Site-specific insertion of genes into integrons: role of the 59-base element and determination of the recombination cross-over point

From examination of published DNA sequences of genes found inserted at a specific site in integrons, all genes are shown to be associated, at their 3' ends, with a short imperfect inverted repeat sequence, a 59-base element or relative of this element. The similarity of the arrangement of gene inserts in the integron and in the Tn7 transposon family is described. A refined consensus for the 59-base element is reported. Members of this family are highly diverged and the relationship of a group of longer elements to the 59-base elements is demonstrated. The ability of 59-base elements of different length and sequence to act as sites for recombination catalysed by the integron-encoded DNA integrase is demonstrated, confirming that elements of this family have a common function. The ability of elements located between gene pairs to act as recombination sites has also been demonstrated. The recombination cross-over point has been localized to the GTT triplet which is conserved in the core sites, GTTRRRY, found at the 3' end of 59-base elements. Recombination at the core site found in inverse orientation at the 5' end of the 59-base elements was not detected, and the sequences responsible for orientation of the recombination event appear to reside within the 59-base element. A model for site-specific insertion of genes into integrons and Tn7-like transposons is proposed. Circular units consisting of a gene associated with a 59-base element are inserted into an ancestral element which contains neither a gene nor a 59-base element.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure and function of 59-base element recombination sites associated with mobile gene cassettes

The integration of gene cassettes into integrons is effected by site-specific recombination catalysed by an integrase, IntI, encoded by the integron. The cassette-associated recombination sites, 59-base elements, are not highly conserved and vary in length from 57 to 141 bp. They can be identified by their location and the relationship of over 20 bp at their outer ends to consensus sequences that are imperfect inverted repeats of one another. The recombination cross-over occurs close to one end of the 59-base element, within a conserved core site with the consensus sequence GTTAGGC or GTTRRRY. By introducing single-base changes at each of these positions in the aadB 59-base element, bases that are critical for site activity were identified. The recombination cross-over was also localized to a unique position between the adjacent G and T residues. Changes introduced in the conserved AAC of the inverse core site (GCCTAAC or RYYYAAC) located at the opposite end of the 59-base element also reduced site activity but to a lesser extent. Sequences of rare recombinants revealed an alternative position for strand exchange and led to the conclusion that 59-base elements comprise two simple sites, analogous to those recognized by other integrases, with each simple site made up of a pair of inversely oriented IntI binding domains separated by a spacer of 7 or 8 bp. Re-examination of the sequences of all known 59-base elements revealed that this simple site configuration was present at both the left and right ends in all 59-base elements. The identity of bases in the spacer is not required for efficient recombination and the cross-over is located at one end of the spacer, suggesting that during IntI1-mediated recombination only one strand exchange occurs.     

A novel family of potentially mobile DNA elements encoding site-specific gene-integration functions: integrons

A family of novel mobile DNA elements is described, examples of which are found at several independent locations and encode a variety of antibiotic resistance genes. The complete elements consist of two conserved segments separated by a segment of variable length and sequence which includes inserted antibiotic resistance genes. The conserved segment located 3' to the inserted resistance genes was sequenced from Tn21 and R46, and the sequences are identical over a region of 2026 bases, which includes the sulphonamide resistance gene sull, and two further open reading frames of unknown function. The complete sequences of both the 3' and 5' conserved regions of the DNA element have been determined. A 59-base sequence element, found at the junctions of inserted DNA sequences and the conserved 3' segment, is also present at this location in the R46 sequence. A copy of one half of this 59-base element is found at the end of the sull gene, suggesting that sull, though part of the conserved region, was also originally inserted into an ancestral element by site-specific integration. Inverted or direct terminal repeats or short target site duplications, both of which are characteristics of class I and class II transposons, are not found at the outer boundaries of the elements described here. Furthermore, the conserved regions do not encode any proteins related to known transposition proteins, except the DNA integrase encoded by the 5' conserved region which is implicated in the gene insertion process. Mobilization of this element has not been observed experimentally; mobility is implied from the identification of the element in at least four independent locations, in Tn21, R46 (IncN), R388 (IncW) and Tn1696. The definitive features of these novel elements are (i) that they include site-specific integration functions (the integrase and the insertion site); (ii) that they are able to acquire various gene units and act as an expression cassette by supplying the promoter for the inserted genes. As a consequence of acquiring different inserted genes, the element exists in a variety of forms which differ in the number and nature of the inserted genes. This family of elements appears formally distinct from other known mobile DNA elements and we propose the name DNA integration elements, or integrons.     

