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Previous Article | Next Article 
Mol Cell Biol, May 1998, p. 3081-3088, Vol. 18, No. 5
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Selective Disruption of Genes Transiently Induced in
Differentiating Mouse Embryonic Stem Cells by Using Gene Trap
Mutagenesis and Site-Specific Recombination
Irmgard S.
Thorey,
Katrin
Muth,
Andreas P.
Russ,
Jürgen
Otte,
Armin
Reffelmann, and
Harald
von Melchner*
Laboratory for Molecular Hematology,
Department of Hematology, University of Frankfurt Medical School,
Frankfurt am Main, Germany
Received 21 November 1997/Returned for modification 15 January
1998/Accepted 28 January 1998
 |
ABSTRACT |
A strategy employing gene trap mutagenesis and site-specific
recombination (Cre/loxP) has been used to identify genes
that are transiently expressed during early mouse development.
Embryonic stem cells expressing a reporter plasmid that codes for
neomycin phosphotransferase and Escherichia coli LacZ were
infected with a retroviral gene trap vector (U3Cre) carrying coding
sequences for Cre recombinase (Cre) in the U3 region. Activation of Cre expression from integrations into active genes resulted in a permanent switching between the two selectable marker genes and consequently the
expression of 
-galactosidase (-Gal). As a result, clones in which
U3Cre had disrupted genes that were only transiently expressed could be
selected. Moreover, U3Cre-activating cells acquired a cell autonomous
marker that could be traced to cells and tissues of the developing
embryo. Thus, when two of the clones with inducible U3Cre integrations
were passaged in the germ line, they generated spatial patterns of
-Gal expression.
| |
INTRODUCTION |
Fusions between promoterless genes
that encode an easily assayable gene product and the controlling
elements of cellular genes have proved valuable tools for studying gene
function and regulation in mammalian cells. Several types of vectors,
referred to as "gene traps," that insert a promoterless reporter
gene into mostly random chromosomal sites, including transcriptionally
active regions, have been developed. By selecting for gene expression,
recombinants in which the reporter gene is fused to the regulatory
elements of an endogenous gene are obtained. Transcripts generated by
these fusions faithfully reflect the activity of a disrupted cellular gene and serve as a molecular tag to clone any gene linked to a
specific function (for reviews, see references 9, 13,
14, and 37). Particularly useful in this
regard have been mouse embryonic stem (ES) cell lines which can pass
genes introduced in vitro to transgenic offspring in vivo (1, 15,
21, 34).
Approximately 50% of genes disrupted in ES cell lines after infection
or electroporation of gene trap vectors generated recessive phenotypes
in mice (7, 32, 35). Based on this high efficiency of gene
inactivation, it appears possible to isolate cell lines with
integrations in most expressed genes (2 × 104 to
4 × 104). However, it would not be practical to pass
all mutations to the germ line since many mutations will involve genes
of lesser significance. Moreover, genes that are not expressed in ES
cells generally go unobserved. Therefore, it would be useful to
prescreen mutagenized ES-cell clones for mutations that affect genes
involved in significant biological processes. To this end, three types of screens have been developed.
One approach involves sequencing DNA regions immediately adjacent to a
gene trap vector. Comparison of the flanking sequences with nucleic
acid databases reveals instances in which the gene trap has disrupted
known genes (12, 37). A second approach uses a marker gene
which can be easily visualized in the developing embryo. Analysis of
pattern formation in chimeric or transgenic mice identifies mutations
in developmentally regulated genes (6, 7, 39). A third
approach relies on a reporter gene that requires an N-terminal signal
sequence for expression. This effectively selects for mutations in
genes that encode secreted proteins (31).
