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Previous Article | Next Article 
Molecular and Cellular Biology, June 1999, p. 4443-4451, Vol. 19, No. 6
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Disrupted Differentiation and Oncogenic
Transformation of Lymphoid Progenitors in E2A-HLF
Transgenic Mice
Kevin S.
Smith,
Joon Whan
Rhee,
Louie
Naumovski, and
Michael L.
Cleary*
Department of Pathology, Stanford University
Medical Center, Stanford, California 94305
Received 24 November 1998/Returned for modification 4 February
1999/Accepted 10 March 1999
 |
ABSTRACT |
The hepatic leukemia factor (HLF) gene codes for a
basic region-leucine zipper (bZIP) protein that is disrupted by
chromosomal translocations in a subset of pediatric acute lymphoblastic
leukemias. HLF undergoes fusions with the E2A
gene, resulting in chimeric E2a-Hlf proteins containing the E2a
transactivation domains and the Hlf bZIP DNA binding and dimerization
motifs. To investigate the in vivo role of this chimeric bZIP protein
in oncogenic transformation, its expression was directed to the
lymphoid compartments of transgenic mice. Within the thymus, E2a-Hlf
induced profound hypoplasia, premature involution, and progressive
accumulation of a T-lineage precursor population arrested at an early
stage of maturation. In the spleen, mature T cells were present but in
reduced numbers, and they lacked expression of the transgene,
suggesting further that E2a-Hlf expression was incompatible with T-cell
differentiation. In contrast, mature splenic B cells expressed E2a-Hlf
but at lower levels and without apparent adverse or beneficial effects
on their survival. Approximately 60% of E2A-HLF mice
developed lymphoid malignancies with a mean latency of 10 months.
Tumors were monoclonal, consistent with a requirement for secondary
genetic events, and displayed phenotypes of either mid-thymocytes or,
rarely, B-cell progenitors. We conclude that E2a-Hlf disrupts the
differentiation of T-lymphoid progenitors in vivo, leading to profound
postnatal thymic depletion and rendering B- and T-cell progenitors
susceptible to malignant transformation.
| |
INTRODUCTION |
Chromosomal translocations
constitute important mechanisms for the activation of cellular
oncogenes in human cancers (29). Many translocations in
hematologic and soft tissue tumors result in the creation of fusion
genes that encode chimeric transcriptional proteins (8). The
modular nature of transcription factors renders them particularly
susceptible to activation by the illicit shuffling of functional
domains induced by chromosomal translocations. The resulting chimeric
proteins frequently display altered transcriptional properties compared
to their wild-type counterparts and in some cases have been shown to
contribute to the perturbed expression of critical subordinate genes.
A recurring target for translocations in a subset of pediatric acute
lymphoblastic leukemias (ALL) is the E2A gene
(16), which codes for differentially spliced members (E12,
E47, ITF1) of the basic helix-loop-helix family of E-box DNA binding
proteins (4). As a result of t(1;19) or t(17;19)
translocations, E2A is juxtaposed with heterologous genes,
resulting in the production of either E2A-PBX1 or
E2A-HLF fusion genes, respectively (13). E2A-HLF fusion products were originally isolated from two
t(17;19)-carrying ALL cell lines (12, 19) with features of
early B-lineage precursors. Two types of DNA rearrangement
(15) result in the production of E2a-Hlf chimeric proteins
containing the transactivation domains of E2a (2, 38) and
the DNA binding and dimerization domains (basic region and leucine
zipper) of Hlf (12, 19). The resulting E2a-Hlf proteins bind
to a consensus palindromic DNA site as homodimers in vitro and are
capable of activating the transcription of synthetic reporter genes
through this site in transient transcriptional assays (14,
20). These properties of E2a-Hlf are essential for its ability to
transform NIH 3T3 cells (22, 45), indicating that in this
context E2a-Hlf acts through a gain-of-function mechanism as a
homodimeric transcriptional activator.
