Excision and reintegration of the Escherichia coli K-12 chromosomal element e14.

The genetic element e14 is a natural component of the Escherichia coli K-12 chromosome. On induction of the SOS pathways, e14 excises as a 14.4-kilobase circle. We report here on the reintegration of e14 into the chromosome of cured (e14 degrees) E. coli K-12 derivatives. Using a Tn10 insertion mutant of e14, we found that reintegration occurred specifically at the locus originally occupied by e14 and with the same orientation. The reintegration event required neither the RecA nor the RecB functions. The attachment site of the free form was located within a 950-base-pair HindIII-AvaI fragment and shared sufficient homology with the host attachment site to form detectable DNA-DNA hybrids. Even though E. coli C and B/5 did not contain e14, they did possess a HindIII restriction fragment that hybridized to the free e14 attachment fragment. E. coli C could be transformed with e14-1272::Tn10, resulting in integration at this site of homology. The Tn10 mutants were also used in mapping the point of e14 attachment. We found the following sequence: fabD purB atte14 umuC. Furthermore, analysis of a recombinant plasmid that contained both the e14 attachment site and the purB locus showed that these two loci occur within 11 kilobases of each other.     

Identification of plasmid and Bacillus subtilis chromosomal recombination sites used for pE194 integration.

The plasmid pE194 (3.7 kilobases) is capable of integrating into the genome of the bacterial host Bacillus subtilis in the absence of the major homology-dependent RecE recombination system. Multiple recombination sites have been identified on both the B. subtilis chromosome and pE194 (J. Hofemeister, M. Israeli-Reches, and D. Dubnau, Mol. Gen. Genet. 189:58-68, 1983). The B. subtilis chromosomal recombination sites were recovered by genetic cloning, and these sites were studied by nucleotide sequence analysis. Recombination had occurred between regions of short nucleotide homology (6 to 14 base pairs) as indicated by comparison of the plasmid and the host chromosome recombination sites with the crossover sites of the integration products. Recombination between the homologous sequences of the plasmid and the B. subtilis genome produced an integrated pE194 molecule which was bounded by direct repeats of the short homology. These results suggest a recombination model involving a conservative, reciprocal strand exchange between the two recombination sites. A preferred plasmid recombination site was found to occur within a 70-base-pair region which contains a GC-rich dyad symmetry element. Five of seven pE194-integrated strains analyzed had been produced by recombination at different locations within this 70-base-pair interval, located between positions 860 and 930 in pE194. On the basis of these data, mechanisms are discussed to explain the recombinational integration of pE194.     

The invertible P-DNA segment in the chromosome of Escherichia coli.

In the chromosome of many strains of Escherichia coli K12 the excisable element e14 is found, which contains an invertible DNA region. This invertible P region, and the gene responsible for the inversion (pin) were cloned, together with other e14 sequences. The element e14 contains a gene which kills the host cell. This can be repressed by a function also coded by e14. The kil and repressor genes as well as the attachment site of the element were mapped in different regions of the element. The invertible segment and pin gene were sequenced. The invertible segment is 1794 bp long, and contains one large internal open reading frame of 879 bp and reading frames which overlap the end pont of the invertible segment. Although pin highly homologous to gin of phage Mu, neither the genetic organization of the P segment nor the sequence of the putative proteins resemble the invertible G segment of phage Mu (which codes for genes involved in tail fiber assembly). The complete DNA sequences of both invertible segments were screened for homology. No resemblance was found. The P segment is flanked by inverted repeat sequences of 16 bp. Comparison of these with related inversion systems points out that the recombination site maps probably within a 2-bp region. This cross-over site is contained within a short palindromic sequence (AAACC AA GGTTT) which is more or less conserved in the recombination sites of all related DNA invertases.     

Nucleotide sequence and expression of the gene for the site-specific integration protein from bacteriophage HP1 of Haemophilus influenzae.

