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Molecular and Cellular Biology, March 2000, p. 2055-2065, Vol. 20, No. 6
0270-7306/00/$04.00+0
Disassociation of Met-Mediated Biological Responses
In Vivo: the Natural Hepatocyte Growth Factor/Scatter Factor Splice
Variant NK2 Antagonizes Growth but Facilitates Metastasis
Toshiyuki
Otsuka,1
John
Jakubczak,1
Wilfred
Vieira,2
Donald P.
Bottaro,3
Diane
Breckenridge,3
William J.
Larochelle,3 and
Glenn
Merlino1,*
Laboratories of Molecular
Biology,1 Cell
Biology,2 and Cellular and Molecular
Biology,3 National Cancer Institute,
National Institutes of Health, Bethesda, Maryland 20892
Received 27 September 1999/Returned for modification 30 November
1999/Accepted 17 December 1999
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ABSTRACT |
Hepatocyte growth factor/scatter factor (HGF/SF) stimulates
numerous cellular activities capable of contributing to the metastatic phenotype, including growth, motility, invasiveness, and morphogenetic transformation. When inappropriately expressed in vivo, an HGF/SF transgene induces numerous hyperplastic and neoplastic lesions. NK1 and
NK2 are natural splice variants of HGF/SF; all interact with a common
receptor, Met. Although both agonistic and antagonistic properties have
been ascribed to each isoform in vitro, NK1 retains the full spectrum
of HGF/SF-like activities when expressed as a transgene in vivo. Here
we report that transgenic mice broadly expressing NK2 exhibit none of
the phenotypes characteristic of HGF/SF or NK1 transgenic mice.
Instead, when coexpressed in NK2-HGF/SF bitransgenic mice, NK2
antagonizes the pathological consequences of HGF/SF and discourages the
subcutaneous growth of transplanted Met-containing melanoma cells.
Remarkably, the metastatic efficiency of these same melanoma cells is
dramatically enhanced in NK2 transgenic host mice relative to wild-type
recipients, rivaling levels achieved in HGF/SF and NK1 transgenic
hosts. Considered in conjunction with reports that in vitro NK2 induces
scatter, but not other activities, these data strongly suggest that
cellular motility is a critical determinant of metastasis. Moreover,
our results demonstrate how alternatively structured ligands can be
exploited in vivo to functionally dissociate Met-mediated activities
and their downstream pathways.
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INTRODUCTION |
Hepatocyte growth factor/scatter
factor (HGF/SF) possesses an impressive panoply of biological
activities, thereby regulating cellular proliferation and a variety of
morphogenetic processes, including cellular migration, extracellular
matrix invasion, branching, and tubulogenesis (reviewed in references
15, 21, 29, 51, and 73). Effects
of this multifunctional cytokine are all mediated through its cell
surface receptor tyrosine kinase (RTK), encoded by the c-MET
proto-oncogene (4, 12, 32, 37). Upon HGF/SF binding, MET
engages a number of SH2-containing signal transducers, including
phosphotidylinositol 3-kinase, phospholipase C-
, Stat3, Grb2, and
the Grb2-associated docking protein Gab1, and indirectly activates the
Ras-mitogen-activated protein kinase (MAPK) pathway (39, 40, 69,
70). Typically, HGF/SF is produced in cells of mesenchymal
origin, influencing Met-expressing embryonic and adult epithelium
through a paracrine mechanism (19, 59, 64). Gene targeting
studies have demonstrated that activation of signaling pathways
downstream of Met is essential for development of murine skeletal
muscle, liver, and placenta (3, 53, 67). In accordance with
its various effects on cultured cells, HGF/SF is thought to regulate
epithelial-mesenchymal conversion and migration of myogenic precursor
cells in vivo.
Chronic MET activation induces the genesis and, more significantly,
progression of a multitude of human and murine tumors, including
melanomas (for example, see references 2, 13, 14, 22, 33, 41,
43, 44, 46, 47, and 65). MET activation can be achieved through coexpression of HGF/SF, resulting in the creation of an autocrine signaling loop (2, 13, 43, 45, 65).
In addition, critical genetic evidence for a role for c-MET in human cancer has come from the discovery that activating
c-MET mutations are associated with hereditary papillary
renal carcinoma (24, 54, 74). As during embryogenesis, a
number of activities ascribed to HGF/SF and Met activation undoubtably
contribute to the manifestation of the full metastatic phenotype. These
include stimulation of angiogenesis, degradation of local extracellular matrix, production of cell adhesion molecules, migration into vessels
and tissues, and colonization at a distant site (reviewed in references
29 and 48).
HGF/SF shows a 38% overall sequence similarity with plasminogen
(15) and a 45% identity to HGF-like/macrophage-stimulating protein at the amino acid level (17, 72). The 92-kDa HGF/SF possesses several recognizable structures, which are shared by all
family members, including the presence of an enzymatically inactive
serine protease domain in the 
chain, and an N domain and four
kringle domains in the 
chain (Fig.
1A). Kringles are highly conserved,
three-disulfide, triple-loop polypeptides thought to participate in
protein-protein interactions (reviewed in reference 66). HGF/SF mRNA can undergo alternative splicing to
create truncated isoforms (Fig. 1A), capable of binding to the HGF/SF receptor with relatively high affinity. Historically, defining the
biological activities associated with these variants has been somewhat
elusive and a point of contention in the field. One natural variant
consisting of the N domain and the first two kringle domains, designated NK2, was originally found to be incapable of stimulating the
growth of cultured human mammary epithelial cells but instead antagonized HGF/SF-induced mitogenesis (6, 30). However, NK2
was later reported to act as a partial agonist, able to scatter certain
cultured epithelial cells (18, 60). More recently, NK2 was
shown to be incapable of triggering induction of tissue inhibitor of
metalloproteases 3, urokinase-type plasminogen activator proteolysis,
invasion, or tubulogenesis in some cells (5, 23, 31).
