Nucleotide sequence of Streptomyces fradiae transposable element Tn4556: a class-II transposon related to Tn3

Challenges and advances in genetic manipulation of filamentous actinomycetes - the remarkable producers of specialized metabolites

Covering: up to February 2019Actinomycetes are Gram positive bacteria of the phylum Actinobacteria. These organisms are one of the most important sources of structurally diverse, clinically used antibiotics and other valuable bioactive products, as well as biotechnologically relevant enzymes. Most strains were discovered by their ability to produce a given molecule and were often poorly characterized, physiologically and genetically. The development of genetic methods for Streptomyces and related filamentous actinomycetes has led to the successful manipulation of antibiotic biosynthesis to attain structural modification of microbial metabolites that would have been inaccessible by chemical means and improved production yields. Moreover, genome mining reveals that actinomycete genomes contain multiple biosynthetic gene clusters (BGCs), however only a few of them are expressed under standard laboratory conditions, leading to the production of the respective compound(s). Thus, to access and activate the so-called "silent" BGCs, to improve their biosynthetic potential and to discover novel natural products methodologies for genetic manipulation are required. Although different methods have been applied for many actinomycete strains, genetic engineering is still remaining very challenging for some "underexplored" and poorly characterized actinomycetes. This review summarizes the strategies developed to overcome the obstacles to genetic manipulation of actinomycetes and allowing thereby rational genetic engineering of this industrially relevant group of microorganisms. At the end of this review we give some tips to researchers with limited or no previous experience in genetic manipulation of actinomycetes. The article covers the most relevant literature published until February 2019.

Efficient transposition of Tn4556 by alterations in inverted repeats using a delivery vector carrying a counter-selectable marker for Streptomyces

A 6625-base pair transposon, Tn4556, was initially isolated from a Streptomyces strain and a sequence analysis was performed; however, its annotation data remain incomplete. At least three positions were identified as frameshift and base-exchange errors by resequencing. The revised sequence revealed that Tn4556 contains four open reading frames that encode transposase, methyltransferase, isoprenyl diphosphate transferase, and resolvase, respectively. Thirty-eight-base pair inverted repeat (IR) sequences at both ends contained a 1-bp mismatch flanked by a target duplication site, and transposition efficiency was improved by the replacement of imperfectly matched IR-L to perfectly matched IR-L. The detection of Tn4556 transposition was markedly facilitated using a delivery vector carrying a strictly counter-selectable marker for Streptomyces strains.

The Tn3-family of Replicative Transposons

Transposons of the Tn3 family form a widespread and remarkably homogeneous group of bacterial transposable elements in terms of transposition functions and an extremely versatile system for mediating gene reassortment and genomic plasticity owing to their modular organization. They have made major contributions to antimicrobial drug resistance dissemination or to endowing environmental bacteria with novel catabolic capacities. Here, we discuss the dynamic aspects inherent to the diversity and mosaic structure of Tn3-family transposons and their derivatives. We also provide an overview of current knowledge of the replicative transposition mechanism of the family, emphasizing most recent work aimed at understanding this mechanism at the biochemical level. Previous and recent data are put in perspective with those obtained for other transposable elements to build up a tentative model linking the activities of the Tn3-family transposase protein with the cellular process of DNA replication, suggesting new lines for further investigation. Finally, we summarize our current view of the DNA site-specific recombination mechanisms responsible for converting replicative transposition intermediates into final products, comparing paradigm systems using a serine recombinase with more recently characterized systems that use a tyrosine recombinase.

Transposition of Tn4560 of Streptomyces fradiae in Mycobacterium smegmatis

Tn4560 (8.6 kb) was derived from Tn4556, a Tn3-like element from Streptomyces fradiae. It contains a viomycin resistance gene that has not been used previously for selection in mycobacteria. Tn4560, cloned in a Streptomyces plasmid, was introduced by electroporation into Mycobacterium smegmatis mc(2)155. Tn4560 transposed into the host genome: there was no obvious target sequence preference, and insertions were in or near several conserved open reading frames. The insertions were located far apart on different AseI macrorestriction fragments. Unexpectedly, the transposon delivery plasmid, pUC1169, derived from the Streptomyces multicopy plasmid pIJ101, replicated partially in M. smegmatis, but was lost spontaneously during subculture. Replication of pUC1169 probably contributed to the relatively high efficiency of Tn4560 delivery: up to 28% of the potential M. smegmatis transformants acquired a stable transposon insertion. The data indicated that Tn4560 may be useful for random mutagenesis of M. smegmatis.