E2a-Hlf is capable of modulating cell survival, a property with
potential implications for its mechanisms of oncogenic action. Conditionally expressed E2a-Hlf prevents apoptosis associated with
cytokine withdrawal from interleukin-3 (IL-3)-dependent Baf3 cells
(21). The survival mechanism may involve E2a-Hlf
cross-regulation of transcriptional regulatory elements normally
mediated by NFIL-3, since both bind the same enhancer sequences and
upon forced expression bypass the IL-3 requirement for survival of
pro-B cells (18). Furthermore, dominant-negative disruption
of E2a-Hlf in t(17;19)-bearing cells results in their apoptosis
(21). The basic leucine zipper (bZIP) domain of Hlf displays
similarity with that of Ces-2, a regulator of apoptosis in
Caenorhabditis elegans (33); however, the
potential role of wild-type Hlf in cell death pathways remains undefined. Hlf, but not Ces-2, is a member of the PAR subfamily of bZIP
proteins that is distinguished by a proline- and acidic amino acid-rich
(PAR) domain that flanks the basic region and contributes to DNA
binding specificity (14). As a homodimer or heterodimer with
other PAR family members, Hlf functions as a transcriptional activator,
albeit with DNA binding and effector properties that differ modestly
from those of E2a-Hlf which lacks the PAR domain (12, 14, 17, 20,
36). Since Hlf normally displays a highly restricted expression
profile that excludes lymphoid cells, a potential model for its role in
oncogenesis invokes ectopic expression as a fusion protein under the
control of the constitutive E2A promoter, resulting in the
corruption of transcriptional pathways that regulate survival in B-cell progenitors.
We report here the effects of E2a-Hlf on primary lymphoid progenitors
in transgenic mice. Within the thymus, high-level E2a-Hlf expression
disrupted normal differentiation, resulting in profound hypoplasia,
premature involution, and progressive accumulation of a T-precursor
population arrested at an early stage of maturation. In contrast to T
cells, mature B cells expressed E2a-Hlf but at reduced levels and
without apparent effects on their survival. A majority of
E2A-HLF transgenic mice succumbed to T- or occasionally B-lineage lymphoblastic malignancies with a mean latency of 10 months.
We conclude that high-level E2a-Hlf expression impedes the
differentiation of T-lineage lymphoid progenitors in vivo and renders
them highly susceptible to malignant transformation.
| |
MATERIALS AND METHODS |
Transgenic mice.
An E2A-HLF cDNA encoding the
mRNA (12) expressed in t(17;19)-bearing cell line HAL-01
(37) was cloned downstream of the Eµ enhancer/simian virus
(SV40) promoter in the vector EµSV (26). The entire insert
was released from the vector backbone by NotI digestion and
purified from agarose gels. Transgenic animals were generated by
standard methods (11) for pronuclear injection of FVB/N
fertilized eggs, using linear insert DNA (5 µg/ml in 10 mM Tris-0.2
mM EDTA). Surviving eggs were transferred 2 to 4 h after injection
into oviducts of pseudopregnant CD-1 host females. Transgenic progeny
were identified by Southern blotting, and transgene-positive lines were
propagated by mating to FVB/N inbred mice. Two lines (10 and 11) were
used for all of the studies described in this report and were
indistinguishable in their characteristics.
DNA and protein analyses.
DNA was isolated from fresh or
frozen tissues, digested with appropriate restriction enzymes, and
analyzed by Southern blot hybridization using previously reported
methods (7). Probes for the mouse T-cell receptor (TCR)
J
2, IGH-JH4, and IG-J
5 have been described previously
(9). Protein extracts were prepared by lysing cells or
tissues in 1× sample buffer (50 mM Tris-Cl [pH 6.8], 10% glycerol,
2% sodium dodecyl sulfate [SDS]) and boiling for 10 min. The lysates
were sonicated and the optical density at 280 nm was determined.
Fifty-microgram aliquots of total cellular protein were subjected to
SDS-polyacrylamide gel electrophoresis followed by Western blot
analysis using an anti-E2a monoclonal antibody (24) as
previously described (39). Immunoreactive proteins were
visualized by the enhanced chemiluminescence detection method as
specified by the manufacturer (Amersham International plc, Amersham, England).
Fluorescence-activated cell sorting (FACS) analysis.
