In vivo interaction of the Escherichia coli integration host factor with its specific binding sites.

The histone-like protein integration host factor (IHF) of Escherichia coli binds to specific binding sites on the chromosome or on mobile genetic elements, and is involved in many cellular processes. We have analyzed the interaction of IHF with five different binding sites in vitro and in vivo using UV laser footprinting, a technique that probes the immediate environment and conformation of a segment of DNA. Using this generally applicable technique we can directly compare the binding modes and interaction strengths of a DNA binding protein in its physiological environment within the cell to measurements performed in vitro. We conclude that the interactions between IHF and its specific binding sites are identical in vitro and in vivo. The footprinting signal is consistent with the model of IHF-binding to DNA proposed by Yang and Nash (1989). The occupancy of binding sites varies with the concentration of IHF in the cell and allows to estimate the concentration of free IHF protein in the cell.     

The interaction of Escherichia coli integration host factor with the cohesive end sites of phages lambda and 21

The interaction of E. coli integration host factor (IHF) with the cohesive end sites (cos's) of phages lambda and 21 has been studied by the DNAase I footprinting technique. Six potential sites in cos lambda differ from the consensus IHF binding sequence by 1 to 3 base pairs. Of the six, one site, I1, binds IHF strongly. The I1 segment protected by IHF contains two sequences that closely match the IHF consensus binding sequence. Another site, I2, binds IHF moderately well, and three sites: 10', 13 and 14 bind IHF very weakly. The 10 site does not bind IHF under the conditions used here. In phage 21 the DNA segment extending to the right from the cohesive ends, which contains three potential IHF binding sites, was examined. Two sites bind IHF well; I1, the 21 analogue of one of the lambda I1 sites, and I0, a site not analogous to a lambda site. The third 21 site, I2, binds IHF moderately well, as does the analogous I2 site in lambda. The significance of the results for lambda DNA packaging is discussed.     

Integration of bacteriophages lambda and phi 80 in wild-type Escherichia coli at secondary attachment sites. II. Genetic structure and mechanism of polylysogen formation for lambda, phi 80 and the lambda att80 hybrid

Summary The frequency of occurrence and the genetic structure of polylysogens were studied for phages , 80 and att80. In the case of , frequency of polylysogenization is high (0.20 to 0.41) with a tandem integration of prophages at the primary att site (att). With 80 and att80, this frequency is about 10 times lower, and usually one prophage becomes integrated at the primary att site (att80-I) while another (sometimes two others) integrates at one of the secondary sites. At least four secondary att80 sites have been found in wild-type Escherichia coli , two of which (near the his and tolC loci) are preferred. The frequency of secondary integration of 80 and att80 does not differ significantly in the wild-type host and in that deleted for the primary att site (0.041 and 0.045, respectively, among surviving cells at an MOI of 10).Homoimmune superinfection has revealed a constitutive cI-independent expression of the 80 int gene in the prophage state. The only 80 tandem detected proved to be unstable. With the 80int ^- mutant, we observed stabilization of 80 tandems; as a consequence, their frequency of occurrence during coinfection with 80int ⁺ was up to the level and no nontandem insertions were found. A model is proposed for the 80 and att80 nontandem integration.Abbreviations TP transducing phage(s) - PFU plaque-forming units - PC pink clear-resistant colonies on EMBO plates - MOI multiplicity of infection - O origin of Hfr transfer

---

     

Bending of the bacteriophage lambda attachment site by Escherichia coli integration host factor

Escherichia coli integration host factor (IHF) is a small basic protein that is required for efficient integrative recombination of bacteriophage lambda. IHF binds specifically to sequences within attP, the site in bacteriophage lambda that undergoes recombination. It has been suggested that the binding of IHF creates bends in DNA so as to help attP condense into a compact structure that is activated for recombination. In this work we show that IHF binding to either of two sites found within attP does indeed produce bending of DNA. In contrast, the other recombination protein needed for integrative recombination, Int, does not appreciably bend the DNA to which it is bound. In agreement with the proposal that IHF bending is important for creating a condensed attP, bending by IHF persists in the presence of bound Int. Our conclusions about protein-directed bends in DNA are based on the study of the electrophoretic mobility of a set of permuted DNA fragments in the presence or absence of IHF and/or Int. To facilitate this study, we have constructed a novel vector that simplifies the generation of permuted fragments. This vector should be useful in studying the bending of other DNA sequences by specific binding proteins.     