Site-specific deletion and rearrangement of integron insert genes catalyzed by the integron DNA integrase.

Deletion of individual antibiotic resistance genes found within the variable region of integrons is demonstrated. Evidence for gene duplications and rearrangements resulting from the insertion of gene units at new locations is also presented. Deletion, duplication, and rearrangement occur only in the presence of the integron-encoded DNA integrase. These events are precise and involve loss or gain of one or more complete insert units or gene cassettes. This confirms the recent definition of gene cassettes as consisting of the gene coding sequences, all except the last 7 bases of the 59-base element found at the 3' end of the gene, and the core site located 5' to the gene (Hall et al., Mol. Microbiol. 5:1941-1959, 1991) and demonstrates that individual gene cassettes are functional units which can be independently mobilized. Both deletions and duplications can be generated by integrase-mediated cointegrate formation followed by integrase-mediated resolution involving a different pair of sites. However, deletion occurs 10 times more frequently than duplication, and we propose that the majority of deletion events are likely to involve integrase-dependent excision of the gene unit to generate a circular gene cassette. The implications of these findings in understanding the evolution of integrons and the spread of antibiotic resistance genes in bacterial populations is discussed.     

Integrons: Novel DNA elements which capture genes by site-specific recombination

Integrons are unusual DNA elements which include a gene encoding a site-specific DNA recombinase, a DNA integrase, and an adjacent site at which a wide variety of antibiotic resistance and other genes are found as inserts. One or more genes can be found in the insert region, but each gene is part of an independent gene cassette. The inserted genes are expressed from a promoter in the conserved sequences located 5 to the genes, and integrons are thus natural expression vectors. A model for gene insertion in which circular gene cassettes are inserted individually via a single site-specific recombination event has been proposed and verified experimentally. The gene cassettes include a gene coding region and, at the 3 end of the gene an imperfect inverted repeat, a 59-base element. The 59-base elements are a diverse family of elements which function as sites recognized by the DNA integrase. Site-specific insertion of individual genes thus represents a further mechanism which contributes to the evolution of the genomes of Gram-negative bacteria and their plasmids and transposons.Members of the most studied class of integrons, which include thesulI gene in the conserved sequences, are believed to be mobile DNA elements on the basis that they are found in many independent locations, and a discrete boundary is found at the outer end of the 5-conserved segment. However, the length of the 3-conserved segment is variable in the integrons examined to date, and it is likely that this variability has arisen as the result of insertion and deletion events. Though the true extent of the 3-conserved segment remains to be determined, it seems likely that these integrons are mobile DNA elements. The second known class of integrons comprises members of the Tn7 transposon family.     

Integrons found in different locations have identical 5' ends but variable 3' ends.

The positions of the outer boundaries of the 5'- and 3'-conserved segment sequences of integrons found at several different locations have been determined. The position of the 5' end of the 5'-conserved segment is the same for six independently located integrons, In1 (R46), In2 (Tn21), In3 (R388), In4 (Tn1696), In5 (pSCH884), and In0 (pVS1). However, the extent of the 3'-conserved segment differs in each integron. The sequences of In2 and In0 diverge first from the conserved sequence, and their divergence point corresponds to the 3'-conserved segment endpoint defined previously (H.W. Stokes and R.M. Hall, Mol. Microbiol. 3:1669-1683, 1989), which now represents the endpoint of a 359-base deletion in In0 and In2. The sequence identity in In3, In1, In4, and In5 extends beyond this point, but each sequence diverges from the conserved sequence at a different point within a short region. Insertions of IS6100 were identified adjacent to the end of the conserved region in In1 and 123 bases beyond the divergence point of In4. These 123 bases are identical to the sequence found at the mer end of the 11.2-kb insertion in Tn21 but are inverted. In5 and In0 are bounded by the same 25-base inverted repeat that bounds the 11.2-kb insert in Tn21, and this insert now corresponds to In2. However, while In0, In2, and In5 have features characteristic of transposable elements, differences in the structures of these three integrons and the absence of evidence of mobility currently preclude the identification of all of the sequences associated with a functional transposon of this type.     

