Remobilization of Sleeping Beauty transposons in
the germline of Xenopus tropicalis
Yergeau et al.

Yergeau et al. Mobile DNA 2011, 2:15
http://www.mobilednajournal.com/content/2/1/15 (24 November 2011)



RESEARCH Open Access

Remobilization of Sleeping Beauty transposons in
the germline of Xenopus tropicalis
Donald A Yergeau1, Clair M Kelley1, Emin Kuliyev1, Haiqing Zhu1, Michelle R Johnson Hamlet1, Amy K Sater2,
Dan E Wells2 and Paul E Mead1*

Abstract

Background: The Sleeping Beauty (SB) transposon system has been used for germline transgenesis of the diploid
frog, Xenopus tropicalis. Injecting one-cell embryos with plasmid DNA harboring an SB transposon substrate
together with mRNA encoding the SB transposase enzyme resulted in non-canonical integration of small-order
concatemers of the transposon. Here, we demonstrate that SB transposons stably integrated into the frog genome
are effective substrates for remobilization.

Results: Transgenic frogs that express the SB10 transposase were bred with SB transposon-harboring animals to
yield double-transgenic ‘hopper’ frogs. Remobilization events were observed in the progeny of the hopper frogs
and were verified by Southern blot analysis and cloning of the novel integrations sites. Unlike the co-injection
method used to generate founder lines, transgenic remobilization resulted in canonical transposition of the SB
transposons. The remobilized SB transposons frequently integrated near the site of the donor locus; approximately
80% re-integrated with 3 Mb of the donor locus, a phenomenon known as ‘local hopping’.

Conclusions: In this study, we demonstrate that SB transposons integrated into the X. tropicalis genome are
effective substrates for excision and re-integration, and that the remobilized transposons are transmitted through
the germline. This is an important step in the development of large-scale transposon-mediated gene- and
enhancer-trap strategies in this highly tractable developmental model system.

Background
Amphibian model systems have provided a wealth of
information on the molecular mechanisms controlling
early vertebrate development. Frogs of the Xenopus
genus are particularly well suited for embryological
study as these animals adapt well to captivity and the
females can be induced to lay large numbers of eggs
throughout the year. The most commonly used amphi-
bian model is the South African clawed frog, X. laevis.
Genetic manipulation of this species is not practical due
to the long generation time (> 1 year) and the pseudo-
tetraploid nature of the genome. Another species of the
Xenopus genus, X. tropicalis, shares the embryological
advantages of its South African cousin and is better sui-
ted for genetic studies as it is a true diploid and has a
relatively short generation time (approximately 6

months). The potential of applying modern genetics to
this classical embryological model system has resulted in
the rapid development of genomic tools for X. tropicalis
in recent years (reviewed in [1,2]), and the publication
of the genome sequence [3].
Our studies have focused on using the class II DNA

‘cut-and-paste’ transposable elements to modify the frog
genome for gene- and enhancer-trapping and for inser-
tional mutagenesis [4-9]. Transposable elements have
been used for many years to experimentally modify the
genomes of plants and invertebrates and, more recently,
have been applied to vertebrate model systems [10,11].
Transgenesis with non-autonomous transposable elements
offers advantages over other transgenic methodologies.
First, transposable elements efficiently integrate into the
target genomes. Second, as the transposon is excised from
the donor plasmid prior to integration, plasmid sequences,
which may cause epigenetic silencing [12,13], are not inte-
grated at the targeted locus. Third, once integrated into
the genome, the transposon transgene is an effective

* Correspondence: paul.mead@stjude.org
1Department of Pathology, St Jude Children’s Research Hospital, 262 Danny
Thomas Place, Memphis, TN 38105, USA
Full list of author information is available at the end of the article

Yergeau et al. Mobile DNA 2011, 2:15
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© 2011 Yergeau et al; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons
Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in
any medium, provided the original work is properly cited.

mailto:paul.mead@stjude.org
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substrate for excision and re-integration (remobilization)
following re-expression of the cognate transposase
enzyme. The ability to remobilize transposons resident in
the genome can be used for a variety of applications,
including large-scale transposon ‘hopping’ screens using
gene- or enhancer-trap constructs.
Remobilization of a non-autonomous transposon trans-

gene is achieved by expressing the transposase enzyme in
the same cell harboring the transposon. This can be
achieved by simply injecting fertilized one-cell embryos
from the outcross of transposon transgenic animals with
mRNA encoding the transposase. As development pro-
ceeds, the injected mRNA is translated by the host cell
and catalyzes the excision and re-integration reactions.
This approach has been used successfully with the Tol2
transposon system in fish and frogs [7,14-16]. Another
approach is to develop transgenic animals that express
the transposase enzyme under the control of tissue speci-
fic promoters and to cross these animals with those that
harbor a transposon substrate to generate double-trans-
genic progeny. This approach has been used very suc-
cessfully for somatic remobilization of the Sleeping
Beauty (SB) transposon to identify cancer genes in mice
[17,18]. Outcross of the transposase enzyme and transpo-
son substrate double transgenic animals can result in
novel remobilization events in the progeny [19-23].
We, and others, have used a co-injection strategy with

the SB [24] transposon system to generate transgenic
Xenopus that express fluorescent proteins under the
control of ubiquitous or tissue-specific promoters
[4,6,25]. The integration events generated by this
method in the frog are not caused by the simple trans-
position of the transposon from the plasmid into the
frog genomic DNA. Analysis of the integration sites
indicated that several copies of the transposon, and
parts of the flanking plasmid sequence, are introduced
at discrete loci as small-order concatemers. This unex-
pected non-canonical integration mechanism makes
cloning the integration site complicated and time con-
suming [6]. Although the integration events generated
by the co-injection strategy resulted in non-canonical
integration, we next investigated whether SB transpo-
sons stably integrated into the X. tropicalis genome are
effective substrates for remobilization. Using a double-
transgenic strategy, we show that SB transposons in the
frog genome can be remobilized following re-expression
of the SB transposase and that the remobilized integra-
tion events occur via canonical transposition.

Results
Generation and analysis of transgenic X. tropicalis
expressing SB10 transposase
A transgenic X. tropicalis line was engineered to express
the SB10 transposase under the control of a synthetic

regulatory element, chicken b-actin promoter coupled
with a cytomegalovirus enhancer (CAGGS [26]) [27]. To
track the inheritance of the SB10 transgene, a X. laevis
g1 crystallin-red fluorescent protein (RFP) [28] reporter
was cloned downstream of the CAGGS-SB10 transgene
in a head-to-head orientation (Figure 1a). The presence
of the linked g1 crystallin-RFP reporter allows screening
for the CAGGS-SB10 transgene based on the presence
of red eyes (Figure 1b). We used the simple linear plas-
mid DNA injection method described by Etkin and
Pearman to generate the transgenic SB transposase-
expressing frogs [29]. Injected embryos were scored for
the presence of RFP expression in the lens, and RFP-
positive tadpoles (27 RFP-positive from 570 injected,
4.7%) were raised to adulthood. A single founder
(CAGGS-SB10;gcRFP 2 M), from a total of five animals
outcrossed to date, was identified. Outcross of male
founder CAGGS-SB10;gcRFP 2M with a wild-type
female resulted in 779 RFP-positive tadpoles from a
total of 3,333 offspring (23.4%). The non-Mendelian
inheritance of the transgene indicates that the germline
of the CAGGS-SB10;gcRFP 2M founder was mosaic for
the transgene. Subsequent outcross of F1 animals
derived from CAGGS-SB10;gcRFP 2M resulted in the
expected 50% of the progeny expressing the dominant
lens-specific RFP reporter (in a representative F1 out-
cross there were 239 RFP-positive tadpoles from a total
of 479, 49.9%). Southern blot analysis of RFP-positive
tadpoles indicated that several copies of the transgene
were integrated at a single locus in the founder (Figure
1c). Reverse transcriptase (RT)-PCR and Western blot
analyses were used to verify that SB10 transposase was
expressed in the transgenic line. RT-PCR analysis
showed that RFP-positive tadpoles at stage 40 [30]
express mRNA encoding the SB transposase enzyme
(Figure 1d). As expected, sibling tadpoles that did not
express the RFP reporter in the lens were also negative
for SB10 mRNA expression. In adults, robust expression
of SB transposase was detected in protein lysates pre-
pared from testes harvested from RFP-positive male
frogs, but not from RFP-negative animals (Figure 1e).
SB10 is also expressed in the liver of the transgenic
frogs, but not in the RFP-negative littermates.

