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 Previous Article | Table of Contents | Next Article 
Blood, Vol. 92 No. 12 (December 15), 1998:
pp. 4622-4631
Expression Trapping: Identification of Novel Genes Expressed in
Hematopoietic and Endothelial Lineages by Gene Trapping in ES Cells
By
William L. Stanford,
Georgina Caruana,
Katherine A. Vallis,
Maneesha Inamdar,
Michihiro Hidaka,
Victoria L. Bautch, and
Alan Bernstein
From the Program in Molecular Biology and Cancer, Samuel Lunenfeld
Research Institute, Mount Sinai Hospital, Toronto, Ontario, Canada; the
Ontario Cancer Institute, Toronto, Ontario, Canada; the Department of
Molecular and Medical Genetics, University of Toronto, Toronto,
Ontario, Canada; and the Department of Biology, University of North
Carolina, Chapel Hill, Chapel Hill, NC.
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ABSTRACT |
We have developed a large-scale, expression-based gene trap strategy
to perform genome-wide functional analysis of the murine hematopoietic
and vascular systems. Using two different gene trap vectors, we have
isolated embryonic stem (ES) cell clones containing lacZ
reporter gene insertions in genes expressed in blood island and
vascular cells, muscle, stromal cells, and unknown cell types. Of 79 clones demonstrating specific expression patterns, 49% and 16% were
preferentially expressed in blood islands and/or the vasculature, respectively. The majority of ES clones that expressed lacZ in blood islands also expressed lacZ upon
differentiation into hematopoietic cells on OP9 stromal layers.
Importantly, the in vivo expression of the lacZ fusion products
accurately recapitulated the observed in vitro expression patterns.
Expression and sequence analysis of representative clones suggest that
this approach will be useful for identifying and mutating novel genes
expressed in the developing hematopoietic and vascular systems.
© 1998 by The American Society of Hematology.
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INTRODUCTION |
THE PHYSICAL AND genetic analysis of
mammalian genes is yielding a vast amount of information concerning the
80,000 or so proteins encoded by our genomes. Clearly, a major
challenge for the immediate future will be to understand the individual functions of each of these proteins and to place them within the correct molecular circuitry in the appropriate cell types. These insights will provide the basis for understanding both normal physiological processes and human disease. Although many mammalian proteins are related in sequence and biochemical functions to proteins
found in other more experimentally tractable organisms, knowledge of
the biological function of these proteins will require direct analysis
within the context of an intact mammal, because the different members
of large mammalian gene families function in diverse cell types during
development and in the adult. In addition, sequence similarity or
homology is neither a necessary nor a sufficient predictor of
similarity of biological function.
The large amount of genetic information in mammalian organisms and the
cellular complexity of the developing embryo require new experimental
approaches that can rapidly and efficiently identify and analyze genes.
In the mouse, the existing repertoire of naturally occurring and
induced mutations has provided important insights into the molecular
mechanisms that regulate embryonic development and cellular
differentiation within the hematopoietic system.1-3 However, positional cloning of each of these mutations is still a
significant and labor-intensive undertaking.
The contemporaneous development of totipotent embryonic stem (ES) cell
lines and homologous recombination in mammalian cells has provided an
entirely new approach to generate new mutations in vitro before
introduction of these mutations into the mouse germline.4,5
However, targeted mutagenesis is also labor intensive and
time-consuming. In addition, gene targeting requires prior detailed
knowledge of the sequence and genomic organization of each gene and
hence is not easily applicable to genome-wide approaches.
A third strategy involves the random insertion of exogenous DNA into
single sites in the mammalian genome.6 When applied to ES
cells, this insertional mutagenesis approach, or gene trapping, provides a genome-wide strategy for functional genomics in a mammal. In
this report, we have combined gene trapping with the developmental potential of ES cells to differentiate in vitro into a wide variety of
distinct cell lineages7-9 to trap genes that are expressed in hematopoietic and vascular endothelial cells. This experimental approach, which we have termed expression trapping, offers a novel strategy to identify, mutate, and characterize large numbers of genes
on the basis of their cell lineage-specific expression.
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MATERIALS AND METHODS |
Vectors.
Two gene trap vectors were used for this study and are shown in
Fig 1. The vector PT1-ATG (PT1 henceforth)
contains the En-2 splice acceptor site positioned immediately
upstream of the lacZ reporter gene with an ATG translational
start site.10 Immediately downstream of the lacZ
gene, the phosphoglycerate kinase-1 (PGK-1) promoter
drives the bacterial neomycin-resistance (neo) gene. The vector GT1.8geo contains the En-2 splice acceptor site
immediately upstream of a lacZ-neo fusion gene.11
The point mutation in the neo fragment of
SA geo12 is not contained in GT1.8geo vector, thereby
allowing neomycin resistance at a lower level of endogenous gene
expression than the SAgeo vector.
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| Fig 1.
Schematic diagram depicting gene trap screening strategy.