Sequence analysis of the inducible chloramphenicol resistance determinant in the Tn1696 integron suggests regulation by translational attenuation.

The sequence of the Tn1696 determinant for inducible nonenzymatic chloramphenicol resistance has been determined. The cml region, the fourth insert of the Tn1696 integron, is 1547 bases and includes a 59-base element at the 3' end, as is typical of integron inserts. One gene, designated cmlA and predicting a polypeptide of 44.2 kDa, is encoded in the insert. However, the cmlA region shows one feature not previously found in an integron insert. A promoter is located within the cmlA insert, and translational attenuation signals related to those of the inducible cat and ermC genes found in gram-positive organisms are also present. The regulatory region includes a leader peptide of nine amino acids, a ribosome stall sequence related to those preceding cat genes, and two alternative pairs of stem-loop structures which either sequester or disclose the ribosome binding site and start codon preceding the cmlA gene.     

Gene cassettes from the insert region of integrons are excised as covalently closed circles

Integrons are DNA elements which generally include one or more discrete gene cassettes inserted at a specific site. We have recently proposed a model for the acquisition and dissemination of genes found in the insert region of integrons, which requires the existence of circularized gene cassettes. Evidence for the existence of covalently closed circular molecules consisting of one or more gene cassettes has now been obtained. Low levels of small molecules which hybridize to probes specific for individual gene cassettes were detected in plasmid DNA isolated from cells containing a plasmid which includes an integron fragment with three gene cassettes aacC1, orfE and aadA2. These molecules were only detected when the gene encoding the integron DNA integrase was also present and are thus products of site-specific cassette excision. The excised cassettes have been shown to be in the form of covalently closed supercoiled circles, by digestion with restriction enzymes exonuclease III and DNase I. The circular excision products detected included either one cassette, aadA2 or orfE, two cassettes, aacC1 and orfE or all three cassettes. The predicted sequence of the recombinant junction in the excised aadA2 cassette confirmed that excision was precise. The predicted unique sequences of the 59-base elements associated with individual genes in the circular cassette form were compiled, and the sequences of the seven-base core sites which flank 59-base elements are now, with few exceptions, exact inverted repeats.     

RNA replication from the simian virus 5 antigenomic promoter requires three sequence-dependent elements separated by sequence-independent spacer regions

We have previously shown for the paramyxovirus simian virus 5 (SV5) that a functional promoter for RNA replication requires proper spacing between two discontinuous elements: a 19-base segment at the 3' terminus (conserved region I [CRI]) and an 18-base internal region (CRII) that is contained within the coding region of the L protein gene. In the work described here, we have used a reverse-genetics system to determine if the 53-base segment between CRI and CRII contains additional sequence-specific signals required for optimal replication or if this segment functions solely as a sequence-independent spacer region. A series of copyback defective interfering minigenome analogs were constructed to contain substitutions of nonviral sequences in place of bases 21 to 72 of the antigenomic promoter, and the relative level of RNA replication was measured by Northern blot analysis. The results from our mutational analysis indicate that in addition to CRI and CRII, optimal replication from the SV5 antigenomic promoter requires a third sequence-dependent element located 51 to 66 bases from the 3' end of the RNA. Minigenome RNA replication was not affected by changes in the either the position of this element in relation to CRI and CRII or the predicted hexamer phase of NP encapsidation. Thus, optimal RNA replication from the SV5 antigenomic promoter requires three sequence-dependent elements, CRI, CRII and bases 51 to 66.     