The nucleotide sequence of the leftmost 2,363 base pairs of the HP1 genome, which includes the attachment site (attP) and the integration region, was determined. This sequence contained an open reading frame encoding a 337-residue polypeptide, which is a member of the integrase family of site-specific recombination proteins as judged by sequence comparison. The open reading frame was located immediately adjacent to the att site and was oriented so that initiation of translation would begin distal to the att site and end in its immediate vicinity. Expression of this DNA segment in Escherichia coli provided extracts which promoted site-specific recombination between plasmids containing cloned HP1 attP and Haemophilus influenzae attB sites. This recombination was directional, since no reaction was observed between plasmids containing attR and attL sites. The reaction was stimulated by the accessory protein integration host factor of E. coli. Evidence was also obtained that the integration host factor influenced the levels of HP1 integrase expression. The deduced amino acid sequence of HP1 integrase has remarkable similarity to that deduced for the integrase of coliphage 186.     

Isolation of an integrated provirus of Moloney murine leukemia virus with long terminal repeats in inverted orientation: integration utilizing two U3 sequences.

We have previously described the construction of a mutant of Moloney murine leukemia virus, in594-2, which carries a 2-base-pair insertion in the U5 region of the genome and is partially defective in forming the integrated proviral DNA. We have now recovered a cloned copy of an unusual provirus from rat cells infected with this mutant. The viral genome is flanked by long terminal repeats in inverted orientation, with U3 sequences joined to cellular DNA at both of the outer edges. In addition, the provirus is a recombinant, containing a segment of a VL30 element in inverted orientation in place of the Moloney murine leukemia virus env region. The recovery of this provirus indicates that two U3 regions can be used for viral integration and suggests that there may be no absolute requirement in the reaction for those U5 sequences outside the 13-base-pair inverted repeats.     

Integration of bacteriophage Mx8 into the Myxococcus xanthus chromosome causes a structural alteration at the C-terminal region of the IntP protein.

Mx8 is a generalized transducing phage that infects Myxococcus xanthus cells. This phage is lysogenized in M. xanthus cells by the integration of its DNA into the host chromosome through site-specific recombination. Here, we characterize the mechanism of Mx8 integration into the M. xanthus chromosome. The Mx8 attachment site, attP, the M. xanthus chromosome attachment site, attB, and two phage-host junctions, attL and attR, were cloned and sequenced. Sequence alignments of attP, attB, attL, and attR sites revealed a 29-bp segment that is absolutely conserved in all four sequences. The intP gene of Mx8 was found to encode a basic protein that has 533 amino acids and that carries two domains conserved in site-specific recombinases of the integrase family. Surprisingly, the attP site was located within the coding sequence of the intP gene. Hence, the integration of Mx8 into the M. xanthus chromosome results in the conversion of the intP gene to a new gene designated intR. As a result of this conversion, the 112-residue C-terminal sequence of the intP protein is replaced with a 13-residue sequence. A 3-base deletion within the C-terminal region had no effect on Mx8 integration into the chromosome, while a frameshift mutation with the addition of 1 base at the same site blocked integration activity. This result indicates that the C-terminal region is required for the enzymatic function of the intP product.     

A Mu gin complementing function and an invertible DNA region in Escherichia coli K-12 are situated on the genetic element e14

The Gin product catalyzes an inversion of 3,000 base pairs of DNA in the genome of bacteriophage Mu. The orientation of the invertible of G-region determines the host range of the phage. Gin- mutants are complemented by a host function in strain HB101 and several other Escherichia coli K-12 strains. At least three clones in the E. coli gene bank described previously (L. Clarke and J. Carbon, Cell 9:91-99, 1976) contained the gin complementing function. This function, which we named pin, catalyzes an inversion of 1,800 base pairs in the adjacent DNA. The invertible region, named the P-region, together with pin, was further subcloned on pBR322. Conjugation and transduction experiments mapped the pin gene between the genes purB and fabD near position 25 on the E. coli chromosome. Also situated in this region is e14, a cryptic, UV- excisable , genetic element (A. Greener and C.W. Hill, J. Bacteriol . 144:312-321, 1980). We demonstrated that pin and the P-region are part of e 14. The e 14 element was cloned on pBR322 by genetic manipulation techniques in vivo. It has the properties of a defective prophage containing integration and excision functions and a SOS-sensitive repressor.     