Interestingly, a unique bivalent monoclonal antibody against a
non-binding-site epitope of the extracellular domain of human HGF/SF
was, like NK2, found to stimulate cell motility but no other
Met-associated activity (42). A second truncated HGF/SF, NK1, was first artificially engineered to consist of the N domain and a
single kringle domain but was later found to occur naturally in mouse
cells as well (9, 28, 60). NK1 was also originally reported
to possess activities antagonistic to HGF/SF in terms of mitogenesis
(28) but later found to stimulate mitogenic and motogenic
activities (9). Schwall et al. (55) have provided evidence suggesting that the presence of cell surface heparan sulfate
proteoglycans can facilitate NK1 mitogenic activity by inducing ligand
dimerization. An artificial four-kringle mutant, NK4, was reported to
inhibit the mitogenic, motogenic, and morphogenic activities of HGF/SF
in vitro (10). Taken together, these data indicate that the
in vitro biological activities of these HGF/SF variants are context
dependent and greatly influenced by the target cell and the culture
conditions in which those cells are grown; moreover, they stand as a
testament to the requirement for in vivo models to assess their bona
fide activities.
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FIG. 1.
Structure and expression of NK2. (A) Schematic
comparison of HGF/SF (designated as HGF in this and all other figures)
and its natural splice variants NK2 and NK1. Each isoform contains a
single so-called N domain at the amino terminus, and either four, two,
or one kringle domain, as shown. However, only HGF/SF is processed into
two chains, the chain containing an enzymatically inactive serine
protease domain. (B) The SalI-SalI NK2 transgene
construct contained the human NK2 cDNA, the mouse MT gene promoter
(mMT-1) and 5' and 3' flanking sequences (MT LCR), and the hGH poly(A)
signal. Mice harboring the NK2 transgene were identified by PCR using
primers MT-S and GH-A, as indicated. (C) Analysis of NK2 transgene
expression in mouse tissues by Northern blot hybridization. For
embryonic expression (three-lane panel at left), wild-type (wt) embryos
were harvested at E16.5, and transgenic embryos from line MN2-38
(38) were harvested at E14.5 (middle lane) and E16.5 (right
lane). Adult (2-month-old) tissues from three independently generated
lines, MN2-17, MN2-38, and MN2-13, were studied. Tissues analyzed
included liver (L), kidney (K), skeletal muscle (M), and skin (S). The
control lanes at far right show expression of HGF/SF sequences in
livers of wild-type and HGF/SF and NK1 transgenic mice. Following
hybridization with a human NK2 cDNA probe (top panels), the filter was
stripped and rehybridized with a control GAP cDNA probe (bottom
panels).
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To this end, we have generated a series of transgenic mice in which
either HGF/SF, NK1, or NK2 was broadly expressed using a mouse
metallothionein (MT) promoter and associated locus control regions
(LCRs) to regulate transcription. Previously, we demonstrated that
ectopic expression of HGF/SF had pleiotropic phenotypic consequences, including enhanced liver growth and regeneration, progressive renal
disease characterized by glomerulosclerosis, disruption of the
olfactory mucosa, aberrant appearance of skeletal muscle in the central
nervous system, patterned hyperpigmentation and aberrant localization
of melanocytes in the dermis and epidermis, precocious mammary
lobuloalveolar development, and susceptibility to diverse tumorigenesis
(52, 61-63) (Fig. 2). More
recently, we reported that mice expressing an NK1 transgene exhibited a remarkably similar array of phenotypes, albeit with reduced severity, indicating that NK1 is a partial agonist of HGF/SF in vivo
(20). In striking contrast, here we demonstrate that NK2 can
antagonize most of the phenotypic consequences of HGF/SF expression in
mice harboring both transgenes. However, by employing various
genetically modified host mice as tumor transplant recipients, we show
that NK2 alone retains an impressive ability to facilitate the
metastasis of melanoma cells expressing high levels of Met.
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FIG. 2.
NK2 extinguishes the phenotypic consequences of ectopic
HGF/SF expression in bitransgenic mice. Shown are panels of tissues,
including kidney (A to D), olfactory mucosa (E to H), and virgin
mammary gland (I to L), from wild-type (A, E, and I), NK2 transgenic
(B, F, and J), HGF/SF-NK2 bitransgenic (C, G, and K), and HGF/SF
transgenic (D, H, and L) mice. Tissues shown are from mice 2.5 months
of age. Note that bitransgenic tissues resemble wild-type tissues and
do not contain the pathological features characteristically evident in
HGF/SF transgenic animals.
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MATERIALS AND METHODS |
Generation and identification of transgenic mice.
