The structure of a partial duplication in the integron of plasmid pDGO100

A family of novel potentially mobile DNA elements called integrons, has recently been described (H. W. Stokes and R. M. Hall, 1989, Mol. Microbiol. 3, 1669-1683). The integrons present in the plasmids pDGO100 and pSa are unusual in that they include a duplication of the sulI gene which is located in one of the two conserved segments that make up these elements. In order to define the nature of the duplication in pDGO100, we have sequenced the sulI gene region located between the aadB and the dhfr genes of pDGO100. This region includes the first 1355 bases of the 2026-base 3'-conserved segment present in the integrons of Tn21, R46 and R388, and the sequence identity in pDGO100 ceases 24 bases beyond the end of the sulI gene. This position corresponds to the center of a 59-base element, a remnant of which is located at the end of sulI. This finding suggests that the 59-base element may have been involved in the event which gave rise to the partial duplication.     

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.     

The cassettes and 3' conserved segment of an integron from Klebsiella oxytoca plasmid pACM1.

pACM1 is a conjugative multiresistance plasmid from Klebsiella oxytoca that encodes SHV-5 extended-spectrum beta-lactamase (ESBL) and has two integrons. The first is a type I (sul type); the second, detected by hybridization with an intI gene probe, has been putatively identified as a defective type I integron. The cassette region of the first integron has now been fully sequenced and contains three aminoglycoside resistance determinants (aac(6')-Ib, aac(3)-Ia, and ant(3")-Ia) and two open reading frames of unknown function. In addition, sequencing of a region downstream from the qacEDelta1-sulI-ORF 5 gene cluster of the first integron revealed a copy of insertion sequence IS6100 flanked by inverted copies of sequence from the 11.2-kb insert (In2) of Tn21. This arrangement is similar to that found in In4 of Tn1696. The coincidence of an ESBL gene and mobile elements on a conjugative plasmid has potential implications for the spread of ESBL-mediated drug resistance, though evidence of bla((SHV-5)) movement mediated by these elements has not been found.     

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)     

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.     

Characterization of the nonenzymatic chloramphenicol resistance (cmlA) gene of the In4 integron of Tn1696: similarity of the product to transmembrane transport proteins.

Integrons constitute a novel family of DNA elements which evolved by site-specific integration of discrete units between two conserved segments. On the In4 integron of Tn1696, a precisely inserted gene cassette of 1,549 bp conferring nonenzymatic chloramphenicol resistance (cmlA) is present between the streptomycin-spectinomycin resistance (aadA2) gene cassette and the 3'-conserved segment of the integron. In this study, we present the nucleotide sequence of the cmlA gene cassette of Tn1696, show its similarity to bacterial efflux systems and other transport proteins, and present evidence for alterations that its expression exerts on bacterial membranes. The cmlA gene cassette apparently carries its own promoter(s), a situation that has not heretofore been observed in the integrons of multiresistance plasmids and transposons of gram-negative bacteria. One or more of these promoters were shown to be functionally active in expressing a cat marker gene from promoter-probe vectors. The putative CmlA polypeptide appears to provoke a reduction of the content of the major porins OmpA and OmpC.     

The integron In1 in plasmid R46 includes two copies of the oxa2 gene cassette.

The sequence of the insert region of the integron In1 found in the IncN plasmid R46 was completed. The insert region is 2929 bases long and includes four gene cassettes, two of which are identical copies of the oxa2 gene cassette flanking an aadA1 cassette. The fourth cassette encodes an open reading frame orfD. From comparison of these data with published maps and sequences it is argued that the integrons found in the IncN plasmids pCU1 and R1767 and in the transposon Tn2410 are closely related to In1 from R46. Both site-specific gene insertion and recA-dependent recombination are likely to have contributed to the evolution of these integrons.     

Broad-host-range IncP-4 plasmid R1162: effects of deletions and insertions on plasmid maintenance and host range

R1162 is an 8.7-kilobase (kb) broad-host-range replicon encoding resistance to streptomycin and sulfa drugs. In vitro deletion of 1.8-kb DNA between coordinates 3.0 and 5.3 kb did not affect plasmid maintenance, but a Tn1 insertion at coordinate 6.3 kb led to a recessive defect in plasmid maintenance. The only cis-acting region necessary for plasmid replication appears to lie between the Tn1 insertion at coordinate 6.3 kb and a second Tn1 insertion at coordinate 6.5 kb. All R1162 sequences between position 6.5 kb and the EcoRI site at coordinate 8.7/0 kb were dispensible for replication in Escherichia coli and Pseudomonas putida. Plasmids carrying insertions in a variety of restriction sites in an R1162::Tn1 derivative were unstable in P. putida but stable in E. coli. Tn5 insertions in R1162 showed a hot spot at coordinate 7.5 kb. A Tn5 insertion at coordinate 8.2 kb appeared to mark the 3' end of the streptomycin phosphotransferase coding sequence. All R1162::Tn5 derivatives showed specific instability in Pseudomonas strains but not in E. coli. The instability could be relieved by internal deletions of Tn5 sequences. In the haloaromatic-degrading Pseudomonas sp. strain B13, introduction of an unstable R1162::Tn5 plasmid led to loss of ability to utilize m-chlorobenzoate as a growth substrate. Our results showed that alteration of plasmid sequence organization in nonessential regions can result in restriction of plasmid host range.     

