Difference between revisions of "General Information/IS and Gene Expression"

Revision as of 17:07, 22 June 2020

Another important aspect of IS impact on their bacterial hosts is their ability to modulate gene expression. In addition to acting as vectors for gene transmission from one replicon to another in the form composite transposons (two IS flanking any gene; Fig.1.2.3) and tIS (Fig.1.13.1) and their ability to interrupt genes, it has been known for some time^[1]^[2] that IS can also activate gene expression. This capacity has recently received much attention due to the increase in resistance to various antibacterials^[3]^[4]^[5], a worrying public health threat^[6]^[7].

They can accomplish this in two ways: either by providing internal promoters whose transcripts escape into neighboring DNA^[2]^[8]^[9]^[10] or by hybrid promoter formation. Many IS carry -35 promoter components oriented towards the flanking DNA (Fig.1.24.1). In a number of cases this plays an important part in their transposition since a significant number of IS transpose using an excised transposon circle (Fig.1.24.1) with abutted left and right ends. For these IS, the other end carries a -10 element oriented inwards towards the Tpase gene. Together with the -35, this generates a strong promoter on formation of the circle junction to drive Tpase expression required for catalysis of integration (Fig.1.24.2) ^[11]^[12]^[13]^[14]. Thus if integration occurs next to a resident -10 sequence, the IS -35 sequence can contribute to a hybrid promoter to drive expression of neighboring genes [see ^[15]]. At present this phenomenon had been reported to occur with over 30 different IS in more than 17 bacterial species^[16]^[17] (Table IS and Gene Expression below). Indeed, specific vector plasmids have been designed to identify activating insertions (e.g. ^[18]).

IS activity can affect efflux mechanisms resulting in increased resistance: IS1 or IS10 insertion can up-regulate the AcrAB-TolC pump in Salmonella enterica^[19]; IS1 or IS2 insertion upstream of AcrEF^[20]^[21] and IS186 insertional inactivation of the AcrAB repressor, AcrR, in Escherichia coli ^[20], all lead to increased resistance to fluoroquinolones. Insertional inactivation of specific porins can also play a significant role^[22].

Fig. 1.24.1. Copy out paste in (DDE).Left column. Illustrates the copy out paste in transposition mechanism. The transposon is represented as a yellow line. Flanking sequences in the donor molecule are blue. Flanking sequences in the target molecule are green. Red circles indicate 3′OH moieties generated by Tpase-catalyzed hydrolysis at the transposon end(s). Red boxes indicate target DNA flanks that are duplicated on insertion. Top to bottom: Tpase catalyzed cleavage at the 3′ transposon ends using H2O as the nucleophile. Liberated 3′OH attack the opposite end to create a bridged molecule which then undergoes replication (dotted line) to generate a circular transpon copy and regenerate the donor molecule. The circle intermediate undergoes cleavage to generate two 3'OH ends which attack the target DNA in a staggered way resulting in integration. Repair at each end then generates the direct target repeat characteristic of many transposons. Right column. Formation of hybrid promoters by copy out -paste in transposition. The left and right terminal inverted repeats of the IS, IRL and IRR, are shown as a square and pointed box respectively. The component –10 and –35 promoter elements of p_junc within these ends are also shown together with the weak p_IRL promoter and the direction of transcription of the transposase. In a first step, single-strand cleavage and transfer from one IR to the other is catalyzed by OrfAB produced from the weak p_IRL promoter. This is indicated at the top of the figure by the curved arrow. In this case, the right end (IRR) is shown attacking the left end (IRL). The resulting figure-eight form is drawn below and shows the free 3’OH group generated on the flanking donor DNA sequence. In a second step, second-strand circularization occurs by an as yet undetermined mechanism involving host functions but independently of transposon proteins [Turlan et al., 2000 ]. The resulting IRR-IRL junction carries suitably placed -35 and –10 hexamers, separated by a canonical 17 bp spacer and form a strong p_junc (bold arrow) promoter able to promote high levels of production of IS911 proteins. Integration of the circle results in disassembly of the promoter restoring low levels of expression from p_IRL. Insertion upstream of a resident -10 promoter element can bring the IR-associated -35 element at the correct distance to form a promoter and activate a downstream gene.

Fig 1.24.2. Promoter Activities of junction fragments from different IS circles.Results of measurements of activities of 9 IS circle junctions when placed upstream of a beta-galactosidase gene.

