Characterization of the Micromonospora rosaria pMR2 plasmid and development of a high G+C codon optimized integrase for site-specific integration

pMR2, an 11.1 kb plasmid was isolated from Micromonospora rosaria SCC2095, NRRL3718, and its complete nucleotide sequence determined. Analysis revealed 13 ORFs including homologs of a KorSA regulatory protein and TraB plasmid transfer protein found on other actinomycete plasmids. pMR2 contains att/int functions consisting of an integrase, an excisionase, and a putative plasmid attachment site (attP). The integrase gene contained a high frequency of codons rarely used in high G+C actinomycete coding regions. The gene was codon optimized for actinomycete codon usage to create the synthetic gene int-OPT. pSPRX740, containing an rpsL promoter and the att/int-OPT region, was introduced into Micromonospora halophytica var. nigra ATCC33088. Analysis of DNA flanking the pSPRX740 integration site confirmed site-specific integration into a tRNA(Phe) gene in the M. halopytica var. nigra chromosome. The pMR2 attP element and chromosomal attachment (attB) site contain a 63 bp region of sequence identity overlapping the 3' end of the tRNA(Phe) gene. Plasmids comprising the site-specific att/int-OPT functions of pMR2 can be used to integrate genes into the chromosome of actinomycetes with an appropriate tRNA gene. The development of an integrative system for Micromonospora will expand our ability to study antibiotic biosynthesis in this important actinomycete genus.     

Bacteriophage T12 of Streptococcus pyogenes integrates into the gene encoding a serine tRNA

The region of temperate bacteriophage T12 responsible for integration into the chromosome of Streptococcus pyogenes has been identified. The integrase gene ( int ) and the phage attachment site ( attP ) are found immediately upstream of the gene for speA , the latter of which is known to be responsible for the production of erythrogenic toxin A (also known as pyrogenic exotoxin A). The integrase gene has a coding capacity for a protein of 41 457 Da, and the C-terminus of the deduced protein is similar to other conserved C-terminal regions typical of phage integrases. Upstream of int is a second open reading frame, which is capable of encoding an acidic protein of 72 amino acids (8744 Da); the position of this region in relation to int suggests it to be the phage excisionase gene ( xis ). The arms flanking the integrated prophage ( attL and attR ) were identified, allowing determination of the sequences of the phage ( attP ) and bacterial ( attB ) attachment sites. A fragment containing the integrase gene and attP was cloned into a streptococcal suicide vector; when introduced into S. pyogenes by electrotransformation, this plasmid stably integrated into the bacterial chromosome at attB . The insertion site for the phage into the S. pyogenes chromosome was found to be in the anticodon loop of a putative type II gene for a serine tRNA. attP and attB share a region of identity that is 96 bp in length; this region of identity corresponds to the 3' end of the tRNA gene such that the coding sequence remains intact after integration of the prophage. The symmetry of the core region of att may set this region apart from previously described phage attachment sites (Campbell, 1992), and may play a role in the biology of this medically important bacteriophage.     

Structural analysis of loci involved in pSAM2 site-specific integration in Streptomyces

pSAM2 is an 11-kb plasmid integrated in the Streptomyces ambofaciens ATCC23877 and ATCC15154 genomes and found additionally as a free replicon in an uv derivative. After transfer into S. ambofaciens DSM40697 (devoid of pSAM2) or into Streptomyces lividans, specific integration of pSAM2 occurred very efficiently. A 58-bp sequence (att) present in both pSAM2 (attP) and S. ambofaciens strain DSM40697 (attB) attachment regions is found at the boundaries (attL and attR) of integrated pSAM2 in S. ambofaciens strain ATCC23877. The S. lividans chromosomal integration zone contained an imperfectly conserved att sequence (attB), and the integration event of pSAM2 was located within a 49-bp sequence of attB. Only one primary functional attB sequence was present in the S. lividans or S. ambofaciens DSM40697 total DNA. The integration zone of S. lividans hybridized with the integration zone of S. ambofaciens DSM40697. The two integration zones were homologous only to the right side of the att sequence. The conserved region contained an open reading frame (ORF A) with a stop codon located 99 bp from the attB sequence in both strains. S. ambofaciens DSM40697 contained DNA sequences related to pSAM2 on the left side of the att site. The att sequence was included in a region conserved in Streptomyces antibioticus, Streptomyces actuosus, Streptomyces bikiniensis, Streptomyces coelicolor, Streptomyces glaucescens, and Streptomyces parvulus. Site-specific integration of a pSAM2 derivative was characterized in another unrelated strain, Streptomyces griseofuscus. This strain contained an imperfectly conserved 58-bp attB sequence, and the integration event took place within a 45-bp sequence of attB. Site-specific integration of pSAM2 in three nonrelated Streptomyces strains suggests the wide host range of pSAM2 integration in Streptomyces.     