However, none of these strategies specifically selects for mutations in
genes that are only transiently expressed. Since during mouse
development most genes are expressed in a temporally and spatially
restricted manner, it would be advantageous to develop a gene trap
approach that enables the recovery of integrations into transiently
expressed genes. To this end, a gene trap expressing the site-specific
recombinase Cre was used to induce a permanent switching between two
selectable marker genes expressed from a constitutive promoter. Since
recombination uncouples the expression of the marker gene from the
Cre-activating cellular promoter, genes that are expressed in a
temporally restricted manner can be identified. Moreover, promoter
uncoupling results in the acquisition of a cell autonomous marker which
facilitates the analysis of cell fate and migration in the developing
embryo.
In this paper we describe five ES-cell clones with gene trap
integrations in genes that are induced during differentiation. Two of
these clones generated spatial patterns of gene expression in
transgenic embryos.
| |
MATERIALS AND METHODS |
Plasmids.
The ppgklxLacZ vector was derived from
ppgklxtkneoIL3 (24) by replacing the genes encoding tkneo
and interleukin 3 (IL-3) with coding sequences for Neo and LacZ,
respectively. Briefly, a loxPLacZ fragment was assembled in pGEM30 by
blunt-end ligation of the LacZ gene (derived from U3LacZ
[20]) into the EcoRI site of the
loxP flanking polylinker (24). loxPLacZ was then
cloned as a SalI/XhoI fragment into the
XhoI site of pSBC-2 (3) upstream of the simian
virus 40 polyadenylation site. A fragment extending from the
XmnI site of ppgklxtkneoIL3 to the NheI site of
the downstream loxP site was isolated by a partial digestion
and cloned into the respective sites of pSBC-2-loxLacZ to obtain
ppgklxtkneoLacZ. Finally, ppgklxneoLacZ was obtained by replacing
the tkneo fusion gene with neo by using blunt-end cloning
and the RsrII and BglII restriction
sites of ppgklxtkneoLacZ. The gene trap construct pGgU3Creen(
) was
obtained as described previously (24).
Cells and viruses.
D3 ES cells were grown on irradiated (32 Gy) mouse embryo fibroblast feeder layers in Dulbecco's modified Eagle
medium supplemented with 15% (vol/vol) preselected and
heat-inactivated fetal calf serum (Linaris, Bettingen, Germany), 100 mM
nonessential amino acids (Gibco), 0.1 mM -mercaptoethanol (Sigma),
1,000 U of leukemia inhibitory factor (LIF) (ESGRO; Gibco/BRL) per ml,
and 5 mg each of penicillin and streptomycin per ml. In some
experiments differentiation was induced by withdrawing LIF and feeder
layers whereas in others differentiation was allowed to proceed in
bacterial plates with Dulbecco's modified Eagle medium supplemented
with 20% fetal calf serum, 0.3 mM -mercaptoethanol, and 100 mM
nonessential amino acids.
ppgklxneoLacZ was transduced into D3 cells by electroporation with a
Bio-Rad Gene Pulser at 240 V and 500 µF. Following incubation for
24 h, cells were selected for 7 days in 320 µg of active G418 (Gibco/BRL) per ml.
Infection of ES cells with the U3Cre gene trap virus was performed by
incubating 150 ES cells with 50 µl of virus-containing supernatant
for 2 h as described previously (24).
Amplification and cloning of upstream sequences.
Inverse PCR
from genomic DNAs was performed with the Cre-specific primers described
previously (24). 5' rapid amplification of cDNA ends (RACE)
was performed with 1 µg of total RNA by using the 5' RACE kit from
Gibco/BRL according to the manufacturer's instructions. The specific
Cre reverse primers were as follows: 5'-GGTATGCTCAGAAAACGCCTG-3',
5'-CGAACCTCATCACTCGTTGCATC-3' (nested), and
5'-CGGTCAGTAAATTGGACACCTTCC-3' (nested). Amplification
reactions were performed in a Perkin-Elmer thermocycler, and amplified
DNA was cloned into the pGEMT vector (Promega) as described previously (24). Inserts were sequenced with an ABI 310 genetic
analyzer (Perkin-Elmer).
Nucleic acid hybridization analyses.