Cloning of a genetically unstable cytochrome P-450 gene cluster involved in degradation of the pollutant ethyl tert-butyl ether by Rhodococcus ruber

Rhodococcus ruber (formerly Gordonia terrae) IFP 2001 is one of a few bacterial strains able to degrade ethyl tert-butyl ether (ETBE), which is a major pollutant from gasoline. This strain was found to undergo a spontaneous 14.3-kbp chromosomal deletion, which results in the loss of the ability to degrade ETBE. Sequence analysis of the region corresponding to the deletion revealed the presence of a gene cluster, ethABCD, encoding a ferredoxin reductase, a cytochrome P-450, a ferredoxin, and a 10-kDa protein of unknown function, respectively. The EthB and EthD proteins could be easily detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and were induced by ETBE in the wild-type strain. Upstream of ethABCD lies ethR, which codes for a putative positive transcriptional regulator of the AraC/XylS family. Transformation of the ETBE-negative mutant by a plasmid carrying the ethRABCD genes restored the ability to degrade ETBE. Complementation was abolished if the plasmid carried ethRABC only. The eth genes are located in a DNA fragment flanked by two identical direct repeats of 5.6 kbp. The ETBE-negative mutants carry a single copy of this 5.6-kbp repeat, suggesting that the 14.3-kbp chromosomal deletion resulted from a recombination between the two identical sequences. The 5.6-kbp repeat is a class II transposon carrying a TnpA transposase, a truncated form of the recombinase TnpR, and a terminal inverted repeat of 38 bp. The truncated TnpR is encoded by an IS3-interrupted tnpR gene.

Horizontal spread of mer operons among gram-positive bacteria in natural environments

Horizontal dissemination of the genes responsible for resistance to toxic pollutants may play a key role in the adaptation of bacterial populations to environmental contaminants. However, the frequency and extent of gene dissemination in natural environments is not known. A natural horizontal spread of two distinct mercury resistance (mer) operon variants, which occurred amongst diverse Bacillus and related species over wide geographical areas, is reported. One mer variant encodes a mercuric reductase with a single N-terminal domain, whilst the other encodes a reductase with a duplicated N-terminal domain. The strains containing the former mer operon types are sensitive to organomercurials, and are most common in the terrestrial mercury-resistant Bacillus populations studied in this work. The strains containing the latter operon types are resistant to organomercurials, and dominate in a Minamata Bay mercury-resistant Bacillus population, previously described in the literature. At least three distinct transposons (related to a class II vancomycin-resistance transposon, Tn1546, from a clinical Enterococcus strain) and conjugative plasmids are implicated as mediators of the spread of these mer operons.

Cloning of the gene encoding avermectin B 5-O-methyltransferase in avermectin-producing Streptomyces avermitilis

Complementation of a mutant lacking avermectin B 5-O-methyltransferase (AveD) of Streptomyces avermitilis, which catalyses the methylation of the hydroxyl group at the C5 position of avermectin B compounds, revealed that the gene encoding AveD is in a 1.25-kb SalI-EcoNI fragment in the left region of the gene cluster for avermectin biosynthesis. The nucleotide sequence of this fragment predicted a 283-aa gene product homologous to several methyltransferases requiring S-adenosyl-l-methionine as a cofactor. After cloning of the aveD region from mutant not producing AveD, the complementation experiments were performed using a pair of hybrid fragments (AveD+/AveD- and AveD-/AveD+). They suggest that the mutation(s) is in the N-terminus of AveD. SSCP analysis of amplified DNA of the aveD region derived from both wild type and mutant strains supports the results of the complementation experiments. Sequence analysis of the aveD region of the mutant strain revealed that a point mutation is within ORF, being Thr23-->Ile substitution. This mutation causes the inactivation of O-methyltransferase activity of AveD.

