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From the Department of Paediatrics, The University of Hong Kong,
Queen Mary Hospital, Hong Kong, China
Received for publication, May 16, 2000, and in revised form, September 22, 2000
The epidermal growth factor (EGF) family of
peptides signals through the erbB family of receptor tyrosine kinases
and plays important roles in development and tumorigenesis. Both EGF
and transforming growth factor (TGF)- Epidermal growth factor
(EGF)1 was initially
identified from mouse submaxillary gland extract as a stimulator of
eyelid opening and incisor eruption when injected into newborn mice and
rats (1). Mature human EGF is composed of 53 amino acids but is derived
from a much larger transmembrane precursor of 1207 amino acids (2). It
belongs to the EGF family of peptides that signals through the erbB
receptors, with EGF receptor being the prototype (3). EGF is released
from its precursor by a specific arginine estero-peptidase that, in
many cells, appears to be limiting (4). However, processing occurs in
granular convoluted tubules of the submandibular gland, and EGF is
released mainly into saliva (5).
Transforming growth factor (TGF)- Important information on the in vivo functions of erbB
signaling has been gained from transgenic mice that overexpress the ligand as well as loss of function mutants (9). Mice deficient in one
or all three of EGF, TGF- Various in vitro studies have shown that EGF reduces
synthesis of insulin-like growth factor (IGF) and IGF-binding protein-3 (22, 23). In vivo, IGF action is influenced by the
IGF-binding proteins (IGFBPs). Six IGFBPs have been found that differ
in their influence on IGF activity. Besides increasing the half-life of IGFs in circulation, IGFBPs can potentiate activities of IGFs on cell
proliferation. In addition, IGF-independent regulatory mechanisms of
IGFBPs have been described. IGF-independent growth inhibition by
IGFBP-3 is believed to occur through IGFBP-3-specific cell surface
association proteins or receptors and involves nuclear translocation
(24). Several transgenic mouse models overexpressing IGFBP-1, -2,-3, or
-4 have been developed over the past few years (25). The overexpression
of IGFBP-3 under the control of a ubiquitous promoter resulted in
selective organomegaly (26). Recent data indicate that low levels of
IGFBP-3 are associated with stunted growth and an increased risk of at
least several types of carcinoma that are common in economically
developed countries (24, 27). Additional studies are required to
determine the clinical relevance of these findings.
To elucidate the role of EGF in vivo, we have recently
overexpressed hEGF in transgenic mice. The two major phenotypes were infertility and stunted growth (28). Here we investigated the possible
mechanisms leading to the growth problem and the relationship between
EGF and IGFBP-3.
Generation of Transgenic Mice--
The procedures for
microinjection have been described previously (29). The DNA construct
consisted of hEGF with the Radioimmunoassay of Serum IGFBP-3--
Blood was collected by
cardiac puncture immediately after the animal was sacrificed by
cervical dislocation. The blood samples were allowed to clot for 15 min
on ice, and then serum was collected by centrifugation. Aliquots were
stored at Histology of Long Bone in Postnatal Mice--
The hind limb was
dissected away from tendon and muscle and then fixed in 4%
paraformaldehyde overnight at 4 °C. Bone was decalcified using a
procedure described in Ref. 31 modified as follows: bone was washed
four times with water for 15 min each and then immersed in 20% EDTA in
water and kept at 4 °C. EDTA solution was changed every second day
during the first week and every third day during the second week or a
longer period. Finally, bone was washed for a total of at least 6 h with five changes of water before embedding in fibrowax (Gurr,
BDH). Sections were cut at 6-µm thickness.
Immunohistochemistry--
Antigen detection was based on the
streptavidin-biotinylated peroxidase system (Dako). The procedures have
been described in detail previously (32). To detect human but not mouse
EGF protein, the polyclonal antibody Ab-3 (Calbiochem) was used at a
dilution of 1:1000 for bone sections. Sections from nontransgenic mice
were used as negative controls. Endogenous EGF expression was
identified using a polyclonal anti-mouse EGF antibody (Serotec) at a
dilution of 1:500 and 1:1000. To confirm the specificity of signals
obtained with anti-mouse EGF antibody, the diluted antibody was
preincubated with 10 mM murine natural EGF (Life Technologies, Inc.) overnight at 4 °C before use.