NK2
transgenic mice were generated on an albino FVB/N genetic background
employing the expression construct used previously for the HGF/SF and
NK1 transgenic mice. Expression of the human NK2 cDNA was placed under
the control of the mouse MT-1 promoter. The construct included the
human growth hormone (hGH) polyadenylation site [poly(A)] and the 5'
and 3' flanking regions of mouse MT genes (Fig. 1B). These contain LCRs
conferring copy-number-dependent and integration-site-independent
transgene expression (36). NK2 transgenic mice were
identified by PCR using as template tail genomic DNA and the following
primer set: MT-S (5'-ACTCGTCCAACGACTATA-3'), specific to the
MT promoter region, and GH-A (5'-AACTTCCAGGGCCAGGAGA-3'), specific to the hGH-poly(A) sequence. HGF/SF transgenic mice were identified by PCR using the following primer set: HGF315
(5'-AGTTATGGTTGTACAATCCCTGAAAAGA-3'), specific to the chain of mouse HGF/SF sequence, and GH-A. NK1 transgenic mice were
identified by PCR using the following primer set: MT-S and HGF292
(5'-CTGAGGAATGTCACAGACTTCGTA-3'), specific to the first
kringle domain sequence of mouse HGF/SF cDNA. Diagnostic PCR products
for the presence of the NK2, HGF/SF, and NK1 transgenes were 1,019, 451, and 709 bp, respectively. Where noted, mice were maintained on 25 mM ZnSO4 in their drinking water. All mouse work was
performed in accordance with the Guide for the Care and Use of
Laboratory Animals (33a).
Histopathological assessment and liver growth analysis.
For
routine histopathological analysis, mouse tissues were fixed in 10%
buffered formalin, embedded in paraffin, sectioned at 5 µm, and
stained with hematoxylin and eosin (H&E). Metastatic melanomas were
visualized using an anti-mouse tyrosinase-related protein 1 (TRP1)
antibody, PEP1 (35), a gift from Vincent Hearing, National Cancer Institute, Bethesda, Md. For comparative analysis of
hepatocyte proliferation in vivo, five to seven 1.5-month-old mice of
each genotype that had been maintained on ZnSO4 water were
given intraperitoneal injections of bromodeoxyuridine (BrdU), according
to the manufacturer's instructions (Amersham Life Science; RPN201).
After 2 h, all mice were euthanatized and their liver tissues were
fixed in 70% ethanol. BrdU incorporation was then detected
immunohistochemically (56), and labeled hepatocyte nuclei
from between 422 and 589 high-power light microscope fields (400×) for
each genotype were scored. For determination of liver growth, between
18 and 27 female mice of each genotype between 1.5 and 3.0 months of
age were used. Exposure to ZnSO4 water had no overt effect
on liver mass, so data from zinc-treated and non-zinc-treated animals
were combined.
Analysis of RNA.
NK2 transgene expression in selected adult
(2-month-old) tissues was assessed 6 h after intraperitoneal
injection of 5 mg of ZnCl2 per kg of body weight. To
compare transgene expression with liver weight/body weight ratios,
total RNA was isolated from 1.5-month-old transgenic and bitransgenic
female mice maintained on 25 mM ZnSO4 water. For fetal
expression, E14.5 and E16.5 mouse embryos were used for RNA isolation.
Total RNA was prepared using guanidine thiocyanate, as described
previously (25). For Northern blot analysis, 15 µg of
total RNA was resolved on a denaturing 1% agarose-formaldehyde gel and
transferred to a nitrocellulose membrane (Schleicher & Schuell). The
membrane was prehybridized and hybridized at 42°C in a solution whose
contents included 50% formamide and 6× SSC (1× SSC is 0.15 M NaCl
plus 0.015 M sodium citrate), washed, and subjected to autoradiography
(25). The 2.2-kbp mouse HGF/SF cDNA probe was synthesized by
PCR, as described previously (62). The 636-bp mouse NK2
probe, covering only the first and second kringle domain of the HGF/SF
cDNA, was synthesized by PCR using the following primer set: HGF313S
(5'-GAGTGTGCCAACAGGTGTATCAGG-3') and HGF291
(5'-AATTGCACAATACTCCCAAGGGGT-3'). For analysis of MT expression, a 355-bp BamHI mouse MT-1 cDNA fragment was used
as hybridization probe (generously provided by Richard Palmiter, University of Washington, Seattle). To control for RNA loading and
transfer variation, filters were routinely rehybridized with a
glyceraldehyde-3-phosphate dehydrogenase (GAP) cDNA probe
(35).
Cell culture and transplantation.
Both the mouse cell lines,
37-32 and 37-7, were derived from neoplasms arising in HGF/SF
transgenic mouse line MH-37 (35, 62). Both lines were
maintained in Dulbecco modified Eagle medium (DMEM) (Gibco)
supplemented with 15% fetal bovine serum (Gibco), 100 IU of penicillin
(Gibco) per ml, 100 µg of streptomycin (Gibco) per ml, 2 mM
L-glutamine (Gibco), 5 µg of insulin (Upstate
Biotechnology Inc.) per ml, and 5 ng of epidermal growth factor
(Upstate Biotechnology Inc.) per ml, and incubated in 5%
CO2 at 37°C. Subcutaneous tumors were produced by
injection of 106 cells in 0.3 ml of DMEM under the back
skin of 2- to 3-month-old wild-type, HGF/SF transgenic, NK2 transgenic,
or HGF/SF-NK2 bitransgenic male and female mice. Tumor diameters were
measured every 3 days using a caliper, and tumor volumes were
calculated according to the formula V = a × b2/2. Rates of tumor growth
were determined based on 3-day intervals. For the experimental
metastasis assay, 105 or 106 cells in 0.3 ml of
DMEM, as indicated, were intravenously injected via the tail vein into
2- to 5.5-month-old male and female HGF/SF transgenic, NK1 transgenic,
NK2 transgenic, and wild-type mice. The conclusions from the metastasis
assay were essentially the same whether 105 or
106 melanoma cells were injected. Gross tumor numbers were
obtained by visual inspection of liver, spleen, kidneys, lungs,
diaphragm, and pleural cavity in mice euthanatized 18 to 25 days
posttransplantation. Microscopic quantification of metastasis was
performed on representative formalin-fixed, H&E-stained sections of all
liver lobes from two to eight representative animals between 1.5 and
2.5 months of age; all mice in this study were euthanatized and
analyzed 21 days posttransplantation. For tumor size determination,
725, 98, and 65 tumors were measured from representative sections of
each liver lobe from NK2, NK1, and HGF/SF mice, respectively.