Freshly
isolated cells from bone marrow, thymus, spleen, and peripheral blood
were stained for four-color analysis, and the fluorescence was analyzed
by using a dual-laser FACS Vantage (Becton Dickinson Immunocytometry
Systems, Mountain View, Calif.) with a four-decade logarithmic
amplifier. Dead cells were detected by staining with propidium iodide
(1 µg/ml) and gated out electronically. Residual erythrocytes were
also gated out electronically. Specific cell populations were sorted by
gating on the desired populations, which were collected for analysis
and Western blotting. Apoptosis was evaluated by flow cytometric
analysis following staining of thymocytes with annexin V and propidium
iodide. All antibodies were purchased from Pharmingen Research Products
(San Diego, Calif.). Specificities of antibodies were as follows:
fluorescein isothiocyanate (FITC)-conjugated 145-2C11 (anti-CD3
);
phycoerythrin (PE)-conjugated RM4-5 (anti-CD4); biotinylated 53-6.7 (anti-CD8
); FITC-conjugated S7 (anti-CD43);
allophycocyanin-conjugated RA3-6B2 (anti-B220); PE-conjugated M1/69
(anti-CD24-heat-stable antigen); biotinylated 6C3/BP1 (anti-Ly51);
avidin-conjugated Texas red; FITC-conjugated 2B8 (anti-CD117/c-Kit);
and biotinylated 7D4 (anti-CD25/p55).
Histology and immunohistochemical analyses.
Tissues for
light microscopy were processed for paraffin embedding following
fixation in 10% buffered formalin. Sections were stained with
hematoxylin and eosin by standard procedures. Immunohistochemical analyses were performed on frozen tissues according to previously published procedures (5), using rat monoclonal antibodies
against mouse lymphoid differentiation antigens.
| |
RESULTS |
Construction of transgenic mice that express E2a-Hlf in lymphoid
compartments.
A transgene construct was created by using an
E2A-HLF cDNA encoding the t(17;19) fusion mRNA
(12) expressed by pro-B ALL cell line HAL-01
(37). It was cloned downstream from the SV40 promoter and
IGH enhancer (Eµ) in the EµSV vector (Fig.
1A), which has been shown in previous
studies to drive transgene expression in cells of both the B- and
T-lymphoid lineages (26). The construct was injected into
FVB/N embryos, and five founders were obtained, all of which showed
germ line transmission of the transgene. Two independent lines with
expression of the transgene in lymphoid compartments were selected for
further studies. By Western blot analysis, immunoreactive proteins with
migrations corresponding to that of E2a-Hlf were most prominently
detected in the thymus and to a lesser extent in the spleen and bone
marrow (Fig. 1B).
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FIG. 1.
Structure and expression of the E2A-HLF
transgene. (A) Schematic illustration of the E2A-HLF
transgene construct consisting of the
E2A-HLFHAL-01 cDNA driven by an Eµ
enhancer and SV40 early promoter. (B) Expression of E2a-Hlf protein in
bone marrow (BM), thymocytes (Thy.), and spleens (Spl.) of transgenic
mice at 16 weeks of age as determined by Western blot analysis using an
anti-E2a monoclonal antibody. Nontransgenic control mice displayed no
E2a-Hlf expression. Gel loadings were standardized based on total
protein content (lower panel). wt, wild type.
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|
Lymphoid hypoplasia and rapid thymic involution in
E2A-HLF mice.
Healthy-appearing transgenic and normal
animals were examined between 4 and 24 weeks of age to assess
lymphocyte numbers and surface phenotypes by flow cytometry. At all
time points, thymuses from transgenic animals were noted to be
substantially smaller on gross examination, and this corresponded to
lower total numbers of thymocytes than in controls (Fig.
2A). At 4 and 6 weeks, thymuses from
E2A-HLF mice contained approximately 30% of the cells as normal littermates; at 8 and 10 weeks, transgenic thymocytes had dropped to 20 and 10%, respectively, of control levels. Total splenic
T-cell numbers (CD3+) were also reduced (70% of control
levels), suggesting that the hypoplasia involved the entire T-cell
lineage (Fig. 2A). Although small in size, transgenic thymuses appeared
histologically normal at 4 weeks, with formation of distinct cortical
and medullary zones and no detectable increase in apoptosis (data not
shown). By FACS analysis, the decrease in thymocyte numbers appeared to affect all thymocyte subpopulations equally since the percentages of
phenotypically immature CD4+8+ cells as well as
the phenotypically mature CD4+8
and
CD48+ subsets were not significantly
different between normal and transgenic animals (Fig. 3). However, at
10 weeks, the relative proportion of immature
CD4+8+ thymocytes was substantially reduced
(13% in transgenic mice versus 54% in control mice)
compared to mature subsets (Fig. 3), reflecting a preferential loss of the double-positive (DP) population. By 24 weeks, both immature and mature populations were markedly affected. Essentially no CD4+8+ cells were
evident, and only 8% of cells in thymuses from E2A-HLF mice
expressed one or both of the CD4 and CD8 differentiation antigens,
compared to 55% in normal mice. Based on these studies, E2A-HLF mice appeared to form a T-lymphoid compartment, but
it was severely hypoplastic and over a period of several months
underwent further marked decline, with loss of mature and immature
thymocytes exceeding the physiologic involution associated with normal
aging.