The major and minor chicken vitellogenin genes are each adjacent to partially deleted pseudogene copies of the other.

The major chicken vitellogenin gene (VTGII) has previously been cloned and sequenced. We now report the isolation of genomic clones that encompass a minor chicken vitellogenin gene (VTGIII) which is also expressed in the liver in response to estradiol. Our analysis reveals that a pseudogene for VTGII (psi VTGII) lies 1,426 base pairs upstream of this VTGIII gene. A reevaluation of published sequence data reveals that the converse is also true, namely, that a pseudogene for VTGIII (psi VTGIII) lies 1,345 base pairs downstream of the VTGII gene. Our results show that a 335-base-pair deletion has removed the psi VTGIII promoter and cap site but left residual estrogen response element in a region where nuclease-hypersensitive sites have been reported to be induced in response to estradiol.     

Site-specific integration of the actinophage R4 genome into the chromosome of Streptomyces parvulus upon lysogenization.

The lysogenization of Streptomyces parvulus by actinophage R4 occurs by site-specific integration of the phage genome into the chromosome. The DNA fragments containing the attachment sites on the host chromosome, the phage genome, and the two junctions created by insertion of the phage genome were cloned and sequenced. The attachment sites were found to share a common core of 12 bp. This common core sequence was not detected in chromosomal DNAs of S. coelicolor and S. lividans.     

Cloning of the integration and attachment regions of bacteriophage P4

Summary The integration and attachment regions of bacteriophage P4 have been cloned into a multicopy plasmid. This plasmid can integrate into the E. coli chromosome at the same location as the parent phage. Integration increases the stability of the plasmid and allows it to be retained even under conditions in which a non-integrated plasmid would be lost. None of the genes needed for P4 lytic growth is required for integration. The P4 integration and attachment regions have been cloned on separate plasmids. A plasmid that carries the attachment site can integrate into the chromosome only if another plasmid that carries the P4 integration functions is present. A plasmid that carries only this trans-acting integration function cannot integrate. Using deletion mutants of the plasmid, the maximum size of the region needed for integration has been determined to be 1.6 kb, of which no more than 1.2 kb codes for the integrase protein. A nonsense mutant defective in integration has been isolated by using a rapid screening procedure that identifies unstable plasmids.     

Evolution of immunity and host chromosome integration site of P2-like coliphages

The amount and distribution of variation in the genomic region containing the genes in the lytic-lysogenic genetic switch and the sequence that determines the integration site into the host chromosome were analyzed for 38 P2-like phages from Escherichia coli. The genetic switch consists of two convergent mutually exclusive promoters, Pe and Pc, and two repressors, C and Cox. The immunity repressor C blocks the early Pe promoter, leading to the establishment of lysogeny. The Cox repressor blocks expression of Pc, allowing lytic growth. Phylogenetic analyses showed that the C and Cox proteins were distributed into seven distinct classes. The phylogenetic relationship differed between the two proteins, and we showed that homologous recombination plays a major role in creating alterations in the genetic switch, leading to new immunity classes. Analyses of the host integration site for these phages resulted in the discovery of a previously unknown site, and there were at least four regular integration sites. Interestingly, we found no case where phages of the same immunity class had different host attachment sites. The evolution of immunity and integration sites is complex, since it involves interactions both between the phages themselves and between phages and hosts, and often, both regulatory proteins and target DNA must change.     

Genomic instability and mobile genetic elements in regions surrounding two discoidin I genes of Dictyostelium discoideum.