Statistical analysis was performed using the Student t test.
Analysis of Met and Met activity.
Quantification of Met and
Met tyrosine phosphorylation was performed as described previously
(35). Lysates were prepared from 37-32 cells treated for 10 min at 37°C with the factors indicated (HGF/SF, 100 ng/ml; NK2, 300 ng/ml). Cultured cells were solubilized in RIPA buffer (50 mM Tris [pH
7.4], 50 mM NaCl, 1% Triton X-100, 5 mM EDTA, 10 mM sodium
pyrophosphate [Sigma], 50 mM sodium fluoride [Sigma], 1 mM sodium
orthovanadate [Sigma], 1 mM phenylmethylsulfonyl fluoride
[Boehringer Mannheim], 10 µg of leupeptin [Boehringer Mannheim]
per ml, 10 µg of pepstatin [Boehringer Mannheim] per ml, and 10 µg of aprotinin [Boehringer Mannheim] per ml). Equivalent amounts
of the resulting lysates were incubated with anti-Met antibody (Santa
Cruz Biotechnology) for 2 h. Following addition of GammaBind G
Sepharose (Pharmacia Biotech) and washing in RIPA buffer, samples were
fractionated by reducing sodium dodecyl sulfate (SDS)-7.5%
polyacrylamide gel electrophoresis (PAGE). After electrophoretic transfer to Immobilon-P membranes (Millipore), filters were blocked and
incubated with anti-Met antibody (Santa Cruz Biotechnology) overnight.
Met was visualized by incubation with anti-rabbit antibody conjugated
to horseradish peroxidase, followed by enhanced chemiluminescence (ECL;
Amersham). After stripping, filters were reblocked and incubated overnight with a phosphotyrosine monoclonal antibody (Upstate Biotechnology).
To determine the comparative effects of HGF/SF and NK2 on Met-induced
MAPK activity, Western blotting for anti-active MAPK
was performed as
described previously (
11). Lysates, prepared
after exposure
of 37-32 cells to either HGF/SF or NK2 (as above),
were fractionated by
SDS-12% PAGE, transferred to Immobilon-P
membrane, and probed with
anti-phospho-MAPK antibody (New England
Biolabs) as per the
manufacturer's instructions. Positive staining
was detected by ECL
(Amersham).
Analysis of HGF/SF and NK2.
Mouse liver lysates (25 µg of
total protein per sample per lane) were fractionated by SDS-10% PAGE
and electrophoretically transferred to Immobilon-P membrane. Membranes
were blocked with bovine serum albumin, probed with anti-human HGF/SF
(N-17; Santa Cruz Biotech) in 0.1% bovine serum albumin-0.05%
NP-40-phosphate-buffered saline, and detected by ECL (Amersham). A
series of standards of purified mouse HGF/SF and human NK2 run in the
same gel as the liver samples allowed a quantitative assessment of
HGF/SF and NK2 levels. Purified mouse HGF/SF was a generous gift from Ermanno Gherardi, MRC Center, Cambridge, United Kingdom; human NK2 was
prepared as described previously (60). These standards revealed that the anti-human HGF/SF antiserum used for immunoblot analysis recognized human HGF/SF with greater overall sensitivity than
it recognized mouse HGF/SF, although both were readily detectable. NK2
levels in sera were quantified using an enzyme-linked immunosorbent assay, as described previously (55).
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RESULTS |
Mice expressing NK2 are healthy and exhibit no overt
hyperproliferative lesions.
To determine the in vivo biological
activities of the natural HGF/SF splice variant, NK2, the human cDNA
was placed under the transcriptional control of the mouse MT gene
promoter and LCRs (Fig. 1B), and the resulting expression vector was
used to make four lines of NK2 transgenic mice. An identical MT
expression construct was used in our previously described HGF/SF and
NK1 transgenic mice (20, 61), so as to allow a direct
comparison of phenotypic consequences of expression of the various
HGF/SF isoforms. Northern blot hybridization (Fig. 1C) was used to
demonstrate that the MT-NK2 transgene, like the MT-HGF/SF and MT-NK1
transgenes, was highly and broadly expressed in three lines, two of
which (MN2-17 and MN2-38) were chosen for further analysis. In all
experiments presented here, results obtained using these two lines were
indistinguishable. Transgene expression was also assessed during
development in line MN2-38. As with the MT-HGF/SF transgene
(61), the MT-NK2 transgene was clearly active in E14.5 and
E16.5 embryos (Fig. 1C). An enzyme-linked immunosorbent assay showed
that NK2 levels in the serum of MN2-38 mice averaged 27 ng/ml;
wild-type control serum had an NK2 level less than the 7.8-ng/ml limit
of detection. Previously, HGF/SF transgenic mouse serum was found to
contain an average of 16.4 ng of HGF/SF per ml compared to wild-type
levels of 3.9 ng/ml (61).