Generation of double-transgenic ‘hopper’ frogs
The CAGGS-SB10;gcRFP 2M line was outcrossed with
SB transposon transgenic animals that express GFP
under the control of the CAGGS promoter (pT2bGFP
[6]). Double-transgenic F2 ’hopper’ frogs (ubiquitous
GFP and lens-specific RFP) were outcrossed with wild-
type frogs and the progeny (F3) were either analyzed for
remobilization events or raised and outcrossed (Figure
2). Five independent substrate donor lines were used to
generate double-transgenic hopper lines for this study.

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As the methodology for the generation and analysis of
the hopper lines is the same for each donor locus, two
donor lines (pT2bGFP 8 F and 7 M) will be described in
detail below.

8F hoppers
The pT2bGFP 8F founder harbors two independently-
segregating alleles: a concatemer of three SB transpo-
sons integrated at a single locus on scaffold 57, at base
number 2456981 (57:2456981) of the JGI X. tropicalis
genomic sequence v4.1 assembly, and another allele
with a single-copy transposon integration [6]. Thus, the
F2 hopper frogs inherited either one, or both, of the 8F
integration events. Southern blot analysis of progeny
from 8Fhopper♂35 indicated that this double-transgenic
hopper had inherited the trimeric concatemer of
pT2bGFP on scaffold 57 alone. Double-transgenic (RFP
+/GFP+) progeny (F3) from the outcross of 8Fhop-
per♂35 were raised and outcrossed, and the resulting
progeny (F4) were analyzed for modification of the par-
ental pT2bGFP locus (Figure 2).
Observation of the GFP expression in the hopper out-

cross populations indicated that, in most cases, the GFP
expression of the progeny was identical to that of the 8F
founder, suggesting that the parental SB transposon
locus was intact. In a small number of the outcross pro-
geny, we observed markedly different GFP expression in
either small populations of cells within the tadpole (Fig-
ure 3a, b) or in whole tadpoles (Figure 4a, b; 40 from
20,015 GFP-positive tadpoles). We reasoned that the
change in GFP expression might result from the modifi-
cation of the parental pT2bGFP locus in the remobilized
progeny. Embryos with small subsets of cells with
increased GFP intensity likely represent stochastic trans-
posase activity in somatic tissues (somatic remobilization
(Figure 3a, b)). An organism-wide change in GFP inten-
sity (Figure 4a) likely represents modification of the par-
ental transposon donor locus during gametogenesis that
is passed on to the resulting progeny. Remobilization of
a transposon from the donor locus to a novel site will
likely alter the local epigenetic environment of the
transgene, and also subject the re-integrated transposon
to the influence of nearby gene regulatory sequences
that differ from the parental locus.
Genomic DNA harvested from GFP-positive progeny

from double transgenic (pT2bGFP8F:CAGGS-SB10;
gcRFP) 8F hopper frogs was analyzed by Southern blot.
Digestion of genomic DNA from pT2bGFP 8F tadpoles
with BglII resulted in three bands when the blot was
hybridized with a GFP probe (Figure 4c). Changes in the
Southern blot hybridization pattern were used to deter-
mine whether the parental concatemer had been altered
by expression of the SB transposase. Analysis of progeny

Figure 1 Generation of a transgenic Xenopus tropicalis that
expresses SB10 transposase. (a) Schematic of the pCAGGS-SB10;
gcRFP construct used to develop SB (SB10) transposase-expressing
transgenic frogs. The two transgenes were cloned in a tail-to-tail
orientation. Not to scale. (b) Red lens in the right eye of an adult F1
transgenic frog from outcross of founder CAGGS-SB10;gcRFP 2 M.
The border of the eye is indicated by the dashed white line. (c)
Southern blot analysis of genomic DNA harvested from RFP-positive
and control animals indicated integration of multiple copies of the
CAGGS-SB10;gcRFP linear transgene. The DNA was digested with
BamHI and the blot was probed with a radiolabelled SB10 cDNA
probe (see schematic (a)). (d) RT-PCR analysis of SB10 expression in
tadpoles. SB RNA was detected in RFP-positive tadpoles (+RFP) but
not in RFP-negative (-RFP) progeny from CAGGS-SB10;gcRFP 2M.
RNA from a wild-type tadpole was used as a negative control (St.
15). A mock reverse transcription reaction, without added RT, with
RNA harvested from an RFP-positive tadpole (+RFP(-RT)) was used
as a negative control. Primers for X. tropicalis a-actin were used as a
control for RNA recovery. (e) Western blot analysis of SB transposase
expression in tissues harvested from adult transgenic frogs. A
monoclonal antibody to SB was used to demonstrate abundant
transposase expression in the testis and liver of RFP-positive adults,
but not in the RFP-negative siblings. Protein lysates prepared from
tadpoles injected with SB10 mRNA at the one-cell stage were
prepared at stage 15 (control lane). The blots were stripped and re-
probed with a monoclonal antibody that recognizes Xenopus a-
actin. PCR: polymerase chain reaction; RFP: red fluorescent protein;
RT: reverse transcriptase; SB: Sleeping Beauty.

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from the outcross of F3 double transgenic hopper frogs
with wild-type animals indicated that most of the pro-
geny had inherited the unaltered pT2bGFP 8F parental
concatemer (Figure 4c; lanes 3, 4 and 5). Examples of
germline remobilization of the pT2bGFP transposon
from ‘GFP-bright’ tadpoles (Figure 4a; tadpoles 1 and 2)
harvested from the outcross of 8Fhopper♂58 are shown
in Figure 4c (lanes 1 and 2, dashed arrows). This data
indicates that, as predicted, the GFP-bright individuals
in the outcross population of the hopper frogs represent
tadpoles that have modified the parental transposon
donor locus. Thus, remobilized animals can be identified
in the outcross population by simply observing the tad-
poles for changes in GFP intensity. Outcross of eleven
8F hopper double transgenic frogs indicated that the fre-
quency of remobilized progeny varied from 0.07% to
0.71% (Figure 4b). The variation in the remobilization

activity between individual hopper frogs likely reflects
subtle differences in epigenetic modification of the sub-
strate and enzyme transgenes in each animal that may
alter the activity of the excision and reintegration
reactions.
Analysis of the cloned flanking sequences of the par-

ental locus (57:2456981) from the remobilized tadpoles
(Figure 4c; lane 1 and 2) showed no sequence change,
indicating that the remobilized transposon was excised
from within the donor concatemer (data not shown).
Extension primer tag selection linker mediated-PCR
(EPTS LM-PCR) and standard genomic PCR [6,8] were
used to clone the integration sites of the novel bands.
The re-integration event from tadpole 8Fhopper♂58-1
had occurred on the same scaffold as the parental inte-
gration site, and thus represented a ‘local hop’ (Table 1
and Figure 5; tadpole 8Fhopper♂58-1). Genomic PCR

Figure 2 Breeding strategy to generate double-transgenic hopper frogs. The F2 hopper frogs were outcrossed with wild-type animals and
the progeny was scored for GFP and RFP expression. The GFP-positive/RFP-negative F3 progeny were either raised to adulthood for outcross or
genomic DNA was harvested after stage 45 for molecular analyses. GFP: green fluorescent protein; RFP: red fluorescent protein.

