The Tn
            <i>3</i>
            -family of Replicative Transposons

Nicolas, Emilien; Lambin, Michaël; Dandoy, Damien; Galloy, Christine; Nguyen, Nathan; Oger, Cédric A.; Hallet, Bernard

doi:10.1128/microbiolspec.mdna3-0060-2014

Cited by 113 publications

(71 citation statements)

References 247 publications

(347 reference statements)

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“…Numbers above the lines of each clade indicate the maximum likelihood bootstrap values. The subgroups adhere closely to those defined by Nicolas et al (1) with some minor variations resulting from the significantly larger Tn sample. The majority of members carry tnpR, serine resolvases (purple circles).…”

Section: Resultssupporting

confidence: 84%

“…3. Note that, with minor exceptions, the entire Tn3 library conforms closely to the previously defined Tn3 family subgroups (1). The majority of Tn3 family members encode a TnpR resolvase (Fig.…”

Section: Resultssupporting

confidence: 67%

“…A similar situation is found in the unrelated Tn4651 subgroup member TnPosp1_p, which has the configuration TϾ AϾ tnpRϾ tnpAϾ. We extracted Tn3 family members from the ISfinder database which served to generate the subgroups defined in the work of Nicolas et al (1). Many others were drawn from the literature and have been given official names (Tn followed by digits, e.g., Tn1234; https://transposon.lstmed.ac.uk/tn-registry), while others were identified using Tn3_finder software (TnCentral, https://tncentral .proteininformationresource.org/TnFinder.html) and given temporary names.…”

Section: Resultsmentioning

confidence: 75%

“…Identification of TA gene pairs in Tn3 family members. As a first step, we undertook a detailed annotation of available Tn3 family members in the ISfinder database (23) and also those listed in the work of Nicolas et al (1). We also searched NCBI for previously annotated Tn3 family members (March 2018) and made use of an in-house script which searches for tnpA, tnpR, and TA genes located in proximity to each other (Tn3finder, https://tncentral.proteininformationresource.org/TnFinder.html; Tn3ϩTA_finder, https://github.com/danillo-alvarenga/tn3-ta_finder) to search complete bacterial genomes in the RefSeq database at NCBI.…”

Section: Resultsmentioning

confidence: 99%

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Toxin-Antitoxin Gene Pairs Found in Tn 3 Family Transposons Appear To Be an Integral Part of the Transposition Module

Lima‐Mendez

Alvarenga

Ross

et al. 2020

mBio

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Much of the diversity of prokaryotic genomes is contributed by the tightly controlled recombination activity of transposons (Tns). The Tn3 family is arguably one of the most widespread transposon families. Members carry a large range of passenger genes incorporated into their structures. Family members undergo replicative transposition using a DDE transposase to generate a cointegrate structure which is then resolved by site-specific recombination between specific DNA sequences (res) on each of the two Tn copies in the cointegrate. These sites also carry promoters controlling expression of the recombinase and transposase. We report here that a number of Tn3 members encode a type II toxin-antitoxin (TA) system, typically composed of a stable toxin and a labile antitoxin that binds the toxin and inhibits its lethal activity. This system serves to improve plasmid maintenance in a bacterial population and, until recently, was believed to be associated with bacterial persistence. At least six different TA gene pairs are associated with various Tn3 members. Our data suggest that several independent acquisition events have occurred. In contrast to most Tn3 family passenger genes, which are generally located away from the transposition module, the TA gene pairs abut the res site upstream of the resolvase genes. Although their role when part of Tn3 family transposons is unclear, this finding suggests a potential role for the embedded TA in stabilizing the associated transposon with the possibility that TA expression is coupled to expression of transposase and resolvase during the transposition process itself. IMPORTANCE Transposable elements (TEs) are important in genetic diversification due to their recombination properties and their ability to promote horizontal gene transfer. Over the last decades, much effort has been made to understand TE transposition mechanisms and their impact on prokaryotic genomes. For example, the Tn3 family is ubiquitous in bacteria, molding their host genomes by the paste-and-copy mechanism. In addition to the transposition module, Tn3 members often carry additional passenger genes (e.g., conferring antibiotic or heavy metal resistance and virulence), and three were previously known to carry a toxin-antitoxin (TA) system often associated with plasmid maintenance; however, the role of TA systems within the Tn3 family is unknown. The genetic context of TA systems in Tn3 members suggests that they may play a regulatory role in ensuring stable invasion of these Tns during transposition.

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Section: Resultssupporting

confidence: 84%

Section: Resultssupporting

confidence: 67%

Section: Resultsmentioning

confidence: 75%

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Toxin-Antitoxin Gene Pairs Found in Tn 3 Family Transposons Appear To Be an Integral Part of the Transposition Module

Lima‐Mendez

Alvarenga

Ross

et al. 2020

mBio

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“…The absence of these sequences upstream of rmtB suggests the nonmobilization of rmtB by Tn2. For this mobilization to occur, the IRL upstream bla TEM-1b gene would have been inactivated by a new passenger gene (in this case, rmtB) and a more distant "surrogate" IR sequence recruited (13). This kind of mobilization had occurred with Tn4401, a derivate transposon of Tn3 that carries bla KPC-2 (14).…”

mentioning

confidence: 99%

Frequent Tn 2 Misannotation in the Genetic Background of rmtB

Martins

Gales

2017

Antimicrob Agents Chemother

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Prokaryotic DNA Transposons: Classes and Mechanism

Chandler

2017

Encyclopedia of Life Sciences

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Transposition plays a major role in genome plasticity causing chromosome rearrangements, deoxyribonucleic acid (DNA) insertion and deletion mutations and is key in gene sequestration and transmission by horizontal gene transfer. The processes play important roles in genome evolution and function. Transposable elements (TR) can be classified according to the chemistry of the transposition process itself: the nature of the catalytic mechanisms involved in the DNA cleavages necessary to liberate a copy of the transposon from its donor DNA and DNA strand transfer events (involved in insertion into a target DNA). This chapter is centred on prokaryotic TE, which use DNA intermediates for their movement. DNA transposable elements are extremely diverse, but, with a few exceptions, the mechanisms they use in their movement are common to both prokaryotic and eukaryotic TE. There are only a limited number of enzyme types that carry out DNA transposition. They are DDE (DED), Y, S, Y1 (HUH), Y2 (HUH) transposases, names of which are based on the active‐site residues involved in catalysis. More recently, an additional class, the casposons, has been identified in archaea and bacteria, which use a different type of sequence‐specific endonuclease. Transposition requires assembly of precise protein DNA complexes called transpososomes. Key Concepts Transposons are found in all living organisms. Transposons are diverse in organisation. Transposons use a limited number of enzyme types (transposases) for their movement. Transposases catalyse DNA cleavage in the donor DNA molecule and DNA strand transfer into the target DNA. Transposition requires an assembly of a precise protein–DNA complex, the transpososome. Transpososomes are assembled through a strictly ordered series of events in which the DNA–protein interactions position the DNA for catalysis.

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The Tn 3 -family of Replicative Transposons

Cited by 113 publications

References 247 publications

Toxin-Antitoxin Gene Pairs Found in Tn 3 Family Transposons Appear To Be an Integral Part of the Transposition Module

Toxin-Antitoxin Gene Pairs Found in Tn 3 Family Transposons Appear To Be an Integral Part of the Transposition Module

Frequent Tn 2 Misannotation in the Genetic Background of rmtB

Prokaryotic DNA Transposons: Classes and Mechanism

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