IS and Gene Expression

IS family	IS name	Mechanism	Gene(s) affected	Organism	Reference	Clinical/Experimental
Table. IS and gene expression.
IS1	IS1	Cointegrate	Em^R	Escherichia coli	^[23]	C?
		Copy-paste circles	bla_TEM-1	Escherichia coli	^[15]	E
		—	acrEF pump	Salmonella enterica	^[19]	E
IS3	IS2	Copy-paste circles	gal	Escherichia coli	^[24]^[25]	E
			gal		^[23]^[2]	E
			argE		^[26]^[20]	E
			Em^R			C?
			bla_ampC			E
			acrEF pump			E
	IS3	Copy-paste circles	argE	Escherichia coli	^[2]	E
			argE		^[8]	E
			citT		^[27]	E
	IS981	Copy-paste circles	ldhB	Lactococcus lactis	^[28]	E
	IS6110	Copy-paste circles	Rv2280 and PE-PGRS gene, Rv1468c	Mycobacterium tuberculosis	^[29]	E
	ISKpn8	Copy-paste circles	blaKCP-2	Escherichia coli, Citrobacter freundii, Enterobacter cloacae, Enterobacter aerogenes, and Klebsiella oxytoca	^[30]	C
IS4	IS10	Cut-paste (hairpin)	his	Salmonella typhimurium	^[31]	E
		Cut-paste	—	Escherichia coli	^[32]	E
		Cut-paste	acrEF pump	Salmonella enterica	^[19]	E
	IS50	Cut-paste (hairpin)	aph3’II	Escherichia coli	^[33]	E
	IS1999	—	bla_VEB-1	Pseudomonas aeruginosa	^[4]	C
	IS1999	—	bla_VEB-1/bla_OXA-48	Escherichia coli	^[3]	C
	ISPa12	—	blaPER-1	Salmonella enterica, Pseudomonas aeruginosa, Providencia stuartii, Acinetobacter baumannii	^[34]	C
	ISAba1	—	bla_ampC	Acinetobacter baumannii	^[35]^[36]^[37]	C
	ISAba1	—	bla_OXA-51/bla_OXA-23	Acinetobacter baumannii	^[38]	C
IS5	IS5	—	EmR	Escherichia coli	^[23]	C?
	ISFtu2		general	Francisella tularensis	^[39]	Natural isolate
	ISVa1		(iron uptake)	Vibrio anguilarum	^[40]	Natural isolate
	IS1168 (IS1186)		nimA, nimB	Bacteroides sp.	^[41]	C
	IS1186		cfiA	Bacteroides fragilis	^[42]^[43]	C
	IS402		bla	Pseudomonas cepacia	^[44]	E
IS6	IS257	Cointegrate	dfrA	Staphylococcus aureus	^[45]	C
	IS257	Cointegrate	tet	Staphylococcus aureus	^[46]
	IS1008	—	bla_OXA-58	Acinetobacter baumannii	^[47]
	IS26	—	aphA7, bla_S2A	Klebsiella pneumoniae	^[48]
	IS26	—	bla_SHV-2a	Pseudomonas aeruginosa	^[49]
	IS140	—	aac(3)-III and -IV	—	^[50]
IS21	ISBf1	Copy-paste circle	cepA	Bacteroides fragilis	^[51]	C
IS21	ISKpn7	Copy-paste circle	blaKPC	Klebsiellea pneumonia	^[52]	C
IS30	IS30	Copy-paste circle	galK	Escherichia coli	^[53]	E
	IS18		aac(6’)-Ij	Acinetobacter sp.	^[54]	C
	IS18		blaOXA257	Acinetobacter sp.	^[55]	C
	IS4351		ermF	Bacteroides fragilis	^[56]	C
	IS4351		cfiA	Bacteroides fragilis	^[5]	C
	IS1086		cnrCBAT (Zn^R)	Cupriavidus metallidurans		E
IS256	IS256	Copy-paste circles	mecA	Staphylococcus sciuri	^[57]^[58]	—
	IS256		llm	Staphylococcus aureus	^[57]^[58]	—
	IS1490		—	Burkholderia cepacia	^[59]	—
	IS406		—	Burkholderia cepacia	^[44]	E
IS481	IS481	Copy-paste circles	katA	Bordetella pertussis	^[60]	—
IS481	ISRme5	Copy-paste circles	cnrCBAT (Zn R)	Cupriavidus metallidurans	^[61]	E
IS630	ISFtu1	Tc-like	general	Francisella tularensis	^[39]	Natural isolate
IS982	IS1187	—	cfiA	Bacteroides fragilis	^[42]	E+C
	IS1187		cfiA	Bacteroides fragilis	^[5]^[62]^[63]	C
	IS982		citQRP	Lactococcus lactis	^[64]	—
IS1380	ISBf12	—	cfiA	Bacteroides fragilis	^[5]	C
	IS612				^[63]
	IS613				^[63]
	IS614				^[5]^[63]^[65]
	IS1188				^[62]
	IS942				^[62]
	ISEcp1		bla_CTX-M-15	Enterobacteriaceae	^[66]
			bla_CTX-M-17	Klebsiella pneumoniae	^[67]
			bla_CTX-M-19	Klebsiella pneumoniae	^[34]
			bla_CTX-M	Kluyvera ascorbata	^[68]
			rmtC	Escherichia coli	^[69]
	IS1187		cfiA	Bacteroides fragilis	^[62]
ISL3	ISSg1	Copy-paste circles	sspB (surface antigen)	Streptococcus gordonii	^[70]	—
ISL3	IS1411	Copy-paste circles	pheBA	Pseudomonas putida	^[71]	—
ISAs1	IS1548	—	lmb (lamelin binding)	Streptococcus agalactiae	^[72]	—
ISAs1	nd	—	—	Acinetobacter baumannii	^[35]	C
ISNYC	IS403	—	bla	Burkholderia cepacia	^[44]	E
	IS404
	IS405