Two gene trap vectors were used. The PT1 vector contains a promoterless
lacZ gene immediately downstream of a splice acceptor (SA) site
and the neoR gene driven by the PGK-1
promoter. Although not all neoR colonies represented
trapped genes, all genes could be trapped regardless of their
expression in undifferentiated ES cells using the PT1 vector. The
GT1.8geo vector contains a promoterless lacZ-neoR
(-geo) fusion gene immediately downstream of an
SA site. Although all neoR colonies represented trapped
genes, only genes expressed in undifferentiated ES cells could be
trapped. ES cells were electroporated with either vector and
G418R clones were picked into 96-well plates and grown to
confluency. The clones were passaged 1:3 into two 96-well plates and
one set of 24-well plates. The cells from one 96-well plate were
frozen, and the cells from the second 96-well plate were assayed for
lacZ expression. The colonies in the 24-well plates were
treated with dispase and then transferred to suspension 24-well plates
and grown in suspension for 3 days; EBs were then transferred to
48-well tissue culture (TC) plates. Cultures were fed every other day
and analyzed for lacZ expression 8, 12, and 16 days after
dispase treatment. Clones exhibiting expression patterns were thawed
and grown for RNA isolation, RACE polymerase chain reaction (PCR) and
sequencing, and/or OP9 coculture and subsequent lacZ
expression, and/or diploid aggregation for in vivo lacZ
expression analysis and germline transmission.
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Generation of trapped ES cell lines.
R1 ES cells were maintained on primary embryonic fibroblasts as
previously described.13 After electroporation and selection in G418, drug-resistant colonies were transferred to 96-well plates and
expanded to confluency. Clones were passaged to two 96-well plates and
one set of 24-well plates. Once clones reached confluency, one 96-well
plate was frozen, the second 96-well plate was assayed for
-galactosidase (-gal) expression, and the 24-well plates were
used for attached EB differentiation cultures. Expression of the
lacZ reporter gene was carefully determined both in
undifferentiated and differentiated ES cells. Clones with observable
expression patterns were refrozen and, in some cases, reanalyzed. In
addition, the expression patterns were photographed and cataloged.
Reporter gene expression.
-gal activity of cultures was detected as follows. Cells were rinsed
in 100 mmol/L Na2HPO4 (pH 7.5) and then fixed
in 0.2% glutaraldehyde, 5 mmol/L EGTA, 2 mmol/L MgCl2, and
100 mmol/L Na2HPO4 for 5 minutes. The cells
were washed 3 times for 5 minutes each in 2 mmol/L MgCl2,
0.02% NP-40, and 100 mmol/L Na2HPO4. The cells
were stained with X-gal overnight at 37°C. -gal activity was
detected in embryos as described above, except that the fixative included 1.5% formaldehyde and embryos were fixed for 30 minutes to 1 hour and washed 3 times for 15 minutes each wash.
Attached EB screen.
ES cells were allowed to differentiate into attached EBs as previously
described,14 with several modifications. Clones were grown
to confluency in 24-well plates, treated with dispase (1:1 dilution in
phosphate-buffered saline [PBS]; Collaborative Research VWR, Mississauga, Ontario, Canada), washed 3 times in PBS, and grown in
suspension in Ultra Low Cluster 24-well plates
(COSTAR, Cambridge, MA) in ES media without
Leukemic Inhibitory Factor (LIF). On day 3 after dispase
treatment, 5 to 10 embryoid bodies were transferred to 48-well tissue
culture plates (Falcon, Mississauga, Ontario, Canada).
Cultures were fed every other day with fresh media. -gal activity
was determined on days 8, 12, and 16 after dispase.
OP9 induction assay.
ES cells were allowed to differentiate on the OP9 stromal cell line as
previously described,9 with several modifications. ES
clones were differentiated on OP9 stroma in replica wells of 6-well
plates (104 ES cells/well) for 5 days to generate
mesodermal colonies. A single-cell suspension was prepared using
trypsin from one well for each clone, and 105 mesodermal
cells were replated onto OP9 stroma in two wells of a 6-well plate and
grown for 3 days. On day 8, nonadherent hematopoietic cells were
transferred from both wells to one new well for an additional 3 days.
-gal activity was determined on mesodermal cells on the duplicate
day 5 OP9 plate and on adherent hematopoietic cells on days 8 and 11.
5 RACE.
RNA was prepared from either undifferentiated or differentiated cells
using Trizol (GIBCO/BRL, Grand Island, NY) according to
the manufacturer's instructions. 5 RACE was performed using the
5 RACE kit (GIBCO/BRL), according to manufacturer's
instructions with modifications previously described.15
5 RACE products were subcloned into the CloneAmp plasmid
(GIBCO/BRL) and sequenced using the Sequenase kit (Pharmacia, Uppsala,
Sweden). Sequences were analyzed by comparison to the
nonredundant GenBank and EST of NCBI using the BLASTN
program (www.ncbi.nlm.nih.gov/BLAST/).
Generation of chimeras.
ES cells were aggregated with diploid embryos as
described,16 transferred into pseudo-pregnant ICR females,
harvested at embryonic day (e) 9.5 to 14.5, and stained for -gal
activity. About half of the diploid embryos were allowed to mature to
term for germline transmission. Chimeric males were bred to ICR
females, and tail DNA of F1 and F2 offspring
was analyzed by Southern blotting and hybridization to En-2 or
RACE fragment probes.
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RESULTS |
Identification of trapped gene expression patterns.