Structural analysis of the 6 kb cryptic plasmid pFAJ2600 from Rhodococcus erythropolis NI86/21 and construction of Escherichia coli-Rhodococcus shuttle vectors

The complete nucleotide sequence of the 5936 bp cryptic plasmid pFAJ2600 from Rhodococcus erythropolis NI86/21 was determined. Based on the characteristics of its putative replication genes, repA and repB, pFAJ2600 was assigned to the family of pAL5000-related small replicons identified in Mycobacterium (pAL5000), Corynebacterium (pXZ10142), Brevibacterium (pRBL1), Bifidobacterium (pMB1) and Neisseria (pJD1). The replication systems of these plasmids show striking similarities to the ones used by the ColE2 family of plasmids from Enterobacteria with respect to both trans-acting factors and ori sequences. Two possible plasmid stabilization systems are encoded on pFAJ2600: a site-specific recombinase (PmrA) related to the Escherichia coli Xer proteins for plasmid multimer resolution and an ATPase (ParA) related to the A-type of proteins in sop/par partitioning systems. The proposed replication termination region of pFAJ2600 has features in common with the Ter loci of Bacillus subtilis. Chimeras composed of a pUC18-Cmr derivative inserted in the parA-repA intergenic region of vector pFAJ2600 produced vectors that could be shuttled between Escherichia coli and several Rhodococcus species (R. erythropolis, R. fascians, R. rhodochrous, R. ruber). The pFAJ2600-based shuttle vector pFAJ2574 was stably maintained in R. erythropolis and R. fascians growing under non-selective conditions.

Tn5041: a chimeric mercury resistance transposon closely related to the toluene degradative transposon Tn4651

This paper reports the discovery and characterization of Tn5041, a novel-type transposon vehicle for dissemination of mercury resistance in natural bacterial populations. Tn5041 (14876 bp), identified in a Pseudomonas strain from a mercury mine, is a Tn3 family mercury resistance transposon far outside the Tn21 subgroup. As in other Tn3 family transposons, Tn5041 duplicates 5 bp of the target sequence following insertion. Tn5041 apparently acquired its mer operon as a single-ended relic of a transposon belonging to the classical mercury resistance transposons of the Tn21 subgroup. The putative transposase and the 47 bp terminal inverted repeats of Tn5041 are closely related to those of the toluene degradative transposon Tn4651 and fall into a distinct subgroup on the fringe of the Tn3 family. The amino acid sequence of the putative resolvase of Tn5041 resembles site-specific recombinases of the integrase family. Besides the mer operon and putative transposition genes, Tn5041 contains a 4 kb region that accommodates a number of apparently defective genes and mobile elements.

Distribution, diversity and evolution of the bacterial mercury resistance (mer) operon

Mercury and its compounds are distributed widely across the earth. Many of the chemical forms of mercury are toxic to all living organisms. However, bacteria have evolved mechanisms of resistance to several of these different chemical forms, and play a major role in the global cycling of mercury in the natural environment. Five mechanisms of resistance to mercury compounds have been identified, of which resistance to inorganic mercury (HgR) is the best understood, both in terms of the mechanisms of resistance to mercury and of resistance to heavy metals in general. Resistance to inorganic mercury is encoded by the genes of the mer operon, and can be located on transposons, plasmids and the bacterial chromosome. Such systems have a worldwide geographical distribution, and furthermore, are found across a wide range of both Gram-negative and Gram-positive bacteria from both natural and clinical environments. The presence of mer genes in bacteria from sediment cores suggest that mer is an ancient system. Analysis of DNA sequences from mer operons and genes has revealed genetic variation both in operon structure and between individual genes from different mer operons, whilst analysis of bacteria which are sensitive to inorganic mercury has identified a number of vestigial non-functional operons. It is hypothesised that mer, due to its ubiquity with respect to geographical location, environment and species range, is an ancient system, and that ancient bacteria carried genes conferring resistance to mercury in response to increased levels of mercury in natural environments, perhaps resulting from volcanic activity. Models for the evolution of both a basic mer operon and for the Tn21-related family of mer operons and transposons are suggested. The study of evolution in bacteria has recently become dominated by the generation of phylogenies based on 16S rRNA genes. However, it is important not to underestimate the roles of horizontal gene transfer and recombinational events in evolution. In this respect mer is a suitable system for evaluating phylogenetic methods which incorporate the effects of horizontal gene transfer. In addition, the mer operon provides a model system in the study of environmental microbiology which is useful both as an example of a genotype which is responsive to environmental pressures and as a generic tool for the development of new methodology for the analysis of bacterial communities in natural environments.