Bibliography

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[1] <pubmed>1101028</pubmed>

[:0-2] 2.0 ^2.1 ^2.2 ^2.3 </nowiki>

[:1-3] 3.0 ^3.1 </nowiki>

[:2-4] 4.0 ^4.1 </nowiki>

[:3-5] 5.0 ^5.1 ^5.2 ^5.3 ^5.4 Sóki J, Eitel Z, Urbán E, Nagy E, ESCMID Study Group on Anaerobic Infections . Molecular analysis of the carbapenem and metronidazole resistance mechanisms of Bacteroides strains reported in a Europe-wide antibiotic resistance survey. - Int J Antimicrob Agents: 2013 Feb, 41(2);122-5 [PubMed:23158541] [DOI] </nowiki>

[6] <pubmed>23887414</pubmed>

[7] <pubmed>23887415</pubmed>

[:4-8] 8.0 ^8.1 </nowiki>

[9] <pubmed>6260746</pubmed>

[10] <pubmed>6311437</pubmed>

[11] <pubmed>26350305</pubmed>

[12] <pubmed>9214651</pubmed>

[13] <pubmed>10438765</pubmed>

[14] <pubmed>11598022</pubmed>

[:5-15] 15.0 ^15.1 </nowiki>

[16] <pubmed>17223624</pubmed>

[17] <pubmed>24499397</pubmed>

[18] <pubmed>8863735</pubmed>

[:6-19] 19.0 ^19.1 ^19.2 </nowiki>

[:7-20] 20.0 ^20.1 ^20.2 Jellen-Ritter AS, Kern WV . Enhanced expression of the multidrug efflux pumps AcrAB and AcrEF associated with insertion element transposition in Escherichia coli mutants Selected with a fluoroquinolone. - Antimicrob Agents Chemother: 2001 May, 45(5);1467-72 [PubMed:11302812] [DOI] </nowiki>

[21] <pubmed>11274125</pubmed>

[22] <pubmed>15212803</pubmed>

[:8-23] 23.0 ^23.1 ^23.2 </nowiki>

[24] <pubmed>4610339</pubmed>

[25] <pubmed>339095</pubmed>

[26] <pubmed>6187472</pubmed>

[27] <pubmed>22992527</pubmed>

[28] <pubmed>12867459</pubmed>

[29] <pubmed>15130120</pubmed>

[30] <pubmed>24433026</pubmed>

[31] <pubmed>6289329</pubmed>

[32] <pubmed>6311437</pubmed>

[33] <pubmed>6260374</pubmed>

[:9-34] 34.0 ^34.1 </nowiki>

[:10-35] 35.0 ^35.1 </nowiki>

[36] <pubmed>14742218</pubmed>

[37] <pubmed>16441449</pubmed>

[38] <pubmed>16630258</pubmed>

[:11-39] 39.0 ^39.1 </nowiki>

[40] <pubmed>7568465</pubmed>

[41] <pubmed>8067736</pubmed>

[:12-42] 42.0 ^42.1 </nowiki>

[43] <pubmed>7545155</pubmed>

[:13-44] 44.0 ^44.1 ^44.2 </nowiki>

[45] <pubmed>7840551</pubmed>

[46] <pubmed>10852863</pubmed>

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[48] <pubmed>2160941</pubmed>

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[59] <pubmed>9098071</pubmed>

[60] <pubmed>7830550</pubmed>

[61] <pubmed>27047473</pubmed>

[:14-62] 62.0 ^62.1 ^62.2 ^62.3 </nowiki>

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[64] <pubmed>8602160</pubmed>

[65] <pubmed>19744834</pubmed>

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[68] <pubmed>16569841</pubmed>