The streptomyces genome contains multiple pseudo-attB sites for the (phi)C31-encoded site-specific recombination system

The integrase from the Streptomyces phage (phi)C31 is a member of the serine recombinase family of site-specific recombinases and is fundamentally different from that of lambda or its relatives. Moreover, (phi)C31 int/attP is used widely as an essential component of integration vectors (such as pSET152) employed in the genetic analysis of Streptomyces species. phiC31 or integrating plasmids containing int/attP have been shown previously to integrate at a locus, attB, in the chromosome. The DNA sequences of the attB sites of various Streptomyces species revealed nonconserved positions. In particular, the crossover site was narrowed to the sequence 5'TT present in both attP and attB. Strains of Streptomyces coelicolor and S. lividans were constructed with a deletion of the attB site ((Delta)attB), and pSET152 was introduced into these strains by conjugation. Thus, secondary or pseudo-attB sites were identified by Southern blotting and after rescue of plasmids containing DNA flanking the insertion sites from the chromosome. The sequences of the integration sites had similarity to those of attB. Analysis of the insertions of pSET152 into both attB(+) and (Delta)attB strains indicated that this plasmid can integrate at several loci via independent recombination events within a transconjugant.     

Mycobacteriophage Bxb1 integrates into the Mycobacterium smegmatis groEL1 gene

Mycobacteriophage Bxb1 is a temperate phage of Mycobacterium smegmatis and forms stable lysogens in which the Bxb1 genome is integrated into the host chromosome. Bxb1 encodes an integrase of the large serine recombinase family that catalyses integration and excision of the Bxb1 genome. We show here that Bxb1 integrates into a chromosomal attB site located within the 3' end of the groEL1 gene such that integration results in alteration of the C-terminal 21 amino acid residues. An integration-proficient plasmid vector containing the Bxb1 integrase gene and flanking DNA sequences efficiently transforms M. smegmatis via integration at attB. Bxb1-integrated recombinants are stable and fully compatible with L5 integration vectors. Strand exchange occurs within an 8 bp common core sequence present in attB and within an attP site situated immediately upstream of the phage integrase gene. Establishment of a defined in vitro system for Bxb1 integration shows that recombination occurs efficiently without requirement for high-energy cofactors, divalent metals, DNA supercoiling or additional proteins.     

Characterization of XerC- and XerD-dependent CTX phage integration in Vibrio cholerae

CTXphi is a filamentous bacteriophage that encodes cholera toxin and integrates site-specifically into the larger of the two Vibrio cholerae chromosomes. The CTXphi genome lacks an integrase; instead, its integration depends on the chromosome-encoded tyrosine recombinases XerC and XerD. During integration, recombination occurs between regions of homology in CTXphi and the V. cholerae chromosome. Here, we define the elements on the phage genome (attP) and bacterial chromosome (attB) required for CTXphi integration. attB is a short sequence composed of one binding site for XerC and XerD spanning the site of recombination. Together, XerC and XerD bind to two sites within attP. While one XerC/D binding site in attP spans the core recombination region, the other site is approximately 80 bp away. Although integration occurs at the core XerC/D binding site in attP, the second site is required for CTXphi integration, suggesting it performs an architectural role in the integration reaction. In vitro cleavage reactions showed that XerC and XerD are capable of cleaving attB and attP sequences; however, additional cellular processes such as DNA replication or Holliday junction resolution by a host resolvase may contribute to integration in vivo.     

Integration of the temperate phage phiU into the putative tRNA gene on the chromosome of its host Rhizobium leguminosarum biovar trifolii

The plasmid pCI6, carrying the attP site of the temperate phage phiU, integrates into the attB site on the chromosome of Rhizobium leguminosarum biovar trifolii strain 4S. The 4 kb EcoRI-HindIII region of pCI6 involved in site-specific integration was subcloned as the attP fragment of phage phiU and sequenced. The attL fragment, one of the new DNA junctions generated from the insertion of pCI6 into the chromosome of the host Rhizobium, was used as a hybridization probe for isolation of the attB fragment of strain 4S. The nucleotide sequence of the 2 kb PstI fragment of strain 4S, which hybridized with the attL fragment, was decided and compared with that of the attP fragment. A 53 bp common sequence was expected to be the core sequence of site-specific integration between phage phiU and strain 4S. One of the ORFs on the attP fragment, which was located adjacent to the core sequence, had structural homology to the integrase family. However, the attB fragment showed high homology with the tRNA genes of Agrobacterium tumefaciens and E. coli. A 47 bp sequence of the 53 bp core sequence overlapped with this tRNA-like sequence. This indicates that the target site of phage phiU integration is the putative tRNA gene on the chromosome of the Rhizobium host.     

