimB and FimE. Efficient inversion by either recombinase also requires the leucine-responsive regulatory protein (Lrp). In addition, FimB recombination is stimulated by the integration host factor (IHF). The effect of IHF on FimE inversion has not previously been reported. Here it is shown that IHF stimulates FimE recombination; in strain MG1655, mutants containing lesions in either the α ( ihfA ) or β ( ihfB ) subunits of IHF show a marked decrease in both FimB- (100-fold) and FimE (15 000-fold)-promoted switching. IHF is shown to bind with high affinity to sites both adjacent to (site I) and within (site II) the fim invertible element. Furthermore, mutations in site I or site II that lower the affinity of IHF binding in vitro were found to lower the frequency of FimE and/or FimB recombination in vivo . Although site I and site II mutations in combination have an effect on FimB-promoted switching comparable to that of IHF knockout mutations (100-fold), the cis site mutations have a much less marked effect (100-fold) on FimE-promoted switching.     

Ribonucleotide reductase activity and deoxyribonucleoside triphosphate metabolism during the cell cycle of S49 wild-type and mutant mouse T-lymphoma cells

We investigated deoxyribonucleoside triphosphate metabolism in S49 mouse T-lymphoma cells synchronized in different phases of the cell cycle. S49 wild-type cultures enriched for G1 phase cells by exposure to dibutyryl cyclic AMP (Bt2cAMP) for 24 h had lower dCTP and dTTP pools but equivalent or increased pools of dATP and dGTP when compared with exponentially growing wild-type cells. Release from Bt2cAMP arrest resulted in a maximum enrichment of S phase occurring 24 h after removal of the Bt2cAMP, and was accompanied by an increase in dCTP and dTTP levels that persisted in colcemid-treated (G2/M phase enriched) cultures. Ribonucleotide reductase activity in permeabilized cells was low in G1 arrested cells, increased in S phase enriched cultures and further increased in G2/M enriched cultures. In cell lines heterozygous for mutations in the allosteric binding sites on the M1 subunit of ribonucleotide reductase, the deoxyribonucleotide pools in S phase enriched cultures were larger than in wild-type S49 cells, suggesting that feedback inhibition of ribonucleotide reductase is an important mechanism limiting the size of deoxyribonucleoside triphosphate pools. The M1 and M2 subunits of ribonucleotide reductase from wild-type S49 cells were identified on two-dimensional polyacrylamide gels, but showed no significant change in intensity during the cell cycle. These data are consistent with allosteric inhibition of ribonucleotide reductase during the G1 phase of the cycle and release of this inhibition during S phase. They suggest that the increase in ribonucleotide reductase activity observed in permeabilized S phase-enriched cultures may not be the result of increased synthesis of either the M1 or M2 subunit of the enzyme.     

Essential interaction between lambdoid phage 21 terminase and the Escherichia coli integrative host factor

Lambdoid phage 21 requires the Escherichia coli integrative host factor (IHF) for growth. lambda-21 hybrids that have 21 DNA packaging specificity also require IHF. IHF-independent (her) mutants have been isolated. her mutations map in the amino-terminal half of the 21 1 gene. The 1 gene encodes the small subunit of the 21 terminase, and the amino-terminal half of the 1 polypeptide is a functional domain for specifically binding 21 DNA. Hence changes in the DNA-binding domain of terminase, her mutations, render 21 terminase able to function in the absence of IHF. Three of four her mutations studied are trans-dominant. An in vitro system was used to show that packaging of 21 DNA is IHF-dependent. IHF is directly required during the early, terminase-dependent steps of assembly. It is concluded that IHF is a host factor required for function of the 21 terminase. It is proposed, in analogy to the role of IHF in lambda integration, that IHF facilitates proper binding of 21 terminase to phage DNA. Consistent with this proposal, possible IHF-binding sites are present in the 21 cohesive end site.     

Role of architectural elements in combinatorial regulation of initiation of DNA replication in Escherichia coli

Bending of DNA is a prerequisite of site-specific recombination and gene expression in many regulatory systems involving the assembly of specific nucleoprotein complexes. We have investigated how the uniquely clustered Dam methylase sites, GATCs, in the origin of Escherichia coli replication ( oriC  ) and their methylation status modulate the geometry of oriC and its interaction with architectural proteins, such as integration host factor (IHF), factor for inversion stimulation (Fis) and DnaA initiator protein. We note that 3 of the 11 GATC sites at oriC are strategically positioned within the IHF protected region. Methylation of the GATCs enhances IHF binding and alters the IHF-induced bend at oriC . GATC motifs also contribute to intrinsic DNA curvature at oriC and the degree of bending is modulated by methylation. The IHF-induced bend at oriC is further modified by Fis protein and IHF affinity for its binding site may be impaired by protein(s) binding to GATCs within the IHF site. Thus, GATC sites at oriC affect the DNA conformation and GATCs, in conjunction with the protein-induced bends, are critical cis -acting elements in specifying proper juxtapositioning of initiation factors in the early steps of DNA replication.