From the Departments of Surgical Oncology,
§ Cell Biology, and
Tumor Biology, University of
Texas M. D. Anderson Cancer Center, Houston, Texas 77030 and the
¶ Department of Surgical Oncology, Emory University School of
Medicine, Atlanta, Georgia 30322
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ABSTRACT |
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Vascular endothelial growth factor (VEGF) is implicated in the angiogenesis of human colon cancer. Recent evidence suggests that factors that regulate VEGF expression may partially depend on c-src-mediated signal transduction pathways. The tyrosine kinase activity of Src is activated in most colon tumors and cell lines. We established stable subclones of the human colon adenocarcinoma cell line HT29 in which Src expression and activity are decreased specifically as a result of a transfected antisense expression vector. This study determined whether VEGF expression is decreased in these cell lines and whether the smaller size and reduced growth rate of antisense vector-transfected cell lines in vivo might result, in part, from reduced vascularization of tumors. Northern blot analysis of these cell lines revealed that VEGF mRNA expression was decreased in proportion to the decrease in Src kinase activity. Under hypoxic conditions, cells with decreased Src activity had a <2-fold increase in VEGF expression, whereas parental cells had a >50-fold increase. VEGF protein in the supernatants of cells was also reduced in antisense transfectants compared with that from parental cells. In nude mice, subcutaneous tumors from antisense transfectants showed a significant reduction in vascularity. These results suggest that Src activity regulates the expression of VEGF in colon tumor cells.
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INTRODUCTION |
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Neovascularization is a critical requirement for tumor growth and metastasis formation. Numerous angiogenic factors that regulate this process have been identified (1). Among them is vascular endothelial growth factor (VEGF),1 which has been implicated in the neovascularization of a wide variety of tumors (2-8). VEGF, also known as vascular permeability factor, is a 36-45-kDa dimeric glycoprotein that has been identified in the conditioned media from numerous cell lines and that is expressed in many tumors (2-12). The gene for this angiogenic factor has ~20% homology to platelet-derived growth factor and ~50% homology to placenta growth factor (13, 14). Recently, several studies suggested that VEGF is the angiogenic factor most closely associated with induction and maintenance of the neovasculature in human colon cancer (2, 10, 15, 16). In primary tumors, the expression of VEGF mRNA is increased in tumors relative to histologically normal bowel mucosa (8, 17). Further studies have implicated VEGF expression in tumor progression and metastasis. We have demonstrated that VEGF expression is greater in colon tumors that have metastasized than in nonmetastatic tumors (2). Using a murine model system for colon cancer, Warren et al. (16) demonstrated that a monoclonal antibody to VEGF inhibits subcutaneous tumor formation in a dose- and time-dependent manner and reduces the number and size of liver metastases.
Although VEGF has undergone considerable study in recent years, the factors in the tumor environment and subsequent signal transduction pathways that regulate VEGF production have yet to be elucidated fully. One environmental condition known to enhance VEGF expression is hypoxia (18-20). Recently, hypoxia was demonstrated to be mediated, in part, by specific activation of the protein-tyrosine kinase activity of Src (18). In addition, cell lines transfected with v-src (a constitutively activated homolog of c-src) have been found to have increased VEGF expression (21). These observations may be of particular relevance to colon tumorigenesis and progression because >80% of primary colon tumors have significantly increased Src activity (22, 23), and further increases in Src activity are observed in the majority of colon tumor metastases (22, 24). Additionally, most colon tumor cell lines are known to express VEGF (10). However, in the HEP3b hepatoma cell line, recent studies have suggested no relationship between Src activation and VEGF production (25).
A potential relationship between Src activation and VEGF production in colon tumor cells has yet to be demonstrated. Recently, we established stable subclones of the well characterized human colon adenocarcinoma cell line HT29 in which Src expression and activity are decreased as a result of a transfected antisense expression vector specific for inhibition of Src (26). The cell lines demonstrated decreased growth in nude mice proportionately to the reduction in c-src levels (26). The purpose of this study was to determine whether VEGF expression and associated biologic activity were decreased by specific down-regulation of Src kinase activity and whether the smaller size and reduced growth rate of antisense vector-transfected cell lines in vivo might result, in part, from reduced vascularization of tumors.