IntI2 integron integrase in Tn7

Integrons can insert and excise antibiotic resistance genes on plasmids in bacteria by site-specific recombination. Class 1 integrons code for an integrase, IntI1 (337 amino acids in length), and are generally borne on elements derived from Tn5090, such as that found in the central part of Tn21. A second class of integron is found on transposon Tn7 and its relatives. We have completed the sequence of the Tn7 integrase gene, intI2, which contains an internal stop codon. This codon was found to be conserved among intI2 genes on three other Tn7-like transposons harboring different cassettes. The predicted peptide sequence (IntI2*) is 325 amino acids long and is 46% identical to IntI1. In order to detect recombination activity, the internal stop codon at position 179 in the parental allele was changed to a triplet coding for glutamic acid. The sequences flanking the cassette arrays in the class 1 and 2 integrons are not closely related, but a common pool of mobile cassettes is used by the different integron classes; two of the three antibiotic resistance cassettes on Tn7 and its close relatives are also found in various class 1 integrons. We also observed a fourth excisable cassette downstream of those described previously in Tn7. The fourth cassette encodes a 165-amino-acid protein of unknown function with 6.5 contiguous repeats of a sequence coding for 7 amino acids. IntI2*179E promoted site-specific excision of each of the cassettes in Tn7 at different frequencies. The integrases from Tn21 and Tn7 showed limited cross-specificity in that IntI1 could excise all cassettes from both Tn21 and Tn7. However, we did not observe a corresponding excision of the aadA1 cassette from Tn21 by IntI2*179E.     

Transposition of the IS21-related element IS1415 in Rhodococcus erythropolis.

Three copies of the IS21-related transposable element IS1415 were identified in Rhodococcus erythropolis NI86/21. Adjacent to one of the IS1415 copies, a 47-bp sequence nearly identical to the conserved 5' end of integrons was found. Accurate transposition of IS1415 carrying a chloramphenicol resistance gene (Tn5561) was demonstrated following delivery from a suicide vector to R. erythropolis SQ1.     

Non-palindromic attI sites of integrons are capable of site-specific recombination with one another and with secondary targets

Genes borne on cassettes are mobile owing to site-specific recombination systems called integrons, which have created various combinations of antibiotic resistance genes in R-plasmids. In these processes, the palindromic site, attC (59-base element), at cassette junctions has been proposed as being essential. Excised and circularized cassettes have been found to integrate with preference for an attI site at one end of the conserved sequence in integrons. In this work, we give evidence that recombination is possible in the absence of the highly organized attC sites between the more simply organized attI sites. Furthermore, at a very low frequency representing the background in our recombination assay, we observed cross-overs between attI and secondary sites. To characterize recombination excluding the attC sites, we have used naturally occurring attI variants and constructed mutants. The cross-over point was identified between a guanine and a thymine in attI using point mutations. Progressive deletions showed the extent of attI and identified two important regions in the conserved sequence 5' of the cross-over point. A region 27–36 bp 5' of attI influenced recombination with attC sites only, whereas a sequence 9–14 bp 5' of the cross-over point in attI was important for recombination with both attI and attC . Recombination between attI and secondary sites could allow fusion of the conserved sequence encoding the integron site-specific recombinase to new sequences.     

Molecular characterization of a STreptococcus mutans mutant altered in environmental stress responses.