In the absence of leukemic inhibitory factor, ES colonies spontaneously
differentiate into embryoid bodies (EBs) in suspension culture. The
complex structure of the EB contains all three germ layers and
resembles the extra-embryonic yolk sac both morphologically and
transcriptionally.7,17-19 As in the yolk sac, the mesoderm of the EB gives rise to angioblastic cords that form morphologically distinquishable blood islands containing primitive hematopoietic cells
surrounded by vascular endothelium.8 Because of the
developmental potential of EBs, the differentiation of ES cells into
EBs has provided an excellent model to study the effects of targeted
mutations on hematopoietic, vascular, and myoblast
lineages.20-22 Thus, the EB should provide an excellent in
vitro expression screen of gene trap clones for insertions in genes
expressed in hematopoietic and vascular lineages. However, EBs grown in
suspension are difficult to manipulate in clonal cultures and the outer
layer of visceral endoderm precludes the identification of small
numbers of lacZ positive cells. Therefore, we modified the EB
culture system so that EBs grow attached to tissue culture
plastic.14 This attached or flat culture method places the
visceral endoderm layer beneath the blood islands and renders the EB
more accessible to observation and experimental manipulation.
The gene trap screening strategy that we used is shown in Fig 1. The
PT1 gene trap vector, which contains a splice acceptor site immediately
upstream of a promoterless lacZ reporter gene and a
neoR gene driven by PGK-1 promoter, was
introduced into ES cells (clone R1) by electroporation. After G418
selection, drug-resistant colonies were transferred to 96-well plates
and expanded to confluency. Clones were replica plated to two 96-well
plates and one set of 24-well plates. Once clones reached confluency,
one 96-well plate was frozen, the second 96-well plate was assayed for
-gal expression, and the 24-well plates were used for attached EB
differentiation cultures. Each neoR colony
represented a vector integration event. If the vector integrated within
an intron, a spliced fusion transcript between lacZ and the
endogenous gene would be generated upon transcriptional activation of
the trapped gene. Because all ES cells that had an integrated PT1
vector were G418 resistant regardless of whether the integration
occurred within a gene, genes that were not expressed in
undifferentiated ES cells could be trapped using this vector. Five
percent (37/779) of the neoR clones tested
expressed lacZ in undifferentiated ES cells, of which 30 clones
continued to be expressed in at least some cells during EB
differentiation (Table 1). By comparison,
61 clones (8%) that did not express lacZ as undifferentiated
ES cells demonstrated lacZ expression during EB differentiation
(Table 1). Of the neoR clones that expressed
lacZ as undifferentiated or differentiated ES cells, one-third
(32 clones) exhibited a restricted pattern of expression (Table 1). The
expression patterns of these clones can be grouped into seven
categories (Table 2). More than one third
of these clones were expressed in blood islands and/or the vasculature; in contrast, stromal and muscle cells each represented only 3% of the clones displaying restricted expression patterns. In
addition, 9% of these clones expressed lacZ constitutively in
virtually all undifferentiated and differentiated cells. The remaining
clones exhibited restricted patterns of expression in a cell type(s)
that has not yet been identified.
In a second series of experiments, we used the GT1.8geo vector (Fig 1)
that contains a splice-acceptor site immediately upstream of a
promoterless -gal-neo fusion gene (or geo). Thus,
unlike the PT1 vector, all neoR clones selected
after introduction of the GT1.8geo vector represented integrations into
genes that were transcriptionally active in undifferentiated ES cells.
Accordingly, a much higher proportion of the GT1.8geo clones (34%
v 5% for PT1) expressed detectable levels of -gal activity
in undifferentiated ES cells (ie, Blue; Table 1). Of those, 159 clones
continued to express lacZ in at least some cells during EB
differentiation. Of the 337 neoR clones that
expressed geo at levels too low to detect lacZ expression (ie, White;
Table 1) as undifferentiated ES cells, more than half upregulated
expression of lacZ in a portion of differentiated cells in EB
cultures. Of the 353 GT1.8geo clones that expressed lacZ, 47 clones displayed an obvious pattern of expression (Tables 1 and 2). The
majority of the pattern-expressing clones expressed lacZ in the
blood islands and/or the endothelium (Table 2).
In contrast to EB body differentiation in which ES cells differentiate
into all three germ layers that eventually give rise to many lineages,
including hematopoietic and vascular cells, ES cells grown in coculture
with OP9 stromal cells differentiate into mesodermal colonies that,
when replated, differentiate into hematopoietic cells.9,23
All gene trap cell lines that demonstrated lacZ expression in
blood islands were reanalyzed by differentiating ES cells in replicate
OP9 stromal cell cultures. ES-derived mesodermal colonies expressing
brachury (M. Hidaka, unpublished observations) were apparent by day 3 of culture. On day 5, a single-cell suspension of a replicate culture
was prepared and replated onto OP9 cells. Primitive erythrocytes and
multipotential precursors differentiated from the mesodermal precursors
within the next 2 to 3 days and single lineage precursors predominated
the cultures by day 119,23 (M. Hidaka, unpublished
observations). Cultures were assayed for lacZ expression at days 5, 8, and 11. The majority of blood island positive clones (70%) expressed
lacZ in hematopoietic cells when cultured on an OP9 feeder
layer (Table 2).
Identification of trapped genes.
To determine the DNA sequence of the trapped genes, RNA was prepared
from either differentiated or undifferentiated ES clones and used to
perform 5 RACE.24 The RACE products of 11 lacZ fusion transcripts were cloned and sequenced.