[69] <pubmed>16940134</pubmed>

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@@ Line 1: / Line 1: @@
-'''<big>A</big>'''nother important aspect of IS impact on their bacterial hosts is their ability to modulate gene expression. In addition to acting as vectors for gene transmission from one replicon to another in the form composite transposons (two IS flanking any gene; [[:Image:1.2.3.png|Fig.1.2.3]]) and tIS [[:Image:1.13.1.png|(Fig.1.13.1)]] and their ability to interrupt genes, it has been known for some time<ref><nowiki><pubmed>1101028</pubmed></nowiki></ref><ref><nowiki><pubmed>6271458</pubmed></nowiki></ref> that IS can also activate gene expression. This capacity has recently received much attention due to the increase in resistance to various antibacterials<ref><nowiki><pubmed>16952941</pubmed></nowiki></ref><ref><nowiki><pubmed>12923109</pubmed></nowiki></ref><ref><nowiki><pubmed>23158541</pubmed></nowiki></ref>, a worrying public health threat<ref><nowiki><pubmed>23887414</pubmed></nowiki></ref><ref><nowiki><pubmed>23887415</pubmed></nowiki></ref>.
+'''<big>A</big>'''nother important aspect of IS impact on their bacterial hosts is their ability to modulate gene expression. In addition to acting as vectors for gene transmission from one replicon to another in the form composite transposons (two IS flanking any gene; [[:Image:1.2.3.png|Fig.1.2.3]]) and tIS [[:Image:1.13.1.png|(Fig.1.13.1)]] and their ability to interrupt genes, it has been known for some time<ref><nowiki><pubmed>1101028</pubmed></nowiki></ref><ref name=":0"><pubmed>6271458</pubmed></nowiki></ref> that IS can also activate gene expression. This capacity has recently received much attention due to the increase in resistance to various antibacterials<ref name=":1"><pubmed>16952941</pubmed></nowiki></ref><ref name=":2"><pubmed>12923109</pubmed></nowiki></ref><ref name=":3"><pubmed>23158541</pubmed></nowiki></ref>, a worrying public health threat<ref><nowiki><pubmed>23887414</pubmed></nowiki></ref><ref><nowiki><pubmed>23887415</pubmed></nowiki></ref>.
-They can accomplish this in two ways: either by providing internal promoters whose transcripts escape into neighboring DNA<ref><nowiki><pubmed>6271458</pubmed></nowiki></ref><ref><nowiki><pubmed>6292860</pubmed></nowiki></ref><ref><nowiki><pubmed>6260746</pubmed></nowiki></ref><ref><nowiki><pubmed>6311437</pubmed></nowiki></ref> or by hybrid promoter formation. Many IS carry -35 promoter components oriented towards the flanking DNA [[:Image:1.24.1.png|(Fig.1.24.1)]]. In a number of cases this plays an important part in their transposition since a significant number of IS transpose using an excised transposon circle [[:Image:1.24.1.png|(Fig.1.24.1)]] with abutted left and right ends. For these IS, the other end carries a -10 element oriented inwards towards the Tpase gene. Together with the -35, this generates a strong promoter on formation of the circle junction to drive Tpase expression required for catalysis of integration [[:Image:1.24.2.png|(Fig.1.24.2)]] <ref><nowiki><pubmed>26350305</pubmed></nowiki></ref><ref><nowiki><pubmed>9214651</pubmed></nowiki></ref><ref><nowiki><pubmed>10438765</pubmed></nowiki></ref><ref><nowiki><pubmed>11598022</pubmed></nowiki></ref>. Thus if integration occurs next to a resident -10 sequence, the IS -35 sequence can contribute to a hybrid promoter to drive expression of neighboring genes [see <ref><nowiki><pubmed>3029382</pubmed></nowiki></ref>]. At present this phenomenon had been reported to occur with over 30 different IS in more than 17 bacterial species<ref><nowiki><pubmed>17223624</pubmed></nowiki></ref><ref><nowiki><pubmed>24499397</pubmed></nowiki></ref> ([[General Information/IS and Gene Expression#IS and Gene Expression|Table IS and Gene Expression below]]). Indeed, specific vector plasmids have been designed to identify activating insertions (e.g. <ref><nowiki><pubmed>8863735</pubmed></nowiki></ref>).