DNA and RNA
hybridizations were performed on Hybond N or Hybond N+ membranes
(Amersham) by using [32P]dCTP-labeled probes and a random
priming labeling kit (Rediprime; Amersham). Blots either were scanned
with a PhosphorImager (Molecular Dynamics) and analyzed with IPLabGel
software (Molecular Dynamics) or were exposed to Kodak-Biomax
autoradiography film.
Histochemical analysis of LacZ expression.
Cells were
stained for 2 h at 37°C with a solution of 1 mg of
5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-Gal)
per ml in phosphate-buffered saline after fixation for 15 min in a solution of 2% formaldehyde and 0.2% glutaraldehyde.
Embryos and fetuses were stained overnight at 37°C after fixation for
60 min and preincubation for 30 min in phosphate-buffered saline
solution containing 0.15 mg of chloroquin per ml, 10 mM potassium
ferricyanide, 10 mM potassium ferrocyanide, 2 mM magnesium chloride,
and 0.2% Triton X-100 (pH 7.4) to reduce endogenous background, i.e.,
-Gal. Stained embryos were embedded in glycol methacrylate (JB-4;
Polysciences) and blocks were cut to 3-µm thicknesses with glass
knives on an ultramicrotome (LKB) as described recently
(16). Sections were counterstained with nuclear fast red,
mounted on clean glass slides, and analyzed by standard microscopy.
Nucleotide sequence accession numbers.
GenBank
accession numbers for the gene trap flanking sequences are as
follows: 1C7a, emb|AJ2237718; 1C7b, emb|AJ223719; 2C2a,
emb|AJ223720; 2C2b, emb|AJ223721; 2E12, emb|AJ223722; 7G4,
gb|L20255; and 8G3, emb|AJ223723.
| |
RESULTS |
Construction of an ES cell line amenable to selectable marker
switching by Cre recombinase.
To obtain an ES cell line that would
allow Cre recombinase to switch two selectable marker genes, we
electroporated D3 ES cells with the expression plasmid ppgklxneoLacZ.
ppgklxneoLacZ consists of two tandemly arrayed selectable marker genes
that are expressed from a pgk promoter (Fig.
1). The 5' gene codes for neomycin
phosphotransferase and is flanked by two loxP recombination targets in identical orientation. The 3' gene codes for
-galactosidase (-Gal) (20) and terminates in a
simian virus 40 polyadenylation sequence. To suppress LacZ translation
from dicistronic transcripts, two tandem copies of bovine growth
hormone polyadenylation sequence were inserted downstream of the
neo gene. Thus, cells expressing ppgklxneoLacZ, albeit
neomycin resistant, should not express LacZ. Since Cre
recombinase excises the sequences flanked by loxP
(25, 26), Cre expression was expected to delete
the neo gene and thereby place the lacZ gene just
downstream of the pgk promoter. As a result, cells would lose neomycin
resistance and start synthesizing -Gal (Fig. 1).
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FIG. 1.
Mechanism of LacZ activation by U3Cre integrations into
transiently expressed genes. Cre expressed from cell-provirus fusion
transcripts (left) excises neo from ppgklxneoLacZ (right)
and places lacZ downstream of the constitutive pgk promoter.
This induces synthesis of -Gal which is independent of U3Cre
expression. For further explanation see the text.
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|
Several ppgklxneoLacZ-expressing cell lines were isolated in G418 and
assayed individually for background -Gal activity by X-Gal staining.
Four of 10 cell lines tested consistently failed to stain with X-Gal
(LacZ
) even after prolonged periods in culture.
When induced to differentiate by withdrawing of LIF and feeder
layers, the cells continued to stain negative, indicating that the
LacZ phenotype is stable (data not shown). One cell
line expressing a single copy of ppgklxneoLacZ (plnLacZ13) was
selected for further analysis. When transfected with a plasmid
expressing Cre recombinase (pMCCre [10]), the
plnLacZ13 cells stained positive for -Gal and harbored
recombined reporter plasmids (data not shown).
Recombined plnLacZ13 expresses LacZ ubiquitously in the early
embryo.