Reverse Transcription-PCR--
Expression of EGF was studied in
a chondrocyte cell line, MCT, which was derived from mouse rib
primary chondrocytes immortalized with temperature-sensitive large T
antigen. At a nonpermissive temperature of 37 °C, these cells stop
growing and acquire characteristics of hypertrophic chondrocytes (33).
Total RNA was extracted, DNase-digested, quantified by absorbance at
260 nm, reverse-transcribed with oligo(dT), and PCR-amplified as
described previously (34). EGF was amplified with primers
5'-GAGAATTCCGCCTGCACCAAC and 5'- TCGTCGCCCCGTCGACACCTAGG. After 30 cycles of 94 °C for 30 s, 57 °C for 30 s, and 72 °C
for 1 min, half of the product was electrophoresed. cDNA samples
from mouse adult kidney and embryos at day 17.5 were used as positive
controls. Amplification with primers for hypoxanthine phosphoribosyl
transferase (hprt), 5'-CCTGCTGGATTACATTAAAGCACTG and
5'-GTCAAGGGCCATATCCAACAACAAC, served as a PCR control. After 30 cycles
(94 °C for 30 s, 55 °C for 30 s, and 72 °C for 1 min), one-eighth of the product was electrophoresed.
We have recently reported the generation of EGF transgenic mice.
They all expressed human EGF protein at high levels in various organs,
and their fertility problem has been reported previously (28). Growth
rate and body weight were compared with those of nontransgenic
littermates. All transgenic animals were born at only half the weight
of their normal littermates. They caught up by day 20 and reached 78%
of the weight of nontransgenic littermates at adulthood (Fig.
1A). The transgenic mice
appeared to be proportionate dwarfs. In the current study, we focused
on investigating the mechanism leading to stunted growth.
EGF Reduced Serum IGFBP-3--
IGF-I is known to be a mediator of
growth hormone action in pubertal growth (35). It also acts from
gestation day 13.5 onward in prenatal mice in a growth
hormone-independent manner, whereas IGF-II controls growth earlier in
gestation (36). In humans, IGF-I, but not IGF-II, has also been shown
to be involved in the control of fetal size during the later months of
intrauterine life (37). The molar concentration of serum IGFBP-3
roughly equals the sum of the IGF-I and IGF-II molar concentrations
(38). We speculated that EGF exerted its effect on growth through the IGF system, and we measured the concentration of serum IGFBP-3. Serum
IGF-I could not be reliably quantified with the system we have been
using for measuring human IGF-I. The mean IGFBP-3 level of transgenic
mice (182.5 ± 94.4 ng/ml; n = 4 founders; 2-9
months old) was significantly lower (p = 0.0011) than
that of normal adult mice (425.1 ± 74.6 ng/ml; n = 12; 8-9 months old; Fig. 1B). One female transgenic
founder was sacrificed at 2 months in the pilot study to detect
transgene expression and found to have embryos at around day 7.5 of
gestation. Serum IGFBP-3 level increased with pregnancy (39). Still,
its value (349 ng/ml) was relatively lower than that of nonpregnant
controls. The results suggest that the action of EGF on growth was
mediated at least in part through decreasing serum IGFBP-3. All
transgenic mice expressed hEGF in various organs to a similar level as
judged by Western analysis (28). Our data suggested that EGF may change
the production/secretion of IGFBP-3 in liver and kidney. Transgenic
mice overexpressing different IGFBPs have been very useful for
addressing the specific functions of IGFBPs (25). Overexpression of
IGFBP-3 resulted in selective organomegaly that differed from
the major sites of transgene expression (26). We believe that in our
transgenic mice, reduced serum IGFBP-3 is the result of EGF
overexpression rather than a secondary effect of growth retardation. In
a recent study (40), EGF administered for 7 days to young adult rats was shown to significantly lower IGFBP-3 levels to 44% of control values without affecting the body weight, whereas circulating IGFBP-1
and -2 levels were unaffected. It has also been shown by Frystyk
et al. (41) that injection of EGF for 4 weeks into adult
rats decreased serum IGF-I and IGFBP-3. The authors discussed that most in vitro studies, including those on hepatocytes,
reported an increase in IGF-I after EGF stimulation. The discrepancies between in vivo and in vitro studies may be
explained by changes in IGFBPs. In both situations, EGF reduced
IGFBP-3. In vitro, reduced IGFBP-3 would increase free
IGF-I. In vivo, reduced IGFBP-3 would decrease circulating
IGF-I because most IGF-I is bound to IGFBP-3 (41). In transgenic mice
overexpressing interleukin-6, growth impairment was also correlated
with reduced IGF-I (42). In IGF-I null mutants, the mice were smaller
from embryonic day 12.5 (36). In our case, EGF also acted prenatally
because we noticed that all transgenic mice identified at weaning were
small from the day of birth. Our data are in agreement with the
hypothesis that EGF affects the production/secretion of IGFBP-3, hence
decreasing the availability of IGFs and resulting in slower growth
before and after birth.