+They can accomplish this in two ways: either by providing internal promoters whose transcripts escape into neighboring DNA<ref name=":0" /><ref name=":4"><pubmed>6292860</pubmed></nowiki></ref><ref><nowiki><pubmed>6260746</pubmed></nowiki></ref><ref><nowiki><pubmed>6311437</pubmed></nowiki></ref> or by hybrid promoter formation. Many IS carry -35 promoter components oriented towards the flanking DNA [[:Image:1.24.1.png|(Fig.1.24.1)]]. In a number of cases this plays an important part in their transposition since a significant number of IS transpose using an excised transposon circle [[:Image:1.24.1.png|(Fig.1.24.1)]] with abutted left and right ends. For these IS, the other end carries a -10 element oriented inwards towards the Tpase gene. Together with the -35, this generates a strong promoter on formation of the circle junction to drive Tpase expression required for catalysis of integration [[:Image:1.24.2.png|(Fig.1.24.2)]] <ref><nowiki><pubmed>26350305</pubmed></nowiki></ref><ref><nowiki><pubmed>9214651</pubmed></nowiki></ref><ref><nowiki><pubmed>10438765</pubmed></nowiki></ref><ref><nowiki><pubmed>11598022</pubmed></nowiki></ref>. Thus if integration occurs next to a resident -10 sequence, the IS -35 sequence can contribute to a hybrid promoter to drive expression of neighboring genes [see <ref name=":5"><pubmed>3029382</pubmed></nowiki></ref>]. At present this phenomenon had been reported to occur with over 30 different IS in more than 17 bacterial species<ref><nowiki><pubmed>17223624</pubmed></nowiki></ref><ref><nowiki><pubmed>24499397</pubmed></nowiki></ref> ([[General Information/IS and Gene Expression#IS and Gene Expression|Table IS and Gene Expression below]]). Indeed, specific vector plasmids have been designed to identify activating insertions (e.g. <ref><nowiki><pubmed>8863735</pubmed></nowiki></ref>).
-IS activity can affect efflux mechanisms resulting in increased resistance: IS''1'' or IS''10'' insertion can up-regulate the [[wikipedia:Efflux_(microbiology)|AcrAB-TolC]] pump in ''[[wikipedia:Salmonella_enterica|Salmonella enterica]]''<ref><nowiki><pubmed>15616308</pubmed></nowiki></ref>; IS''1'' or IS''2'' insertion upstream of AcrEF<ref><nowiki><pubmed>11302812</pubmed></nowiki></ref><ref><nowiki><pubmed>11274125</pubmed></nowiki></ref> and IS''186'' insertional inactivation of the AcrAB repressor, AcrR, in ''[[wikipedia:Escherichia_coli|Escherichia coli]]''<ref><nowiki><pubmed>11302812</pubmed></nowiki></ref>, all lead to increased resistance to [[wikipedia:Quinolone_antibiotic|fluoroquinolones]]. Insertional inactivation of specific [[wikipedia:Porin_(protein)|porins]] can also play a significant role<ref><nowiki><pubmed>15212803</pubmed></nowiki></ref>.<center>
+IS activity can affect efflux mechanisms resulting in increased resistance: IS''1'' or IS''10'' insertion can up-regulate the [[wikipedia:Efflux_(microbiology)|AcrAB-TolC]] pump in ''[[wikipedia:Salmonella_enterica|Salmonella enterica]]''<ref name=":6"><pubmed>15616308</pubmed></nowiki></ref>; IS''1'' or IS''2'' insertion upstream of AcrEF<ref name=":7"><pubmed>11302812</pubmed></nowiki></ref><ref><nowiki><pubmed>11274125</pubmed></nowiki></ref> and IS''186'' insertional inactivation of the AcrAB repressor, AcrR, in ''[[wikipedia:Escherichia_coli|Escherichia coli]] <ref name=":7" />'', all lead to increased resistance to [[wikipedia:Quinolone_antibiotic|fluoroquinolones]]. Insertional inactivation of specific [[wikipedia:Porin_(protein)|porins]] can also play a significant role<ref><nowiki><pubmed>15212803</pubmed></nowiki></ref>.<center>