Table 3 summarizes the lacZ
expression pattern, the gene trap vector, and sequence information for
each clone. Eight of the RACE product sequences corresponded to novel
genes, of which four shared similarity with EST sequences. The
sequences of three of the trapped genes corresponded to genes that
encode known protein products: Mena, Karyopherin 3,
and 5GMP synthetase. Clone K18E2 encodes Mena,
the mammalian homologue of Drosophilia Enabled(ena), which was
originally cloned by a genetic screen for suppressors of Abl-dependent
phenotypes.25,26 In clone K18E2, the PT1 vector has
integrated into the first intron of Mena, which is
downstream of the initiation codon and, therefore, should
result in a null mutation. Clone B2C3 encodes the murine homologue of
karyopherin/importin 3 and yeast Pse1p,27 proteins that
are involved in the transport of proteins and mRNA across the nuclear
membrane.28,29 The RACE product suggests that a fusion
protein was generated from the N-terminal 312 amino acids and
lacZ. Mutational analysis of Xenopus karyopherin-
suggests that this fusion protein should bind weakly to the nuclear
pore complex and to RanGTP but not to karyopherin- 28 and
may act as a weak dominate negative mutation. In ES clone GC10G7, the GT1.8geo vector has integrated within the 3 coding region of the
gene for guanosine 5-monophosphate (GMP) synthetase.
GMP-synthetase catalyzes the amination of xanthosine
5-monophosphate to form GMP in the presence of glutamine and
ATP. Although GMP-synthetase is expressed in many cell types in the
adult, we observed high levels of -gal activity only in endothelial
cells and a population of hematopoietic cells (Table 3).
In vitro and in vivo expression of selected clones.
Previous studies using these vectors have demonstrated that the lacZ
fusion protein expression accurately represents wild-type expression of
the trapped gene.15,30,31 To determine if the patterns of
expression in vitro were a good predictor of in vivo expression,
selected ES clones were aggregated with diploid embryos to generate
chimeric mice. Analysis of lacZ reporter gene expression was
performed first on chimeric embryos to assess quickly expression patterns and subsequently was confirmed in F1 embryos
(summarized along with sequence analysis in Table 3). In this report,
we present three clones that correspond to a sequence homologous to
several ESTs (K17G2), a completely novel gene (GC11E10), and Mena (K18E2). K17G2 was isolated using the PT1 vector and
displayed significant sequence similarity to several ESTs from human,
rodent, Drosophilia, and yeast cDNA libraries. K17G2-lacZ was
expressed at low to medium levels in undifferentiated ES cells
(Fig 2A), whereas its expression was
restricted to blood islands (labeled bi) and some associated
endothelial cells (arrows) in attached EBs (Fig 2B). Differentiation on
OP9 stromal cells showed that K17G2-lacZ was expressed in some
mesodermal (labeled M) and hematopoietic cells (arrow; Fig 2C and D,
respectively). To analyze the expression pattern of K17G2-lacZ
in vivo, K17G2 ES cells were used to generate chimeric mice. As
predicted by in vitro expression, K17G2-lacZ was expressed by
embryonic vasculature (arrow) including the pericardium (arrow) as well
as circulating blood cells (Fig 2F and G) in e12.5 embryos. In the
adult, K17G2-lacZ expression was observed in splenocytes, thymocytes, and bone marrow cells and in the vasculature, including the
endocardium as well as the pericardium. In addition, analysis of K17G2
F1 embryos showed additional tissues that expressed the K17G2-lacZ fusion product (Fig 2E). For example, the
lacZ fusion product was expressed in the myocardium and the
dorsal root ganglia (Fig 2H and I, respectively). Brother-sister
matings of K17G2 heterozygous littermates failed to produce viable
homozygous mice, indicating that the trapped K17G2 gene is essential
for embryogenesis (data not shown).
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| Fig 2.
K17G2-lacZ expression in vitro and in vivo. Overnight
X-gal staining showed fusion transcript expression at medium intensity
in most undifferentiated K17G2 ES cells (A). The fusion transcript was
expressed in the blood island (bi) and some of the associated vascular
endothelium (arrows) in attached EB culture (B). Differentiation of
clone K17G2 on OP9 stromal cells demonstrated lacZ expression
in mesodermal (M) colonies (C) and hematopoietic clusters (arrow; D).
X-gal staining of an e10.5 F1 embryo demonstrated limited
lacZ expression in the embryo (whole mount; E). An X-gal
stained e12.5 F1 embryo demonstrated lacZ
expression in the pericardium (F) and vascular endothelium and
circulating hematopoietic cells (G). In addition, the myocardium (H)
and the dorsal root ganglia (I) also express the lacZ fusion protein.
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Clone GC11E10 was isolated using the GT1.8geo vector and represents a
novel ORF. The GC11E10-geo fusion protein was expressed at medium to
high levels in undifferentiated ES cells
(Fig 3A). In attached EBs, expression
appeared within blood islands (bi) and the vasculature (arrow)
associated with these structures (Fig 3B). Differentiation of GC11E10
ES cells on OP9 stromal cells demonstrated lacZ expression
within mesodermal (M) colonies (Fig 3C) and high levels of expression
within hematopoietic cell clusters (long arrow) and large hematopoietic
cells that may be megakaryocytes (short arrows; Fig 3D). In vivo,
lacZ was expressed in the yolk sac, dorsal aorta, heart, the
developing liver, and vasculature (Fig 3E and F). Further analysis
demonstrated lacZ expression within blood cells circulating
throughout the embryo and blood islands in the yolk sac (Fig 3G and H).
The GC11E10-geo fusion protein was also expressed in endothelial cells
throughout the embryo, including the intersomitic vessels (arrow) shown
in Fig 3I.