In contrast to mice bearing either the MT-HGF/SF or MT-NK1 transgene,
NK2 transgenic mice failed to exhibit overt abnormal
phenotypes. No
hyperplastic lesions were observed in the kidney
or olfactory mucosa
(Fig.
2B and F), and no anomalies were associated
with the mammary
gland (Fig.
2J) or skeletal muscle (data not
shown). NK2 mice did not
experience gastrointestinal obstruction
or progressive renal disease,
which is highly characteristic of
HGF/SF mice (Fig.
2D). The liver was
not enlarged; in fact, when
expression of the MT-NK2 transgene was
stimulated by exposing
juvenile mice to zinc-containing water, the
weight of the liver
relative to the body appeared to be slightly
reduced. When crossed
with the pigmented strain C57BL/6,
first-generation MN2-38 and
MN2-17 transgenic mice were found to
exhibit no overt hyperpigmentation.
However, histopathological analysis
of their skin revealed the
occasional presence of pigment cells outside
the normal confines
of the hair shaft, in the dermis and epidermis
(data not shown).
This ectopic pigment cell localization was more
obvious in line
MN2-38, which was characterized by higher transgene
expression
in the skin (Fig.
1C). Such aberrant pigment cell
localization
was not observed in wild-type
animals.
NK2 antagonizes HGF/SF-induced pathology in bitransgenic mice.
The small reduction in liver size observed in zinc-treated NK2
transgenic mice raised the possibility that NK2 was capable of
inhibiting HGF/SF-mediated hepatocyte proliferation in vivo. To further
test this hypothesis, bitransgenic mice harboring both the MT-HGF/SF
and MT-NK2 transgenes were generated. Figure
3 shows that NK2 expression in all
bitransgenic mice reduced to nearly normal levels the anomalous liver
growth associated with the constitutive activation of Met in HGF/SF
transgenic hepatocytes (52). Moreover, analysis of BrdU
incorporation revealed that the labeling index of bitransgenic
hepatocytes was significantly decreased relative to HGF/SF transgenic
hepatocytes (Fig. 3). The presence of the MT-NK2 transgene could be
inhibiting hepatocyte proliferation in bitransgenic mice by
specifically antagonizing HGF/SF activity or by squelching expression
of the MT-HGF/SF transgene through competition for MT-specific
transcription factors. To distinguish between these two possibilities,
the structure and activity of these two transgenes were compared.
Southern blot analysis revealed that the two MT-driven transgenes were
equivalently represented in terms of copy number (data not shown).
Northern blot analysis demonstrated that at the level of RNA,
expression of the two transgenes and the endogenous MT gene was
coordinately regulated in bitransgenic hepatocytes (Fig.
4A), indicating that there was no
shortage of MT-specific transcription factors for which the two
transgenes would have to compete. The same result was also seen in
livers from bitransgenic juvenile mice that were exposed to water
containing zinc (data not shown). Western blotting was then utilized to
quantify the relative levels of HGF/SF and NK2 protein in transgenic
and bitransgenic liver extracts. Based on comparisons with recombinant standards, it can be estimated that, in 25 µg of transgenic liver extract, HGF/SF and NK2 are represented at levels between 2 and 4 ng
and 5 and 10 ng, respectively (Fig. 4B). Thus, the 33-kDa NK2 appears
to be present in the bitransgenic livers in about a sevenfold molar
excess relative to the 92-kDa HGF/SF. Figure 4B also demonstrates that
NK2 is not expressed at the expense of HGF/SF and confirms that the
normal liver weight/body weight ratios characteristic of bitransgenic
mice are not caused by diminution of HGF/SF levels. These data support
the contention that NK2 can antagonize certain HGF/SF-mediated
activities at the level of ligand-receptor interaction in vivo, as has
been shown in vitro (6, 11, 31).
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FIG. 3.
NK2 inhibits the proliferative effects of HGF/SF on
hepatocytes. Shown are mean liver weight/body weight ratios (white
bars) and hepatocyte labeling indices (black bars) from wild-type
(FVB/N), NK2 transgenic, NK2-HGF/SF bitransgenic, and HGF/SF transgenic
livers. All values were normalized to wild type (set at 1.0), and error
bars represent standard errors of the means. For both liver size and
hepatocyte proliferation, the P value is <0.0001 in
NK2-HGF/SF bitransgenic versus HGF/SF transgenic mice.
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FIG. 4.
Comparative transgene expression in livers of HGF/SF and
NK2 transgenic and HGF/SF-NK2 bitransgenic mice. (A) Northern blot
analysis of total liver RNA (15 µg/sample) using as probe mouse
sequences equivalent to NK2 (top panels), mouse MT cDNA (middle
panels), or mouse GAP cDNA (bottom panels). Numbers at the top indicate
liver weight/body weight ratios (LW/BW). All mice were 1.5 months of
age. (B) Quantitative Western blot analysis of mouse HGF/SF and human
NK2 transgenic mouse liver extracts (25 µg/sample) using an
anti-human HGF/SF antibody. Arrows mark positions of unprocessed
pro-HGF/SF, processed HGF/SF, and NK2. Liver weight/body weight ratios
(lw/bw) are shown at top. Recombinant mouse HGF/SF (R-mHGF) and human
NK2 (R-hNK2) standards of known amounts (in nanograms) are displayed on
the extreme left and right, respectively. A short exposure shown at
bottom permits quantification of NK2 levels in liver extracts. In
general, RNA and protein results in panels A and B, respectively, are
in accord.