Recombination activity of a distinctive integron-gene cassette system associated with Pseudomonas stutzeri populations in soil

Class 1 integrons have strongly influenced the evolution of multiple antibiotic resistance. Diverse integrons have recently been detected directly in a range of natural environments. In order to characterize the properties of these environmental integrons, we sought to isolate organisms containing integrons from soils, which resulted in the isolation of Pseudomonas stutzeri strain Q. Further isolation efforts targeted at this species resulted in recovery of two other strains (P and BAM). 16S rRNA sequences and chromosome mapping showed that these three strains are very closely related clonal variants in a single genomovar of P. stutzeri. Only strains Q and BAM were found to contain an integron and an associated gene cassette array. The intI and attI components of these strains showed 99 and 90% identity, respectively. The structure of these integrons and their associated gene cassettes was similar to that reported previously for other integron classes. The two integrons contained nonoverlapping sets of cassette-associated genes. In contrast, many of the cassette-associated recombination sites in the two integrons were similar and were considered to constitute a distinct subfamily consisting of 59-base element (59-be) recombination sites (the Pseudomonas subfamily). The recombination activity of P. stutzeri integron components was tested in cointegrate assays. IntIPstQ was shown to catalyze site-specific recombination between its cognate attI site and 59-be sites from antibiotic resistance gene cassettes. While IntIPstQ did not efficiently mediate recombination between members of the Pseudomonas 59-be subfamily and other 59-be types, the former sites were functional when they were tested with IntI1. We concluded that integrons present in P. stutzeri possess recombination activity and represent a hot spot for genomic diversity in this species.     

Mobile gene cassettes and integrons: capture and spread of genes by site-specific recombination

An integron is a genetic unit that includes the determinants of the components of a site-specific recombination system capable of capturing and mobilizing genes that are contained in mobile elements called gene cassettes. An integron also provides a promoter for expression of the cassette genes, and integrons thus act both as natural cloning systems and as expression vectors. The essential components of an integron are an int gene encoding a site-specific recombinase belonging to the integrase family, an adjacent site, attl, that is recognized by the integrase and is the receptor site for the cassettes, and a promoter suitably oriented for expression of the cassette-encoded genes. The cassettes are mobile elements that include a gene (most commonly an antibiotic-resistance gene) and an integrase-specific recombination site that is a member of a family of sites known as 59-base elements. Cassettes can exist either free in a circularized form or integrated at the attl site, and only when integrated is a cassette formally part of an integron. A single site-specific recombination event involving the integron-associated attl site and a cassette-associated 59-base element leads to insertion of a free circular cassette into a recipient integron. Multiple cassette insertions can occur, and integrons containing several cassettes have been found in the wild. The integrase also catalyses excisive recombination events that can lead to loss of cassettes from an integron and generate free circular cassettes. Due to their ability to acquire new genes, integrons have a clear role in the evolution of the genomes of the plasmids and transposons that contain them. However, a more general role in evolution is also likely. Events involving recombination between a specific 59-base-element site and a nonspecific secondary site have recently been shown to occur. Such events should lead either to the insertion of cassettes at non-specific sites or to the formation of stable cointegrates between different plasmid molecules, and a cassette situated outside the integron context has recently been identified.     

Nucleotide sequence of the AAD(2'''') aminoglycoside adenylyltransferase determinant aadB. Evolutionary relationship of this region with those surrounding aadA in R538-1 and dhfrII in R388.

The nucleotide sequence of the aadB gene which confers resistance to kanamycin, gentamicin, and tobramycin has been determined. The size of the longest reading frame is 747 bases encoding a protein of predicted size 27,992 daltons. A segment of the aadB gene sequence (including the promoter region) was found upstream of the aadA gene in R538-1 and of the dhfrII gene in R388 and the proposed promoters for these genes coincide with the aadB promoter region. The sequence homology extends upstream to the end of the sequenced regions of R388 and R538-1. Almost perfect homology was also found between the sequences 3'- to the aadB gene and 3'- to the aadA genes of R538-1 and pSa. This segment includes a 59 base element previously found flanking the Tn7 aadA gene. A model is presented for the evolution of this region of the plasmid genomes in which the 59- base element functions as an insertional "hot spot" and the possibility that this region is analogous to the aadA/aadB region of the Tn21- like transposon family is considered.     