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FIG. 2.
Thymic hypoplasia and rapid involution in
E2A-HLF mice. (A) Total cell numbers were determined on
viable cell suspensions of thymuses (left) from transgenic and
nontransgenic (NTG) littermates at the indicated ages. Numbers of
splenocytes (right) expressing B220 or CD3 were determined by FACS at 4 weeks of age. Results represent the average and standard deviations of
determinations from four to six transgenic or two to four nontransgenic
animals at each time point. (B) Spleen cells (16 weeks of age) were
cultured at a density of 106 cells/ml in normal tissue
culture medium without addition of cytokines or mitogens. The number of
viable cells was determined by microscopy using a hemocytometer and
trypan blue exclusion. Data are means and standard deviations of
triplicate determinations from three animals in each cohort (open
boxes, E2A-HLF mice; filled boxes, nontransgenic mice). The
data for EµSV-bcl-2-22 (filled circles) are from reference
41. FACS analysis of splenocytes prior to
explantation showed a modestly skewed B/T ratio in E2A-HLF
mice. Numbers indicate percentages of cells in each phenotypic
subset.
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FIG. 3.
FACS analysis of premalignant thymocytes from
E2A-HLF mice and their nontransgenic (NTG) littermates.
Two-color contour plots show expression of CD4 and CD8 in thymocytes
from mice at different ages (indicated at the top). Progressive loss of
CD4+8+ DP and then SP thymocytes is observed in
E2A-HLF mice. Numbers indicate percentages of cells in each
phenotypic subset.
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B-cell development was also assessed by FACS analysis, given that
transgene expression was observed in the bone marrow. Total B-cell
(B220+) numbers in the spleen (Fig. 2A) did not differ
between transgenic and control mice. Analysis of B-cell differentiation
antigens (CD43, CD24, and BP1) showed that the percentages of immature and mature B cells in the bone marrow were comparable to those in
normal littermates (data not shown), indicating that there was not a
block in B-cell differentiation or preferential survival of specific
subpopulations. Splenocytes from E2A-HLF mice at 16 weeks
showed a modestly increased B/T-cell ratio by FACS analysis (Fig. 2B)
but did not display enhanced survival in vitro following their
explantation (Fig. 2B).
Progressive expansion of a primitive thymocyte subpopulation in
E2A-HLF mice.
In addition to the rapid thymic
involution observed in E2A-HLF mice, a proportion of cells
remaining in the thymus at 24 weeks displayed an atypical phenotype. In
E2A-HLF mice, most of the CD4+ thymocytes
expressed a lower level of surface CD4 compared to the high levels
present on single-positive CD4+8 thymocytes
in nontransgenic littermates (Fig. 3). Single-positive (SP;
CD4+8 and CD48+)
thymocytes typically represent late-stage thymocytes that also coexpress high levels of the TCR-associated protein CD3 and upon final
maturation exit the thymus to enter immunologically reactive sites such
as lymph nodes and the spleen. In E2A-HLF mice, however, FACS analysis showed that the majority of CD4+ thymocytes
at 24 weeks lacked coexpression of CD3 (Fig.
4A). Nearly 85% of cells in the
CD4+ compartment consisted of this phenotypically
atypical subpopulation characterized as
CD34lo8. These cells also
expressed low levels of the progenitor cell antigens c-Kit and CD25
(Fig. 4B) and lacked detectable TCR -chain expression (not shown).
This phenotype is similar to that of an early progenitor that
constitutes a very minor subpopulation in the normal thymus, consistent
with our inability to detect a comparable population in nontransgenic
controls (Fig. 4A). In E2A-HLF mice, however,
CD34lo8 cells were detected at
all time points including 4 weeks, when they constituted about 11% of
the CD4+ subset. Animals between 10 and 24 weeks showed
varying proportions of these phenotypically distinctive cells,
suggesting that they were progressively and preferentially accumulating
with increasing age (Fig. 4A). As determined by their forward light
scatter characteristics, CD34lo8 cells were the size of
small thymocytes (data not shown), suggesting a low proliferation index
consistent with their slow accumulation. They also appeared to be
confined to the thymus, since
CD34lo8 cells could not be
detected in comparable analyses of the spleen (Fig. 4A). FACS analysis
showed that splenic T-cell populations were relatively similar in their
subset distributions for transgenic and control littermates at all time
points (data not shown).