Integration of bacteriophages lambda and phi 80 in wild-type Escherichia coli at secondary attachment sites. I. Formation of secondary lysogens

Summary The family of lambdoid phages displays a varying specificity of integration into the host chromosome. The phage DNA failed to get inserted at the secondary site(s) of the gal operon (frequency <2.6x10^-8) in the presence of the primary (normal) att site. By contrast, 80 and the att80 hybrid (x80) became integrated into wild-type Escherichia coli at at least two secondary att sites of the btuB locus, and the latter near purE and purC as well (frequency 2x10^-3-10^-4). The integration of 80 and att80 into btuB occurred with about the same frequency as in cells in which the normal insertion site had been deleted (0.7-4.0x10^-6). An analysis of the secondary lysogens with the prophage in btuB showed them to be polylysogens; the additional prophage(s) was found at the primary att site. We also failed to observe the integration into other loci of 80 and att80 with the formation of secondary monolysogens (frequency <0.0035 at MOI-10^-3 or 10). It is presumed that these prophages become integrated at secondary att sites only if the primary site is occupied.Abbreviations MOI multiplicity of infection (PFU/cell) - PFU plaque-forming unit - TP transducing phage - P1/HfrH P1vir multiplied on HfrH - Rif-R rifampin-resistance - Int int protein     

Preferred secondary attachment site of prophage phi80 on Escherichia coli K-12 chromosome]

The integration frequency of phage att80 immlambdac1857 into the chromosome of a mutant strain H47 Escherichia coli K-12 deleted for the normal prophage insertion site is found to be about 20-fold decreased as compared with its integration into the wild type strain. The most of the resulting lysogens contain the prophage at the secondary attachment site of the mutant bacterial chromosome which is preferentially utilized for prophage insertion. This attachment site (att80-II) is located close to his-genes on the chromosome of H47 strain. Prophage curing procedure of such abnormal lysogens results in the appearance of rare auxotrophic heat-resistant survivors with the His- phenotype. In some cases the prophage insertion can induce an inversion of a neighbouring genetic region. Such lysogens contain the purC gene near prophage located at the att80-II site, and after curing they segregate the heat-resistant His- and Pur- colonies.     

Growth phase variation of integration host factor level in Escherichia coli.

We have measured the intracellular abundance of integration host factor (IHF), a site-specific, heterodimeric DNA-binding protein, in exponential- and stationary-phase cultures of Escherichia coli K-12. Western immunoblot analysis showed that cultures that had been growing exponentially for several generations contained 0.5 to 1.0 ng of IHF subunits per microgram of total protein and that this increased to 5 to 6 ng/microgram in late-stationary-phase cultures. IHF is about one-third to one-half as abundant in exponentially growing cells as HU, a structurally related protein that binds DNA with little or no site specificity. Wild-type IHF is metabolically stable, but deletion mutations that eliminated one subunit reduced the abundance of the other when cells enter stationary phase. We attribute this reduction to the loss of stabilizing interactions between subunits. A mutation that inactivates IHF function but not subunit interaction increased IHF abundance, consistent with results of previous work showing that IHF synthesis is negatively autoregulated. We estimate that steady-state exponential-phase cultures contain about 8,500 to 17,000 IHF dimers per cell, a surprisingly large number for a site-specific DNA-binding protein with a limited number of specific sites. Nevertheless, small reductions in IHF abundance had significant effects on several IHF-dependent functions, suggesting that the wild-type exponential phase level is not in large excess of the minimum required for occupancy of physiologically important IHF-binding sites.     

Overproduction of Escherichia coli integration host factor, a protein with nonidentical subunits.

Integration host factor (IHF) is a small, basic protein that is needed for efficient recombination of bacteriophage lambda, as well as for other host and viral functions. We have constructed strains in which the two subunits of IHF, encoded by the himA and hip genes of Escherichia coli, are expressed under the control of the lambda rho L promoter. Separate overexpression of himA and hip led to the production of unstable and insoluble peptides, respectively. In contrast, the overexpression of both genes conjointly led to the accumulation of large amounts of active IHF. Extracts of such cells provided the starting material for a rapid purification procedure that results in milligram quantities of apparently homogeneous IHF.     

The P1 plasmid partition complex at parS. The influence of Escherichia coli integration host factor and of substrate topology

The P1 ParB protein is required for active partition and thus stable inheritance of the plasmid prophage. ParB and the Escherichia coli protein integration host factor (IHF) participate in the assembly of a partition complex at the centromere-like site parS. In this report the role of IHF in the formation of the partition complex has been explored. First, ParB protein was purified for these studies, which revealed that ParB forms a dimer in solution. Next, the IHF binding site was mapped to a 29-base pair region within parS, including the sequence TAACTGACTGTTT (which differs from the IHF consensus in two positions). IHF induced a strong bend in the DNA at its binding site. Versions of parS which have lost or damaged the IHF binding site bound ParB with greatly reduced affinity in vitro and in vivo. Measurements of binding constants showed that IHF increased ParB affinity for the wild-type parS site by about 10,000-fold. Finally, DNA supercoiling improved ParB binding in the presence of IHF but not in its absence. These observations led to the proposal that IHF and superhelicity assist ParB by promoting its precise positioning at parS, a spatial arrangement that results in a high affinity of ParB for parS.     