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| Fig 3.
GC11E10-lacZ expression. Overnight X-gal staining showed
fusion transcript expression at medium to high levels in most
undifferentiated ES cells (A). In attached EB cultures, lacZ
was expressed within blood islands (bi) and the associated vascular
endothelium (arrows; B). Differentiation of clone GC11E10 on OP9
stromal cells demonstrated lacZ expression in mesodermal (M)
colonies (C) and a proportion of hematopoietic clusters long arrow as
well as all large hematopoietic cells (short arrows; D). Overnight
whole mount X-gal staining of an e9.5 chimeric embryo and yolk sac
demonstrated lacZ expression in the dorsal aorta, heart, liver,
and vasculature (E). LacZ expression in the yolk sac was
confined to endothelial and hematopoietic cells (F and G). LacZ
was expressed by the endocardium and circulating blood cells in the
heart (H) and by the intersomitic endothelial cells (arrow; I).
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As discussed above, clone K18E2 (a PT1 clone) represents an integration
into the first intron of Mena. Mena has been implicated in actin assembly and cell motility; thus, although its embryonic expression has not been previously described, its ubiquitous expression in rapidly dividing cells was expected. Mena-lacZ was expressed at very high levels in nearly all undifferentiated ES cells
(Fig 4A) and virtually all cells in
attached EBs including the blood island (bi) shown in Fig 4B.
Differentiation of K18E2 on OP9 stromal cells demonstrated high levels
of Mena-lacZ expression in mesodermal cells (Fig 4C), but only
low level expression in a minority of hematopoietic cells (long arrow;
Fig 4D). This pattern and level of lacZ expression was
reproduced in F1 embryos. Mena-lacZ was expressed
by almost all cells in the developing embryo with the exception of
hepatocytes and some hematopoietic cells (Fig 4E and F and data not
shown).
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| Fig 4.
Mena-lacZ (K18E2) expression. Overnight X-gal staining
demonstrated high-level lacZ expression in undifferentiated ES
cells (A) and in virtually all cells in the attached EB culture,
including blood islands (bi) and their associated vasculature (arrow;
B). Differentiation of clone K18E2 on OP9 stromal cells followed by
overnight X-gal staining demonstrated high-level lacZ
expression in mesodermal (M) colonies (C), whereas most hematopoietic
cells did not express lacZ (short arrows), although low-level
expression was observed in some isolated hematopoietic cells (long
arrows; D). Mena-lacZ was expressed at high levels in vivo, as
demonstrated by strong X-gal staining in less than 90 minutes in an
e10.5 F1 embryo (E). Overnight X-gal staining of an e13.5
F1 embryo showed strong lacZ expression in all tissues
except the liver (F).
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DISCUSSION |
We have developed an expression-based strategy to identify and mutate
genes that are preferentially expressed in cells of the hematopoietic
and vascular lineages. Gene trap vectors were introduced into ES cells
by electroporation and sibling clones were allowed to differentiate
into attached EBs to identify expression patterns. Clones exhibiting
reporter gene expression in blood islands were then differentiated on
OP9 stromal cells to determine if hematopoietic cells expressed the
reporter gene. From almost 1,300 clones, we isolated 79 clones with
identifiable expression patterns, of which 33 were preferentially
expressed in hematopoietic and/or endothelial cells. These in
vitro patterns of expression, which can be analyzed relatively quickly
and in large numbers, were reliable predictors of in vivo patterns of
expression as subsequently determined in chimeric and F1
embryos. ES clones with expression patterns of interest were then used
to clone and sequence the upstream coding region of the trapped gene by
5 RACE. Three of the clones corresponded to known genes and
eight were novel. The three known genes, Mena, Karyopherin
3, and 5GMP synthetase, have diverse biological
and biochemical functions, yet little is known about their
developmental expression or the consequences of mutations in these
genes on mammalian development or function in the adult. We are
currently introducing these mutations into the mouse germline to
determine their biological function in vivo. Detailed in vivo analysis
of mutant phenotypes, combined with sequence analysis and expression
pattern, should provide valuable insight into the biological functions
of these genes.
In vivo analysis of several of the novel hematopoietic and vascular
genes has demonstrated tissue-specific expression of these genes.
GC11E10 expression is confined to hematopoietic and endothelial lineages (Fig 3 and data not shown). The GC11E10 mutation has been
transmitted through the germline. Brother-sister matings of
heterozygous littermates are currently being performed to analyze gene
function. K17G2 is expressed exclusively in the hematopoietic, vascular, heart, and sensory nervous systems in the embryo. In the
adult, 17G2 expression is dramatically upregulated in the vascular
system and is expressed at low levels by most hematopoietic cells and
is expressed at high levels by approximately 1% of bone marrow cells
(data not shown). Preliminary analysis of K17G2 homozygous embryos has
determined that a significant percentage of the homozygous embryos are
edematous and develop hemorrhages. More thorough investigation of
expression and homozygous phenotype is required to assess the function
of K17G2.
Gene trapping in ES cells is a powerful technique because it
simultaneously integrates gene identification and structure, expression, and functional analysis into one process. Previously published gene trap screens have used one of these three types of
analysis as the primary determinant to select clones for further study.