Since one goal of this study was to devise a
system that would enable analysis of cell fate and migration in the
developing embryo, it was important to investigate whether a
recombined reporter plasmid would express LacZ in all embryonic
tissues. Therefore, we injected the ppgklxneoLacZ-expressing
plnLacZ13 cells into C57BL/6 blastocysts and transferred these into the
uteri of NMRI mouse recipients. Chimeric males were mated with C57BL/6
females and agouti offspring carrying the transgene were identified by tail blotting. Mice heterozygous for the transgene were crossed to a
transgenic Cre deleter strain which has been shown to
express the recombinase ubiquitously (29). X-Gal staining of
the developing embryos showed that in doubly transgenic mice -Gal
was expressed ubiquitously. However, virtually no -Gal expression
was observed in embryos carrying only one transgene (Fig.
2). Although plnLacZ13 mice showed some
-Gal expression within a small circumscribed area of the
forebrain, presumably due to a slight leakiness of the reporter
plasmid, this background was clearly distinguishable from positive
controls on microscopic tissue sections (data not shown).
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FIG. 2.
In vivo recombination of ppgklxLacZ in transgenic
plnLacZ13 mice. Embryos resulting from crosses between heterozygous
plnLacZ13 and Cre deleter strains were recovered at the
indicated stages of gestation (E = day) and stained with X-Gal as
described in Materials and Methods. Embryos in each panel are
littermates.
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|
Ubiquitous expression of -Gal was confirmed for
plnLacZ13mice by staining embryonic tissue sections,
including those from the liver, kidney, intestine, heart, limb,
and rib cartilage (data not shown). This suggested that
ppglxneoLacZ had integrated into a chromosomal locus that does not
significantly restrict expression. Moreover, no obvious
loss-of-function abnormalities were observed in homozygous plnLacZ13
mice, indicating that the integration did not disrupt any vital genes.
A U3Cre/plnLacZ13 integration library preselected in G418 contains
clones with inducible LacZ expression.
A library of approximately
1 × 105 to 2 × 105 independent
proviral integrations was constructed in microtiter plates by
infecting plnLacZ13 cells (
150 cells per well) with the
retroviral gene trap vector U3Cre, which contains a promoterless Cre
recombinase gene in the U3 region of the long terminal repeat (LTR). As
has been shown in previous studies, activation of this type of gene trap occurs from integrations in or near 5' exons and does not require
in-frame fusions with the coding sequences of cellular genes (12,
24, 36, 38).
Since activation of Cre expression from integrations into transcribed
genes results in loss of the neomycin resistance gene (Fig. 1), the
library was first selected in G418. This was expected to eliminate all
integrations into genes that express Cre to levels high enough to cause
recombination. Thus, surviving cells were likely to have provirus
integrations in transcriptionally inactive chromosomal regions
(including silent genes) or in genes expressed too weakly to cause
recombination.
To identify cell pools with inducible U3Cre integrations,
aliquots removed from each well were allowed to differentiate for 4 days without LIF or feeder layers. This period was chosen
because we have found in earlier experiments that by this time
over 50% of the cells express the mesodermal marker brachyury,
which is indicative of gastrulation (11, 33). Since
gastrulation corresponds to cellular diversification, we expected
enhanced gene activity and therefore a higher fraction of genes that
would be accessible to gene trap mutagenesis. Of 960 pools,
44 stained positive for -Gal. Upon retesting, nine pools
expressed -Gal even before differentiation, indicating that G418
selection did not completely eliminate the integrations into expressed
genes. Five pools with inducible -Gal expression and one pool with
constitutive -Gal expression were selected to isolate the cell lines
2E12, 1C7, 8G3, 2H7, 2C2, and 7G4, respectively.