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.     

Identification of related genes in phages phi 80 and P22 whose products are inhibitory for phage growth in Escherichia coli IHF mutants.

Bacteriophage lambda grows in both IHF+ and IHF- host strains, but the lambdoid phage phi 80 and hybrid phage lambda (QSRrha+)80 fail to grow in IHF- host strains. We have identified a gene, rha, in the phi80 region of the lambda(QSRrha+)80 genome whose product, Rha, inhibits phage growth in an IHF- host. A search of the GenBank database identified a homolog of rha, ORF201, a previously identified gene in phage P22, which similarly inhibits phage growth in IHF- hosts. Both rha and ORF201 contain two possible translation start sites and two IHF binding site consensus sequences flanking the translation start sites. Mutations allowing lambda (QSRrha+)80 and P22 to grow in IHF- hosts map in rha and ORF201, respectively. We present evidence suggesting that, in an IHF+ host, lambda(QSRrha+)80 expresses Rha only late in infection but in an IHF- host the phage expresses Rha at low levels early in infection and at levels higher than those in an IHF+ host late in infection. We suspect that the deregulation of rha expression and, by analogy, ORF201 expression, is responsible for the failure of phi80, lambda(QSRrha+)80, and P22 to grow in IHF mutants.     

Mechanism of non-tandem integration of prophage phi 80 into the chromosome of the wild-type Escherichia coli

We studied the ability of lambda, phi 80 and their hybrid lambda att80 to lysogenize homoimmune monolysogens and examined the prophage locations on the chromosome of the resulting polylysogens. We observed an effective integration of phi 80 and lambda att80, in contrast to lambda, into the host chromosome, exclusively, at the attachment sites that were not occupied by the resident prophage (nontandem). Besides, the lambda att80 (int+) prophage was observed to ensure effective nontandem integration of a homoimmune int mutant DNA. Hence, we inferred that the expression of the int gene in the phi 80 prophage is constitutive, cI-independent and results in nontandem integration of the homoimmune prophage. The validity of this inference has been supported experimentally: (i) the only lysogen that was found to contain a phi 80 tandem was highly unstable (spontaneous segregation of monolysogens occurred 6-7 times more frequently than with the lambda tandem); (ii) an int inactivating mutation stabilized the phi 80 tandem; as a result, the int mutant has the frequency of tandem integration as high as that of lambda, while no nontandem integration was observed. A hypothesis is proposed which accounts for the instability of the phi 80 tandems and explains the relation between this phenomenon and the prophage ability to integrate into secondary attachment sites in the presence of the primary (normal) one.     

Global gene expression profiling in Escherichia coli K12. The effects of integration host factor

We have used nylon membranes spotted in duplicate with full-length polymerase chain reaction-generated products of each of the 4,290 predicted Escherichia coli K12 open reading frames (ORFs) to measure the gene expression profiles in otherwise isogenic integration host factor IHF(+) and IHF(-) strains. Our results demonstrate that random hexamer rather than 3' ORF-specific priming of cDNA probe synthesis is required for accurate measurement of gene expression levels in bacteria. This is explained by the fact that the currently available set of 4,290 unique 3' ORF-specific primers do not hybridize to each ORF with equal efficiency and by the fact that widely differing degradation rates (steady-state levels) are observed for the 25-base pair region of each message complementary to each ORF-specific primer. To evaluate the DNA microarray data reported here, we used a linear analysis of variance (ANOVA) model appropriate for our experimental design. These statistical methods allowed us to identify and appropriately correct for experimental variables that affect the reproducibility and accuracy of DNA microarray measurements and allowed us to determine the statistical significance of gene expression differences between our IHF(+) and IHF(-) strains. Our results demonstrate that small differences in gene expression levels can be accurately measured and that the significance of differential gene expression measurements cannot be assessed simply by the magnitude of the fold difference. Our statistical criteria, supported by excellent agreement between previously determined effects of IHF on gene expression and the results reported here, have allowed us to identify new genes regulated by IHF with a high degree of confidence.     