A mutant defective in aciduricity, GS5Tn1, was constructed following mutagenesis of Streptococcus mutans GS5 with the conjugative transposon Tn916. The mutant grew poorly at acidic pH levels and was sensitive to high osmolarity and elevated temperatures. These properties resulted from a single insertion of Tn916 into the GS5 chromosome, and the DNA fragment harboring the transposon was isolated into the cosmid vector, charomid 9-20. Spontaneous excision of Tn916 from the cosmid revealed that Tn916 inserted into a 8.6-kb EcoRI fragment. On the basis of the restriction analyses of insert fragments, it was found that Tn916 inserted into a 0.9-kb EcoRI-XbaI fragment. Nucleotide sequence analysis of this fragment indicated the presence of two open reading frames, ORF1 and ORF2. By using a marker rescue strategy, a 6.0-kb HindIII fragment including the target site for Tn916 insertion and the 5' end of ORF1 was isolated and sequenced. The deduced amino acid sequences of ORF1 and ORF2 showed significant homology with the diacylglycerol kinase and Era proteins, respectively, from Escherichia coli. Nucleotide sequence analysis of the Tn916 insertion junction region in the GS5Tn1 chromosome revealed that the transposon inserted near the 3' terminus of ORF1. Restoration of ORF1 to its original sequence in mutant GS5Tn1 was carried out following transformation with integration vector pVA891 containing an intact ORF1. The resultant transformant showed wild-type levels of aciduricity as well as resistance to elevated temperatures and high osmolarity. These results suggest that the S. mutans homolog of diacylglycerol kinase is important for adaptation of the organism to several environmental stress signals.     

Physical and genetic map of a Rhizobium meliloti nodulation gene region and nucleotide sequence of nodC.

Infection of alfalfa by the soil bacterium Rhizobium meliloti proceeds by deformation of root hairs and bacterial invasion of host tissue by way of an infection thread. We studied an 8.7-kilobase (kb) segment of the R. meliloti megaplasmid, which contains genes required for infection. Site-directed Tn5 mutagenesis was used to examine this fragment for nodulation genes. A total of 81 R. meliloti strains with mapped Tn5 insertions in the 8.7-kb fragment were evaluated for nodulation phenotype on alfalfa plants; 39 of the insertions defined a 3.5-kb segment containing nodulation functions. Of these 39 mutants, 37 were completely nodulation deficient (Nod-), and 2 at the extreme nif-distal end were leaky Nod-. Complementation analysis was performed by inoculating plants with strains carrying a genomic Tn5 at one location and a plasmid-borne Tn5 at another location in the 3.5-kb nodulation segment. Mutations near the right border of the fragment behaved as two distinct complementation groups. The segment in which these mutations are located was analyzed by DNA sequencing. Several open reading frames were found in this region, but the one most likely to function is 1,206 bases long, reading from left to right (nif distal to proximal) and spanning both mutation groups. The genetic behavior of this segment may be due either to the gene product having two functional domains or to a recombinational hot spot between the apparent complementation groups.     

The amo operon in marine, ammonia-oxidizing γ-proteobacteria

A bank of transfer-defective Tn7 insertion mutants of the multi-resistant IncHI2 megaplasmid, R478, was generated. Complementation analysis of these mutations identified a large 144-kb transfer-associated region of R478. A 6.8-kb segment from the transfer region was sequenced. The precise locations of Tn7 insertion within four distinct R478::Tn7 transfer-defective mutants were mapped and each insertion was found to disrupt a specific open reading frame. These transfer-associated determinants of R478 were designated htdB (H transfer determinant), htdD, htdT and htdC. Both htdB and htdC encoded amino acid sequences that showed a low homology with pilus biosynthetic proteins encoded by the F plasmid.     

The nucleotide sequence of the mercuric resistance operons of plasmid R100 and transposon Tn501: further evidence for mer genes which enhance the activity of the mercuric ion detoxification system

Summary The DNA sequences of the mercuric resistance determinants of plasmid R100 and transposon Tn501 distal to the gene (merA) coding for mercuric reductase have been determined. These 1.4 kilobase (kb) regions show 79% identity in their nucleotide sequence and in both sequences two common potential coding sequences have been identified. In R100, the end of the homologous sequence is disrupted by an 11.2 kb segment of DNA which encodes the sulfonamide and streptomycin resistance determinants of Tn21. This insert contains terminal inverted repeat sequences and is flanked by a 5 base pair (bp) direct repeat. The first of the common potential coding sequences is likely to be that of the merD gene. Induction experiments and mercury volatilization studies demonstrate an enhancing but non-essential role for these merA-distal coding sequences in mercury resistance and volatilization. The potential coding sequences have predicted codon usages similar to those found in other Tn501 and R100 mer genes.     

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.     

A second gene in a Balbiani ring. Chironomus salivary glands contain a 6.5-kb poly(A)+ RNA that is transcribed from a hierarchy of tandem repeated sequences in Balbiani ring 1

A second gene has been discovered at a previously studied Balbiani ring in Chironomus. Northern hybridizations demonstrated that cDNA clone pCt35 originated from a salivary gland specific 6.5-kilobase (kb) RNA that was abundant, nonribosomal, and apparently poly(A)+. pCt35 had a 120-base pair (bp) insert with 1.6 copies of a 75-bp sequence that contained two open reading frames. Southern hybridizations indicated that pCt35 was homologous to at least a 4-kb block of genomic DNA organized as a hierarchy of 150- and 300-bp tandem repeats. In situ hybridization localized these sequences to Balbiani ring 1. From these results we postulated that a 6.5-kb RNA gene may have evolved by stepwise duplication and amplification of a 75-bp ancestral sequence.     