To verify clonality, genomic DNAs were cleaved with
BamHI and hybridized on Southern blots to a
Cre-specific probe. Since BamHI cleaves within the 5' third
of Cre, each nonrearranged provirus should generate three hybridizing
fragments, i.e., a constant fragment of 2.6 kb derived from the
provirus and two variable fragments representing sequences extending
from the BamHI sites in the LTRs to the BamHI
sites in the 5' and 3' flanking cellular DNA, respectively. Figure
3 (left panel) shows that each clone contained one to three nonrearranged proviruses, which is consistent with a multiplicity of infection of ~1.5.
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FIG. 3.
U3Cre provirus integrations and site-specific
recombination in clones isolated after induction of differentiation.
(Upper panel) Structure of U3Cre proviruses (left) and reporter
plasmids (right) before and after recombination. (Lower panel) Southern
blot analysis of clones recovered from the plnLacZ13 integration
library following induction of differentiation. Genomic DNAs extracted
from individual clones before (u, undifferentiated) and after (d,
differentiated) differentiation were cleaved with BamHI,
fractionated on agarose gels, blotted onto nylon filters, and
hybridized to 32P-labeled Cre-specific (left) or
pgk-specific (right) probes. The large-molecular-size bands hybridizing
to pgk represent the endogenous pgk promoter.
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All clones generated differentiated progeny that stained positive for
-Gal, indicating that U3Cre expression was induced. However, the
fraction of LacZ+ cells among the progeny of each clone
varied from as high as 100% in 7G4 cells to 25% in 1C7 cells (Fig.
4). Assuming that differentiating cells
gradually lose their proliferative potential, this staining
heterogeneity is likely to reflect gene activation in distinct
precursor cells. Thus, a less mature progenitor would yield higher
numbers of LacZ+ cells than any of its more differentiated
progeny.
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FIG. 4.
Induction of -Gal expression in differentiating
U3Cre-expressing clones. Cells were induced to differentiate by the
withdrawal of LIF and feeder layers for 4 days. Cells were stained with
X-Gal before (left panels) and after (right panels) differentiation and
examined by light microscopy at a ×100 magnification. Samples are
representative of four independent inductions.
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To confirm recombination, genomic DNAs were cleaved with
BamHI and hybridized on Southern blots to a pgk-specific
probe. As shown in Fig. 3 (right panel, top), BamHI cuts
within the 5' ends of pgk and lacZ, such that nonrecombined
cells generate an internal hybridizing fragment of 2.7 kb. Since this
fragment accommodates all sequences flanked by loxP, its
deletion should generate a residual fragment of 0.6 kb. Figure 3 (right
panel, bottom) shows that each differentiated clone contained this
fragment, indicating that ppgklxneoLacZ had recombined. However, as
expected from the heterogeneous staining patterns, recombination was
mostly incomplete.
Recombination of ppgklxneoLacZ is caused by inducible
cell-provirus fusion transcripts.
To ascertain that Cre
was expressed from cell-provirus fusion transcripts, Northern blots
with RNAs from differentiating clones were hybridized to a Cre-specific
probe. U3 gene trap integrations expressed in ES cells typically
generate cell-provirus fusion transcripts of variable sizes that
initiate in a nearby cellular promoter and terminate in the
polyadenylation site of the 5' LTR. In some cases, a second
transcript which initiates at the same cellular promoter but terminates
in the polyadenylation site of the 3' LTR is also seen (Fig.
5, upper panel) (2, 35).
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FIG. 5.
Analysis of cell-provirus fusion transcripts in clones
with inducible LacZ expression. (Upper panel) Predicted transcripts
from U3Cre integrations into expressed genes. (Lower panels) Northern
blot analysis of cell-provirus fusion transcripts in differentiating
clones. RNAs were extracted from individual clones after incubation of
the cells for various intervals in bacterial plates without LIF or
feeder layers. Twenty micrograms of total RNA (7G4, 2E12, 8G3, and 2H7)
and 5 µg of polyadenylated RNA (2C2) were fractionated on
formaldehyde-agarose gels, blotted onto nylon filters, and hybridized
to 32P-labeled Cre or L32 (19) probes.