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FIG. 4.
Expansion of a primitive thymocyte population in
E2A-HLF transgenic mice. (A) Two-color contour plots of CD4
and CD3 expression in CD4+ gated thymocytes or splenocytes
from mice at different ages show accumulation of a
CD34lo population in thymuses of transgenic
but not normal mice. A similar population is not detected in the spleen
at 24 weeks. (B) Two-color contour plots demonstrating that
CD34lo gated thymocytes express low levels of
c-Kit and CD25. CD3+8+ thymocytes from same
transgenic animal served as a negative control.
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E2a-Hlf arrests thymocyte differentiation.
The presence and
progressive accumulation of a primitive thymocyte population in
E2A-HLF mice but not in normal littermates strongly
suggested a direct effect of transgene expression on early progenitors.
The identity of cells expressing E2a-Hlf was more directly addressed by
purification of specific subsets by using cell sorting followed by
Western blot analysis. The
CD34lo8 progenitor population
purified from thymuses at 24 weeks expressed high levels of E2a-Hlf
(Fig. 5, lane 9). In contrast, mature SP thymocytes coexpressing CD3 from the same thymus lacked detectable expression of E2a-Hlf (Fig. 5, lane 10). Furthermore, purified CD3+ splenocytes from 24-week E2A-HLF mice also
lacked E2a-Hlf detectable by sensitive Western blot analysis (lane 8),
indicating that mature T cells that had exited the thymus did not
express the transgene. Transgene expression could not be examined in
thymocytes at an intermediate stage of differentiation
(CD3+4+8+) from 24-week-old animals
since there were insufficient numbers of cells. However, the
CD3+4+8+ population was purified at
6 weeks of age, prior to their complete loss, and shown to express
E2a-Hlf but at substantially lower levels compared to
CD34lo8 cells (Fig. 5, lane
11). Therefore, the expanding progenitor population expressed
high-level E2a-Hlf, but T-lineage cells that had progressed beyond this
point showed either low or no E2a-Hlf expression. Taken together, these
data suggested that high-level E2a-Hlf expression was incompatible with
normal T-cell differentiation, leading instead to maturation arrest at
the progenitor stage.
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FIG. 5.
Expression of E2a-Hlf within various lymphoid
populations purified by flow sorting from E2A-HLF mice at 6 and 24 weeks of age. Identities and sources of the cell populations are
indicated above the gel lanes. Western blot analysis was performed with
an anti-E2a monoclonal antibody (24). Extracts from equal
numbers of cells were loaded per gel lane. The control lane contains
extract from transiently transfected cells expressing wild-type (wt)
and chimeric E2a proteins of human origin. Wild-type E2a proteins were
not detected in most lanes due to minimal cross-reactivity of the YAE
antibody with mouse E2a proteins (24) at the low amounts of
protein available for analysis.
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Although the foregoing analyses demonstrated that T cells resident in
the spleen lacked expression of E2a-Hlf, Western blot analysis detected
E2a-Hlf protein in unfractionated splenocytes isolated from 4- and
24-week-old animals (Fig. 1 and 5, lanes 3 and 7). The source of this
protein was investigated by additional flow sorting of splenocytes.
Most of the E2a-Hlf protein was found in the fraction of cells that
expressed the B-lineage antigen B220 (Fig. 5, lanes 5 and 8).
Therefore, in contrast to T cells, B-lineage cells in the spleen
expressed the transgene although at levels lower than that observed in
the CD34lo8 thymic progenitor population.
E2A-HLF transgenic mice develop lymphoid malignancies
of diverse phenotypes.
E2A-HLF transgenic mice displayed
increased mortality starting at about 6 months of age due to
development of lymphoid tumors. In a cohort of 36 transgenic animals
maintained over a period of 2 years, 60% (22 animals) succumbed to
tumors with a mean latency of 10 months (Fig.