Characterization of the Streptomyces peucetius ATCC 29050 genes encoding doxorubicin polyketide synthase

The dps genes of Streptomyces peucetius, encoding daunorubicin (DNR)-doxorubicin (DXR) polyketide synthase (PKS), are largely within an 8.7-kb region of DNA that has been characterized by Southern analysis, and gene sequencing, mutagenesis and expression experiments. This region contains nine ORFs, many of whose predicted products are homologous to known PKS enzymes. Surprisingly, the gene encoding the DXR PKS acyl carrier protein is not in this region, but is located about 10 kb distant from the position it usually occupies in other gene clusters encoding type-II PKS. An in-frame deletion in the dpsB gene, encoding a putative subunit of the DXR PKS, resulted in loss of production of DXR and the known intermediates of its biosynthetic pathway, confirming that this gene and, by implication, the adjacent dps genes are required for DXR biosynthesis. This was verified by expression of the dps genes in the heterologous host, Streptomyces lividans, which resulted in the production of aklanonic acid, an early intermediate of DXR biosynthesis.

Conduction of pEC22, a plasmid coding for MR.EcoT22I, mediated by a resident Tn3-like transposon, Tn5396

pEC22 is a small plasmid that encodes the restriction-modification system MR.EcoT22I. Restriction and functional analysis of the plasmid identified the positions of genes encoding that system. The plasmid is able to be conducted by conjugal plasmids, a process mediated by a transposon contained within pEC22. This cryptic transposon, called Tn5396, was isolated from pEC22 and partially sequenced. The sequence of Tn5396 is for the most part typical of transposons of the Tn3 family and is most similar to that of Tn1000. The transposon differs from closely related transposons in that it lacks well-conserved sequences in the inverted-repeat region and has an unusually long terminal inverted repeat. Consideration of regions of internal sequence similarity in this and other transposons in the Tn3 family supports a theory of the mechanism by which the ends of Tn3-like transposons may maintain substantial identity between their inverted repeats over the course of evolutionary time.

Identification of the region that determines the specificity of binding of the transposases encoded by Tn3 and gamma delta to the terminal inverted repeat sequences

To analyze the region that determines the specificity of binding of the Tn3 transposase to the terminal inverted repeat sequences (IR), we first determined the nucleotide sequence of a Tn3-family transposon, gamma delta, which is supposed to encode a transposase similar to that of Tn3. gamma delta was 5981 bp in length and contained three coding frames: Two were the genes, tnpA and tnpR, encoding transposase (1002 amino acids) and resolvase/repressor (183 amino acids), respectively, and the third, named tnpX, encoding a protein (698 amino acids) of unknown function but containing two NTP-binding motifs. Utilizing the tnpA sequence, we then constructed a series of Tn3-gamma delta hybrid genes encoding chimeric proteins in the N-terminal segments of the transposases (amino acid position 1 to 242 of Tn3 or 1' to 243' of gamma delta), which has been previously shown to be responsible for specific binding of transposase to IR sequences in Tn3. Examination of their DNA-binding activities revealed that the subsegment of the N-terminus from amino acid position 1 to 109 determines the specificity of binding to the IR sequences. The third coding frame found in gamma delta, tnpX, is located downstream of tnpR and is expressed from the tnpR promoter in the absence of the tnpR gene product, resolvase/repressor, to produce a protein that inhibits the growth of the host cells. Possible roles of this protein are discussed.

Sequence around the centromere of Saccharomyces cerevisiae chromosome II: similarity of CEN2 to CEN4

We report the sequence of a 12 kilobase region spanning the centromere of Saccharomyces cerevisiae chromosome II. The sequence from the left arm includes genes for histones H2A and H2B. The sequence from the right arm includes a gene that probably encodes a novel trehalase, as well as the COQ1 gene (for an enzyme involved in coenzyme Q biosynthesis), and an open reading frame with significant similarity to bacterial genes of unknown function. The trehalase gene (YBR0106) on chromosome II is located beside the centromere and transcribed towards it. This is identical to the arrangement of the neutral trehalase gene (NTH1) beside the centromere of chromosome IV. The centromere regions of chromosomes II and IV may therefore have arisen through a duplication of the centromere region of an ancestral chromosome. The YBR0106 and NTH1 proteins are 77% identical in predicted amino acid sequence, but there is no pronounced sequence similarity between the two centromeres (CEN2 and CEN4) outside of the universally conserved CDE I and CDE III elements. The genes flanking the centromere and trehalase genes differ between the two chromosomes, so the similarity between chromosomes II and IV may be less extensive than that recently reported between chromosomes III and XIV.