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EXPERIMENTAL PROCEDURES |
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Construction of c-src Expression Vectors--
A construct
spanning the translation start site of c-src was generated
by annealing two primers,
5-AGCTTGGACCATGGGTAGCAACAAGAGCAAGCCCAAGGAT-3
and
5
-CTAGATCCTTGGGCTTGCTCTTGTTGCTACCCATGGTCCA-3
. The sense construct was synthesized in a similar manner with primers
5
-AGCTATCCTTGGGCTTGCTCTTGTTGCTACCCATGGTCCT-3
and
5
-CTAGAGGACCATGGGTAGCAACAAGAGCAAGCCCAAGGAT-3
. The pcDNAI plasmid (Invitrogen, San Diego, CA) was then digested with
HindIII and XbaI, and a ligation reaction was
performed to insert the sense and antisense constructs.
Escherichia coli was transformed by the plasmids; selected
clones were harvested; the bacteria were lysed by alkali treatment; and
the plasmids were purified. Confirmation of the correct insert was
determined by the polymerase chain reaction (PCR) followed by DNA
sequencing.
Transfection-- HT29 parental (HT29-P) cells were grown to 70% confluency under the conditions described below. Cells were transfected in serum-free medium for 6 h with 100 µg of LipofectAMINE (Life Technologies, Inc.) and 16 µg of plasmid DNA. The medium was then replenished with medium supplemented with 250 µg/ml G418 (Life Technologies, Inc.). Colonies resistant to G418 were expanded, and the resulting clones were screened for expression and activity of Src, as described below.
Cell Culture-- HT29 cells, derived from a colon adenocarcinoma (27), were maintained in Dulbecco's modified Eagle's medium (DMEM) with Earle's salts and 2 mM glutamine (Life Technologies, Inc.) supplemented with 10% fetal bovine serum (FBS; Hyclone Laboratories, Logan, UT). Stable HT29 subclones expressing c-src "sense" (HT29-S8 and HT29-S20) and "antisense" (HT29-AS15 and HT29-AS33) constructs were also maintained under these conditions, except that the medium was supplemented with 250 µg/ml G418. For experiments examining the effect of tumor cell-conditioned medium on endothelial cell proliferation, HT29-P cells and subclones were grown to 100% confluence in DMEM supplemented with 1% FBS for 24 h.
Immunoprecipitation and Immune Complex Kinase Assays--
Prior
to lysis, cells were rinsed twice with ice-cold phosphate-buffered
saline (PBS). Detergent lysates were made in a standard radioimmune
precipitation assay buffer. Cells were homogenized and clarified by
centrifugation at 10,000 × g. Cell lysates (250 µg
of protein) were reacted for 2 h with either monoclonal antibody 327 (Oncogene Science Inc., Cambridge, MA) for immunoprecipitation of
Src or monoclonal antibody 1B7 (Wako Bioproducts, Richmond, VA) for
immunoprecipitation of Yes. Immune complexes were formed by incubation
with 6 µg of rabbit anti-mouse IgG (Organon Teknika, Durham, NC) for
1 h and then with 50 µl of 10% (v/v) Formalin-fixed Pansorbin
(Staphylococcus aureus, Cowan strain; Calbiochem) for 30 min. Pellets were washed three times in a buffer consisting of 0.1%
Triton X-100, 150 mM NaCl, and 10 mM sodium
phosphate. Immune complex kinase assays were performed by standard
procedures as described previously (22). Briefly, reactions were
initiated by adding to each sample 10 µCi of
[-32P]ATP, 10 mM Mg2+, and 100 µM sodium orthovanadate in 20 mM HEPES. After
10 min at 25 °C, reactions were terminated by adding SDS sample
buffer. Proteins were separated by SDS-polyacrylamide gel
electrophoresis on 8% polyacrylamide gels, and radioactive proteins
were detected by autoradiography.