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and sequencing was used to verify both the 5’- and 3’-
ends of the novel insertion site. The integration site of
the remobilized pT2bGFP transposon is at 57:2491386
and is 34,405 bp away from the parental locus on chro-
mosome 6 (Figure 5b). Sequence analysis of the integra-
tion site indicated that the remobilization event was

catalyzed by a canonical transposition event. That is, the
transposon inserted precisely at the predicted boundary
of the indirect repeat/direct repeats (IR/DRs). Further-
more, the integrated transposon is flanked by the
expected TA dinucleotide target site duplication cata-
lyzed by SB transposase [31-33]. Thus, unlike the co-
injection method used to generate the pT2bGFP founder
lines that results in unexpected concatemer formation
(Figure 5a, [6]), the remobilization events catalyzed by
re-expression of SB transposase are via canonical trans-
position (Figure 5b). To date, we have identified 40
remobilization events, based on differences in GFP
expression intensity, from 20,015 GFP-positive tadpoles
from the outcross of 8F hopper frogs (Figure 4b). South-
ern analysis has confirmed excision and re-integration of
a SB transposon from the parental locus and yields an
apparent remobilization frequency of approximately
0.2%.
Pre-sorting tadpoles based on GFP intensity may

underestimate the total remobilization activity if the re-
integration event resulted in GFP expression that was
not markedly different from the parental expression. To
test this, we outcrossed a double transgenic hopper frog
(8Fhopper♂51) and analyzed all of the GFP-positive
progeny by Southern blot. The 8Fhopper♂51 frog inher-
ited both of the pT2bGFP transposon alleles from the
8F founder. The progeny from this 8Fhopper♂51 out-
cross displayed GFP expression patterns and intensities
that were indistinguishable from that of the parental
alleles (data not shown). From the 677 GFP-positive
progeny analyzed by Southern blot, we identified four
excision-only events and two remobilizations. Samples
of genomic DNA where changes were evident by South-
ern blot analysis were used in EPTS LM-PCR to clone
the integration site of the remobilization events. In this
experiment, the remobilization frequency was 0.3% (two
remobilization events out of 677 GFP-positive tadpoles).
These data indicated that the actual remobilization fre-
quency may be somewhat higher than that estimated by
simple visual inspection of the GFP-positive progeny.
The observed rate of excision-only events in this out-
cross population was 4 out of 677, that is, 0.6%.
Scoring the outcross progeny of hopper frogs for

changes in GFP intensity may also overestimate the
remobilization frequency, as this method may not distin-
guish between remobilization events and excision-only
events. We analyzed 25 GFP-bright tadpoles from the
outcross of 8F and 7M (see below) hopper frogs, by
Southern blot analysis and by cloning the novel inser-
tion sites by EPTS LM-PCR. Only one GFP-bright tad-
pole had an excision-only modification of the parental
transposon donor locus (4%); 24 GFP-bright tadpoles
(96%) had re-integration events that were evident by
novel bands on the Southern blot and by cloning the

Figure 3 Somatic remobilization of pT2bGFP in double
transgenic tadpoles. Outcross of double transgenic hopper frogs
resulted in progeny that inherited both transgenes. In rare instances,
we identified double transgenic tadpoles that express intense levels
of the GFP transgene reporter in individual cells or in small groups
of cells. The change in GFP expression seen in these somatic cells is
likely to be due to sporadic remobilization of the pT2bGFP
transposon and the change in GFP intensity is likely due to the
influence of the local chromatin environment at the novel
integration site. The region of each tadpole shown (dashed box) is
indicated on the cartoon inset. (a) Tail of a double transgenic
tadpole with a single muscle cell expression intense GFP (arrow). (b)
Double transgenic tadpole with high-level GFP expression in a
subset of cells in the brachial cartilage (arrow). The immobilized
tadpole was also photographed using a dsRED filter and the two
images were overlaid to demonstrate that this animal had inherited
the CAGGS-SB10;gcRFP transgene (RFP expression in the lens is
indicated by the white arrowhead). GFP: green fluorescent protein;
RFP: red fluorescent protein.

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sequences flanking the canonical re-transposition events.
Thus, while it is possible to identify excision-only events
by changes in GFP expression, the vast majority of GFP-
bright progeny represent re-integration events.
Remobilization of transposons resident in the genome

may result in chromosomal rearrangements near the
donor locus [34-41]. In mice, germline remobilization of
SB transposons from a high-copy number

(approximately 30 copies) concatemer resulted in fre-
quent alteration of the genomic sequences flanking the
transposon donor locus; nine out of nine remobilized
pedigrees examined displayed genomic alterations span-
ning 105 bp to 107 bp flanking the donor site [41]. To
determine whether SB remobilization in the frog
resulted in similar genomic alterations near the donor
locus, we examined the sequences flanking the 8F donor

Figure 4 Excision and re-integration of SB transposons in the progeny of double-transgenic hopper frogs. (a) GFP expression in sibling
tadpoles derived from the outcross of an 8F hopper frog. Tadpoles 1 and 2 are significantly brighter than their GFP-positive siblings (tadpoles 3,
4 and 5). Tadpole 6 is a GFP-negative tadpole. Dorsal view, with anterior facing towards the right. (b) Representative data for the outcross
population of 8F hopper frogs. Table includes data from breeding four F2 (8F♂54, 8F♂55, 8F♂56 and 8F♀61) and seven F3 (8F35♂A, B, C etc.)
double-transgenic hoppers with wild-type frogs. The outcross progeny were scored for GFP expression and the GFP-bright progeny were either
harvested for integration site analysis or raised to adulthood and outcrossed. A range of apparent remobilization activity from 0% to 0.7% was
observed in individual 8F hopper frogs, with an average rate of two remobilization events per thousand GFP-positive progeny (0.2%). (c)
Southern blot analysis of genomic DNA harvested from the progeny of double transgenic 8F hopper frogs. Genomic DNA was digested with
BglII and the blot was probed with a radiolabelled GFP cDNA probe. DNA harvested from tadpoles in lanes 3, 4 and 5 have the same banding
pattern as the parental pT2bGFP 8F founder line. Lanes 1 and 2 show example of remobilization of an SB transposon. The dashed arrow
indicates the change in the mobility of the transposon-harboring BglII fragment. Lane 6 contains DNA from GFP-negative siblings. GFP: green
fluorescent protein; SB: Sleeping Beauty.

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locus by PCR. Genomic DNA samples from eight remo-
bilization events and eight excision-only events were
used to amplify the sequences flanking the 5’ and 3’
ends of the 8F concatemer on chromosome 6. In each
case, genomic PCR using primers that amplify the 5’
and 3’ junctions of the 8F locus generated the appropri-
ate sized products (data not shown), indicating that the
sequences directly flanking the donor locus are intact
following excision of pT2bGFP transposons from the
donor site.
Sequence analysis of the re-integration target sites

indicated a similar base distribution flanking the canoni-
cal TA dinucleotide to that observed with SB integration
in mammalian genomes [42,43] (Figure 5d). Transpo-
sons of the Tc1/mariner family, including SB, integrate
at TA dinucleotides. The consensus sequence for SB
integration in frogs, as in mammals, is a palindromic
ATATATAT sequence, where the canonical TA target
is in bold, although none of the re-integration events
observed in the frog have this exact palindrome.
Cloning the integration sites of the novel loci indi-

cated that the remobilized transposons frequently inte-
grate near the parental locus (Figures 5 and 6; 12 out of
15 classed as local hopping, 80%). In two cases, we iden-
tified remobilization events that had re-integrated within
the parental transposon concatemer on scaffold 57
(Table 1 and Figure 6a). The scaffold identity was used
to ‘map’ the chromosomal location [44] of the novel

integration events and showed that, while local hopping
was more frequent, re-integration on other chromo-
somes was also detected (Figure 6b; three out of fifteen
(20%) of integrations are on different chromosomes).
GFP-bright progeny from the outcross of 8F hopper

frogs were raised to the adult stage, and outcrossed to
demonstrate that the remobilized transposon alleles are
stably transmitted through the germline. Genomic DNA
was harvested from GFP-positive and GFP-negative sib-
lings and used for Southern blot analysis and for cloning
the novel integration site by EPTS LM-PCR. For exam-
ple, remobilized female frog 62E3 produced GFP-bright
progeny and integration site analysis showed a single
copy of the pT2bGFP transposon on scaffold 140
(140:1237072). The novel re-integration event was on
the same chromosome as the donor locus (chromosome
6, linkage group 2), approximately 1 cM from the paren-
tal 8F concatemer, and represents a local hop (data not
shown). The 62E3 integration event was in the 3’ UTR
of a muscle-related coiled coil protein (GenBank acces-
sion number XM_002935280.1) gene.