We have found that the genomic regions surrounding the linked discoidin I genes of various Dictyostelium discoideum strains have undergone rapid changes. Wild-type strain NC-4 has three complete discoidin I genes; its axenic derivative strain Ax-3L has duplicated a region starting approximately 1 kilobase upstream from the two linked genes and extending for at least 8 kilobases past the genes. A separately maintained stock, strain Ax-3K, does not have this duplication but has undergone a different rearrangement approximately 3 kilobases farther upstream. We show that there are repeat elements in these rapidly changing regions. At least two of these elements, Tdd-2 and Tdd-3, have characteristics associated with mobile genetic elements. The Tdd-3 element is found in different locations in related strains and causes a 9- to 10-base-pair duplication of the target site DNA. The Tdd-2 and Tdd-3 elements do not cross-hybridize, but they share a 22-base-pair homology near one end. At two separate sites, the Tdd-3 element has transposed into the Tdd-2 element, directly adjacent to the 22-base-pair homology. The Tdd-3 element may use this 22-base-pair region as a preferential site of insertion.     

Negative and positive regulation by a short segment in the 5''-flanking region of the human cytomegalovirus major immediate-early gene.

To analyze the significance of inducible DNase I-hypersensitive sites occurring in the 5'-flanking sequence of the major immediate-early gene of human cytomegalovirus (HCMV), various deleted portions of the HCMV immediate-early promoter regulatory region were attached to the chloramphenicol acetyltransferase (CAT) gene and assayed for activity in transiently transfected undifferentiated and differentiated human teratocarcinoma cells, Tera-2. Assays of progressive deletions in the promoter regulatory region indicated that removal of a 395-base-pair portion of this element (nucleotides -750 to -1145) containing two inducible DNase I sites which correlate with gene expression resulted in a 7.5-fold increase in CAT activity in undifferentiated cells. However, in permissive differentiated Tera-2, human foreskin fibroblast, and HeLa cells, removal of this regulatory region resulted in decreased activity. In addition, attachment of this HCMV upstream element to a homologous or heterologous promoter increased activity three- to fivefold in permissive cells. Therefore, a cis regulatory element exists 5' to the enhancer of the major immediate-early gene of HCMV. This element negative modulates expression in nonpermissive cells but positively influences expression in permissive cells.     

Long terminal repeat of murine retroviral DNAs: sequence analysis, host-proviral junctions, and preintegration site.

The nucleotide sequence of the long terminal repeat (LTR) of three murine retroviral DNAs has been determined. The data indicate that the U5 region (sequences originating from the 5' end of the genome) of various LTRs is more conserved than the U3 region (sequences from the 3' end of the genome). The location and sequence of the control elements such as the 5' cap, "TATA-like" sequences, "CCAAT-box," and presumptive polyadenylic acid addition signal AATAAA in the various LTRs are nearly identical. Some murine retroviral DNAs contain a duplication of sequences within the LTR ranging in size from 58 to 100 base pairs. A variant of molecularly cloned Moloney murine sarcoma virus DNA in which one of the two LTRs integrated into the viral DNA was also analyzed. A 4-base-pair duplication was generated at the site of integration of LTR in the viral DNA. The host-viral junction of two molecularly cloned AKR-murine leukemia virus DNAs (clones 623 and 614) was determined. In the case of AKR-623 DNA, a 3- or 4-base-pair direct repeat of cellular sequences flanking the viral DNA was observed. However, AKR-614 DNA contained a 5-base-pair repeat of cellular sequences. The nucleotide sequence of the preintegration site of AKR-623 DNA revealed that the cellular sequences duplicated during integration are present only once. Finally, a striking homology between the sequences flanking the preintegration site and viral LTRs was observed.     

Constitutive and interleukin-1 (IL-1)-inducible factors interact with the IL-1-responsive element in the IL-6 gene.