 {|
 |
@@ Line 19: / Line 19: @@
 ! scope="col" |IS family||IS name||Mechanism||Gene(s) affected||Organism||Reference||Clinical/Experimental
 |-
-| rowspan="3" |IS<i>1</i>|| rowspan="3" |IS<i>1</i>||Cointegrate||<i>Em<sup>R</sup></i>|| rowspan="2" |<i>Escherichia coli</i>||<ref><nowiki><pubmed>6283551</pubmed></nowiki></ref>||C?
+| rowspan="3" |IS<i>1</i>|| rowspan="3" |IS<i>1</i>||Cointegrate||<i>Em<sup>R</sup></i>|| rowspan="2" |<i>Escherichia coli</i>||<ref name=":8"><pubmed>6283551</pubmed></nowiki></ref>||C?
 |-
-|Copy-paste circles||<i>bla<sub>TEM-1</sub></i>||<ref><nowiki><pubmed>3029382</pubmed></nowiki></ref>||E
+|Copy-paste circles||<i>bla<sub>TEM-1</sub></i>||<ref name=":5" />||E
 |-
-|—||<i>acrEF</i> pump||<i>Salmonella enterica</i>||<ref><nowiki><pubmed>15616308</pubmed></nowiki></ref>||E
+|—||<i>acrEF</i> pump||<i>Salmonella enterica</i>||<ref name=":6" />||E
 |-
 | rowspan="12" |IS<i>3</i>|| rowspan="6" |IS<i>2</i>|| rowspan="6" |Copy-paste circles||<i>gal</i>|| rowspan="6" |<i>Escherichia coli</i>||<ref><nowiki><pubmed>4610339</pubmed></nowiki></ref><ref><nowiki><pubmed>339095</pubmed></nowiki></ref>||E
 |-
-|<i>gal</i>|||<ref><nowiki><pubmed>6283551</pubmed></nowiki></ref><ref><nowiki><pubmed>6271458</pubmed></nowiki></ref>||E
+|<i>gal</i>|||<ref name=":8" /><ref name=":0" />||E
 |-
-|<i>argE</i>|| rowspan="4" |<ref><nowiki><pubmed>6187472</pubmed></nowiki></ref><ref><nowiki><pubmed>11302812</pubmed></nowiki></ref>||E
+|<i>argE</i>|| rowspan="4" |<ref><nowiki><pubmed>6187472</pubmed></nowiki></ref><ref name=":7" />||E
 |-
 |<i>Em<sup>R</sup></i>||C?
@@ Line 37: / Line 37: @@
 |<i>acrEF</i> pump||E
 |-
-| rowspan="3" |IS<i>3</i>|| rowspan="3" |Copy-paste circles||<i>argE</i>|| rowspan="3" |<i>Escherichia coli</i>||<ref><nowiki><pubmed>6271458</pubmed></nowiki></ref>||E
+| rowspan="3" |IS<i>3</i>|| rowspan="3" |Copy-paste circles||<i>argE</i>|| rowspan="3" |<i>Escherichia coli</i>||<ref name=":0" />||E
 |-
-|<i>argE</i>||<ref><nowiki><pubmed>6292860</pubmed></nowiki></ref>||E
+|<i>argE</i>||<ref name=":4" />||E
 |-
 |<i>citT</i>||<ref><nowiki><pubmed>22992527</pubmed></nowiki></ref>||E
@@ Line 53: / Line 53: @@
 |Cut-paste||—||<i>Escherichia coli</i>||<ref><nowiki><pubmed>6311437</pubmed></nowiki></ref>||E
 |-
-|Cut-paste||<i>acrEF</i> pump||<i>Salmonella enterica</i>||<ref><nowiki><pubmed>15616308</pubmed></nowiki></ref>||E
+|Cut-paste||<i>acrEF</i> pump||<i>Salmonella enterica</i>||<ref name=":6" />||E
 |-
 |IS<i>50</i>||Cut-paste (hairpin)||<i>aph3’II</i>||<i>Escherichia coli</i>||<ref><nowiki><pubmed>6260374</pubmed></nowiki></ref>||E
 |-
-| rowspan="2" |IS<i>1999</i>|| rowspan="2" |—||<i>bla<sub>VEB-1</sub></i>||<i>Pseudomonas aeruginosa</i>||<ref><nowiki><pubmed>12923109</pubmed></nowiki></ref>||C
+| rowspan="2" |IS<i>1999</i>|| rowspan="2" |—||<i>bla<sub>VEB-1</sub></i>||<i>Pseudomonas aeruginosa</i>||<ref name=":2" />||C
 |-
-|<i>bla<sub>VEB-1</sub></i>/<i>bla<sub>OXA-48</sub></i>||<i>Escherichia coli</i>||<ref><nowiki><pubmed>16952941</pubmed></nowiki></ref>||C
+|<i>bla<sub>VEB-1</sub></i>/<i>bla<sub>OXA-48</sub></i>||<i>Escherichia coli</i>||<ref name=":1" />||C
 |-
-|IS<i>Pa12</i>||—||<i>blaPER-1</i>||<i>Salmonella enterica</i>, <i>Pseudomonas aeruginosa</i>, <i>Providencia stuartii</i>, <i>Acinetobacter baumannii</i>||<ref><nowiki><pubmed>12936998</pubmed></nowiki></ref>||C