7M hoppers
The pT2bGFP 7M founder had a concatemer of 8 to 10
pT2bGFP transposons at a single locus within a repeat
on scaffold 38 (Linkage Group 10, chromosome 10), and
mapped, by fluorescence in situ hybridization (FISH)
analysis, near a telomere on chromosome 10 (Figure 7).

Table 1 Integration site analysis for remobilized progeny from 8F hoppers.

Tadpole Right indirect repeat/direct repeats flanking sequence Integration site 5’ flanking gene 3’ flanking gene

Parental 8F GCAACGCTagtcac...cagttATTGATTa 57:2456981 pSST739 C7orf72-like

8F♂51-498 GCGCAATACTATTATAcagttgaagtcgg 57:2452131 pSST739 C7orf72-like

8F♂51-55 CGGGCCATGATGTATAcagttgaagtcgg pT2bGFPb pSST739 C7orf72-like
8F♀61-1 GTGGAGCTCTGAAATAcagttgaagtcgg pT2bGFPb pSST739 C7orf72-like
8F♂58-2 AAAGGCAACACGCGTAcagttgaagtcgg 57:2470830 pSST739 C7orf72-like

8F♂58-8 GAATCTCTGTGATCTAcagttgaagtcgg 57:2491386 pSST739 C7orf72-like

8F♂C-43 CAGAGCTAGATATATAcagttgaagtcgg 57:2507804 C7orf72-like C7orf72-like

8F35♀F-1 TGGAAATGCCTATATAcagttgaagtcgg 57:2544323 C7orf72-like Ikaros

8F35♂C-44 AAGAAAGCACTTGGTAcagttgaagtcgg 57:2672369 Dopa decarboxylase Dopa decarboxylase

8F♀60-1 CCCCCTTCGGTGATTAcagttgaagtcgg 57:2897938 Grb10 Cordon-bleu

8F35♂A-207 ACAAACGGGCCATGTAcagttgaagtcgg 57:2991209 Grb10 Cordon-bleu

8F♂58-9 TATCTAAACAAAGTTAcagttgaagtcgg 588:587502 Cam-PDE 1C Cam-PDE 1C

6265 TCACTACATATTTCTAcagttgaagtcgg 294:394261 PTPRM PTPRM

8F♂58-3 TAAGAATTAATAGTTAcagttgaagtcgg 250:752306 c-Fyn c-Fyn

8F35♂C-35 TATAAATAAAGATATAcagttgaagtcgg 223:803513 Connexin 31.1 C1orf94-like

8F♂B-203 AAGGCAGTCAGTTATAcagttgaagtcgg 15:2263789 RDC-1 COP9

8F35♂A-205 GATAACTCTTAAGTTAcagttgaagtcgg 484:822241 Amphiphysin Amphiphysin

Sequences flanking the novel transposon insertion site were cloned using extension primer tag selection linker mediated-PCR. The remobilization events are
mediated by canonical transposition reactions and the transposon sequence (italics) is flanked by the characteristic TA dinucleotide target site duplication (bold).
The flanking sequence (depicted in capital letters) was used to interrogate the X. tropicalis genome sequence database (Joint Genome Institute X. tropicalis
genome sequence assembly v4.1; [3]) to assign the integration sites to the genomic sequence scaffolds. The genes flanking the novel integration site are listed.
aThe parental integration site on scaffold 57 was mediated by a non-canonical mechanism. bTwo remobilization events showed reintegration of the excised
transposon into the donor concatamer locus on scaffold 57.

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http://www.ncbi.nih.gov/entrez/query.fcgi?db=Nucleotide&cmd=search&term=XM_002935280.1


Double transgenic 7M hopper frogs were generated by
breeding heterozygous pT2bGFP 7M F1 frogs with het-
erozygous CAGGS-SB10;gcRFP 2M F1 frogs, and the
progeny were sorted for GFP-positive and RFP-positive
expression. The double-heterozygous 7M hopper frogs
were outcrossed with wild-type animals and remobiliza-
tion events were scored in the progeny by observing the
outcross population for changes in GFP expression. To
date, ten 7M hoppers have been outcrossed and 112
remobilized (GFP-bright) tadpoles have been identified
from 11,646 GFP-positive progeny (Figure 7a). Genomic
DNA from several GFP-bright tadpoles was analyzed by
Southern blot, and this data verified that the banding
pattern had changed from the parental 7M pattern, indi-
cative of transposon remobilization. The novel integra-
tion sites were cloned (Table 2), and sequence analysis
confirmed that the remobilized transposons had re-inte-
grated via canonical SB-mediated transposition (data not
shown). The average apparent rate of remobilization was
approximately 1%, and is five-times higher than that

observed for the 8F hopper animals. The higher rate of
remobilization observed in the 7M hoppers compared to
the 8F hoppers may be due to the increased number of
potential substrate transposons in the donor concatemer
(three for 8F compared with 8 to 10 for 7M). A range of
remobilization activities, from 0% to 5%, was noted
between the different 7M hopper frogs. The 7M hoppers
were produced by breeding frogs that were heterozygous
for the SB10 enzyme transgene with frogs that were het-
erozygous for the pT2bGFP 7M allele. Double-heterozy-
gous males (7Mhopper♂1, 7Mhopper♂2, 7Mhopper♂3,
7Mhopper♂5, 7Mhopper♂14, 7Mhopper♂20) produced
offspring with an average remobilization frequency of
approximately 0.44%. The frequency of GFP-positive
progeny in the outcrosses from these males was
approximately 50%, as expected for the Mendelian
inheritance of a heterozygous dominant allele. Two 7M
hopper male frogs (7Mhopper♂9 and 7Mhopper♂11)
produced a much higher rate of remobilized (GFP-
bright) tadpoles than their siblings (approximately 1.9%

Figure 5 Integration site analysis of remobilized SB transposons. (a) Schematic representation of the 8F donor locus showing the predicted
orientation of the trimeric concatemer in scaffold 57. This injection-mediated integration event occurred by a non-canonical mechanism. (Not to
scale.) (b) Schematic representation of the novel integration event in the remobilized tadpole shown in Figure 4b. EPTS LM-PCR was used to
clone the sequence flanking the 5’ end of the pT2bGFP transposon and the 5’ and 3’ flanking sequences were verified using PCR primers
designed to the scaffold sequence. The novel integration event occurred on the same scaffold (57 at position 2544323 bp) of the Joint Genome
Institute X. tropicalis genome sequence assembly v4.1 as the 8F transposon donor locus (57:2456981) and represented a local hop. The sequence
of the SB transposon and genomic DNA junctions (arrows) indicated that the remobilization event occurred via a canonical transposition
reaction. The pT2bGFP transposon is flanked by the expected TA dinucleotide target site duplication (TSD; bold underlined), and the transposon
is inserted precisely, without any flanking plasmid sequence from the donor site. The genomic DNA sequence of scaffold 57 is capitalized and
the transposon sequence is in lowercase italics. (Not to scale.) (c) The preferred sequence for SB transposon re-integration in the X. tropicalis
genome. Weblogo analysis http://weblogo.berkeley.edu for the five base pair sequence flanking the TA target site. The relative size of the letters
indicates the strength of the information on the y-axis, with the maximum indicated by two bits. The table shows the base distribution of the
pT2bGFP transposon re-integration target sites. EPTS LM-PCR: extension primer tag selection linker-mediated polymerase chain reaction; PCR:
polymerase chain reaction; SB: Sleeping Beauty.

