Site promiscuity of coliphage HK022 integrase as a tool for gene therapy.

The integrase (Int) encoded by the lambdoid coliphage HK022 targets in its host chromosome a 21 base pair (bp) recombination site termed attB or BOB'. attB comprises two 7 bp partially inverted (palindromic) Int-binding sites of 7 bp each termed B and B'. B and B' flank a central 7 bp crossover site or 'overlap' (O). We show that replacing O with a random 7 bp sequence supports Int-mediated site-specific recombination as long as the cognate and larger phage recombination site attP features an identical O sequence. This promiscuity allowed us to identify on the human genome several native active secondary attB sites ('attB') with random overlaps that flank human deleterious mutations, raising the prospect of using such sites to cure the 'attB'-flanked mutations by Int-catalyzed RMCE (recombinase-mediated cassette exchange) reactions. An analysis of such active and inactive 'attB's suggested a minimal 14-15 bp attB consensus sequence (instead of the 21 bp) with a reduced 3 bp palindrome.

Transcriptional analysis of the pst operon of Escherichia coli.

The pst operon of Escherichia coli, which encodes the phosphate-specific transport system, is composed of five genes, pstS, pstC, pstA, pstB and phoU, whose transcription is induced by phosphate starvation. A phosphate-regulated promoter located upstream of the most proximal gene ( pstS) controls the transcription of the entire operon. Though the full-length pst mRNA could be detected by an improved RT-PCR protocol, Northern analysis using several pst-specific probes failed to reveal this transcript. Instead, smaller but distinct pst mRNA species were evident. Primer-extension experiments localized the 5' ends of pst mRNAs within the operon. The data suggest that the full-length mRNA is rapidly processed post-transcriptionally.

The effect of mutations in the Xis-binding sites on site-specific recombination in coliphage HK022.

Excisionase (Xis) is an accessory protein that is required for the excision of the related prophages lambda and HK022. Xis binds to two tandemly arranged binding sites (X1 and X2) on the P arm of the recombination sites attP and attR. Gel-retardation analyses and site-specific recombination assays were conducted on derivatives bearing site-directed mutations in the X1 and X2 sites of phage HK022. The results confirm the cooperative binding of Xis to its sites, showing that binding to X1 stimulates further binding to X2. The results also show that mutants affected in a single site are inactive in excision, whereas mutants affected in both sites, which show a complete absence of Xis binding, display significant excision activity. This restored activity is attributed to the interaction of Xis with Integrase, the protein that catalyzes the site-specific recombination reaction.

Core-binding specificity of bacteriophage integrases.

The site-specific recombination systems of bacteriophages lambda and HK022 share the same mechanism and their integrase proteins show strong homology. Nevertheless the integrase protein of each phage can only catalyze recombination between its own att sites. Previous work has shown that the specificity determinants in the att sites are located within the sequences that bind the integrase to the core of att. DNA fragments that carry attL and attR sites of each phage were challenged with each of the two integrases and the DNA-protein complexes were examined by the gel-retardation technique. The results show that each integrase can form higher-order DNA-protein complexes only with its cognate att sites, suggesting that differences in the mode of binding to the core are responsible for the specificity difference between the two integrases.

Site-specific recombination in mammalian cells expressing the Int recombinase of bacteriophage HK022.

The int gene of bacteriophage HK022, coding for the integrase protein, was cloned in a mammalian expression vector downstream of the human cytomegalovirus (CMV) promoter. Green monkey kidney cells (COS-1) and mouse embryo fibroblast cells (NIH3T3) transiently transfected with the recombinant plasmid express the integrase protein. Co-transfection of this plasmid with reporter plasmids for site-specific recombination and PCR analyses show that the integrase promotes site-specific integration as well as excision. These reactions occurred without the need to supply integration host factor and excisionase, the accessory proteins that are required for integrase-promoted site-specific recombination in vitro as well as in the natural host Escherichia coli.

The integration host factor (IHF) affects the expression of the phosphate-binding protein and of alkaline phosphatase in Escherichia coli.

The genes encoding alkaline phosphatase (phoA) and the inducible inorganic phosphate transport system Pst (pstS,C,A,B,U) belong to the PHO regulon. Mutants of Escherichia coli lacking the global regulatory protein integration host factor (IHF) show an increased level of alkaline phosphatase and a decreased level of Pst. IHF binds weakly but specifically to a DNA fragment containing the promoter region of the pst operon but does not bind to a fragment that includes the promoter region of phoA. It is proposed that IHF is a positive regulator of the pst operon and as such controls indirectly the expression of phoA.

The relation between ppGpp and the PHO regulon in Escherichia coli.