The interleukin-6 (IL-6) promoter is rapidly and transiently activated with other cytokines, including IL-1, tumor necrosis factor, and platelet-derived growth factor, as well as phorbol esters and agents that increase intracellular cyclic AMP. In this study, we have investigated cis-acting regulatory elements and trans-acting factors responsible for IL-1-induced IL-6 gene expression. Studies on the 5' deletion mutants of the human IL-6 gene suggested that the IL-1-responsive element was mapped within the IL-6 promoter region (-180 to -123) which was homologous to the c-fos serum-responsive enhancer element. Gel retardation assay identified two types of nuclear factors that bound to this region, one constitutive and the other inducible. These two factors recognized a 14-base-pair (bp) palindromic sequence, ACATTGCACAATCT. Furthermore, three copies of this 14-bp palindrome conferred IL-1 responsiveness to the basal enhancerless IL-6 promoter, indicating that a 14-bp-dyad symmetry sequence was an IL-1-responsive element in the IL-6 gene.     

A helper-dependent capsid-modified adenovirus vector expressing adeno-associated virus rep78 mediates site-specific integration of a 27-kilobase transgene cassette

Random integration of viral gene therapy vectors and subsequent activation or disruption of cellular genes poses safety risks. Major efforts in the field are aimed toward targeting vector integration to specific sites in the host genome. The adeno-associated virus (AAV) Rep78 protein is able to target AAV integration to a specific site on human chromosome 19, called AAVS1. We studied whether this ability could be harnessed to achieve site-specific integration of a 27-kb transgene cassette into a model cell line for human hematopoietic cells (Mo7e). To deliver rep78 and the transgene to Mo7e cells, we used helper-dependent adenovirus (Ad) vectors containing Ad serotype 35 fiber knob domains (HD-Ad). An HD-Ad vector containing the rep78 gene under the control of the globin locus control region (LCR) (Ad.LCR-rep78) conferred Rep78 expression on Mo7e cells. Upon coinfection of Ad.LCR-rep78 with an HD-Ad vector containing a 27-kb globin-LCR-green fluorescent protein (GFP) transgene cassette flanked by AAV inverted terminal repeats (ITRs) (Ad.AAV-LCR-GFP), transduced cells were cloned and expanded (without selection pressure), and vector integration was analyzed in clones with more than 30% GFP-positive cells. Vector integration into the AAVS1 region was seen in 30% of analyzed integration sites, and GFP expression from these integrants was stable over time. Of the remaining integration sites, 25% were within the genomic globin LCR. In almost 90% of sites, transgene integration occurred via the Ad ITR. This indicates that rescue of the AAV ITR-flanked transgene cassette from Ad.AAV-LCR-GFP is not required for Rep78-mediated integration into AAVS1 and that free ends within the vector genome can be created by breaks within the Ad ITRs, whose structure is apparently recognized by cellular "nicking" enzymes. The finding that 55% of all analyzed integration sites were either within the AAVS1 or globin LCR region demonstrates that a high frequency of targeted integration of a large transgene cassette can be achieved in human hematopoietic stem cell lines.     

Transfer RNA genes frequently serve as integration sites for prokaryotic genetic elements.

The DNA sequences were determined at the boundaries of the integrated copy of the archaebacterial genetic element SSV1. A 44 bp sequence present as a single copy on the 15.5 kb circular SSV1 DNA flanked the integrated copy as a direct DNA sequence repeat, suggesting that SSV1 integration occurred by recombination between this 44 bp SSV1 sequence and an identical sequence on the bacterial chromosome. At the left attachment site, a region encompassing the 44 bp attachment core sequence and the 31 nucleotides upstream of it displayed all characteristics expected for an arginine tRNA gene. An analysis of published attachment site sequences of other systems revealed that tRNA genes also constitute the bacterial attachment site in the case of three temperate phages and two transmissible plasmids in eubacteria, indicating a widespread occurrence of tRNA genes as integration target sites. This finding may be important for the understanding of mechanisms and evolution of site-specific recombination.