6). An additional eight animals in this
cohort died of unknown causes with no evidence of tumor. No deaths from tumors were observed in a comparable cohort of nontransgenic
littermates. Tumor-bearing animals frequently presented with tachypnea
reflective of thymic enlargement and associated mediastinal
compression. Histologically, all tumors displayed the features of
diffuse lymphomas comprised of medium to large cells with round,
eccentric nuclei containing prominent nucleoli (Fig.
7A). Generalized lymphadenopathy and
splenomegaly were commonly present due to tumor infiltration that was
apparent on microscopic examination of these and other organs (Fig.
7B).
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FIG. 6.
Tumor development in E2A-HLF mice. The
mortality for a cohort (n = 28 animals) of
E2A-HLF mice is shown over the 27-month observation period.
Deaths were the result of malignant lymphoma confirmed by histologic
examination. No deaths from lymphoma were observed in a comparable
cohort of normal littermates.
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FIG. 7.
Histologic and molecular features of tumors arising in
E2A-HLF transgenic mice. (A and B) Tissue sections were
stained with hematoxylin and eosin for thymic tumor and liver
infiltrated by lymphoma, respectively (magnification, ×36). (C and D)
Immunohistochemical analyses showing CD3 and B220 expression in two
different thymic and nodal tumors, respectively. (E) Southern blot
analysis of TCR gene rearrangements in lymphomas. Dash indicates
migration of the germ line band. Lanes: C, germ line control; 1 to 3, 5, and 6, T-lineage tumors; 4, B-lineage tumor. (F) Western blot
analysis showing expression of E2a-Hlf in lymphomas (lanes 1 to 5, T
lineage; lane 6, B lineage).
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Tumors were phenotyped by FACS or immunohistochemistry to assess
cellular origin and extent of differentiation (Fig. 7C and D; Table
1). Most tumors consisted of T-lineage
cells since they expressed CD3, although the mean fluorescence
intensity varied from low to intermediate levels that were less than
the high levels typically found on normal SP
CD4+8 or CD48+
thymocytes. Tumors expressing CD3 also invariably coexpressed CD4 and
CD8, although they were occasionally heterogeneous with respect to the
intensity of CD4 or CD8 expression. The phenotypes were consistent with
a mid-thymocyte stage of differentiation and in some cases were similar
to that of transitional intermediates (CD3med4+8+). No tumors displayed a
phenotype comparable to that of the primitive CD34lo8 population. Gene
rearrangement analyses demonstrated that the T-lineage lymphomas were
mono- or oligoclonal based on the presence of one or several non-germ
line bands detected with TCR J2 probes in each tumor (Fig. 7E).
Monoclonality was further evidenced by analysis of tissues from two
different sites in single animals which revealed the same
configurations of rearranged bands (not shown). Western blot analyses
of tumor tissues demonstrated high-level expression of E2a-Hlf (Fig.
7F). Approximately 10% of tumors expressed the pan-B-cell antigen B220
in the absence of CD3, CD4, or CD8, indicative of an origin in the
B-cell lineage (Fig. 7D; Table 1). B220+ tumors generally
displayed germ line configurations of IGH and TCR
genes, suggesting that they arose from very early in the B-cell lineage. Taken together, these data demonstrated that
E2A-HLF mice were highly predisposed to development of
tumors originating from early within the T- or occasionally the
B-lymphoid lineage.
| |
DISCUSSION |
These studies identify a novel property of E2a-Hlf that is likely
to have important implications for its role in the pathogenesis of
human leukemias. When directed to the lymphoid compartments of
transgenic mice, E2a-Hlf displayed a potent capacity to antagonize the
differentiation of T-lymphoid progenitors in vivo and render them
highly susceptible to malignant transformation. High-level E2a-Hlf
expression was clearly incompatible with normal thymocyte maturation,
but we cannot rule out the possibility that it might have also
contributed to enhanced survival of a subset of primitive thymocytes
that progressively accumulated in E2A-HLF mice. Conversely, lower levels of E2a-Hlf expression appeared to be tolerated by B cells
without adverse effects on their differentiation. Notably, at these
levels of expression, E2a-Hlf did not appear to measurably enhance the
survival of mature or immature B-lymphoid lineage cells. Following
latencies of at least 6 months, T- and to a lesser extent B-lineage
progenitors were prone to development of malignancies that expressed
high levels of the transgene.