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http://weblogo.berkeley.edu


compared with 0.44% for male sibling hoppers). Intrigu-
ingly, these animals appear to be homozygous for both
the enzyme (CAGGS-SB10;gcRFP) and substrate
(pT2bGFP) transgenes; 100% of the outcross progeny
were RFP-positive and nearly all (> 98%) were also GFP-
positive. Southern blot analysis of the outcross progeny
indicated that all of the GFP-positive animals (n = 107
for 7Mhopper♂9; n = 114 for 7Mhopper♂11) had

inherited the 7M concatemer, and the banding pattern
was identical to the parental locus. The GFP-bright tad-
poles in the outcross populations of 7Mhopper♂9 and
7Mhopper♂11 showed changes in parental 7M locus
indicative of excision and re-integration of a transposon
from the substrate donor locus. The rare (< 2%) GFP-
negative tadpoles observed in the outcross populations
did not inherit the pT2bGFP transgene as determined

Figure 6 Schematic representation of remobilized SB transposons in the X. tropicalis genome. (a) Local hopping on X. tropicalis
chromosome 6 depicts the integration sites for eight local (< 200 kb) remobilization events (hops). (Not to scale.) This region of X. tropicalis
chromosome 6 is syntenic with human chromosome 7. The Vista http://genome.lbl.gov/vista alignment shows regions of homology between
the frog and human genomic sequences; pink represents non-coding regions and blue represents conserved exons. The position of the 8F
donor concatemer is indicated by the grey box. The remobilized transposition events are depicted by the grey triangles. The position and
orientation of predicted genes near the 8F locus are depicted in the lower section of the panel. (b) Schematic representation of the X. tropicalis
chromosomes indicating the distribution of remobilized SB transposons. The parental 8F donor site is on chromosome 6 (thick line). The
predicted loci of the remobilized transposons are depicted by the thin black lines. Approximately 80% of the remobilization events occur near
the donor locus (local hopping), and the remaining 20% are distributed randomly throughout the genome. SB: Sleeping Beauty.

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http://genome.lbl.gov/vista


by Southern blot and genomic PCR for GFP sequences
(data not shown). The unexpected non-Mendelian
inheritance of hoppers 7M♂9 and 7M♂11 is unex-
plained; however, this data suggests that increasing the
copy number of the transposon substrates in the hopper
lines may increase the remobilization frequency
observed in the outcross population.
To date, four 7M female hopper frogs have been out-

crossed, and the mean remobilization rate from these
animals is 2.54%. This may reflect individual differences
in excision and reintegration activities between different
hopper animals, or it may indicate that remobilization,
driven by the CAGGS-SB10 transgene, is more efficient
in the female germline (mean 2.54%; n = 4) than in the
male germline (mean 0.76%; n = 9, unpaired Student’s t-
test, P = 0.0088, degrees of freedom, 11). With the 8F
hoppers, we observed a modest increase in the mean
remobilization efficiency with the female hoppers
(0.56%; n = 2) compared to the male hoppers (0.25%; n
= 7); however, due to the small sample size, this may
not be statistically significant (Student’s t-test P = 0.25,
degrees of freedom, 1).
The 7M pT2bGFP concatemer is located on scaffold

38 that maps to chromosome 10 (Figure 7b and 7c).
Genomic DNA harvested from representative GFP-
bright tadpoles from the 7M hopper outcrosses was ana-
lyzed by Southern blot and the novel integration sites
were cloned by EPTS LM-PCR. As noted for the remo-
bilized 8F hopper progeny above, the novel integration
events from the 7M hoppers were canonical SB-
mediated transposition events. As determined for the
remobilization events from the 8F hopper frogs, a strong
bias for local re-integration was observed for the 7M
hoppers; re-integration events on the same scaffold
(scaffold 38) as the transposon donor were cloned from
the GFP-bright tadpoles.

Discussion
SB transposons can be remobilized in X. tropicalis
Here, we demonstrate that SB transposons integrated
into the frog genome are effective substrates for remobi-
lization following re-expression of the SB transposase.
Unlike the integration events observed in the co-injec-
tion strategy that were mediated by a complex non-
canonical mechanism, the remobilized SB transposons
re-integrated via canonical SB-mediated transposition.
The observed frequency of excision and subsequent re-
integration of the parental pT2bGFP transposon was
low (on average, less than 1%). Our data in X. tropicalis
is similar to that observed in other in vitro [45] and in
vivo [19,46,47] systems, where low-copy number trans-
poson donor sites served poorly as substrates for remo-
bilization. In mammals, increasing the number of
transposon substrates by using donor sites that contain

high-order concatemers resulted in increased remobili-
zation activity [19,46]. For example, in AB1 embryonic
stem cells, a single SB transposon was ‘knocked in’ to
the Hprt gene on the mouse X chromosome and subse-
quent transient expression of SB transposase (SB10)
resulted in a transposition rate of circa 3.5 × 10-5 events
per cell per generation [45]. In mice, low-copy number
SB transposon donor sites result in a low frequency of
remobilization events that are passed through the germ-
line [19,47]. For example, single-copy SB transposon
donors result in novel re-integration sites in approxi-
mately one embryo in every one hundred (around 1%)
in an outcross of double transgenic ‘seed’ mice [47].
Increasing the number of transposon substrates by using
donor sites that contain high-order concatemers
resulted in increased remobilization activity; however,
Geurts and colleagues noted that there was not a linear
correlation between donor site copy number and remo-
bilization activity [47]. This suggests that other factors,
such as the methylation status, and other local chroma-
tin-environment factors, may also influence the ability
of integrated SB transposons to serve as substrates for
remobilization. Horie and colleagues observed that low-
copy number SB transposon concatemers served very
poorly as substrates for remobilization in mice, and that
the presence of more copies of the SB transposon in the
concatemer acted synergistically to increase the fre-
quency of excision and re-integration. With a donor site
that contained around 20 copies of the transposon sub-
strate, a remobilization rate of 1.25 transpositions per
genome per animal (125%) was observed [19]. Keng and
colleagues also reported a similar transposition fre-
quency when using double transgenic mice that con-
tained either 20 copies (1.16 transpositions per GFP-
positive mouse) or 100 copies (1.14 transpositions per
GFP-positive mouse) of the substrate transposon in the
donor concatemer [46].
In this study, we used low-copy number donor sites as

substrates for remobilization as the integration events
observed with the plasmid-mRNA co-injection strategy
were mediated by a complex, non-canonical integration
mechanism [6]. We reasoned that, if a similar non-cano-
nical mechanism were used in the remobilization step,
starting with a simple substrate would help facilitate
cloning of the remobilization event. Although the remo-
bilization frequency observed in the outcross of the dou-
ble transgenic frogs is low, the re-integration events are
canonical SB-mediated transpositions. There are several
strategies available to increase the frequency of remobili-
zation events in the frog genome. Increasing the copy
number of SB transposon substrates will likely signifi-
cantly increase the frequency of novel re-integration
events in the outcross progeny from hopper frogs.
Transgenic frogs with multiple copies of the pT2bGFP