Genomic engineering of Escherichia coli by the phage attachment site-based integration system with mutant loxP sites

Metabolic engineering of Escherichia coli using plasmids is problematic, which is addressed by developing a toolbox for genomic engineering of E. coli. This toolbox includes the attP site-based integration vectors and the attB site-based template vectors, equipped with mutant loxP sites (i.e., LE* and RE*). The former vectors facilitate integration of passenger genes into attB sites while the latter allows creation of new attB sites. Consequently, the inserted vector backbone is flanked by LE* and RE* sites and can be rescued by Cre. Based on this approach, the biosynthetic pathway of poly(3-hydroxybutyric acid) was first built in E. coli. By scoring the observable phenotype of integrants, the result revealed that the efficiency of gene integration could reach 100%. In addition, reconstruction of the n-butanol-synthesizing pathway in E. coli resulted in a plasmid-free producer strain. As a consequence, the producer strain was able to stably overproduce n-butanol (3.7 g/L) from glucose (20 g/L). Finally, exoglucanase was overexpressed in E. coli that carried multiple genomic copies of the celY gene. Overall, it indicates a promise of our method for cycling improvement of E. coli.     

A genomic-scale search for regulatory binding sites in the integration host factor regulon of Escherichia coli K12

We examined general aspects of the DNA-protein interaction between the integration host factor (IHF) global regulator and its regulatory binding sites in the Escherichia coli K12 genome. Two models were developed with distinct weight matrices for the regulatory binding sites recognized by IHF. Using these matrices we performed a genome scale scan and built a set of computationally predicted binding sites for each of the models. The sites found by the model associated with repetitive sequences had a higher score in the sequence to matrix alignment. They were also more rare than the other sites. The sites not associated with repeats rapidly tended to become undistinguishable from the background as statistical stringency was relaxed. We compared our results to the known sites documented in RegulonDB and found new members of the IHF Regulon. The two models exhibit clearly distinct affinity patterns (scores in the sequence to matrix alignments and in the number of regulatory sites), as we vary the stringency of the statistical confidence parameters. We suggest that these differences may play an important role in the dynamics of the network. We concluded that IHF may regulate two genes encoding ATP-dependent RNA helicases. This interaction is not described in RegulonDB, even as a computational prediction. IHF may also regulate RNA modification processes.     

Evidence for common binding sites for ferrichrome compounds and bacteriophage phi 80 in the cell envelope of Escherichia coli.

Mutants ton A and ton B of Escherichia coli K12, known to be resistant to bacteriophage phi80, were found to be insensitive as well to albomycin, an analogue of the specific siderochrome ferrichrome. Ferrichrome at micromolar concentrations strongly inhibited plaque production by phi80. Preincubation with ferrichrome did not inactivate the phage. At a concentration at which ferrichrome allowed 90% inhibition of plaque formation, the chromium analogue of ferrichrome showed no detectable activity. Similarly, ethylenediaminetetraacetic acid, ferrichrome A, and certain siderochromes structurally distinct from ferrichrome, such as ferrioxamine B, schizokinen, citrate, and enterobactin, did not show detectable inhibitory activity. However, rhodotorulic acid showed moderate activity. A host range mutant of phi80, phi80h, was also inhibited by ferrichrome, as was a hybrid of phage lambda possessing the host range of phi80. However, phage lambdacI- and a hybrid of phi80 possessing the host range of lambda were not affected by ferrichrome. Finally, ferrichrome and chromic deferriferrichrome were shown to inhibit adsorption of phi80 to sensitive cells, ferrichrome giving 50% inhibition of adsorption at a minimal concentration of 8 nM. It is suggested that a component of the ferrichrome uptake system may reside in the outer membrane of E. coli K12 and may also function as a component of the receptor site for bacteriophage phi80, and that ferrichrome inhibition of the phage represents a competition for this common site.     

The integration host factor of Escherichia coli binds to multiple sites at plasmid R6K gamma origin and is essential for replication.

Examination of the effect of the himA and himD mutants of E. coli on the maintenance of plasmid R6K has revealed that the gamma origin-containing replicons cannot be established in any of the mutants deficient in the production of E. coli Integration Host Factor (IHF). Contrary, the R6K derivatives containing other origins of the plasmid (alpha and/or beta) replicate in a host lacking functional IHF protein. We show that IHF protein binds specifically to a segment of the replication region which is essential for the activity of all three R6K origins. Mapping the IHF binding sequence with neocarzinostatin showed that the protein protects three segments of the origin: two strong binding sites reside within an AT-rich block, while the third, considerably weaker site is separated from the other two by a cluster of the seven 22 bp direct repeats. These seven repeats have been shown previously to bind the R6K-encoded initiator protein pi. We also demonstrate that the establishment of pi-origin complexes prior to IHF addition prevents the binding of the IHF protein to the gamma origin. The binding sequences of IHF and pi proteins do not overlap, therefore, we propose that the binding of pi protein alters the structure of the DNA and thereby prevents the subsequent binding of IHF protein.