Structure of the chromosomal insertion site for pSAM2: functional analysis in Escherichia coli

The element pSAM2 from Streptomyces ambofaciens integrates into the chromosome through site-specific recombination between the element ( att  P) and the chromosomal ( att  B) sites. These regions share an identity segment of 58 bp extending from the anti-codon loop through the 3' end of a tRNA^Pro gene. To facilitate the study of the att  B site, the int and xis genes, expressed from an inducible promoter, and att  P from pSAM2 were cloned on plasmids in Escherichia coli . Compatible plasmids carrying the different att  B regions to be tested were introduced in these E . coli strains. Under these conditions, Int alone could promote site-specific integration; Int and Xis were both required for site-specific excision. This experimental system was used to study the sequences required in att  B for efficient site-specific recombination. A 26 bp sequence, centred on the anti-codon loop region and not completely included in the identity segment, retained all the functionality of att  B; shorter sequences allowed integration with lower efficiencies. By comparing the 26-bp-long att  B with att  P, according to the Lambda model, we propose that B and B', C and C' core-type Int binding sites consist of 9 bp imperfect inverted repeats separated by a 5 bp overlap region.     

An unexpected location of the arginine catabolic mobile element (ACME) in a USA300-related MRSA strain

In methicillin resistant Staphylococcus aureus (MRSA), the arginine catabolic mobile element (ACME) was initially described in USA300 (t008-ST8) where it is located downstream of the staphylococcal cassette chromosome mec (SCCmec). A common health-care associated MRSA in Copenhagen, Denmark (t024-ST8) is clonally related to USA300 and is frequently PCR positive for the ACME specific arcA-gene. This study is the first to describe an ACME element upstream of the SCCmec in MRSA. By traditional SCCmec typing schemes, the SCCmec of t024-ST8 strain M1 carries SCCmec IVa, but full sequencing of the cassette revealed that the entire J3 region had no homology to published SCCmec IVa. Within the J3 region of M1 was a 1705 bp sequence only similar to a sequence in S. haemolyticus strain JCSC1435 and 2941 bps with no homology found in GenBank. In addition to the usual direct repeats (DR) at each extremity of SCCmec, M1 had two new DR between the orfX gene and the J3 region of the SCCmec. The region between the orfX DR (DR1) and DR2 contained the ccrAB4 genes. An ACME II-like element was located between DR2 and DR3. The entire 26,468 bp sequence between DR1 and DR3 was highly similar to parts of the ACME composite island of S. epidermidis strain ATCC12228. Sequencing of an ACME negative t024-ST8 strain (M299) showed that DR1 and the sequence between DR1 and DR3 was missing. The finding of a mobile ACME II-like element inserted downstream of orfX and upstream of SCCmec indicates a novel recombination between staphylococcal species.     

Site-Specific Recombination of Temperate Myxococcus xanthus Phage Mx8: Genetic Elements Required for Integration

Like most temperate bacteriophages, phage Mx8 integrates into a preferred locus on the genome of its host, Myxococcus xanthus, by a mechanism of site-specific recombination. The Mx8 int-attP genes required for integration map within a 2.2-kilobase-pair (kb) fragment of the phage genome. When this fragment is subcloned into a plasmid vector, it facilitates the site-specific integration of the plasmid into the 3' ends of either of two tandem tRNAAsp genes, trnD1 and trnD2, located within the attB locus of the M. xanthus genome. Although Int-mediated site-specific recombination occurs between attP and either attB1 (within trnD1) or attB2 (within trnD2), the attP x attB1 reaction is highly favored and often is accompanied by a deletion between attB1 and attB2. The int gene is the only Mx8 gene required in trans for attP x attB recombination. The int promoter lies within the 106-bp region immediately upstream of one of two alternate GTG start codons, GTG-5208 (GTG at bp 5208) and GTG-5085, for integrase and likely is repressed in the prophage state. All but the C-terminal 30 amino acid residues of the Int protein are required for its ability to mediate attP x attB recombination efficiently. The attP core lies within the int coding sequence, and the product of integration is a prophage in which the 3' end of int is replaced by host sequences. The prophage intX gene is predicted to encode an integrase with a different C terminus.     