Heterogeneous duplications in patients with Pelizaeus-Merzbacher disease suggest a mechanism of coupled homologous and nonhomologous recombination

We describe genomic structures of 59 X-chromosome segmental duplications that include the proteolipid protein 1 gene (PLP1) in patients with Pelizaeus-Merzbacher disease. We provide the first report of 13 junction sequences, which gives insight into underlying mechanisms. Although proximal breakpoints were highly variable, distal breakpoints tended to cluster around low-copy repeats (LCRs) (50% of distal breakpoints), and each duplication event appeared to be unique (100 kb to 4.6 Mb in size). Sequence analysis of the junctions revealed no large homologous regions between proximal and distal breakpoints. Most junctions had microhomology of 1-6 bases, and one had a 2-base insertion. Boundaries between single-copy and duplicated DNA were identical to the reference genomic sequence in all patients investigated. Taken together, these data suggest that the tandem duplications are formed by a coupled homologous and nonhomologous recombination mechanism. We suggest repair of a double-stranded break (DSB) by one-sided homologous strand invasion of a sister chromatid, followed by DNA synthesis and nonhomologous end joining with the other end of the break. This is in contrast to other genomic disorders that have recurrent rearrangements formed by nonallelic homologous recombination between LCRs. Interspersed repetitive elements (Alu elements, long interspersed nuclear elements, and long terminal repeats) were found at 18 of the 26 breakpoint sequences studied. No specific motif that may predispose to DSBs was revealed, but single or alternating tracts of purines and pyrimidines that may cause secondary structures were common. Analysis of the 2-Mb region susceptible to duplications identified proximal-specific repeats and distal LCRs in addition to the previously reported ones, suggesting that the unique genomic architecture may have a role in nonrecurrent rearrangements by promoting instability.     

Binding of the purified integron DNA integrase IntI1 to integron- and cassette-associated recombination sites

The site-specific recombinase IntI1, encoded by class 1 integrons, catalyses the integration and excision of gene cassettes by recognizing two classes of sites, the integron-associated attI1 site and the 59-base element (59-be) family of sites that are associated with gene cassettes. IntI1 includes the four conserved amino acids that are characteristic of members of the integrase family, and IntI1 proteins with single amino acid substitutions at each of these positions had substantially reduced catalytic activity, consistent with this classification. IntI1 was purified as a fusion protein and shown to bind to isolated attI1 or 59-be recombination sites. Binding to attI1 was considerably stronger than to a 59-be. Binding adjacent to the recombination cross-over point was not detected. A strong IntI1 binding site within attI1 was localized by both deletion and footprinting analysis to a 14 bp region 24–37 bp to the left of the recombination cross-over point, and this region is known to be critical for recombination in vivo ( Recchia et al ., 1994 ). An imperfect (13/15) direct repeat of this region, located 41–55 bp to the left of the recombination cross-over point, contains a weaker IntI1 binding site. Mutation of the stronger binding site showed that a single base pair change accounted for the difference in the strength of binding.     

Structure and sequence of the mitochondrial 20S rRNA and tRNA tyr gene of Paramecium primaurelia

The sequence and structure of the large (20s) mitochondrial (mt) rRNA gene and flanking regions from Paramecium primaurelia have been determined. The gene contains two regions of strong homology with other large mt rRNAs: one 44-base region near the 5' end and a 321-base region near the 3' end. Another region of strong homology to both ends of E. coli 23s RNA exists at loci consistent with these regions. The Paramecium gene appears to be 2204 bases in length and contains slightly more homology to E. coli rRNA than its mammalian or fungal counterparts. The gene, located about 1200 bp from the replicative terminal end of the linear mt DNA, is transcribed in the same polarity as replication. Previous R-looping studies detected no large introns within the gene. Here we describe sequences resembling degenerate rRNAs, one of which could represent a small intron. A tRNA tyr gene was found on the same DNA strand, 127 bp downstream from the large rRNA presumptive 3' end. The tRNA is flanked on both sides by short DNA regions of approximately 90% A + T content.