Starving of Escherichia coli cells for inorganic orthophosphate (Pi) results in the accumulation of spoT-dependent ppGpp and induces the expression of genes of the PHO regulon. In a delta relA delta spoT strain that is unable to accumulate ppGpp the expression of two genes (phoA and pstS) that belong to the PHO regulon is impaired, even in constitutive mutants. The transcription of phoA and of pstS is not affected in the ppGpp0 strain, and therefore this impairment is due to a post-transcriptional defect. Conversely, overexpression of ppGpp inhibits transcription of these two PHO regulon genes. In phoB mutants, the accumulation of ppGpp during Pi starvation is diminished, suggesting that PhoB or one of the PHO products is involved in the control of ppGpp accumulation. We propose that the presence of ppGpp in the cell, but not its accumulation as a result of the starvation stress, is important for the expression of the PHO genes.

A second site-specific recombination event in the lambdoid bacteriophage HK022.

An in vitro site-specific recombination reaction of the lambdoid phage HK022 has revealed two supercoiled products that proved to be Holliday intermediates. One of them is the Holliday intermediate which has resulted from an attP x attB reaction. The other is an intermediate which has resulted from a recombination reaction between attP and the attL site of the product from the first reaction. The preferential attL x attP over attR x attP reaction was confirmed in vitro and in vivo by challenging attP sites with attL and attR sites. The biased attP x attL over attP x attR reaction in phage HK022 is discussed.

Identifying determinants of recombination specificity: construction and characterization of chimeric bacteriophage integrases.

Bacteriophage integrases are members of a family of structurally related enzymes that promote recombination between DNA molecules that carry specific sites. Phages lambda and HK022 encode closely related integrases that recognize different sets of sequences within the core regions of their respective attachment sites. To locate the amino acid residues that determine this difference in specificity, we isolated recombinant phages that produce chimeric integrases and measured the ability of these chimeras to promote recombination of lambda and HK022 sites in vivo. A chimera that is of lambda origin except for one HK022 residue at position 99 and 12 HK022 residues located between positions 279 and 329 had wild-type HK022 specificity and activity for both integrative and excisive recombination. Chimeras containing certain subsets of these 13 residues had incomplete specificity. The region around position 99 is not well-conserved in other members of the integrase family, but the 279-329 segment includes residues that are highly conserved and believed to be directly involved in catalysis. Many chimeras were inactive in recombining either HK022 or lambda sites. Selection for mutants that restored activity to these chimeras revealed sets of residues that are likely to interact with each other.

Identifying determinants of recombination specificity: construction and characterization of mutant bacteriophage integrases.

The Integrases of bacteriophages lambda and HK022 promote recombination between DNA molecules that carry attachment sites. The two integrases are about 70% identical in sequence and catalyze nearly identical reactions, but recognize different sets of sites. To identify the amino acids that determine this difference in specificity, we selected mutants of lambda integrase with increased ability to recombine HK022 sites. This selection yielded eleven different amino acid substitutions at eight different positions. Three of the positions belong to a larger set that were identified as important for the lambda/HK022 specificity difference by analysis of chimeric integrases. Substitution of the HK022 for the corresponding lambda residue at each of these three positions increased recombination of HK022 sites, and one double substitution, N99D-E319R, increased recombination to nearly wild-type HK022 levels. Mutations at the other five positions changed residues that are identical in the wild-type proteins or are at positions identified by chimera analysis as unimportant for the lambda/HK022 specificity difference. All of the mutants isolated by selection for increased recombination of HK022 sites retained considerable ability to recombine lambda sites. However, we found that substitution of HK022 for lambda residues at three additional positions, S282P, G283K, and R287K, specifically reduced recombination of lambda sites. These three substitutions when combined with N99D and E319R were sufficient to change the specificity of lambda to that of HK022 integrase. The first three substitutions act principally to prevent recombination of lambda sites, and the second two to remove a barrier to recombination of HK022 sites. We suggest that many natural alterations in the specificity of protein-DNA interactions occur by multi-step changes that first relax and then restrict specificity.

Guanosine 3',5'-bispyrophosphate (ppGpp) synthesis in cells of Escherichia coli starved for Pi.

Cells of Escherichia coli which enter a phase of starvation for Pi induce the synthesis of the nucleotide guanosine 3',5'-bispyrophosphate (ppGpp). This induction is relA independent but depends on the spoT gene product. A mutant unable to produce ppGpp is impaired in the expression of two genes which belong to the pho regulon, a defect which is dependent on the product of spoT. We suggest that ppGpp is essential for the proper induction of the genes which belong to the pho regulon.

Position and direction of strand exchange in bacteriophage HK022 integration.

The positions of the endonucleolytic cleavages promoted by the integrase protein (Int) of coliphage HK022 within its attB site were determined. The protein catalyses a staggered cut, which defines an overlap sequence of 7 bp within the core site. The overlap region is at the center of symmetry of a palindromic sequence which appears in all four putative att core binding sites for Int. We confirm that the order of strand exchange is similar to that in phage lambda.