Abnormal Proliferation of Osteoblasts--
To gain further
insights into the effects of EGF overexpression on bone development, we
investigated the histology of long bones of transgenic mice. In wild
type mice, osteoblasts were found as an even lining along the bone
cortex both on the outer surface (periosteum) and inner surface along
the marrow cavity (endosteum). In transgenic mice, hEGF immunostaining
was found in both the periosteum (Fig.
2A) and the endosteum (Fig.
2B). In addition, abnormal accumulation of osteoblasts in
the periosteum and/or endosteum was found in some areas
(Fig. 2D). This imbalance in bone remodeling, however, did
not result in thickening of the cortical bone. In contrast, we found
that the thickness of the cortical bone in transgenic mice was reduced
compared with that of normal mice (data not shown). It has been shown
that in cultured fetal rat long bone, EGF stimulated thymidine
incorporation at a low concentration, whereas it stimulated bone
resorption at a higher concentration (43). The long bone has also been shown to harbor EGF receptors in osteoblast-like cells (44). Our data
raised the possibility that EGF overexpression increased osteoblast
proliferation in vivo.
Endogenous EGF Is Expressed Mainly in Hypertrophic
Chondrocytes--
Unlike normal mice at 6 months of age (Fig.
3A), the growth plate of our
transgenic animals still contained columns of chondrocytes consisting
of a considerable number of prehypertrophic chondrocytes (Fig.
3B). However, the signal of hEGF immunostaining in the
growth plate of our transgenic animals was too weak to be detected.
Ideally, the growth plate of younger transgenic animals should be
studied. To gain insight into the normal role of EGF in bone
development, we studied endogenous EGF expression in the growth plate
of fetal (day 14.5-17.5), 2-day-old, 2-week-old, and 4-week-old mice.
EGF was strongly expressed in some proliferating and all hypertrophic chondrocytes at all stages studied (Fig.
4, A and B). The
specificity of immunostaining was shown by the fact that it could be
blocked by preabsorbing the antibody with 10 mM EGF.
Similar results were obtained by Tajima et al. (45), who
reported staining in resting, proliferating, and hypertrophic zones of
the adult mouse femur epiphyseal plate. We further substantiated our
findings by studying the expression of EGF in a mouse chondrocyte cell
line, MCT. At a nonpermissive temperature of 37 °C, the cells stop
growing and express molecular markers of hypertrophic chondrocytes such
as type X collagen and osteopontin (33). By reverse transcription-PCR, we found EGF expression only when MCT cells differentiated to hypertrophic chondrocytes at 37 °C (Fig. 4C). Although
TGF- Comparison with TGF-
Of the four features originally observed when EGF was injected into
newborn animals, accelerated eyelid opening and incisor eruption were
most striking. In addition, abnormal skin structure and stunted growth
occurred at high doses of EGF (1). In our transgenic mice, only growth
retardation was remarkable and would be attributed to the decrease of
IGFBP-3. Because other phenotypes encountered in the previous study
were not observed in our transgenic mice, the mechanism of action of
EGF on eyelid opening and incisor eruption might be different from that
on growth. To our knowledge, this is also the first report on the
in vivo effects of EGF on chondrocyte and osteoblast
proliferation. During bone development, EGF may play a role in
chondrocyte hypertrophy. We also provide in vivo evidence
that EGF overexpression did not lead to tumorigenesis in our transgenic
animals. Additional studies to reveal the distinct biological effects
of EGF and TGF- We thank Dr. Véronique Lefebvre for the
gift of MCT, our colleagues at Hong Kong University (Dr. Danny Chan,
Victor Leung, Keith Leung, Kingston Mak, Davy Lee, and Anthony Chan)
for enthusiastic help, and Prof. Louis Low for help with
radioimmunoassay. We thank Dr. Kuma Kaluarachchi for expert
advice on bone analysis. We are also grateful to Drs. M. Setou, Y. Okada, and S. Takeda (University of Tokyo, Tokyo, Japan) for
constructive comments on the manuscript.