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Figure 7 Transposon hopping from the 7M donor locus. (a) The outcross progeny from nine 7M hopper adults were scored for changes in
GFP intensity indicative of transposon remobilization. The 7M donor locus contains a concatemer of approximately eight to ten pT2bGFP
transposons on chromosome 10. The remobilization frequency is expressed as a percentage of GFP bright tadpoles observed in the GFP-positive
outcross population. 7M hopper frogs 7M♂9 and 7M♂11 are ‘functionally homozygous’ for both the transposon substrate allele and the
transposase enzyme transgene (see text for details), and display higher remobilization activity (approximately 1.8%) than their ‘heterozygous’
male hopper littermates (7M♂1, 7M♂2, 7M♂3, 7M♂5, 7M♂14, 7M♂20; approximately 0.44%). Outcross of 7M hopper 7M♀25 produced a
remobilization rate of > 4%. (b) Schematic representation of the X. tropicalis chromosomes indicating the distribution of remobilized SB
transposons. The parental 7M donor site (thick line) is located on scaffold 38 which maps to chromosome 10. Remobilization of discrete
transposons away from the 7M donor locus is represented by the grey arrows. (Not to scale.) (c) Fluorescence in situ hybridization of metaphase
chromosomes verifies that the 7M parental donor locus is located near a telomere of X. tropicalis chromosome 10. GFP: green fluorescence
protein; SB: Sleeping Beauty.

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transposon have been generated (7M and ♀622E) that
each harbor more than seven copies of the pT2bGFP
transposon [6]. The total number of transposon sub-
strates in each hopper line can be further increased by
incrossing the hopper lines with other pT2bGFP foun-
ders that contain multiple copies of the SB transposon.
In addition to donor site transposon copy number, the
transgenic transposase enzyme may also influence the
remobilization activity in the frog. The transgenic SB
enzyme frog described here was generated using the
first generation SB transposase (SB10; [24]). In recent
years, several hyperactive mutant forms of the SB
enzyme have been developed, including SB11 that has
approximately three-fold higher activity [48] and
SB100X that has a 100-fold increase in enzymatic activ-
ity when compared to SB10 [49]. In addition to the
choice of modified enzyme, different promoters with
varying transcriptional activity could be used to drive
expression of the SB transgene to enhance the rate of
germline remobilization. This may not be as simple as
finding the most powerful promoter and/or enhancer
available, as SB is sensitive to overproduction inhibition,
where increasing levels of enzyme impair the overall
transposition efficiency [48].

Why are different integration mechanisms observed with
the co-injection and the double transgenic strategies?
There are several possible reasons for the different inte-
gration mechanisms used in the two SB-mediated meth-
ods, that is, injection-mediated and breeding-mediated
transposition. First, the concentration of the substrate is
vastly higher in the injection method where approxi-
mately 75 pg (around 10.8 × 106 copies) of the plasmid
harboring the SB transposon substrate was co-injected
with SB mRNA. By comparison, the pT2bGFP 8F foun-
der used in the transgenic remobilization strategy con-
tained three copies of the SB transposon. The SB
transposase catalyzes transposition as a dimer of dimers
(tetramer) bound to the indirect IR/DR elements that

flank the transposon [32]. The massive excess of sub-
strate present in the injection-mediated strategy may
prohibit the correct assembly of transposase on the sub-
strate and may result in non-canonical enzymatic activ-
ity. Also, the integrated transposon may also be a better
substrate for SB activity due to DNA methylation and
heterochromatinization [50,51]. Recent studies have
shown that CpG methylation and supercoiling of SB
transposon-harboring plasmids result in highly efficient
transposition by the co-injection method in mammals
when compared to non-methylated linear plasmid DNA
donors [52]. Finally, the differences in the integration
mechanisms observed with the two strategies may
reflect differences in the availability of host factors for
SB transposition in the developing gametes and the
early-cleavage stage Xenopus embryos.

Potential uses for SB remobilization in X. tropicalis
The demonstration that SB transposons stably integrated
into the frog genome are effective substrates for remobi-
lization is an important step in the development of
large-scale insertional mutagenesis and enhancer- or
gene-trap screens in the frog. The breeding-based remo-
bilization strategy described here provides a simple and
robust method for generating novel transgenic lines
without the need for labor- and skill-intensive micro-
injection methodologies. The frog provides several
important advantages for transposon-based genetic
screens. First, each outcross can generate several thou-
sand progeny. The high fecundity of X. tropicalis indi-
cates that, even if the remobilization frequency is low,
multiple novel re-integration events can be identified in
a single outcross.
A second advantage is that Xenopus have a long life-

span in captivity that may reach two decades or more,
and the animals remain fertile for more than ten years.
This has important implications for remobilization stra-
tegies, as double transgenic hopper frogs can be main-
tained and outcrossed at regular intervals for many

Table 2 Integration site analysis for remobilized progeny from 7M Hoppers

Tadpole Right IR/DR flanking sequence Integration site 5’ flanking gene 3’ flanking gene

Parental 7M TGTTAGTTATTACTTAcagttgaagtcgg 38:3796832 EDEM2 PHF20

E208-91 TCATTATCAGTATATAcagttgaagtcgg 38:552620 EMILIN3 EMILIN3

3-1 GCTACTCACACAGTTAcagttgaagtcgg 13:899336 SPRY2 NDFIP2

2-7M TGTTACTGGGCACTTAcagttgaagtcgg 3:3883685 MYNN MDS1

A21A-1 AGTGTGTAGCTATATAcagttgaagtcgg 909:49452 GBP3 GBP3

C2AB-5 CGGGCCATGATGTATAcagttgaagtcgg Repeat - -

E2F3-95 GCACATAATACACATAcagttgaagtcgg Unknown - -

E220-248 CATGTAcagttgaagtcgg Unknown - -

Sequences flanking seven novel transposon insertion sites from 7M hoppers were cloned using extension primer tag selection linker mediated-PCR. The
transposon sequence (italics) is flanked by the characteristic TA dinucleotide target site duplication (bold). The flanking sequence (depicted in capital letters) was
used to interrogate the X. tropicalis genome sequence database (Joint Genome Institute X. tropicalis genome sequence assembly v4.1; [3]) to assign the
integration sites to the genomic sequence scaffolds. The genes flanking the novel integration site are indicated.

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years; male frogs can be outcrossed every two weeks and
females every two months. Laboratories with limited
animal holding space can, with a small cadre of hopper
frogs, perform large-scale enhancer- or gene-trap
screens, keeping only those tadpoles with interesting
GFP expression profiles. The long lifespan of the hopper
frogs may also have important implications if epigenetic
silencing of the transgenic transposase locus is identified
over a series of generations. Stably integrated transgenes
are frequently subjected to epigenetic silencing over suc-
cessive generations [12,53,54]. Silencing of the transpo-
sase locus would likely result in abolishment of the
hopping activity. As each generation of frog lives for
many years, having to regenerate new lines for hopping
strategies is not likely to be a problem in this species.
The propensity of SB to catalyze local hopping events

is a third advantage that can be exploited to generate
insertional mutants of genes near the donor locus. In
mice, approximately 75% of remobilized SB transposons
re-integrate within 3 Mb of the donor locus [19]. Our
data with remobilization of the 8F locus indicates that
local hopping is also a feature of the SB transposition in
X. tropicalis. Transgenic SB transposon frogs that have
integrations in gene-dense regions of the genome can be
used as donors for insertional mutagenesis strategies, as
re-integration within a nearby gene may disrupt the nor-
mal activity of that locus. In the example presented
here, the 8F transposon donor is located on scaffold 57,
which maps to X. tropicalis chromosome 6 and is synte-
nic with human chromosome 7 (Figure 6a). It is in a
gene dense region with approximately 50 genes in the 3
Mb flanking the transposon donor. The genome size of
X. tropicalis is approximately one-half that of the
human genome [3], while the gene content of the frog is
similar to that of man. Thus, the overall gene density is
relatively high in the frog. Different DNA ‘cut and paste’
transposon systems offer unique advantages for manipu-
lating the vertebrate genome. For example, the local
hopping activity of SB can be exploited to saturate the
genomic sequences flanking the transposon donor locus
with novel re-integration events. We have recently
demonstrated that Tol2 transposons stably integrated
into the frog genome are effective substrates for remobi-
lization [7]. The local hopping activity of Tol2 is less
pronounced than that of SB; approximately 20% of Tol2
re-integration events occur near the donor locus, com-
pared to approximately 80% for SB. Using nested trans-
poson substrates, with, for example, an SB transposon
cloned within a Tol2 element, genome-wide remobiliza-
tion screens could be performed using Tol2 to randomly
distribute the dual substrate throughout the genome,
with subsequent SB remobilization to locally saturate
regions of interest with novel insertion events. In the
study described here, we have used a simple ubiquitous