Identification of int and attP on the genome of lactococcal bacteriophage Tuc2009 and their use for site-specific plasmid integration in the chromosome of Tuc2009-resistant Lactococcus lactis MG1363.

The DNA sequence of the int-attP region of the small-isometric-headed lactococcal bacteriophage Tuc2009 is presented. In this region, an open reading frame, int, which potentially encodes a protein of 374 amino acids, representing the Tuc2009 integrase, was identified. The nucleotide sequence of the bacteriophage attachment site, attP, and the sequences of attB, attL, and attR in the lysogenic host Lactococcus lactis subsp. cremoris UC509 were determined. A sequence almost identical to the UC509 attB sequence was found to be present in the plasmid-free Tuc2009-resistant L. lactis subsp. cremoris MG1363. This site could be used for the site-specific integration of a plasmid carrying the Tuc2009 int-attP region in the chromosome of MG1363, thereby demonstrating that the application of chromosomal insertion vectors based on bacteriophage integration functions is not limited to the prophage-cured original host strain of the phage.     

Site-specific integrative elements of rhizobiophage 16-3 can integrate into proline tRNA (CGG) genes in different bacterial genera.

The integrase protein of the Rhizobium meliloti 41 phage 16-3 has been classified as a member of the Int family of tyrosine recombinases. The site-specific recombination system of the phage belongs to the group in which the target site of integration (attB) is within a tRNA gene. Since tRNA genes are conserved, we expected that the target sequence of the site-specific recombination system of the 16-3 phage could occur in other species and integration could take place if the required putative host factors were also provided by the targeted cells. Here we report that a plasmid (pSEM167) carrying the attP element and the integrase gene (int) of the phage can integrate into the chromosomes of R. meliloti 1021 and eight other species. In all cases integration occurred at so-far-unidentified, putative proline tRNA (CGG) genes, indicating the possibility of their common origin. Multiple alignment of the sequences suggested that the location of the att core was different from that expected previously. The minimal attB was identified as a 23-bp sequence corresponding to the anticodon arm of the tRNA.     

Mutational analysis of att554, the target of the site-specific transposon Tn554.

Tn554 is a high-frequency, site-specific transposable element of Staphylococcus aureus which has integrative properties resembling those of temperate bacteriophages. Tn554 inserts at a unique chromosomal location, designated att554. att554 contains a core hexanucleotide sequence, 5'-GATGTA-3' (nucleotides numbered -3 to +3). Most of the time (greater than 99%) insertion occurs immediately 3' to this sequence; the resulting orientation of Tn554 to att554 is designated as the (+) orientation. Infrequent insertions immediately 5' to the core sequence result in the opposite, or (-) orientation. Mutational analysis of a cloned att554 site indicates that deletions extending from the left and ending at -15 or from the right ending between +8 and +12 reduced attachment site efficiency. Plasmids with deletions extending closer to the insertion site, although still retaining the core sequence from -3 to +3, were totally inactive. Tn554 insertions into partially active att554 sites retained normal site- and orientation-specificity with respect to att554, but they frequently contained abnormal sequences at the junction of att554 and the 3' end of Tn554. These data indicate that att554 contains a short nucleotide sequence essential for transposition and flanking sequences that greatly increase the frequency of recombination.     

Site-Specific Recombination of Temperate Myxococcus xanthus Phage Mx8: Regulation of Integrase Activity by Reversible, Covalent Modification

Temperate Myxococcus xanthus phage Mx8 integrates into the attB locus of the M. xanthus genome. The phage attachment site, attP, is required in cis for integration and lies within the int (integrase) coding sequence. Site-specific integration of Mx8 alters the 3' end of int to generate the modified intX gene, which encodes a less active form of integrase with a different C terminus. The phage-encoded (Int) form of integrase promotes attP x attB recombination more efficiently than attR x attB, attL x attB, or attB x attB recombination. The attP and attB sites share a common core. Sequences flanking both sides of the attP core within the int gene are necessary for attP function. This information shows that the directionality of the integration reaction depends on arm sequences flanking both sides of the attP core. Expression of the uoi gene immediately upstream of int inhibits integrative (attP x attB) recombination, supporting the idea that uoi encodes the Mx8 excisionase. Integrase catalyzes a reaction that alters the primary sequence of its gene; the change in the primary amino acid sequence of Mx8 integrase resulting from the reaction that it catalyzes is a novel mechanism by which the reversible, covalent modification of an enzyme is used to regulate its specific activity. The lower specific activity of the prophage-encoded IntX integrase acts to limit excisive site-specific recombination in lysogens carrying a single Mx8 prophage, which are less immune to superinfection than lysogens carrying multiple, tandem prophages. Thus, this mechanism serves to regulate Mx8 site-specific recombination and superinfection immunity coordinately and thereby to preserve the integrity of the lysogenic state.     

