General Information/IS History

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It is now over 40 years since the first IS were described. They were identified as short DNA segments found repeatedly associated with mutations in the gal operon and bacteriophage λ [1][2][3]. Shortly after, it was established that IS were normal residents of the Escherichia coli chromosome [4] sometimes present in multiple copies. They were shown to be involved in generating deletions [5] and in activating gene expression [6][7][6,7]. They were also identified as constituents of bacterial plasmids [8][9][10]. At about the same time, it was observed that antibiotic resistance genes could also be transferred or “transposed” from one plasmid to another [11][12][13] (Fig.1.2.1) and it was recognized that IS and “transposons” (a term originally coined by Hedges and Jacob [14]) were both members of a group of genetic entities: transposable or mobile genetic elements (TE or MGE).

Fig.1.2.1. The first Transposon discovered in 1974. This figure illustrates the independent movement (transposition) of the Ampicillin resistance transposon, transposon A (later renamed as Tn1), from its original plasmid RP4 to three different plasmids R64, JR66a and Sa. It also shows secondary transposition from Sa to R64 (bottom)

Transposons and IS were identified by electron microscopy of heteroduplexes between plasmids or phage with and without the insertion or by homoduplexes (Fig.1.2.2) and (Fig.1.2.4) [15][16]) This relationship between IS and transposons was reinforced by the observation that different DNA segments carrying different genes could be translocated by two flanking IS (compound transposons) [17][18][19] (Fig.1.2.3) and (Fig.1.2.4). In many compound transposons one of the IS is inactivated or has reduced activity due to mutation. This tends to increase the coherence of the transposon in comparison to the autonomous activity of the individual IS. For example, in Tn5, the inside end (IE) of the left IS50 carries a mutation which both creates a better promoter sequence to drive expression of the resistance genes and introduces a UAA nonsense codon at the 3’ end of the transposase gene [20][21].

Fig. 1.2.2. Electron microscopy showing Insertions with short stems. Part of a heteroduplex molecule formed between plasmids R100.1 and Rldrdl9 showing a single stranded insertion loop of the ampicillin resistance transposon Tn3 carried by plasmid Rldrd19 but not by R100.1. In this type of experiment, both plasmids are denatured into their single strand DNA form, mixed and renatured to form double stranded DNA where they are complementary and single strand regions where they do not share sequence homology. (Electron Microscopy by Edouard Boy de la Tour and Lucien Caro)
Fig. 1.2.3. Compound Transposons structure schema. Examples of Tn5, Tn10, Tn903, Tn602, and Tn9. The figure is not to scale. The TE is shown as a pink box; purple arrows, Tpase genes; red boxes, passenger genes; thin arrows, promoters and transcription direction; dark blue arrows, terminal inverted repeats; white asterisks, GATC Dam methylation sites which are present in some TE and control their level of activity; OE and IE, outside ends and inside ends of the IS with respect to the transposon. This is a generic cartoon showing the general arrangement of flanking IS in several different Tn. Tn5 (5818 bp) carries inverted copies of IS50 (1534 bp); Tn10 (9147 bp) carries inverted copies of IS10 (1329 bp); Tn903 (3094 bp) carries inverted copies of IS903 (1057 bp, Tpase 307 aa); Tn602 (3064 bp) carries direct flanking copies of IS903. Tpase, Tpase; kan, tet, cam: resistance genes for kanamycin, tetracycline and chloramphenicol respectively; Tn9 (2638 bp) carries direct flanking copies of IS1 (768bp).
Fig. 1.2.4 Compound Tn5.The left of the figure shows the structure of Tn5 and the way in which the flanking inverted IS50 insertion sequences would form a double strand stem on denaturation and renaturation. The righthand panel Structure of plasmid pOX38 :: Tn5 as revealed by electron microscopy. Plasmid DNA was denatured and renaturedto form a snap-back structure that locates the Tn5 insertion. (Electron Microscopy by Edouard Boy de la Tour and Lucien Caro)

In the case of Tn10, the left IS10 differs from the functional right IS10 at a number of nucleotide positions in both in its regulatory region and in the transposase [22]. On the other hand, not all composite transposons possess an inactive copy of the flanking IS. In Tn9, flanked by two directly repeated copies of IS1, both IS are active [23]. It was also realized [24] that IS might be related to the controlling elements discovered by genetic analysis of maize several decades previously [25][26][27]. However, in spite of the observation that IS can be present in some bacterial species in extremely high copy numbers [28][29], little at the time prepared us for the subsequent recognition of the preponderant role they play in shaping genomes, of their extreme diversity and their widespread distribution (see reference [30](Fig.1.2.5).

Fig. 1.2.5 Transposases: the most abundant and ubiquitous genes in nature.A "word cloud" (http://www.wordle.net) representing the 100 most abundant functional roles in metagenomes. The font size of each functional role is proportional to its abundance (Taken from Aziz et al 2010)

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