The new class II transposon Tn163 is plasmid-borne in two unrelated Rhizobium leguminosarum biovar viciae strains

Tn163 is a transposable element identified in Rhizobium leguminosarum bv. viciae by its high insertion rate into positive selection vectors. The 4.6 kb element was found in only one further R. leguminosarum bv. viciae strain out of 70 strains investigated. Both unrelated R. leguminosarum bv. viciae strains contained one copy of the transposable element, which was localized in plasmids native to these strains. DNA sequence analysis revealed three large open reading frames (ORFs) and 38 bp terminal inverted repeats. ORF1 encodes a putative protein of 990 amino acids displaying strong homologies to transposases of class II transposons. ORF2, transcribed in the opposite direction, codes for a protein of 213 amino acids which is highly homologous to DNA invertases and resolvases of class II transposons. Homology of ORF1 and ORF2 and the genetic structure of the element indicate that Tn163 can be classified as a class II transposon. It is the first example of a native transposon in the genus Rhizobium. ORF3, which was found not to be involved in the transposition process, encodes a putative protein (256 amino acids) of unknown function. During transposition Tn163 produced direct repeats of 5 bp, which is typical for transposons of the Tn3 family. However, one out of the ten insertion sites sequenced showed a 6 bp duplication of the target DNA; all duplicated sequences were A/T rich. Insertion of Tn163 into the sacB gene revealed two hot spots. Chromosomes of different R. leguminosarum bv. viciae strains were found to be highly refractory to the insertion of Tn163.

Analysis of the transfer region of the Streptomyces plasmid SCP2

pIJ903, a bifunctional derivative of the 31.4 kb low-copy-number, conjugative Streptomyces plasmid SCP2*, was mutagenized in Streptomyces lividans using Tn4560. Mutant plasmids differing in their transfer frequencies, chromosome mobilization abilities, pock formation, and complementation properties were isolated. The mutations defined five transfer-related genes, traA, traB, traC, traD and spd, clustered in a region of 9 kb. The deduced sequences of the putative TraA and TraB proteins showed no overall similarity to known protein sequences, but the phenotype of traA mutant plasmids and sequence motifs in the putative TraA protein suggested that it might be a DNA helicase.

Transposon mutagenesis by Tn4560 and applications with avermectin-producing Streptomyces avermitilis

The Tn3-like Streptomyces transposon Tn4560 was used to mutagenize Streptomyces avermitilis, the producer of anthelmintic avermectins and the cell growth inhibitor oligomycin. Tn4560 transposed in this strain from a temperature-sensitive plasmid to the chromosome and from the chromosome to a plasmid with an apparent frequency of about 10(-4) to 10(-3) at both 30 and 39 degrees C. Auxotrophic and antibiotic nonproducing mutations were, however, obtained only with cultures that were kept at 37 or 39 degrees C. About 0.1% of the transposon inserts obtained at 39 degrees C caused auxotrophy or abolished antibiotic production. The sites of insertion into the S. avermitilis chromosome were mapped. Chromosomal DNA fragments containing Tn4560 insertions in antibiotic production genes were cloned onto a Streptomyces plasmid with temperature-sensitive replication and used to transport transposon mutations to other strains, using homologous recombination. This technique was used to construct an avermectin production strain that no longer makes the toxic oligomycin.

DNA binding domains in Tn3 transposase

Various segments of Tn3 transposase were fused individually to beta-galactosidase, and the resulting fusion proteins were examined for their DNA binding ability by a nitrocellulose filter binding assay. Analyses of a series of the fusion proteins revealed that the N-terminal segment of the transposase (amino acid positions 1-242; the transposase gene encodes 1004 residues in all) had specific DNA binding ability for the 38 bp terminal inverted repeat (IR) sequence, and the central segment (amino acid positions 243-632) had non-specific DNA binding ability. Further analyses of each of the two regions revealed that the N-terminal segment could be divided into at least two subsegments (amino acid positions 1-86 and 87-242), neither of which had specific DNA binding ability, but which both possessed non-specific DNA binding ability. The central segment included two subsegments (amino acid positions 243-289 and 439-505) with non-specific DNA binding ability. These results and other observations suggest that Tn3 transposase has several domains including those responsible for non-specific DNA binding, and a combination of two or more domains gives rise to specific DNA binding activity. The C-terminal segment of the transposase (amino acid positions 633-1004), which is very well conserved among transposases encoded by Tn3 family transposons, had no DNA binding ability. This segment may represent the main part of the catalytic domain responsible for the initiation step of transposition.