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|
As expected, each clone expressed cell DNA-provirus fusion
transcripts which, in all but the 7G4 cells, were induced by
differentiation. More importantly, clones 2E12 and 8G3 expressed the
fusion transcripts only transiently (Fig. 5, lower panel).
Interestingly, U3Cre expression in clone 8G3 was induced twice, on days
1 and 7. This pattern is reminiscent of the expression of certain
cytokine genes in differentiating ES cells (28).
Sequences flanking the U3Cre proviruses hybridize to single-copy
genes.
To investigate whether U3Cre proviruses had disrupted
single-copy genes, upstream proviral sequences were isolated by inverse PCR or 5' RACE and sequenced (8, 36). All sequences showed typical cell DNA-provirus junctions and varied in size from 4 to 500 nucleotides (Table 1). While the
sequences from inducible integrations showed no homology to known genes
or expressed sequence tags, the 7G4 flanking sequence was 100%
identical with the 5' end of the stathmin cDNA (Table 1 and data not
shown). Stathmin is a cell cycle-regulated, tubulin binding protein
which has been previously shown to be highly expressed in proliferating
cells (4, 17, 23).
Each of the cloned flanking sequences hybridized to a single
BamHI restriction fragment in wild-type DNA, indicating that they were derived from single-copy genes. Additional hybridizing fragments representing the allele occupied by the provirus were generated in each corresponding parental clone (data not shown).
-Gal expression patterns in transgenic embryos.
To test
whether the selected clones were still totipotent, we individually
injected each into blastocysts and mated the resulting chimeras with
C57BL/6 mice. Analysis of the offspring indicated that three clones had
contributed to the germ line despite extensive in vitro
manipulation. Moreover, the transgenes were inherited in each
case in an autosomal Mendelian fashion (Table 1).
To examine whether the inducible gene trap integrations were also
inducible in vivo, mice bearing the U3Cre but not the
ppgklxneoLacZ transgene were mated with homozygous
plnLacZ13 mice. Developing embryos were recovered after
8.5 days of gestation and stained for -Gal expression. Two different
lines of transgenic mice were used as positive controls. One strain
originated from a doubly transgenic plnLacZ13/Cre
deleter mouse from which it received a recombined reporter plasmid
through the germ line. The other strain was derived from clone 7G4,
which expresses Cre constitutively. In both cases, embryos stained
completely with X-Gal, indicating ubiquitous recombination of
ppgklxneoLacZ. In contrast, 8G3 embryos did not express -Gal in
extraembryonic tissues (Fig. 6). On
stained embryo sections, LacZ+ cells were missing from the
yolk sac and the amnion, indicating that Cre was activated after
extraembryonic lineage segregation (Fig. 6). However, the overall
staining pattern was a mosaic between LacZ+ and
LacZ cells. Since no mosaic was detected in the positive
controls, the pattern may have been caused by an independent activation of Cre in different lineages. Alternatively, the short-lived fusion transcripts expressed in 8G3 cells (Fig. 5) may have prevented ubiquitous recombination of ppgklxneoLacZ. As has been shown
previously, Cre recombinase seems to require at least 72 h to
recombine 80% of its targets (33a).
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FIG. 6.
-Gal expression patterns in transgenic embryos.
Embryos resulting from crosses between heterozygous 7G4, 2C2, or 8G3
mice and homozygous plnLacZ13 reporter mice were recovered at 8.5 days of gestation and stained with X-Gal. A, whole mounts; B, heart; C,
intestinal stalk; D, somites; E, yolk sac. pln, plnLacZ13; Cre,
Cre deleter. The whole mounts and tissue sections were
examined by light microscopy at ×20 and ×100 magnifications,
respectively. Cell clusters in 2C2 are marked by arrowheads. Note that
despite the presence of recombined reporter plasmids, the endodermal
component of the extraembryonic membranes does not express LacZ.