Lambda integrase cleaves DNA in cis.

In the Int family of site-specific recombinases, DNA cleavage is accomplished by nucleophilic attack on the activated scissile phosphodiester bond by a specific tyrosine residue. It has been proposed that this tyrosine is contributed by a protomer bound to a site other than the one being cleaved ('trans' cleavage). To test this hypothesis, the difference in DNA binding specificity between closely related integrases (Ints) from phages lambda and HK022 was exploited to direct wild type Ints and cleavage- or activation-defective mutants to particular sites on bispecific substrates. Analysis of Int cleavage at individual sites strongly indicates that DNA cleavage is catalyzed by the Int bound to the cleaved site ('cis' cleavage). This conclusion contrasts with those from previous experiments with two members of the Int family, FLP and lambda Int, that supported the hypothesis of trans cleavage. We suggest explanations for this difference and discuss the implications of the surprising finding that Int-family recombinases appear capable of both cis and trans mechanisms of DNA cleavage.

Determinants of site-specific recombination in the lambdoid coliphage HK022. An evolutionary change in specificity.

The temperate bacteriophage HK022, like its relative lambda, inserts its chromosome into a specific site in the bacterial chromosome during lysogenization and excises it after induction. However, we find that the recombinational specificities of the two phages differ: they use different bacterial sites, and neither promotes efficient insertion or excision of the other phage chromosome. In order to determine the basis for this difference in specificity, we sequenced the HK022 elements that are involved in insertion and excision, and compared them to the corresponding lambda elements. The location, orientation, size and overall arrangement of the int and xis genes and the phage attachment sites are nearly identical in the two genomes, as is common for other functionally related elements in lambdoid phages. The Xis proteins of the two phages are functionally interchangeable, and their predicted amino acid sequences differ by but one residue. In contrast, the two Int proteins are not functionally interchangeable, and their sequences, although similar, differ at many positions. These sequence differences are not uniformly distributed: the amino-terminal 55 residues are completely conserved, but the remaining 302 show a pattern of differences interspersed with identities and conservative changes. These findings imply that the specificity difference between HK022 and lambda site-specific recombination is a consequence of the inability of the respective Int proteins to recognize pairs of heterologous attachment sites. The two phage attachment sites are remarkably similar, especially the two "arm" segments, which in lambda contain binding sites for Int, Xis and integration host factor. They are less similar in the segment between the two arms, which in lambda contains the points of recombinational strand exchange and a second class of binding site for Int protein (the "core-type" sites). The two bacterial attachment sites are quite different, although both have a short stretch of perfect homology with their respective phage partners at the points of strand exchange. We propose that the two Int proteins recognize similar or identical sites in the arms of their cognate attachment sites, and that differences in binding or action at the core-type sites is responsible for the divergent specificities. Genetic experiments and sequence comparisons suggest that both proteins recognize different but overlapping families of core-type sites, and that divergence in specificity has been achieved by an alternating succession of small, mutually compatible changes in protein and site.

The effect of the locus pstB on phosphate binding in the phosphate specific transport (PST) system of Escherichia coli.

The periplasmic phosphate binding protein is a product of the phoS gene and is an essential component of the phosphate specific transport (PST) system, which mediates Pi uptake in Escherichia coli. The binding of Pi to periplasmic protein(s) and the kinetic parameters of Pi uptake were studied in phoT and pstB mutants of E. coli. These mutants are impaired in Pi uptake but have a periplasmic Pi-binding protein whose Pi-binding capacity was estimated by the retention kinetics. The Pi-binding activity in two pstB mutants was found to be weaker as compared to phoT9 and the wild type. The KD values for Pi binding to periplasmic protein were determined by equilibrium dialysis. In the pstB mutants the KD value was found to be 9-31 times higher than the values obtained for the wild type and the phoT mutant. The apparent Km values for Pi uptake in one pstB mutant is 14.3 times higher than in the wild type. Vmax of the mutant is 8.3 times lower that of the wild type. The data indicate that pstB, an essential gene of the PST transport system, is promoting the binding capacity of the Pi-binding protein.

A new locus in the phosphate specific transport (PST) region of Escherichia coli.

PhoS64 is a mutation in the Phosphate Specific Transport (PST) region on the E. coli chromosome which lacks the periplasmic phosphate binding protein. In contrast to other phoS mutations (which have the same phenotype) it complements the mutations in phoT and pstB. A detailed genetic map of the PST region constructed by three point transductional crosses has revealed that phoS64 is located distally from other phoS mutations. The genetic order obtained was phoS64-phoU35-pstB401-phoT-phoS-ilvC. The data indicate that phoS64 belongs to a different complementation unit in the PST region not known hitherto. We propose to name it phoV.