Transposon Tn5090 of plasmid R751, which carries an integron, is related to Tn7, Mu, and the retroelements.

Integrons confer on bacterial plasmids a capability of taking up antibiotic resistance genes by integrase-mediated recombination. We show here that integrons are situated on genetic elements flanked by 25-bp inverted repeats. The element carrying the integron of R751 has three segments conserved with similar elements in Tn21 and Tn5086. Several characteristics suggest that this element is a transposon, which we call Tn5090. Tn5090 was shown to contain an operon with three open reading frames, of which two, tniA and tniB, were predicted by amino acid similarity to code for transposition proteins. The product of tniA (559 amino acids) is a probable transposase with 25% amino acid sequence identity to TnsB from Tn7. Both of these polypeptides contain the D,D(35)E motif characteristic of a protein family made up of the retroviral and retrotransposon IN proteins and some bacterial transposases, such as those of Tn552 and of a range of insertion sequences. Like the transposase genes in Tn552, Mu, and Tn7, the tniA gene was followed by a gene, tniB, for a probable ATP-binding protein. The ends of Tn5090, like those of most other elements producing D,D(35)E proteins, begin by 5'-TG and also contains a complex structure with four 19-bp repeats at the left end and three at the right end. Similarly organized repeats have been observed earlier at the termini of both Tn7 and phage Mu, where they bind their respective transposases and have a role in holoenzyme assembly. Another open reading frame observed in Tn5090, tniC, codes for a recombinase of the invertase/resolvase family, suggesting a replicative transposition mechanism. The data presented here suggest that Tn5090, Tn7, Tn552, and Mu form a subfamily of bacterial transposons which in parallel to many insertion sequences are related to the retroelements.     

Molecular cloning of the Harvey sarcoma virus circular DNA intermediates. II. Further structural analyses.

Three species of unintegrated supercoiled Harvey sarcoma virus DNA (6.6, 6.0, and 5.4 kilobase pairs) have been molecularly cloned from Harvey sarcoma virus-infected cells. On the basis of restriction enzyme analyses, the 6.6- and 6.0-kilobase pair viral DNAs contain two and one copies, respectively, of a 650-base pair DNA segment which contains sequences present at the 3' and 5' termini of the viral genome. R-loop structures formed between Moloney leukemia virus RNA and the cloned Harvey sarcoma virus DNA indicated that about 500 base pairs of the 650-base pair repeating segment was complementary to the 3' end of the viral RNA. During amplification in the Escherichia coli host, some recombinants containing the 6.6- or the 6.0-kilobase pair Harvey sarcoma virus DNA insert acquired or lost the complete 650-base pair DNA segment. These changes occurred in both recA+ and recA- E. coli.     

Tn5386, a novel Tn916-like mobile element in Enterococcus faecium D344R that interacts with Tn916 to yield a large genomic deletion

We describe Tn5386, a novel ca.-29-kb Tn916-like mobile element discovered to occur in ampicillin-resistant, Tn916-containing Enterococcus faecium D344R. PCR amplification experiments after overnight growth with or without tetracycline revealed "joint" regions of circularized Tn5386 composed of 6-bp sequences linking different transposon termini. In one case (no tetracycline), the termini were consistent with those derived by target site analysis of the integrated element. In the other case, the termini were virtually identical in distance from the integrase binding regions, as seen with Tn916. These data are consistent with a model in which one PCR product results from the action of Tn5386 integrase, whereas the other results from the action of the Tn916 integrase on Tn5386. Spontaneous conversion of D344R to an ampicillin-susceptible phenotype (D344SRF) was associated with a 178-kb deletion extending from the left end of Tn5386 to the left end of Tn916. Examination of the Tn5386 junction after the large deletion event suggests that the deletion resulted from an interaction between the nonintegrase ends of Tn5386 and Tn916. The terminus of Tn5386 identified in this reaction suggested that it may have resulted from the activity of the Tn916 integrase (Int(Tn916)). The "joint" of the circular element resulting from this excision was amplifiable from D344R, the sequence of which revealed a heteroduplex consistent with Int(Tn916)-mediated excision. In contrast, Tn5386 joints amplified from ampicillin-susceptible D344SRF revealed ends consistent with Tn5386 integrase activity, reflecting the absence of Tn916 from this strain. Tn5386 represents a new member of the Tn916 transposon family. Our data suggest that excision of Tn5386 can be catalyzed by the Tn916 integrase and that large genomic deletions may result from the interaction between these heterologous elements.