The first group of screens used no preselection to study mutant
phenotypes. Collectively, these studies have determined that nearly
40% of gene trap mutants result in recessive embryonic lethality.12,32-34 Several sequence-based screening
strategies have been developed to either rapidly isolate 5RACE
sequences,35-37 isolate 3RACE
sequences,38,39 or clone proviral integration sites by
plasmid rescue.40 In addition, Skarnes et al11
modified the GT1.8geo vector to trap specifically genes that encode
secreted or transmembrane proteins. Several groups, including
ourselves, have performed screens based on regulated expression. Each
of these screens analyzed clones that contained integrations into genes
that were transcriptionally active in ES cells. The expression of the
fusion transcripts was either analyzed by in vivo
expression30 or regulation by exogenous
factors15,41,42 or by in vitro differentiation.43-45 The previous in vitro prescreening
strategies identified clones with regulated expression in
cardiomyocyte, neuronal, and chondrocyte lineages.
Thus, the expression trapping approach described here complements and
extends the previous expression-based gene trap screens by specifically
identifying integrations into genes preferentially expressed in
hematopoietic and endothelial lineages. In addition, we have designed
the screen to perform large-scale, genome-wide scans for genes of
interest. All integrations with identifiable expression patterns in
vitro were catalogued to generate a biological resource of gene-trap
insertions based on expression pattern, cDNA sequence, and mutant
phenotypes.
The attached EB differentiation assay used here as the primary screen
enabled us to identify a large number of genes with a spatially or
cell-type restricted expression in several cell lineages, including
hematopoietic, endothelial, stromal, and myocyte. Many cell types
develop in these cultures; thus, a screen based on in vitro expression
patterns would be feasible provided the patterns accurately reflect the
pattern of gene expression within the context of a developing embryo or
adult. Therefore, an important result from the studies reported here
was the observation that the patterns of expression observed in vitro
accurately paralleled the expression of the gene in vivo. Clones that
exhibited lacZ expression patterns in unknown cell types are
currently being tested in vivo to determine the cell lineages in which
they are expressed. This information should widen the range of cell
types and corresponding lineage-restricted genes that can be trapped by
this strategy.
We were particularly interested in comparing the expression trapping
parameters of the PT1 vector, in which the neo gene is under
the control of an autonomous promoter and GT1.8geo, which will only
give rise to a G418-resistant colony if the vector has integrated into
an actively expressed gene. A priori, each vector has its own
advantages and disadvantages. PT1 can trap genes that are not expressed
in undifferentiated ES cells but that may only be activated in
differentiated derivatives. On the other hand, the PT1 vector will also
give rise to G418-resistant colonies after integration within
intergenic regions. These integration events would be expected to lower
the numbers of trapped genes per ES clones. In contrast, GT1.8geo will
only give rise to G418-resistant colonies after integration within a
gene, providing that the gene is already expressed in undifferentiated
ES cells. Interestingly, one third of the blue PT1 clones but only one
eighth of the blue GT1.8geo clones exhibited identifiable expression
patterns (Table 1). Thus, although integration of the PT1 vector in
both intragenic and intergenic regions can result in G418-resistant ES
clones, a higher percentage of -gal-positive PT1 clones have
identifiable expression patterns. Therefore, provided that the
screening method is efficient, the PT1 vector, or similar vectors, can
be used to trap genes not expressed in ES cells. In addition, because the neoR gene is driven by the PGK-1
promoter, it should be possible to use high G418
selection46 to produce homozygous ES cells for each gene
trap line at a high throughput. Because of differing levels of
neoR activity in GT1.8geo cell lines, high G418
selection would be more difficult and labor-intensive. The homozygous
ES cell lines could be used to perform chimeric analysis as well as a
functional in vitro gene trap screen to assay mutations affecting
development of hematopoietic, endothelial, or myoblast lineages. We are
currently pursuing these strategies.
Finally, it should be possible to increase the efficiency and
versatility of the screen by incorporating multiplex assays to identify
various gene families. Related strategies based on the ability of ES
cells to differentiate and respond to exogenous factors in vitro will
also make it possible to identify genes that are differentially
regulated in many distinct cell lineages in vivo. When combined with
the potential of ES cells to give rise to germ cells, this approach
simultaneously should provide expression, sequence, and phenotypic
information on a very wide spectrum of genes. Thus, expression trapping
in ES cells provides a useful complement to other strategies designed
to analyze at a functional level the very large number of proteins
encoded by the mammalian genome.
| |
ACKNOWLEDGMENT |
The authors thank Caryn Ito and Janet Rossant for critical reading of
the manuscript; Bill Skarnes for the GT1.8geo vector; Ken Harpel for
the preparation of histological sections; Sandra Tondat, Marina
Gertsenstein, Lois Schwartz, and Sarang Kulkarni for transgenic work;
and Michelle Tam for technical assistance.
| |
FOOTNOTES |
Submitted May 18, 1998;
accepted August 10, 1998.
Supported by grants from Bristol-Myers Squibb (Princeton, NJ), the
Leukemia Society of America (New York, NY), the National Institutes of
Health (Bethesda, MD), and the Terry Fox Foundation (Vancouver, British
Columbia, Canada).
The publication costs of this
article were defrayed in part by
page charge payment. This article
must therefore be hereby marked
"advertisement"
in accordance with 18 U.S.C. section
1734 solely to indicate this fact.
Address reprint requests to Alan Bernstein, PhD, Samuel Lunenfeld
Research Institute, Mount Sinai Hospital, 600 University Ave, Toronto,
Ontario, M5G 1X5, Canada; e-mail: bernstein{at}mshri.on.ca.
| |
REFERENCES |
1.