Immunoblotting-- Clarified cell lysates (250 µg/lane) were separated by SDS-polyacrylamide gel electrophoresis on 10% polyacrylamide gels and electroblotted onto nitrocellulose membranes (Schleicher & Schuell) using standard procedures (22). Membranes were blocked with 15% skimmed milk in PBS and then incubated with anti-Src or anti-Yes antibodies at a 1:1000 dilution followed by horseradish peroxidase-conjugated rabbit anti-mouse IgG. Specific binding of antibody was determined using the ECL detection system (Amersham Corp.).
mRNA Extraction and Northern Blot
Analysis--
Polyadenylated mRNA was extracted from tumor cells
grown under confluent conditions in culture using the TRI reagent kit
(Molecular Research Center, Inc. Cincinnati, OH). Twenty µg of total
RNA was fractionated on 1% denaturing formaldehyde-agarose gels,
transferred to a Hybond nylon membrane (Amersham Corp.) by capillary
elution, and UV-cross-linked at 120,000 µJ/cm2 using a UV
Stratalinker 1800 (Stratagene, La Jolla, CA). Following prehybridization, the membranes were probed for VEGF and
glyceraldehyde-3-phosphate dehydrogenase. Each cDNA probe was
purified by agarose gel electrophoresis, recovered using a QIAEX gel
extraction kit (QIAGEN Inc., Chatsworth, CA), and radiolabeled by the
random primer technique using a commercially available kit (Amersham
Corp.) that utilizes [-32P]dCTP (Amersham Corp.).
Nylon filters were washed at 65 °C with 30 mM NaCl, 3 mM sodium citrate (pH 7.2), and 0.1% (w/v) SDS. Autoradiography was then performed.
Semiquantitative Reverse Transcription-Polymerase Chain
Reaction--
cDNA was synthesized from total RNA extracted from
HT29-P cells and antisense cell lines (HT29-AS33 and HT29-AS15) by
reverse transcription (RT) in a 20-µl reaction containing 0.5 µg of
random primers (Life Technologies, Inc.), 200 units of SuperScriptTM
RNase H reverse transcriptase (Life Technologies, Inc.),
0.1 µg of mRNA, 4 µl of 5 × RT buffer (375 mM
KCl, 250 mM Tris-HCl (pH 8.3 at room temperature), and 15 mM MgCl2), 5 mM dithiothreitol, 0.1 mM each dNTP, 20 units of RNasin (Life Technologies, Inc.),
and diethyl pyrocarbonate-treated water. Each mixture was incubated at
37 °C for 1 h and then quick-chilled on ice.
Densitometric Quantitation--
Protein kinase activity and VEGF
mRNA expression were quantitated by densitometry of autoradiograms
using the ImageQuantTM software program (Molecular Dynamics, Inc.,
Sunnyvale, CA) in the linear range of the film. Semiquantitative PCR
products were separated by agarose gel electrophoresis, and after
ethidium bromide staining, they were exposed to UV light and
photographed with Polaroid Type 55 positive/negative film. The positive
bands on the film were quantitated by densitometry using -actin as
an internal control.
Determination of VEGF Protein Levels in Cell
Supernatants--
For these determinations, equal densities as opposed
to equal numbers of cells were chosen because of previous experiments in colon tumor cells demonstrating that density affects VEGF expression (29, 30). Thus, HT29-P cells were seeded at 20 × 106,
HT29-AS33 cells at 25 × 106, and HT29-AS15 cells at
40 × 106 cells/100-mm tissue culture plate to
compensate for size differences in these cells. Cells were grown for
24 h in DMEM/F-12 (1:1 mixture) supplemented with 10% FBS, washed
three times with PBS, and changed to 7.5 ml of DMEM/F-12 (1:1 mixture)
supplemented with 1% FBS. Cell supernatants were collected, filtered,
and stored at 12 °C, and concomitantly, cell pellets were
harvested by trypsinization, and cell number was determined. The amount
of VEGF protein in the supernatant was determined with an enzyme-linked
immunosorbent assay kit (R&D Systems, Minneapolis, MN) according to the
manufacturer's instructions. VEGF was expressed as pg of VEGF
protein/106 cells/24 h.