promoter element to drive expression of the GFP repor-
ter. Substrate transposons that harbor potentially more
mutagenic elements, such as polyadenylation trap ele-
ments [55], can be used to efficiently disrupt the activity
of the ‘trapped’ gene.
Finally, the frog is an excellent model for embryologi-

cal and biochemical studies due to its small size, simple
husbandry and the ease of manipulating embryos at all
stages of development. Furthermore, as a tetrapod spe-
cies, X. tropicalis shares a similar body plan with mam-
mals, allowing analysis of developmental processes that
are unique to higher vertebrates, such as limb and digit
pattern formation. Combining these features with a sim-
ple and robust method for generating novel transgenic
lines will provide valuable tools to apply to this highly
tractable developmental model system.

Conclusions
SB transposons stably integrated into the X. tropicalis
genome are substrates for remobilization
Co-injection of plasmid DNA harboring a SB transposon
together with mRNA encoding the SB transposase
results in efficient transgenesis of X. tropicalis. The inte-
gration events mediated by this co-injection approach
are complex and frequently contain low-order concate-
mers of the transposon. In this study, we demonstrate
that SB transposons stably integrated in the frog genome
are effective substrates for remobilization. Transgenic
frogs that express SB10 transposase in the germline
were bred with SB transposon frogs and the double
transgenic progeny were outcrossed to wild-type ani-
mals. Remobilization events were readily identified by
increased GFP expression in the offspring where the
parental transposon concatemer had been modified by
the SB10 enzyme. Integration site analysis of the GFP-
bright progeny indicated that the transposon re-integra-
tion events had occurred via a canonical cut and paste
mechanism. The rate of remobilization observed in the
frog was similar to that observed in other species when
a low copy number concatemer was used as the trans-
poson donor.

SB transposon remobilization as a tool for genetic
manipulation of X. tropicalis
The diploid frog X. tropicalis offers several advantages
for large-scale forward genetic screens in a tetrapod
model, including vast numbers of progeny per spawn,
long lifespan and availability of genomic resources
including the genome sequence and genetic map. Here,
we have demonstrated that we can exploit the cut and
paste activity of SB transposase to generate novel trans-
poson transgenics by simply breeding the double-trans-
genic hopper frogs. Novel transposon lines are readily
identified by changes in GFP reporter expression in the

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remobilized progeny compared to the parental GFP pat-
tern. The local hopping activity of SB can be exploited
to saturate genomic regions that flank the transposon
donor sites. The ability to generate thousands of pro-
geny in each outcross, combined with the ease of identi-
fying novel insertion events, will allow large-scale SB-
mediated screens to be performed in X. tropicalis.

Methods
Plasmids and generation of transgenic lines
The generation of the pT2bGFP construct and the
transgenic pT2bGFP X. tropicalis line 8F have been
described previously [6]. The pCAGGS-SB10 construct
was a gift from Dr David Largaespada [27]. A 3,613 bp
HincII/BamHI fragment containing the promoter/
enhancer and the SB10 transposase from pCAGGS-SB10
was cloned in pBluescript SK+ (pBS-SK+) to generate
pBS-CAGGS-SB10. The 2.2 kb X. laevis g1 crystallin
promoter driving dsRed construct was a gift from Dr
Robert Grainger (2.2 g1 crystallin-RFP; [28]). An
approximately 3.5 kb g1-crystallin promoter-RFP frag-
ment was PCR amplified from 2.2 g1 crystallin-RFP
using primers DSR1 5’-GTAAGCGGCAGGGTCGGA-3’
and DSR2 5’-GCCTCGAGCGATTTCGGCC-
TATTGGT-3’, cloned into pGEM-Teasy (Promega,
Madison, WI, USA), and fully sequenced, to yield
pGEM-gcRFP. An approximately 3.5 kb SacI restriction
fragment from pGEM-gcRFP encoding the g1 crystallin-
RFP reporter was cloned into the unique SacI restriction
site of pBS-CAGGS-SB10. A single clone was selected
with the two mini-genes oriented tail-to-tail in the pBS-
SK plasmid (pCAGGS-SB10;gcRFP; Figure 1a). The
pCAGGS-SB10;gcRFP construct was linearized with ScaI
and injected in vitro into X. tropicalis fertilized embryos
at the one-cell stage (500 pg of linear plasmid DNA in 3
nL of water) as described previously [6,8]. Tadpoles
were scored for expression of RFP in the lens after stage
40 [30]. RFP-positive tadpoles (27 positive from 570
injected, 4.7%) were selected and raised to adulthood
and outcrossed to determine germline transmission of
the transgene. Male frog CAGGS-SB10;gcRFP 2M pro-
duced progeny that expressed RFP robustly in the lens
and was selected for further analysis.

Husbandry and micro-injection of X. tropicalis
X. tropicalis tadpoles were maintained at 28°C in static
tanks and were staged according to Nieuwkoop and
Faber [30]. Adult animals were housed in a recirculating
aquarium at 26°C. Transgenic adult frogs were identified
by implanting a radio-frequency identification microchip
(microSensys GmbH, Erfurt, Germany) beneath the skin
of the dorsal surface of each animal [56]. The unique
16-digit alphanumeric sequence encoded on each chip
provides a convenient method for identifying individual

animals throughout their lifespan. Female X. tropicalis
animals were pre-primed with a 1:5 dilution of human
chorionic gonadotropin (hCG) overnight, and primed
the day of injection with 200 U of hCG. Fertilized eggs
were obtained by natural matings. Injected eggs were
allowed to heal at 28°C and transferred to tanks for
growth at 28°C [56]. This project was approved by St.
Jude Children’s Research Hospital’s Institutional Animal
Care and Use Committee.

RT-PCR analysis of SB expression
Total cellular RNA was isolated using the RNAeasy kit
(Clontech, Mountain View, CA, USA) from individual
RFP-positive and RFP-negative stage 40 embryos gener-
ated by outcross of CAGGS-SB10;gcRFP 2M. First
strand cDNA was synthesized and used as template for
32P-labelled PCR reactions as described previously [57].
Primers for SB10 amplification (SB3 5’-GCCGCTCAG-
CAAGGAAGA-3’ and SB4 5’-GAAGACCCATTTGC-
GACCAAG-3’) annealed at 56°C and produced a 383 bp
fragment. Primers to Xenopus a-actin were used as a
control for RNA recovery.