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Prompted by these liver results, we analyzed other tissues from
HGF/SF-NK2 bitransgenic mice up to 6 months of age. In contrast
to
HGF/SF transgenic mice (Fig.
2D, H, and L), in HGF/SF-NK2 bitransgenic
mice the kidney exhibited little or no glomerulosclerosis or tubular
hyperplasia; the olfactory mucosa was overtly normal, with no
sign of
olfactory gland hyperplasia or nervous depletion; and
virgin mammary
epithelium demonstrated no obvious precocious alveolar
development
(Fig.
2C, G, and K). These results indicate that the
pathological
consequences of chronic, HGF/SF-mediated Met activation
associated with
anomalous cellular proliferation can be effectively
antagonized in vivo
by the splice variant
NK2.
NK2 facilitates metastasis but not growth of Met-overexpressing
malignant melanoma cells in vivo.
Previously, we determined that
cultured 37-32 cells, a melanoma line established from HGF/SF
transgenic mice and overexpressing both the transgene and endogenous
c-met, could be growth inhibited up to, but not more than,
60% in minimal medium supplemented with recombinant NK2 to levels in
100-fold excess (0.3 to 1.0 µg/ml) of those that can be achieved in
serum, in vivo (35). Unlike HGF/SF, NK2 is incapable of
inducing robust Met autophosphorylation or MAPK in these melanoma cells
(Fig. 5). To ascertain the relative effect of NK2 on growth and metastasis of 37-32 cells in vivo, transgenic lines of mice overexpressing various HGF/SF isoforms were
exploited as genetically modified hosts for transplantation challenge.
Initially, 106 melanoma cells were injected subcutaneously
into syngeneic wild-type FVB/N, transgenic HGF/SF, transgenic NK2, or
HGF/SF-NK2 bitransgenic host mice. Figure
6 shows that melanomas grew in the NK2
transgenic hosts nearly as well as in the wild-type mice. However, when
transplanted subcutaneously into HGF/SF mice, melanomas became palpable
much earlier and grew at an accelerated rate relative to those in
either wild-type or NK2 mice. Significantly, the time of appearance and rate of growth of tumors transplanted into bitransgenic host animals expressing both NK2 and HGF/SF were no different than those for either
the wild-type or NK2 single transgenic hosts. Together, these data
indicate that, while NK2 could not effectively disrupt the HGF/SF-Met
autocrine signaling loop driving baseline 37-32 melanoma growth, this
variant was able to completely antagonize the paracrine-enhanced in
vivo growth associated with overexpression of the HGF/SF transgene
originating from genetically modified host mouse tissues.
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FIG. 5.
Quantification of Met and Met activity in melanoma
cells. Extracts prepared from 37-32 melanoma cells treated with either
nothing (control), HGF/SF, or NK2 were immunoprecipitated (IP) with
anti-Met antibody and subsequently probed with either
anti-phosphotyrosine (-pY, top left) or anti-Met (-c-Met, bottom
left) antibodies. Extracts were also directly probed with
anti-phospho-MAPK antibody (right). Molecular masses in kilodaltons are
shown. Note that, relative to NK2, HGF/SF induces phosphorylation of
Met and MAPK without altering the levels of Met.
|
|
View larger version (25K):
[in this window]
[in a new window]
|
FIG. 6.
NK2 antagonizes paracrine, but not autocrine,
HGF/SF-induced subcutaneous melanoma growth. One million 37-32 melanoma
cells were injected under the back skin of 2- to 3-month-old wild-type
(WT), HGF/SF transgenic, NK2 transgenic, and HGF/SF-NK2 bitransgenic
mice; tumor sizes were measured; and growth rates were calculated.
|
|
The 37-32 melanoma cells, derived on an FVB/N inbred genetic
background, were shown to be highly metastatic to a number of
nude
mouse tissues but with a clear partiality for liver (
35).
To
determine the specific effect of the host-generated HGF/SF
isoforms on
metastasis, 37-32 melanoma cells were introduced intravenously
into
syngeneic wild-type and HGF/SF, NK1, and NK2 transgenic mice.
Gross
metastatic colonization by 37-32 cells of the liver and
other organs
was elevated in HGF/SF transgenic mice relative to
that in wild-type
controls (Table
1; Fig.
7A), reminiscent of
the heightened growth
response of these same melanoma cells when
transplanted
subcutaneously into HGF/SF transgenic mice (Fig.
6). Gross metastatic
efficiency of 37-32 cells was enhanced in
NK1 transgenic hosts as well
(data not shown). When this experimental
metastasis assay was repeated
with another cell line containing
barely detectable levels of HGF/SF
and Met (HGF/SF transgenic
mouse-derived line 37-7 [
35]), the incidence of gross metastasis
to a variety
of target organs in both HGF/SF and NK2 transgenic
host mice was not
significantly different from that for wild-type
mice (Table
1). This
result suggests that host-generated HGF/SF
isoforms were acting
directly through responsive melanoma cells
and not by creating a more
permissive host.
View this table:
[in this window]
[in a new window]
|
TABLE 1.
Incidence of metastasis and organ site selection of
malignant cells in host transgenic mice expressing HGF/SF or its
splice variantsa
|
|
View larger version (8028K):
[in this window]
[in a new window]
|
FIG. 7.