Initial examination of E2A-HLF mice showed severe decreases
in thymocyte numbers compared to control littermates. This was evident
as a rapidly evolving hypoplasia with over 90% involution of
transgenic thymuses by 24 weeks of age. The most affected cells were
the immature DP thymocytes. Normally, this population undergoes a
vigorous selection process based on TCR affinity toward recognized self
antigens in which unselected cells undergo apoptotic death and
survivors mature to ultimately exit the thymus and establish the
peripheral T-cell pool. E2a-Hlf did not enhance the survival of DP
thymocytes but, rather, induced their preferential loss. With the loss
of this maturing population, there was a subsequent decrease in the
mature SP CD4+8 and
CD48+ cells in transgenic thymuses at later
time points. Immature DP but not SP cells expressed E2a-Hlf, indicating
that E2a-Hlf expression and thymocyte maturation were incompatible.
Consistent with this conclusion, mature T cells isolated from the
spleen also did not express E2a-Hlf, indicating that the peripheral
T-cell compartment was composed of lymphocytes (in reduced numbers)
that had silenced the transgene by unknown mechanisms.
The thymic abnormalities in E2A-HLF mice are similar to
those observed in mice harboring deficiencies of apoptosis regulatory proteins that play important roles in negative selection of thymocytes. Premature loss of the DP thymocyte population occurs in mice
nullizygous for the death-repressing proteins Bcl-2 and
Bcl-xL (25, 31, 35, 42). These mice also display
a concomitant loss of the majority of peripheral mature SP T cells.
Decreased numbers of SP T cells are also seen in transgenic mice
ectopically expressing the death-promoting molecule Bax, while DP
thymocytes are increased in number (6). A possible
mechanism, therefore, for loss of DP thymocytes in E2A-HLF
mice could be mediated through effects on these apoptosis regulatory
genes. However, we detected no differences in their expression in
E2A-HLF transgenic thymuses compared with control
littermates (40). Disruption of T-cell homeostasis and malignant transformation also occurs in the thymus following
inactivating mutations of the E2A gene. Previous studies
have demonstrated partial loss of the DP population and thymic tumors
in E2A nullizygous mice (3, 44). These studies
suggest that perturbation of E2a-regulated transcriptional pathways in
the thymus has developmental and oncogenic consequences and that
thymocyte transformation can occur through loss of function. It is
unclear how much, if any, of the thymic phenotype induced by E2a-Hlf
can be attributed to disruption of E2a as opposed to Hlf pathways.
Further resolution of this issue will require an analysis of mice
expressing mutated forms of E2a-Hlf and/or dominant-negative forms of E2a.
E2a-Hlf expression, per se, did not appear to be incompatible with
B-cell maturation. Nearly all of the E2a-Hlf expression within the
spleen was accounted for by the B220+ mature B-lymphocyte
population. However, the levels of expression were substantially below
those observed in T-cell progenitors of the thymus. This is not easily
explained by possible expression bias of the transgene construct, since
the SV40 promoter/Eµ enhancer element is generally capable of
expressing at high levels in both the B- and T-cell compartments. We
cannot rule out the possibility that B-cell progenitors with high-level
E2a-Hlf expression were lost at early stages of differentiation,
comparable to the fate of E2a-Hlf-expressing DP thymocytes.
E2A-HLF mice did not develop hyperplastic B-cell
proliferations in the absence of tumors, and splenic B lymphocytes did
not display alterations in their survival properties. Although the
absence of perturbations in survival may reflect low-level transgene
expression in mature B cells, progenitor B-lineage tumors that
developed in E2A-HLF mice also did not display enhanced in
vitro survival in spite of high-level transgene expression. Therefore,
we observed no in vivo correlate of the previously reported ability of
E2a-Hlf to protect IL-3-dependent Baf3 cells from cell death induced by
cytokine withdrawal in vitro (21). The mechanistic basis for
the latter may involve transcriptional deregulation of subordinate
target genes by E2a-Hlf that are shared with cytokine transcriptional
regulators like NFIL-3 (18). However, recent studies show
that survival elicited by E2a-Hlf does not require the DNA binding and
dimerization motifs of Hlf (23). Alterations in survival,
therefore, may reflect dominant-negative perturbations in
transcriptional programs that are dependent on E2a and not primarily
subordinate to Hlf.