Western blot analysis of SB10 protein in tissues harvested
from transgenic frogs
Whole embryo or adult tissue samples were snap frozen
in a dry ice and ethanol bath and stored at -80°C. 100
μl of RIPA buffer (150 mM sodium chloride, 50 mM
tris(hydroxymethyl)aminomethane with hydrogen chlor-
ide pH 7.5, 1% (v/v) nonyl phenoxypolyethoxylethanol
(IPEGAL), 0.5% (w/v) sodium deoxycholate, 0.1% (w/v)
sodium dodecyl sulfate, 1X Complete Protease Inhibitor
Cocktail (Roche, Indianapolis, IN, USA)) was added to
the frozen samples, mixed by vortex, extracted with
Freon (200 μL of 1,1,2-trichlorotrifluroethane (Sigma-
Aldrich, St. Louis, MO, USA)) and centrifuged at 16,100
× g for 15 minutes at 4°C. The upper phase was trans-
ferred to a fresh tube and the protein concentration was
measured using the Bradford assay (Bio-Rad, Hercules,
CA, USA). Aliquots of each sample were diluted with an
equal volume of 2× Laemmli Sample Buffer containing
b-mercaptoethanol (Bio-Rad) and denatured by heating
at 100°C for 5 minutes. Proteins were separated by elec-
trophoresis on 4% to 15% (w/v) Criterion precast polya-
crylamide gels (Bio-Rad); pre-stained SDS-PAGE
standards (Bio-Rad) were used as molecular weight mar-
kers. Proteins were transferred to Hybond-P polyvinyli-
dene difluoride (PDVF; GE Healthcare Life Sciences,
Piscataway, NJ, USA) membranes at 50 V for 1.5 hours
at 4°C. Protein transfer was verified by staining the
membrane with Ponceau S. Monoclonal anti-SB trans-
posase antibody (MAB2798; R&D Systems, Minneapolis,
MN, USA) was resuspended at a final concentration of
500 μg/mL and diluted 1:500 to probe the membranes

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blocked with Superblock (Pierce, Rockford, IL, USA)
containing 0.05% (v/v) Tween 20. A secondary goat
anti-mouse horseradish peroxidase-conjugated antibody
was diluted to 1:10,000 and developed using the Chemi-
luminescent Detection System (Pierce). Membranes
were stripped with Restore Western Blot Stripping Solu-
tion (Pierce) and re-probed with a mouse monoclonal
antibody specific for Xenopus b-actin (ab8224; Abcam,
Cambridge, MA, USA) as a control for protein recovery.

Fluorescent protein expression analysis
A Leica FLIII fluorescent dissecting microscope was
used to analyze GFP and RFP expression. Digital images
were captured using a Nikon Ri1 color digital camera
and the Nikon Elements Basic Research software pack-
age (Nikon, Melville, NY, USA). Tadpoles were immobi-
lized for photography by brief anesthesia in 0.015% (w/
v) tricaine methanesulphonate.

Southern blot hybridization
Genomic DNA was harvested from individual tadpoles
by overnight proteinase K digestion at 56°C and phenol/
chloroform/isoamyl alcohol extraction using standard
protocols [8]. Genomic DNA (3 μg to 5 μg) was digested
with BglII, separated on a 0.7% (w/v) agarose gel and
transferred to Hybond N+ hybridization transfer mem-
branes (GE Healthcare Life Sciences, Piscataway, NJ,
USA). The hybridization membranes were probed with
a 32P-radiolabeled fragment of the GFP open reading
frame (approximately 700 bp) and exposed onto a GE
Healthcare Life Sciences phosphorimager screen for
detection.

Genomic PCR and transposon integration site analysis
Integration site analysis was performed EPTS LM-PCR
to the right arm (IR/DR) of the SB transposon as
described previously [6,8]. The integration sites were
verified using genomic PCR strategies with primers that
bind to scaffold sequences beyond the EPTS LM-PCR
products. PCR primers were also designed to amplify
the predicted sequences that flank the left IR/DR of the
SB transposon. All genomic PCR products were cloned
into either pGEM-T Easy (Promega) or TOPO-TA
(Invitrogen, Carlsbad, CA, USA) and sequenced. Novel
sequences were queried against the Joint Genome Insti-
tute X. tropicalis genome (version 4.1; http://genome.jgi-
psf.org/Xentr4/Xentr4.home.html) and scaffolds were
assigned to chromosomes and linkage groups based on
the genetic map developed at the University of Houston
[44].

List of abbreviations
bp: base pair; CAGGS: chicken β-actin promoter coupled with a
cytomegalovirus enhancer; EPTS LM-PCR: extension primer tag selection

linker-mediated polymerase chain reaction; FISH: fluorescence in situ
hybridization; GFP: green fluorescent protein; hCG, human chorionic
gonadotropin; IR/DR: indirect repeat/direct repeats; PCR: polymerase chain
reaction; RFP: red fluorescent protein; RT: reverse transcriptase; SB: Sleeping
Beauty; UTR: untranslated region.

Acknowledgements
We thank Cheryl Winter for animal husbandry, Drs David Largaespada and
Robert Grainger for providing plasmids (pCAGGS-SB10 and 2.2 g1-crystallin-
RFP, respectively). We thank the following St. Jude Children’s Research
Hospital shared resources: the Hartwell Center of Bioinformatics and
Biotechnology for DNA sequencing and bioinformatics support; the
Cytogenetics Lab for FISH analysis; and the Animal Resource Center. Support
for this study was provided by the National Institutes of Health (HD042994,
MH079381 to PEM and HD046661 to AKS and DEW) and by the American
Lebanese and Syrian Associated Charities (PEM).

Author details
1Department of Pathology, St Jude Children’s Research Hospital, 262 Danny
Thomas Place, Memphis, TN 38105, USA. 2Department of Biology and
Biochemistry, University of Houston, Houston, TX 77204, USA.

Authors’ contributions
DAY carried out embryo injections, scored tadpoles, performed molecular
analysis of transposon integration sites and helped prepare the manuscript.
CMK performed molecular analyses of transposon integration sites, scored
tadpoles and helped prepare the manuscript. EK performed embryo
injections, scored progeny, assisted with molecular analyses and helped with
general husbandry. HZ performed embryo injections and helped score
progeny. MRJH generated the SB10 transposase transgenic line. AKS and
DEW provided mapping data to assign sequence scaffolds to the X. tropicalis
linkage groups and/or chromosomes. PEM conceived the study, directed the
project and wrote the manuscript. All authors read and approved the final
manuscript.

Competing interests
The authors declare that they have no competing interests.

Received: 22 July 2011 Accepted: 24 November 2011
Published: 24 November 2011

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doi:10.1186/1759-8753-2-15
Cite this article as: Yergeau et al.: Remobilization of Sleeping Beauty
transposons in the germline of Xenopus tropicalis. Mobile DNA 2011 2:15.

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http://www.ncbi.nlm.nih.gov/pubmed/21552255?dopt=Abstract
http://www.ncbi.nlm.nih.gov/pubmed/21552255?dopt=Abstract
http://www.ncbi.nlm.nih.gov/pubmed/21552255?dopt=Abstract
http://www.ncbi.nlm.nih.gov/pubmed/20211730?dopt=Abstract
http://www.ncbi.nlm.nih.gov/pubmed/20211730?dopt=Abstract
http://www.ncbi.nlm.nih.gov/pubmed/16330190?dopt=Abstract
http://www.ncbi.nlm.nih.gov/pubmed/16330190?dopt=Abstract

	Abstract
	Background
	Results
	Conclusions

	Background
	Results
	Generation and analysis of transgenic X. tropicalis expressing SB10 transposase
	Generation of double-transgenic ‘hopper’ frogs
	8F hoppers
	7M hoppers

	Discussion
	SB transposons can be remobilized in X. tropicalis
	Why are different integration mechanisms observed with the co-injection and the double transgenic strategies?
	Potential uses for SB remobilization in X. tropicalis

	Conclusions
	SB transposons stably integrated into the X. tropicalis genome are substrates for remobilization
	SB transposon remobilization as a tool for genetic manipulation of X. tropicalis

	Methods
	Plasmids and generation of transgenic lines
	Husbandry and micro-injection of X. tropicalis
	RT-PCR analysis of SB expression
	Western blot analysis of SB10 protein in tissues harvested from transgenic frogs
	Fluorescent protein expression analysis
	Southern blot hybridization
	Genomic PCR and transposon integration site analysis

	Acknowledgements
	Author details
	Authors' contributions
	Competing interests
	References