Characterization of the genetic elements required for site-specific integration of plasmid pSE211 in Saccharopolyspora erythraea.

The 18.1-kilobase plasmid pSE211 integrates into the chromosome of Saccharopolyspora erythraea at a specific attB site. Restriction analysis of the integrated plasmid, pSE211int, and adjacent chromosomal sequences allowed identification of attP, the plasmid attachment site. Nucleotide sequencing of attP, attB, attL, and attR revealed a 57-base-pair sequence common to all sites with no duplications of adjacent plasmid or chromosomal sequences in the integrated state, indicating that integration takes place through conservative, reciprocal strand exchange. An analysis of the sequences indicated the presence of a putative gene for Phe-tRNA at attB which is preserved at attL after integration has occurred. A comparison of the attB site for a number of actinomycete plasmids is presented. Integration at attB was also observed when a 2.4-kilobase segment of pSE211 containing attP and the adjacent plasmid sequence was used to transform a pSE211- host. Nucleotide sequencing of this segment revealed the presence of two complete open reading frames (ORFs) and a segment of a third ORF. The ORF adjacent to attP encodes a putative polypeptide 437 amino acids in length that shows similarity, at its C-terminal domain, to sequences of site-specific recombinases of the integrase family. The adjacent ORF encodes a putative 98-amino-acid basic polypeptide that contains a helix-turn-helix motif at its N terminus which corresponds to domains in the Xis proteins of a number of bacteriophages. A proposal for the function of this polypeptide is presented. The deduced amino acid sequence of the third ORF did not reveal similarities to polypeptide sequences in the current data banks.     

Control of directionality in the site-specific recombination system of the Streptomyces phage phiC31

The genome of the Streptomyces temperate phage phiC31 integrates into the host chromosome via a recombinase belonging to a novel group of phage integrases related to the resolvase/invertase enzymes. Previously, it was demonstrated that, in an in vitro recombination assay, phiC31 integrase catalyses integration (attP/attB recombination) but not excision (attL/attR). The mechanism responsible for this recombination site selectivity was therefore investigated. Purified integrase was shown to bind with similar apparent binding affinities to between 46 bp and 54 bp of DNA at each of the attachment sites, attP, attB, attL and attR. Assays using recombination sites of 50 bp and 51 bp for attP and attB, respectively, showed that these fragments were functional in attP/attB recombination and maintained strict site selectivity, i.e. no recombination between non-permissive sites, such as attP/attP, attB/attL, etc., was observed. Using bandshifts and supershift assays in which permissive and non-permissive combinations of att sites were used in the presence of integrase, only the attP/attB combination could generate supershifts. Recombination products were isolated from the supershifted complexes. It was concluded that these supershifted complexes contained the recombination synapse and that site specificity, and therefore directionality, is determined at the level of stable synapse formation.     

The phi 80 and P22 attachment sites. Primary structure and interaction with Escherichia coli integration host factor

Although the lambdoid bacteriophage phi 80 and P22 possess site-specific recombination systems analogous to bacteriophage lambda, they have different attachment (att) site specificities. We have identified and determined the nucleotide sequences of the att sites of phi 80 and P22 and have examined the interaction of these sites with purified Escherichia coli integration host factor (IHF). The sizes of the homologous core regions of the att sites vary greatly: P22 has a 46-base pair core, while phi 80 and lambda have 17- and 15-base pair cores, respectively. The core sequences of the three phage show no significant homology, although dispersed regions of homology in arm sequences indicate that the three phage att sites are related. All three att sites have a high A + T composition, and restriction fragments carrying these sites migrate anomalously upon polyacrylamide gel electrophoresis. IHF binds to a site to the left of the common core in the phi 80 and P22 phage att sites (attP) and to a site to the right of the core in P22 attP and attB (the bacterial att site). In the lambda system, IHF interacts with three regions on attP (designated H1, H2, and H') and none on attB (Craig N., and Nash, H.A. (1984) Cell 39, 707-716). Alignment of the IHF sites of all three phage results in a consensus sequence for IHF binding, Pyr-AANNNNTTGATAT. Among the three phage, the number of IHF sites differs; however, the location and orientation of the binding sites in relation to the respective core regions are well conserved. An IHF site analogous to lambda H2 is present in both phi 80 and P22 attP, while a site analogous to lambda H' is present in P22 attP. This conservation suggests that IHF plays a very similar role in the site-specific recombination pathways of all three phage, and that the flanking arm sequences are necessary for phi 80 and P22 attP function, as is the case for lambda attP function. These structural similarities presumably reflect a conservation of the mechanism of site-specific recombination for the three phage.     