In addition to the rapid thymic involution observed in
E2A-HLF mice, there was concomitant emergence of an immature
T-cell population. This CD4lo83
(CD4lo) population, which increased from 11 to 85% of
total CD4+ thymocytes by 6 months of age, was
phenotypically similar to progenitor cells that have been identified in
the normal developing murine thymus (43). These native
progenitors are multipotent in their abilities to reconstitute cells of
T and B lineages as well as dendritic cells in vivo (1, 34).
Because of their limited numbers, we could not further address the
potential relationship of CD4lo cells in E2A-HLF
mice with native progenitors. Our studies, however, are consistent with
an E2a-Hlf-imposed developmental block at the CD4lo stage
(Fig. 8) due to high-level expression of
the E2a-Hlf protein. Recent studies suggest a role for Hlf in the
developing mammalian nervous system (10a). Thus, its ectopic
expression following fusion with E2a may perturb developmental programs
that are normally quiescent in the lymphoid compartment leading to
thymocyte developmental arrest. While our findings reveal a previously
unrecognized role for E2a-Hlf, they are consistent with the abilities
of other lymphoid oncogenes to disrupt thymocyte differentiation. For
example, thymocytes from E2A-PBX1 mice are arrested at a
transitional intermediate stage of thymocyte differentiation
(CD4+8+3med) and rapidly progress
to overt lymphomas (9). Furthermore, transgenic mice
ectopically expressing the oncogenes LMO1/RBTN1/TTG1 (32), LMO2/RBTN2 (27),
TAL-1 (28), or HOX11 (10)
manifest perturbations in thymocyte differentiation and succumb to
T-cell tumors.
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|
FIG. 8.
Schematic illustration of thymocyte maturational arrest
induced by E2A transgenes. The profile of thymocyte
differentiation is based on the data of Moore and Zlotnik
(34). Vertical bars denote stages of maturational arrest in
E2A-HLF and E2A-PBX1 mice, respectively. Temporal
expression profiles for selected surface antigens are shown below. TN,
triple negative.
|
|
Over 60% of E2A-HLF transgenic mice developed lymphoid
malignancies with a mean latency of 10 months, demonstrating the in vivo oncogenic capacity of E2a-Hlf. Occasional tumors displayed characteristics of B-lineage progenitors, the cell type targeted by
E2a-Hlf in pediatric ALL. However, similar to the E2A-PBX1 chimeric oncogene, E2A-HLF clearly favored development of
T-lineage tumors in transgenic mice, in spite of their consistent
associations with B-lineage progenitor leukemias in humans. The basis
for targeted transformation of developing thymocytes is unknown but is
consistent with a generally lower oncogenic threshold of murine
thymocytes, a predisposition potentially rendered by the complexity of
genetic changes that normally occur during TCR gene
recombinations in developing a functional repertoire. Within the
T-lineage compartment, however, the two E2A chimeric genes
display measurable differences in their propensities to target specific
subpopulations. In premalignant mice, E2a-Hlf resulted in the outgrowth
of very early (CD4lo) progenitors whereas E2a-Pbx1 targeted
more differentiated transitional intermediates (Fig. 8). Although we
cannot rule out variability attributable to regulatory elements of the
transgenes or their sites of integration, the differences mirror the
association of E2a-Hlf and E2a-Pbx1 with B-lineage precursors that are
characterized as pro-B (early)- and pre-B (later)-cell leukemias,
respectively, in pediatric ALL. These similarities suggest potential
stage-specific sensitivities of differentiating lymphocytes to
perturbations in Pbx and Hlf transcriptional programs. Therefore,
E2A-HLF transgenic mice should provide a useful model system
for studying the maturational arrest induced by this oncogene in
pediatric ALL.
| |
ACKNOWLEDGMENTS |
We gratefully acknowledge Carmencita Nicolas and Roxane Brown for
expert technical support, Stephen Hunger for helpful discussions, and
Mary Stevens for microinjections. We thank Phil Verzola and Beth Houle
for photographic support.
This study was supported by funds from the NIH (CA42971 and CA34233),
NIH training grants (CA09302 and AI-07290), a National Research Service
Award (CA66284) to K.S.S., and fellowship funds from the Howard Hughes
Medical Institute to L.N.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pathology, Stanford University Medical Center, Stanford, CA 94305. Phone: (650) 723-5471. Fax: (650) 498-6222. E-mail:
michael.cleary{at}stanford.edu.
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Molecular and Cellular Biology, June 1999, p. 4443-4451, Vol. 19, No. 6
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
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