Bernstein A, Forrester L, Reith AD, Dubreuil P, Rottapel R:
The murine W/c-kit and Steel loci and the control of hematopoiesis.
Semin Hematol
28:138, 1991[Medline]
[Order article via Infotrieve]
2.
Bedell MA, Jenkins NA, Copeland NG:
Mouse models of human disease. Part I: Techniques and resources for genetic analysis of mice.
Genes Dev
11:1, 1997[Free Full Text]
3.
Bedell MA, Largaespada DA, Jenkins NA, Copeland NG:
Mouse models fo human disease. Part II: Recent progress and futurre directions.
Genes Dev
11:11, 1997[Free Full Text]
4.
Doetschman T, Gregg RG, Maeda N, Hooper ML, Melton DW, Thompson S, Smithes O:
Targetted correction of a mutant HPRT gene in mouse embryonic stem cells.
Nature
330:576, 1987[Medline]
[Order article via Infotrieve]
5.
Thomas KR, Capecchi MR:
Site-directed mutagenesis by gene targeting in mouse embryo-derived stem cells.
Cell
51:503, 1987[Medline]
[Order article via Infotrieve]
6.
Gossler A, Joyner AL, Rossant J, Skarnes WC:
Mouse embryonic stem cells and reporter constructs to detect developmentally regulated genes.
Science
244:463, 1989[Abstract/Free Full Text]
7.
Doetschman TC, Eistetter H, Katz M, Schmidt W, Kemler R:
The in vitro development of blastocyst-derived embryonic stem cell lines: Formation of visceral yolk sac, blood islands and myocardium.
J Embryol Exp Morph
87:27, 1985[Medline]
[Order article via Infotrieve]
8.
Wang R, Clark R, Bautch VL:
Embryonic stem cell-derived cystic embryoid bodies form vascular channels: An in vitro model of blood vessel development.
Development
114:303, 1992[Abstract]
9.
Nakano T, Kodama H, Honjo T:
Generation of lymphohematopoietic cells from embryonic stem cells in culture.
Science
265:1098, 1994[Abstract/Free Full Text]
10.
Hill DP, Wurst W:
Screening for novel pattern formation genes using gene trap approaches.
Methods Enzymol
225:664, 1993[Medline]
[Order article via Infotrieve]
11.
Skarnes WC, Moss JE, Hurtley SM, Beddington RSP:
Capturing genes encoding membrane and secreted proteins important for mouse development.
Proc Natl Acad Sci USA
92:6592, 1995[Abstract/Free Full Text]
12.
Friedrich G, Soriano P:
Promoter traps in embryonic stem cells: A genetic screen to identify and mutate developmental genes in mice.
Genes Dev
5:1513, 1991[Abstract/Free Full Text]
13.
Nagy A, Rossant J, Nagy R, Abramow-Newerly W, Roder JC:
Derivation of completely cell culture-derived mice from early passage embryonic stem cells.
Proc Natl Acad Sci USA
90:8424, 1993[Abstract/Free Full Text]
14.
Bautch VL, Stanford WL, Rapoport R, Russell S, Byrum RS, Futch TA:
Blood island formation in attached cultures of murine embryonic stem cells.
Dev Dyn
205:1, 1996[Medline]
[Order article via Infotrieve]
15.
Sam M, Wurst W, Kluppel M, Jin O, Heng H, Bernstein A:
Gene trap characterization of Aquarius, a novel gene with RNA-dependent RNA polymerase motif.
Dev Dyn
212:304, 1998[Medline]
[Order article via Infotrieve]
16.
Nagy A, Rossant J:
Production of completely ES cell derived fetuses, in
Joyner AL
(ed):
Gene Targeting: A Practical Approach. Oxford, UK, IRL, 1993, p 147.
17.
Schmitt RM, Bruyns E, Snodgrass HR:
Hematopoietic development of embryonic stem cells in vitro: Cytokine and receptor gene expression.
Genes Dev
5:728, 1991[Abstract/Free Full Text]
18.
Keller G, Kennedy M, Papayannopoulou T, Wiles MV:
Hematopoietic commitment during embryonic stem cell differentiation in culture.
Mol Cell Biol
13:473, 1993[Abstract/Free Full Text]
19.
Snodgrass HR, Graham DK, Stanford WL, Licato LL:
Embryonic stem cells: research and clinical potentials, in
Smith D,
Sacher RA,
Jefferies LC
(eds):
Peripheral Blood Stem Cells. Bethesda, MD, American Association of Blood Banks, 1993, p 65.
20.
Weiss MJ, Keller G, Orkin SH:
Novel insights into erythroid development revealed through in vitro differentiation of GATA-1 embryonic stem cells.
Genes Dev
8:1184, 1994[Abstract/Free Full Text]
21.
Shalaby F, Ho J, Stanford WL, Fisher K-D, Schuh AC, Schwartz L, Bernstein A, Rossant J:
A requirement for Flk-1 in primitive and definitive hematopoiesis, and vasculogenesis.
Cell
89:981, 1997[Medline]
[Order article via Infotrieve]
22.
Narita N, Bielinska M, Wilson DB:
Cardiomyocyte differentiation by GATA-4-deficient embryonic stem cells.
Development
122:3755, 1996[Abstract]
23.
Nakano T, Kodama H, Honjo T:
In vitro development of primitive and definitive erythrocytes from different precursors.