Plasmids carrying cloned fragments of RF DNA from the filamentous phage φLf can be integrated into the host chromosome via site-specific integration and homologous recombination

Different regions of RF DNA from the filamentous bacteriophage phiLf were cloned in Escherichia coli vectors that can not be maintained in Xanthomonas. After introduction into X. campestris pv. campestris 17 (Xc17), most of these constructs were found to integrate into the host chromosome, either by recA-dependent homologous recombination or recA-independent site-specific integration. Mutations in himA, which codes for the alpha-subunit of the Integration Host Factor, does not affect the integration. Integration occurs into a chromosomal region which harbors a copy of a defective phage (4445 bp) that shares a high degree of identity with the phiLf genome. While various parts of the 4445-bp region are susceptible to homologous recombination, site-specific integration requires the attB sequence on the chromosome and the phage attP. The attB shows a high level of sequence identity (22 out of 28 bp) to the dif site required for E. coli Xer site-specific recombination, including the 6-bp central region, and 8/11 identity in both the left XerC-binding arm and the right XerD-binding arm, with the innermost 5 nt of the arms forming a dyad symmetry that is also present in dif. The attP has the same central region and shows 10/11 identity to the dif site in the left arm, but the sequence of the right arm is less conserved than that of attB. The smallest regions still capable of mediating integration are a cloned 72-bp phiLf attP-containing sequence and a 51-bp Xc17 attB-containing sequence, which was reinserted into the Xc17 chromosome after the 4445-bp region had been deleted, indicating that accessory sequences are not necessary and that the integrase required for site-specific integration is neither specified by the 4445-bp Xc17 chromosomal region nor encoded by the phiLf genome.     

Phage R4 integrase mediates site-specific integration in human cells.

The R4 integrase is a site-specific, unidirectional recombinase derived from the genome of phage R4 of Streptomyces parvulus. Here we define compact attB and attP recognition sites for the R4 integrase and express the enzyme in mammalian cells. We demonstrate that R4 integrase functions in human cells, performing efficient and precise recombination between R4 attB and attP sites cloned on an extrachromosomal vector. We also provide evidence that the enzyme can mediate integration of an incoming plasmid bearing an attB or attP site into endogenous sequences in the human genome. Furthermore, when R4 attB and attP sites are placed into the human genome, either by random integration or at a specific sequence by using the phi C31 integrase, they act as targets for integration of incoming plasmids bearing R4 att sites. The R4 integrase has immediate utility as a site-specific integration tool for genome engineering, as well as potential for further development.     

Overdrive, a T-DNA transmission enhancer on the A. tumefaciens tumour-inducing plasmid

During crown gall tumorigenesis a specific segment of the Agrobacterium tumefaciens tumour-inducing (Ti) plasmid, the T-DNA, integrates into plant nuclear DNA. Similar 23-bp direct repeats at each end of the T region signal T-DNA borders, and T-DNA transmission (transfer and integration) requires the right-hand direct repeat. A chemically synthesized right border repeat in its wild-type orientation promotes T-DNA transmission at a low frequency; Ti plasmid sequences which normally flank the right repeat greatly stimulate the process. To identify flanking sequences required for full right border activity, we tested the activity of a border repeat surrounded by different amounts of normal flanking sequences. Efficient T-DNA transmission required a conserved sequence (5' TAAPuTPy-CTGTPuT-TGTTTGTTTG 3') which lies to the right of the two known right border repeats. In either orientation, a synthetic oligonucleotide containing this conserved sequence greatly stimulated the activity of a right border repeat, and a deletion removing 15 bp from the right end of this sequence destroyed it stimulatory effect. Thus, wild-type T-DNA transmission required both the 23-bp right border repeat and a conserved flanking sequence which we call overdrive.