NK2 enhances metastatic efficiency, but not growth, of
high-Met-expressing melanoma cells. The figure shows results of
analysis of liver metastasis of melanoma cells in genetically modified
host mice. One million 37-32 melanoma cells were injected intravenously
into the tail vein of wild-type (WT), NK2 transgenic, NK1 transgenic,
and HGF/SF transgenic mice. (A and B) After 3 weeks, livers were
examined grossly (A) and histopathologically (B) for the presence of
metastatic tumors. Melanomas were immunohistochemically visualized
(brown staining) using an anti-mouse TRP1 antibody. (C) Liver
preparations from the genetically modified host mice were used to
quantify both mean numbers of 37-32 melanoma cell metastases (white
bars) and mean tumor sizes (black bars). Error bars indicate standard
errors of the means. There was no statistically significant difference
in the numbers of metastases per liver in the three transgenic lines.
For mean tumor size, P value was <0.001 for NK2 versus
either NK1 or HGF/SF; P value was 0.2 for NK1 versus
HGF/SF.
|
|
Having established the positive impact of host-generated HGF/SF on
metastasis of high-Met melanoma cells, the effects of host-generated
NK2 were next considered. Remarkably, rather than antagonizing
metastasis, as it did growth, host-generated NK2 dramatically
stimulated the incidence of gross hepatic metastasis of 37-32
cells,
achieving levels that were at least as high as those found
in HGF/SF
transgenic hosts (Table
1; Fig.
7A). This gross observation
was
confirmed microscopically and quantified by subjecting several
experimental livers to histopathological analysis (Fig.
7B). The
efficiency of microscopic metastasis to liver was approximately
ninefold greater in NK2 transgenic hosts than in their wild-type
counterparts (
P < 0.0005) and equal to or greater than
that in
either HGF/SF or NK1 mice (Table
1 and data not shown). In
contrast,
the average size of the metastatic tumors in the NK2 mouse
livers
appeared to be equivalent to that in wild type and reduced
compared
to either NK1 or HGF/SF mice (Fig.
7A and B). Morphometric
quantification
confirmed that, although the number of liver metastases
was enhanced
by NK2 as for the other isoforms, growth at the
colonization site
relative to that for HGF/SF and NK1 was significantly
reduced
(Fig.
7C). Kidney metastases were also smaller and therefore
less
conspicuous at both the gross and the microscopic level in NK2
transgenic hosts compared to those in HGF/SF mice (data not shown);
however, kidney metastases were present in significantly greater
numbers relative to wild-type hosts as well (Table
1).
| |
DISCUSSION |
The ability of the HGF/SF alternative splice variants, NK1 and
NK2, to function in vitro as HGF/SF agonists or antagonists appears to
be contextual, depending on the cell type and the conditions under
which it is cultured (6, 9, 18, 23, 28, 30, 31, 34, 55, 58,
60). These isoforms have been detected in mice and humans, and
yet their in vivo function is unknown. Recently, we demonstrated that
NK1, when broadly expressed in mice, induces all phenotypes observed in
HGF/SF transgenic mice, although with reduced severity (20).
From this result, we concluded that NK1 acts in vivo as a partial
agonist of HGF/SF. In the present study, we show that the in vivo
behavior of NK2 is distinct from that of NK1, and more complex. With
the exception of relatively mild ectopic localization of melanocytes
outside the hair follicles, NK2 transgenic mice exhibited no overt
phenotypic abnormalities. However, NK2 effectively mitigated the
constellation of HGF/SF-mediated lesions in HGF/SF-NK2 bitransgenic
mice, including liver enlargement and elevated hepatocyte
proliferation, olfactory gland hyperplasia and mucosal disorganization,
renal tubular hyperplasia and subsequent glomerulosclerosis, alveolar
mammary hyperplasia, and hyperpigmentation. These lesions are generally
attributable to dysregulated cellular growth. The observed coordinate
regulation of expression of the two MT-driven transgenes, at the level
of both RNA and protein, in bitransgenic livers indicated that
amelioration of the phenotypes associated with HGF/SF overexpression in
these animals was not the simple consequence of transcription factor
competition, or squelching. Instead, NK2 protein itself appeared to
effectively antagonize HGF/SF-induced, Met-mediated mitogenic signaling
in vivo.
Remarkably, however, when introduced intravenously into the tail vein
of NK2 transgenic mice, 37-32 melanoma cells exhibited a ninefold
enhancement in efficiency of metastasis to the liver, their preferred
site, relative to wild-type host mice of the same age, sex, and genetic
background. Moreover, the incidence of metastasis in NK2 animals was at
least as high as that observed in either HGF/SF or NK1 transgenic
hosts, indicating that NK2 functions in vivo as a potent agonist of
Met-driven metastatic dissemination. Notably, however, the average mass
of liver metastases from these NK2 transgenic hosts was reduced
approximately five- or threefold relative to those arising over the
same time in HGF/SF or NK1 animals, respectively, indicating that, in
this experimental model of metastasis, NK2 was incapable of stimulating
melanoma growth in the manner demonstrated by host-generated HGF/SF.
This metastatic behavior was mirrored in other organs as well.
Together, these findings clearly show that the activities associated
with HGF/SF, and mediated by a single RTK, Met, can be functionally
dissociated in vivo. Furthermore, the same isoform can apparently serve
in vivo as both HGF/SF agonist and antagonist.