+|IS<i>Pa12</i>||—||<i>blaPER-1</i>||<i>Salmonella enterica</i>, <i>Pseudomonas aeruginosa</i>, <i>Providencia stuartii</i>, <i>Acinetobacter baumannii</i>||<ref name=":9"><pubmed>12936998</pubmed></nowiki></ref>||C
 |-
-| rowspan="2" |IS<i>Aba1</i>|| rowspan="2" |—||<i>bla<sub>ampC</sub></i>|| rowspan="2" |<i>Acinetobacter baumannii</i>||<ref><nowiki><pubmed>12951337</pubmed></nowiki></ref><ref><nowiki><pubmed>14742218</pubmed></nowiki></ref><ref><nowiki><pubmed>16441449</pubmed></nowiki></ref>||C
+| rowspan="2" |IS<i>Aba1</i>|| rowspan="2" |—||<i>bla<sub>ampC</sub></i>|| rowspan="2" |<i>Acinetobacter baumannii</i>||<ref name=":10"><pubmed>12951337</pubmed></nowiki></ref><ref><nowiki><pubmed>14742218</pubmed></nowiki></ref><ref><nowiki><pubmed>16441449</pubmed></nowiki></ref>||C
 |-
 |<i>bla<sub>OXA-51</sub></i>/<i>bla<sub>OXA-23</sub></i>||<ref><nowiki><pubmed>16630258</pubmed></nowiki></ref>||C
 |-
 | rowspan="6" |IS<i>5</i>
-|IS<i>5</i>|| rowspan="6" |—||<i>EmR</i>||<i>Escherichia coli</i>||<ref><nowiki><pubmed>6283551</pubmed></nowiki></ref>||C?
+|IS<i>5</i>|| rowspan="6" |—||<i>EmR</i>||<i>Escherichia coli</i>||<ref name=":8" />||C?
 |-
-|ISFtu2||general||<i>Francisella tularensis</i>||<ref><nowiki><pubmed>19749055</pubmed></nowiki></ref>||Natural isolate
+|ISFtu2||general||<i>Francisella tularensis</i>||<ref name=":11"><pubmed>19749055</pubmed></nowiki></ref>||Natural isolate
 |-
 |ISVa1||(iron uptake)||<i>Vibrio anguilarum</i>||<ref><nowiki><pubmed>7568465</pubmed></nowiki></ref>||Natural isolate
@@ Line 76: / Line 76: @@
 |IS<i>1168</i> (IS<i>1186</i>)||<i>nimA</i>, <i>nimB</i>||<i>Bacteroides</i> sp.||<ref><nowiki><pubmed>8067736</pubmed></nowiki></ref>||C
 |-
-|IS<i>1186</i>||<i>cfiA</i>||<i>Bacteroides fragilis</i>||<ref><nowiki><pubmed>8057831</pubmed></nowiki></ref><ref><nowiki><pubmed>7545155</pubmed></nowiki></ref>||C
+|IS<i>1186</i>||<i>cfiA</i>||<i>Bacteroides fragilis</i>||<ref name=":12"><pubmed>8057831</pubmed></nowiki></ref><ref><nowiki><pubmed>7545155</pubmed></nowiki></ref>||C
 |-
-|IS<i>402</i>||<i>bla</i>||<i>Pseudomonas cepacia</i>||<ref><nowiki><pubmed>3025189</pubmed></nowiki></ref>||E
+|IS<i>402</i>||<i>bla</i>||<i>Pseudomonas cepacia</i>||<ref name=":13"><pubmed>3025189</pubmed></nowiki></ref>||E
 |-
 | rowspan="6" |IS<i>6</i>
@@ Line 107: / Line 107: @@
 | rowspan="2" |IS<i>4351</i>||<i>ermF</i>|| rowspan="2" |<i>Bacteroides fragilis</i>||<ref><nowiki><pubmed>3038844</pubmed></nowiki></ref>|| rowspan="2" |C
 |-
-|<i>cfiA</i>||<ref><nowiki><pubmed>23158541</pubmed></nowiki></ref>
+|<i>cfiA</i>||<ref name=":3" />
 |-
 |IS<i>1086</i>||<i>cnrCBAT</i> (Zn<sup>R</sup>)||<i>Cupriavidus metallidurans</i>|| ||E
@@ Line 118: / Line 118: @@
 |IS<i>1490</i>||—||<i>Burkholderia cepacia</i>||<ref><nowiki><pubmed>9098071</pubmed></nowiki></ref>||—
 |-
-|IS<i>406</i>||—||<i>Burkholderia cepacia</i>||<ref><nowiki><pubmed>3025189</pubmed></nowiki></ref>||E
+|IS<i>406</i>||—||<i>Burkholderia cepacia</i>||<ref name=":13" />||E
 |-
 | rowspan="2" |IS<i>481</i>||IS<i>481</i>|| rowspan="2" |Copy-paste circles||<i>katA</i>||<i>Bordetella pertussis</i>||<ref><nowiki><pubmed>7830550</pubmed></nowiki></ref>||—
@@ Line 124: / Line 124: @@
 |IS<i>Rme5</i>||<i>cnrCBAT</i> (Zn R)||<i>Cupriavidus metallidurans</i>||<ref><nowiki><pubmed>27047473</pubmed></nowiki></ref>||E
 |-
-|IS<i>630</i>||IS<i>Ftu1</i>||Tc-like||general||<i>Francisella tularensis</i>||<ref><nowiki><pubmed>19749055</pubmed></nowiki></ref>||Natural isolate
+|IS<i>630</i>||IS<i>Ftu1</i>||Tc-like||general||<i>Francisella tularensis</i>||<ref name=":11" />||Natural isolate