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In 2C2 embryos, LacZ+ cells were seen in both the embryo
proper and extraembryonic tissues (Fig. 6). However, unlike the
positive controls, the LacZ+ cells appeared in clusters
throughout the extraembryonic membranes. Although suggestive of a
progenitor-progeny relationship, these clusters most likely reflect Cre
activation in distinct embryonic cell lineages.
| |
DISCUSSION |
This study exploited the combined features of gene trap
mutagenesis and site-specific recombination to identify genes that are
induced during early mouse development. ES cells expressing a specific
reporter construct were infected with gene trap retroviruses containing
coding sequences for Cre recombinase in the U3 region. By using the
-Gal gene as a conditionally expressed marker gene, cell clones in
which Cre was expressed from transcripts initiating in the flanking
cellular DNA could be identified. Five inducible U3Cre integrations
were selected during ES-cell differentiation, two of which were passed
to the germ line. Since U3Cre expression was also induced during
embryonic development, the results confirm previous studies showing
that genes regulated in vitro are also regulated in vivo (18, 20,
22, 27, 30, 32).
Analysis of provirus flanking sequences derived from the inducible
clones identified integrations into as-yet-unidentified single-copy
genes. Although recent results seem to suggest that up to 60% of all
gene trap integrations are integrations into previously characterized
genes or expressed sequence tags (12), we believe that the
present strategy does not favor recovery of integrations into known
genes. This is because selection is applied for integrations into 5'
exons of transiently expressed genes, both of which are
underrepresented in conventional cDNA libraries.
The gene trap approach described here has several unique advantages.
Unlike previously described strategies in which gene trap insertions
are restricted to expressed genes, switching between two selectable
marker genes by means of Cre recombinase allows enrichment for
integrations into silent genes. By first eliminating integrations into
active genes, it is possible to screen large pools of recombinant
clones for integrations into regulated genes. This circumvents the
laborious analysis of individual clones (6, 20, 35, 39).
The most important feature of the system is the recombinase-induced
uncoupling between -Gal and Cre expression. As a result, LacZ
continues to be expressed even in the absence of Cre recombinase, thereby providing the means for the recovery of transiently expressed genes. In line with this, two of the five fusion transcripts analyzed in this study were present only transiently in differentiating cells.
Since most developmentally regulated genes are expressed in a
temporally and spatially restricted manner, the strategy is ideal for
the molecular analysis of mouse development.
A further consequence of promoter uncoupling is the acquisition of an
autonomous marker by the gene trap-activating cells. Such a genetic
marker could be useful for demarcating cell lineages and for tracking
cell fate and migration in the developing embryo. Although the LacZ
expression patterns described in this study are reminiscent of gene
trap activations in many different lineages, activations at later
stages of differentiation are likely to be more restricted and thus
earmark the progenitors of more specialized cells and tissues.
Staining patterns will also provide valuable clues as to which tissues
or organs should be examined for loss-of-function abnormalities induced
by gene disruptions. This feature is particularly helpful in cases
where mutations generate only subtle phenotypes.
Finally, the strategy used here is prone to yield strains of mice in
which Cre expression is controlled by tissue-specific promoters. Such
strains should be a valuable tool for targeted gene disruptions in
special cells or tissues.
| |
ACKNOWLEDGMENTS |
We thank Frieder Schwenk and Klaus Rajewsky for providing the
Cre deleter mouse, André Sobel for the stathmin cDNA,
and Christina Friedel and Sabine Reindel for technical assistance.
This work was supported by grants from the Deutsche
Forschungsgemeinschaft, Bonn, Germany, and the VW Foundation,
Wolfsburg, Germany, to H.V.M.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory for
Molecular Hematology, Department of Hematology, University of Frankfurt Medical School, Theodor-Stern-Kai 7, 60590 Frankfurt am Main, Germany.
Phone: 49-69-63016696. Fax: 49-69-63017463. E-mail:
melchner{at}em.uni-frankfurt.de.
Present address: Wellcome/CRC Institute of Cancer and Developmental
Biology, Cambridge CB2 1QR, United Kingdom.
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Abstract
Introduction