Science
272:722, 1996[Abstract]
24.
Frohman MA, Dush MK, Martin GR:
Rapid production of full-length cDNAs from rare transcripts: Amplification using a single-gene specific oligonucleotide primer.
Proc Natl Acad Sci USA
85:8998, 1988[Abstract/Free Full Text]
25.
Gertler FB, Comer AR, Juang JL, Ahern SM, Clark MJ, Liebl EC, Hoffman FM:
Enabled, a dosage-sensitive suppressor of mutations in the Drosophilia Abl tyrosine kinase, encodes an Abl substrate with SH3 domain-binding properties.
Genes Dev
9:521, 1995[Abstract/Free Full Text]
26.
Gertler FB, Niebuhr K, Reinhard M, Wehland J, Soriano P:
Mena, a relative of VASP and Drosophilia enabled, is implicated in the control of microfilament dynamics.
Cell
87:227, 1996[Medline]
[Order article via Infotrieve]
27.
Yaseen NR, Blobel G:
Cloning and characterization of human karyopherin 3.
Proc Natl Acad Sci USA
94:4451, 1997[Abstract/Free Full Text]
28.
Kutay U, Izaurralde E, Bischoff FR, Mattaj IW, Gorlich D:
Dominant-negative mutants of importin-b block multiple pathways of import and export through the nuclear pore complex.
EMBO J
16:1153, 1997[Medline]
[Order article via Infotrieve]
29.
Seedorf M, Silver PA:
Importin/karyopherin protein family members required for mRNA export from the nucleus.
Proc Natl Acad Sci USA
94:8590, 1997[Abstract/Free Full Text]
30.
Wurst W, Rossant J, Prideaux V, Kownacka M, Joyner AL, Hill DP, Guillemot F, Gasca S, Cado D, Auerbach A, Ang S-L:
A large-scale gene-trap screen for insertional mutations in developmentally regulated genes in mice.
Genetics
139:889, 1995[Abstract]
31.
Torres M, Stoykova A, Huber O, Chowdery K, Bonaldo P, Mansouri A, Butz S, Kemler R, Gruss P:
An alpha-E-catenin gene trap mutation defines its function in preimplantation development.
Proc Natl Acad Sci USA
94:901, 1997[Abstract/Free Full Text]
32.
Skarnes WC, Auerbach BA, Joyner AL:
A gene trap approach in mouse embryonic stem cells: The lacZ reporter is activated by splicing, reflects endogenous gene expression, and is mutagenic in mice.
Genes Dev
6:903, 1992[Abstract/Free Full Text]
33.
von Melchner H, DeGregori JV, Rayburn H, Reddy S, Friedel C, Ruley HE:
Selective disruption of genes expressed in totipotent embryonal stem cells.
Genes Dev
6:919, 1992[Abstract/Free Full Text]
34.
DeGregori J, Russ A, von Melchner H, Rayburn H, Priyaranjan P, Jenkins NA, Copeland NG, Ruley HE:
A murine homolog of the yeast RNA1 gene is required for postimplantation development.
Genes Dev
8:265, 1994[Abstract/Free Full Text]
35.
Holzschu D, Lapierre L, Neubaum D, Mark WH:
A molecular strategy designed for the rapid screening of gene traps based on sequence identity and gene expression pattern in adult mice.
Transgenic Res
6:97, 1997[Medline]
[Order article via Infotrieve]
36.
Chowdhury K, Bonaldo P, Torres M, Stoykova A, Gruss P:
Evidence for the stochastic integration of gene trap vectors into the mouse germline.
Nucleic Acids Res
25:1531, 1997[Abstract/Free Full Text]
37.
Townley DJ, Avery BJ, Rosen B, Skarnes WC:
Rapid sequence analysis of gene trap integrations to generate a resource of insertional mutations in mice.
Genome Res
7:293, 1997[Abstract/Free Full Text]
38.
Yoshida M, Yagi T, Furuta Y, Takayanagi K, Kominami R, Takeda N, Tokunaga T, Chiba J, Ikawa Y, Aizawa S:
A new strategy of gene trapping in ES cells using 3RACE.
Trans Res
4:277, 1995[Medline]
[Order article via Infotrieve]
39.
Zambrowicz BP, Freidrich GA, Buxton EC, Lilleberg SL, Person C, Sands AT:
Disruption and sequence identification of 2,000 genes in mouse embryonic stem cells.
Nature
392:608, 1998[Medline]
[Order article via Infotrieve]
40.
Hicks GG, Shi EG, Li XM, Li CH, Pawlak M, Ruley HE:
Functional genomics in mice by tagged sequence mutagenesis.
Nat Genet
16:338, 1997[Medline]
[Order article via Infotrieve]
41.
Forrester L, Nagy A, Sam M, Watt A, Stevenson L, Bernstein A, Joyner AL, Wurst W:
Induction gene trapping in ES cells: Identification of developmentally regulated genes that respond to retinoic acid.
Proc Natl Acad Sci USA
93:1677, 1996[Abstract/Free Full Text]
42.
Sam M, Wurst W, Forrester L, Vauti F, Heng H, Bernstein A:
A novel family of repeat sequences in the mouse genome responsive to retinoic acid.
Mamm Genome
7:741, 1996[Medline]
[Order article via Infotrieve]
43.
Scherer CA, Chen J, Nachabeh A, Hopkins N, Ruley HE:
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