*
This work was supported by a grant from the Hong Kong
Research Grants Council (to S.-Y. C.).The costs of publication of this article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
To whom correspondence should be addressed. Tel.: 852-28554634;
Fax: 852-28551523; E-mail: sychan@hkucc.hku.hk.
¶
Recipient of the Lee Po Chun Overseas Scholar Award (2000).
Published, JBC Papers in Press, September 22, 2000, DOI 10.1074/jbc.M004189200
The abbreviations used are:
EGF, epidermal
growth factor;
TGF, transforming growth factor;
hEGF, shortened human
EGF precursor;
IGFBP, insulin-like growth factor-binding protein;
IGF, insulin-like growth factor;
PCR, polymerase chain reaction.
Expression of Epidermal Growth Factor in Transgenic Mice
Causes Growth Retardation*
§ and¶
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only bind to erbB1 and
activate it. The precursor of EGF is distinct from that of TGF- in
having eight additional EGF-like repeats. We have recently shown that the EGF precursor without these repeats is biologically active and
leads to hypospermatogenesis in transgenic mice. Here we present evidence that the growth of transgenic mice widely expressing this
engineered EGF precursor is also stunted. These mice were consistently
born at half the normal weight and reached almost 80% of normal weight
at adulthood. The mechanism involved a reduction of serum insulin-like
growth factor-binding protein-3. Chondrocyte development in the growth
plate was affected, and osteoblasts accumulated in the endosteum and
periosteum. Besides these novel findings on the in vivo
effects of EGF on bone development, we observed no sign of tumor
formation in our transgenic animals. In contrast to previous reports on
TGF- transgenic mice, we show that the biological functions of EGF
and TGF- are clearly distinct.
INTRODUCTION
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binds to the EGF receptor with an
affinity similar to that of EGF, and the two share many biological
effects. TGF- is a 50-amino acid polypeptide derived from a
160-amino acid membrane-bound precursor. It was initially isolated as
one of the transforming peptides from sarcoma virus-transformed fibroblasts (6). EGF, TGF-, and amphiregulin only bind and activate
EGF receptors (also called erbB1 and HER1) (7), and they are referred
to as group one of the EGF family. In recent years, information on the
EGF family and erbB receptor family has expanded rapidly. In in
vitro studies on cells expressing multiple erbB family members,
signal specificity was shown to be controlled by ligand specificity as
well as receptor homo- and heterodimerization (8).
, and amphiregulin revealed their distinct
role in mammary gland development (10). Mice without TGF- or with a
mutant EGF receptor showed an identical phenotype of affected hair and
eyelid development (11-13). In addition to these defects, mice with a
null mutation in EGF receptor died at peri-implantation, midgestation,
or shortly after birth, depending on their genetic background (14-16).
In cancer tissues, overexpression of EGF receptor, TGF-, and
amphiregulin, but not EGF, is frequently found (7). In agreement with
this observation, transgenic mice overexpressing TGF- showed
epithelial hyperplasia of several organs, pancreatic metaplasia, and
breast carcinoma (17, 18). Amphiregulin was found to be a preneoplastic
tumor marker in transgenic models of mammary tumors, including
transgenic mice of TGF- and erbB2 (19). Expression of
amphiregulin in basal keratinocytes induced a psoriasis-like phenotype
in transgenic mice (20). To provide further information on the
physiological and pathological roles of EGF and to distinguish its
in vivo effects from those of other EGF receptor ligands, we
have generated transgenic mice widely expressing a shortened human EGF
precursor (hEGF). The eight EGF-like repeats were deleted, leaving the
active EGF domain in the transmembrane form. This would release the
effect of EGF-like repeats, if any, on the exposure of the EGF domain
and allows direct comparison of its effects with TGF-. Our previous
study has shown that hEGF, like the full-length precursor, is
biologically active in transforming NIH3T3 (21).
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-actin promoter to give widespread
expression in transgenic animals. The eight EGF-like repeats in the
extracellular domain of hEGF were removed as described previously (21).
Transgenic mice were characterized by Southern analysis,
immunoblotting, and immunohistochemistry of hEGF (28, 30).
20 °C. Serum IGFBP-3 was measured using undiluted serum
with the immunoradiometric assay kit from Diagnostic Systems
Laboratories, Inc. Controls were age- and strain-matched normal mice
including nontransgenic littermates. The statistical difference between
the transgenic and control groups was analyzed using the Mann-Whitney test.