 |-
 | rowspan="3" |IS<i>982</i>
-| rowspan="2" |IS<i>1187</i>|| rowspan="3" |—|| rowspan="2" |<i>cfiA</i>|| rowspan="2" |<i>Bacteroides fragilis</i>||<ref><nowiki><pubmed>8057831</pubmed></nowiki></ref>||E+C
+| rowspan="2" |IS<i>1187</i>|| rowspan="3" |—|| rowspan="2" |<i>cfiA</i>|| rowspan="2" |<i>Bacteroides fragilis</i>||<ref name=":12" />||E+C
 |-
-|<ref><nowiki><pubmed>23158541</pubmed></nowiki></ref><ref><nowiki><pubmed>11344163</pubmed></nowiki></ref><ref><nowiki><pubmed>12604530</pubmed></nowiki></ref>||C
+|<ref name=":3" /><ref name=":14"><pubmed>11344163</pubmed></nowiki></ref><ref name=":15"><pubmed>12604530</pubmed></nowiki></ref>||C
 |-
 |IS<i>982</i>||<i>citQRP</i>||<i>Lactococcus lactis</i>||<ref><nowiki><pubmed>8602160</pubmed></nowiki></ref>||—
 |-
 | rowspan="12" |IS<i>1380</i>
-|IS<i>Bf12</i>|| rowspan="12" |—|| rowspan="6" |<i>cfiA</i>|| rowspan="6" |<i>Bacteroides fragilis</i>||<ref><nowiki><pubmed>23158541</pubmed></nowiki></ref>|| rowspan="12" |C
+|IS<i>Bf12</i>|| rowspan="12" |—|| rowspan="6" |<i>cfiA</i>|| rowspan="6" |<i>Bacteroides fragilis</i>||<ref name=":3" />|| rowspan="12" |C
 |-
-|IS<i>612</i>||<ref><nowiki><pubmed>12604530</pubmed></nowiki></ref>
+|IS<i>612</i>||<ref name=":15" />
 |-
-|IS<i>613</i>||<ref><nowiki><pubmed>12604530</pubmed></nowiki></ref>
+|IS<i>613</i>||<ref name=":15" />
 |-
-|IS<i>614</i>||<ref><nowiki><pubmed>23158541</pubmed></nowiki></ref><ref><nowiki><pubmed>12604530</pubmed></nowiki></ref><ref><nowiki><pubmed>19744834</pubmed></nowiki></ref>
+|IS<i>614</i>||<ref name=":3" /><ref name=":15" /><ref><nowiki><pubmed>19744834</pubmed></nowiki></ref>
 |-
-|IS<i>1188</i>||<ref><nowiki><pubmed>11344163</pubmed></nowiki></ref>
+|IS<i>1188</i>||<ref name=":14" />
 |-
-|IS<i>942</i>||<ref><nowiki><pubmed>11344163</pubmed></nowiki></ref>
+|IS<i>942</i>||<ref name=":14" />
 |-
 | rowspan="5" |IS<i>Ecp1</i>||<i>bla<sub>CTX-M-15</sub></i>||Enterobacteriaceae||<ref><nowiki><pubmed>11470367</pubmed></nowiki></ref>
@@ Line 150: / Line 150: @@
 |<i>bla<sub>CTX-M-17</sub></i>||<i>Klebsiella pneumoniae</i>||<ref><nowiki><pubmed>12435670</pubmed></nowiki></ref>
 |-
-|<i>bla<sub>CTX-M-19</sub></i>||<i>Klebsiella pneumoniae</i>||<ref><nowiki><pubmed>12936998</pubmed></nowiki></ref>
+|<i>bla<sub>CTX-M-19</sub></i>||<i>Klebsiella pneumoniae</i>||<ref name=":9" />
 |-
 |<i>bla<sub>CTX-M</sub></i>||<i>Kluyvera ascorbata</i>||<ref><nowiki><pubmed>16569841</pubmed></nowiki></ref>
@@ Line 156: / Line 156: @@
 |<i>rmtC</i>||<i>Escherichia coli</i>||<ref><nowiki><pubmed>16940134</pubmed></nowiki></ref>
 |-
-|IS<i>1187</i>||<i>cfiA</i>||<i>Bacteroides fragilis</i>||<ref><nowiki><pubmed>11344163</pubmed></nowiki></ref>
+|IS<i>1187</i>||<i>cfiA</i>||<i>Bacteroides fragilis</i>||<ref name=":14" />
 |-
 | rowspan="2" |IS<i>L3</i>
@@ Line 166: / Line 166: @@
 |IS<i>1548</i>|| rowspan="2" |—||<i>lmb</i> (lamelin binding)||<i>Streptococcus agalactiae</i>||<ref><nowiki><pubmed>20520730</pubmed></nowiki></ref>||—
 |-
-|nd||—||<i>Acinetobacter baumannii</i>||<ref><nowiki><pubmed>12951337</pubmed></nowiki></ref>||C
+|nd||—||<i>Acinetobacter baumannii</i>||<ref name=":10" />||C
 |-
 | rowspan="3" |IS<i>NYC</i>
-|IS<i>403</i>|| rowspan="3" |—|| rowspan="3" |bla|| rowspan="3" |<i>Burkholderia cepacia</i>|| rowspan="3" |<ref><nowiki><pubmed>3025189</pubmed></nowiki></ref>|| rowspan="3" |E
+|IS<i>403</i>|| rowspan="3" |—|| rowspan="3" |bla|| rowspan="3" |<i>Burkholderia cepacia</i>|| rowspan="3" |<ref name=":13" />|| rowspan="3" |E
 |-
 |IS<i>404</i>

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