How can NK2 simultaneously induce agonistic and antagonistic
activities, and why do NK1 and NK2 evoke such different in vivo responses? Despite the availability of a relatively detailed blueprint of Met signaling pathways and their integral components, the
mechanistic basis by which various HGF/SF isoforms differentially
elicit Met-mediated cellular responses is not yet understood. It is
assumed that ligand-induced dimerization triggers the
activation-autophosphorylation of generic RTKs, including Met (reviewed
in reference 71), and that processed, two-chain
HGF/SF binds Met, either as a monomer or as a dimer, inducing a
conformational shift toward a stabilized active receptor configuration
(reviewed in reference 7). The recently resolved crystal structure of NK1 suggests assemblage as a homodimer capable of
simultaneously engaging two Met receptors and provides a rationale for
the agonism demonstrated by NK1 (8, 68). Interaction with
endogenous glycosaminoglycans may be exceedingly important in realizing
the agonistic behavior of this variant in vivo (8, 9, 52, 55,
68). If it is a pure antagonist, the behavior of NK2 could be
explained through its ability to compete with HGF/SF for receptor
binding, without inducing the appropriate activating conformational
change in Met. However, we show in this report that NK2 does not behave
as a pure antagonist in vivo. Although all HGF/SF isoforms appear to
engage and activate Met (18, 23, 31, 51, 60), we demonstrate
here that Met autophosphorylation and MAPK activation are
quantitatively different in 37-32 melanoma cells treated with NK2 than
in those treated with HGF/SF. NK2 activities could also be explained by
qualitative differences in Met tyrosine phosphorylation, which could in
turn affect transducer recruitment and/or modify substrate target
selection. Alternatively, differential signal persistence and/or
intensity in individual pathways may account for the behavior of NK2.
For example, the Met pathway(s) engaged in the induction of
metastasis-associated behavior in vivo might require a weaker signal
relative to other activities and still be triggered by NK2 despite its
reduced ability to activate Met. Our in vitro data suggest that MAPK
does not regulate this pathway. However, a credible candidate is the
pathway(s) mediated by phosphotidylinositol 3-kinase, which can be
activated by NK2 in some cultured cell lines (11) and in
association with p110 can bind directly to the C-terminal
Y1349/Y1356 multifunctional docking site of Met
(38, 39) and mediate cellular activities capable of
contributing to metastatic spread (1, 16, 26, 27, 49, 57).
An important question then arises concerning the identity of the
specific cellular activity, or activities, induced by NK2 that so
efficiently facilitate metastasis in vivo. A number of studies on NK2
behavior in vitro proffer some insight. As originally described, NK2
was unable to induce, or could actually block, mitogenesis of cultured
cells (6, 18, 30, 34). More recent in vitro studies showed
that NK2 alone was incapable of inducing many other activities
associated with metastasis, including in vitro invasion or
urokinase-type plasminogen activator proteolysis (23),
branching morphogenesis (23, 31), or angiogenesis (58). In contrast, NK2 was able to scatter canine MDCK cells in vitro (18) and stimulate cellular migration in a modified Boyden chamber assay system (60). Relying on these in vitro studies as a backdrop, our results present a strong case for enhanced cellular motility being critically influential in promoting metastasis in a bona fide animal model. However, enhanced NK2-induced scattering is almost certainly not sufficient for the acquisition of a full metastatic phenotype (16). In our melanoma model system,
other requisite Met-mediated activities are likely being provided via the autocrine stimulation from the transgenic HGF/SF produced by the
37-32 cells themselves. Indeed, the fact that the subcutaneous growth
of 37-32 tumor transplants is not effectively inhibited by
host-generated NK2 suggests that the autocrine HGF/SF-Met signaling pathway is resistant to the antimitogenic effects of exogenous NK2.
Such a conclusion raises serious doubts about the therapeutic efficacy
of RTK antagonists whose malignant targets arise as a consequence of
the creation of such autocrine RTK signaling loops.
Conclusions from the above discussion depend on the assumption that the
metastatic enhancement induced by either NK2, NK1, or HGF/SF is a
direct consequence of ligand binding to Met robustly expressed by the
37-32 malignant melanoma cells. However, an intriguing alternative
possibility is that genetically modified host animals ectopically
expressing these ligands become broadly permissive for metastasis,
irrespective of the ability of the transplanted tumor cell to respond
directly to Met ligands. HGF/SF and its variants could, for example,
interact with host cells to induce subtle alterations in extracellular
matrix or angiogenic networking, making these animals more susceptible
to metastatic colonization in general. Although we cannot rule out this
possibility at this time, the fact that low-Met 37-7 cells fail to
demonstrate significantly enhanced metastatic behavior in these same
transgenic hosts argues against it. This important issue will continue
to be investigated; either way, these studies demonstrate the great
experimental opportunity offered by an approach exploiting genetically
modified host mice as tumor transplant recipients.
| |
ACKNOWLEDGMENTS |
We thank Ralph Schwall for quantification of NK2 levels in mouse
sera, Miriam Anver for histopathologic consultation and morphometric measurements, Richard Palmiter for the mouse MT-1 cDNA probe, Ermanno
Gherardi for the purified mouse HGF/SF standard, Vincent Hearing for
the TRP1 antibody, Ricardo Dreyfuss and Steve Neal for photography, and
Nelson Ellmore and Barbara Kasprzak for technical assistance with cell
culture and immunohistochemistry, respectively. We are indebted to
Andrew Chan and Stuart Aaronson for the NK2 cDNA and for highly useful discussions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Molecular
Genetics Section, Laboratory of Molecular Biology, National Cancer
Institute, NIH, Building 37, Room 2E24, Bethesda, MD 20892-4255. Phone:
(301) 496-4270. Fax: (301) 480-7618. E-mail:
gmerlino{at}helix.nih.gov.
| |
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Abstract
Introduction