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View larger version (32K):
[in a new window]
Fig. 1.
Reduced body weight and IGFBP-3 in transgenic
mice. A, the ratio of mean weight of transgenic mice
(n = 4 founders) to that of wild type littermates
(n = 4) at various time points after birth.
B, serum IGFBP-3 levels of the four above-mentioned founders
as determined by radioimmunoassay. The wild type value was obtained
from 12 mice including their 4 littermates. Values shown are the
mean ± 1 S.D.
View larger version (104K):
[in a new window]
Fig. 2.
Abnormality of osteoblasts.
Immunostaining of hEGF (brown) in the osteoblasts
lining the periosteum (A) and endosteum (B) of
transgenic mice. C, hematoxylin and eosin staining to reveal
the typical morphology of osteoblasts. A single layer of osteoblasts
(arrow) lines the endosteum in wild-type mice. D,
in contrast, there were irregular clumps of osteoblasts in transgenic
mice. The tibia is shown. Scale bars, 25 µm.
expression has been reported in a number of cell lines, to our
knowledge, cell lines expressing EGF are rare. We suggest a specific
role for EGF in the last stages of chondrocyte differentiation. The MCT
cell line will allow us to study the regulation of EGF
production and its role in chondrogenesis.
View larger version (111K):
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Fig. 3.
Growth plate in transgenic mice.
Hematoxylin and eosin-stained sections of the proximal tibia from
(A) a wild type 6-month-old mouse and (B) a
representative transgenic mouse still show clear columns of
chondrocytes. Scale bars, 25 µm.
View larger version (70K):
[in a new window]
Fig. 4.
Endogenous EGF expression in hypertrophic
chondrocytes. A, EGF immunostaining (brown)
was found in some proliferating chondrocytes (arrow) but was
found mainly in hypertrophic chondrocytes (arrowhead). The
hind limb of a 14.5-day embryo is shown. B, immunostaining
of hypertrophic chondrocytes shown at a higher magnification. The
pattern of EGF expression was found to be the same at 2 days, 2 weeks,
and 4 weeks after birth (data not shown). Scale bars, 25 µm. C, reverse transcription-PCR analysis of EGF
expression in MCT cells. EGF was switched on when MCT cells
were allowed to differentiate at 37 °C for 1 day (lane 3)
and was maintained at 3 days (lane 4). Adult kidney is known
to have high EGF expression (lane 5). Whole
embryos at 17.5 days were also used as controls without (lane
6) and with reverse transcription (lane 7).
Amplification with hprt primers served as a PCR control
(bottom panel). Product size: EGF, 503 base
pairs; hprt, 352 base pairs.
Transgenic Mice: A Role for EGF in
Tumorigenesis?--
Because both EGF and TGF-, as well as their
precursors, activate EGF receptors (46-48), we compared the phenotype
of our mice with that reported for transgenic mice overexpressing
TGF- or the TGF- precursor (17, 18). Transgenic mice
overexpressing TGF- weighed approximately 10% less than the control
mice (49). None of the neoplastic changes reported in liver,
coagulation gland, and pancreas of TGF- mice was observed in
our mice at a gross or histological level, despite the expression of
hEGF in these organs as detected by immunohistochemistry and/or Western blotting. Indeed, we observed patch necrosis in the liver of all of our
transgenic animals (Fig. 5). This was in
sharp contrast to liver enlargement and increased proliferation in
TGF- mice (49). These data suggested an important functional
difference between EGF and TGF-.
View larger version (121K):
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Fig. 5.
Liver necrosis in transgenic mice.
Hematoxylin and eosin staining of wild type (A) and
transgenic (B) liver is shown. Immunostaining of hEGF in
wild type (C) and transgenic (D) liver is shown.
Positive staining (brown) was detected in sinusoid cells of
transgenic mice. Scale bars, 25 µm.
in vivo are under way in our laboratory.
We are also generating transgenic mice expressing EGF in a
tissue-specific manner to distinguish the systemic
versus paracrine effects of EGF.
ACKNOWLEDGEMENTS
FOOTNOTES
The contribution of these two authors was equal.
Present address: Department of Anatomy and Cell Biology,
Graduate School of Medicine, University of Tokyo, Tokyo
113-0033, Japan.
ABBREVIATIONS
REFERENCES
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