Tn4556 and luciferase: synergistic tools for visualizing transcription in Streptomyces

Progress in understanding genetic regulatory controls in the Actinomycetes has been rate limited by the properties of in vivo transcriptional probes. We have developed a set of plasmid- and transposon-based promoter-probe vectors that employ the Vibrio harveyi luciferase-encoding luxAB cassette as a reporter of transcription. The primary advantages of luciferase (Lux) over other reporter gene products are: (i) unsurpassed sensitivity; (ii) utility during stationary-phase gene expression; and (iii) the ability to localize promoter activity spatially within developing colonies. We have used these vectors to screen for Streptomyces coelicolor promoters that exhibit developmental phenotypes or that are induced by various environmental stimuli. The plasmid-based probes have proved invaluable for identifying cis- and trans-acting elements that are required for stationary-phase expression of the S. coelicolor sapA gene. A collection of novel bld and whi insertion mutants has been obtained by use of the Lux-encoding transposon, Tn5353.

Construction and application of plasmid- and transposon-based promoter-probe vectors for Streptomyces spp. that employ a Vibrio harveyi luciferase reporter cassette

Several versatile promoter-probe vectors have been constructed for Streptomyces strains which utilize the production of blue-green light as a measure of transcription activity. Three plasmid vectors (two high and one low copy number) and two transposons are described. The multicopy plasmids pRS1106 and pRS1108 contain a transcription terminator and multiple-cloning polylinker upstream of promoterless luciferase (lux) and neomycin resistance reporter genes. Plasmid pHI90 is similar in structure to the pRS vectors except that its single copy number is an advantage for regulation studies or situations in which overexpression is otherwise toxic to the cell. The two transposons carry a promoterless lux cassette cloned such that transposition into a target DNA and fusion to the target's transcription unit occur simultaneously. Tn5351 was created by inserting the luciferase genes near the right end of the viomycin resistance transposon Tn4563. Tn5353 carries the luciferase genes near the right end of a neomycin resistance transposon derived from Tn4556. The size of Tn5353 was minimized by deleting nonessential transposon sequences, making this element small enough to be cloned into phi C31 bacteriophages for efficient transposon delivery to target cells of Streptomyces strains. The two Tnlux transposons have been used to generate Streptomyces coelicolor morphological mutants and to monitor transcription from chromosomal promoters during development.

Tn4563 transposition in Streptomyces coelicolor and its application to isolation of new morphological mutants

The Tn3-like transposon Tn4556 (and its derivatives Tn4560 and Tn4563) has been used for insertion mapping of genetic loci cloned on plasmids, but it has been difficult to obtain chromosomal insertions, largely because of the lack of a strong selection against transposon donor molecules. In this communication, we report two efficient selection techniques for transposition and their use in the isolation of chromosomal insertion mutations. A number of independent Streptomyces coelicolor morphological mutants (bld and whi) were obtained. Two of the bld mutations were mapped to locations on the chromosome by SCP1-mediated conjugation; at least one mutation, bld-5m1, appears to define a novel locus involved in control of S. coelicolor morphogenesis and antibiotic production.

Transposition of Tn5096 and other IS493 derivatives in Streptomyces griseofuscus

Tn5096 was constructed by inserting an apramycin resistance gene, aac(3)IV, into IS493 from Streptomyces lividans. By using conventional and pulsed-field gel electrophoresis, Tn5096 and related transposons were shown to insert into many different locations in the Streptomyces griseofuscus chromosome and in two linear plasmids. On insertion into the target site CANTg, 3 bp appeared to be duplicated. Independent transpositions were obtained by delivery of the transposon from a temperature-sensitive plasmid. The frequency of auxotrophy among cultures containing transpositions was about 0.2%.

The Tn21 subgroup of bacterial transposable elements

The Tn3 family of transposable elements is probably the most successful group of mobile DNA elements in bacteria: there are many different but related members and they are widely distributed in gram-negative and gram-positive bacteria. The Tn21 subgroup of the Tn3 family contains closely related elements that provide most of the currently known variation in Tn3-like elements in gram-negative bacteria and that are largely responsible for the problem of multiple resistance to antibiotics in these organisms. This paper reviews the structure, the mechanism of transposition, the mode of acquisition of accessory genes, and the evolution of these elements.