Effects of Hypoxia on VEGF Expression in HT29-P Cells and Transfectants-- HT29-P and HT29-AS15 cells were grown to confluence in standard medium. The medium was changed, and cells were then transferred to a hypoxia chamber (Proox Model 110, Reming Bioinstruments Co., Redfield, NY). Control cultures were harvested just prior to hypoxic exposure (t = 0), and protein and RNA were harvested. Identical cultures were then incubated for 4, 6, and 24 h, and cells were harvested at these time points for protein and RNA analysis.
Quantitation of Murine Tumor Microvasculature-- Cells from clones to be tested were grown in tissue culture to log phase (~70% confluent), trypsinized, and counted with the aid of a hemocytometer. 1 × 106 cells of each clone were injected subcutaneously in the flank of eight nude mice/cell type. For quantitation of tumor microvasculature, tumors were harvested after 60 days and frozen in liquid nitrogen. Cryostat sections of tissues previously frozen in O.C.T. compound were fixed sequentially (5 min each) with acetone, acetone/chloroform (1:1), and acetone. The sections were washed three times, and endogenous peroxidase was blocked with 3% hydrogen peroxide in methanol for 12 min. The samples were washed three times with PBS and incubated with a protein-blocking solution consisting of PBS containing 1% normal goat serum and 1% horse serum for 20 min at room temperature. Excess blocking reagent was drained off, and the samples were incubated with the primary antibody (rat anti-mouse CD31 antibody, 1:100 dilution; Pharmingen, San Diego, CA) overnight at 4 °C. Sections were washed with PBS and incubated with the secondary antibody (peroxidase-labeled mouse anti-rat antibody, 1:200 dilution; Boehringer Mannheim) for 1 h. Sections were washed four times with PBS, rinsed briefly with distilled water, and then incubated with stable diaminobenzadine (Research Genetics, Huntsville, AL) for 20 min to develop the peroxidase signal. Sections were counterstained with Mayer's hematoxylin (Sigma), washed, mounted with Universal Mount (Research Genetics), and dried on a 60 °C hot plate. Because heterogeneity in vascularization was observed, the four most vascular areas of each tumor were identified, and vessels were quantitated. Vessel counts in HT29-P and HT29-AS15 tumors were compared by two-tailed, unpaired Student's t test.
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RESULTS |
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Expression and Activity of Src and Yes in HT29 Transfectants-- Expression vectors spanning the translation start site of c-src in the sense and antisense orientations were made and transfected into HT29-P cells, and G418-resistant clones were isolated as described under "Experimental Procedures." Each clone was then screened for expression and activity of Src. To examine specificity of effects on Src, each clone was also screened for expression and activity of the related tyrosine kinase, Yes. The results with two antisense and two sense transfectants are shown in Fig. 1. When HT29-P cells were compared with the two sense transfectants, HT29-S8 and HT29-S20, no differences were apparent in autophosphorylation (Fig. 1, row A), phosphorylation of the exogenous substrate enolase (row B), or expression of either Src or Yes (row C). In contrast, the antisense clone HT29-AS15 had a 4.0-fold reduction in Src (row C) and 4.5-fold reduction in autophosphorylation (row A) and enolase phosphorylation (row B). Clone HT29-AS33 was intermediate in level and activity of Src, with expression reduced 2.0-fold (row C) and autophosphorylation (row A) and enolase phosphorylation (row B) reduced 2.5-fold. As is also shown in Fig. 1, neither the levels nor protein-tyrosine kinase activities of Yes were altered in the antisense transfectants relative to the sense transfectants or HT29-P cells. Therefore, the effects of the antisense expression vector were specific for Src.
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Effect of Src on VEGF mRNA Expression-- Transfection of the parental cell line with the control expression vector (sense) caused a minor increase in VEGF mRNA expression (Fig. 2). However, the establishment of cell lines with decreased Src kinase activity demonstrated a decrease in mRNA expression at levels of 54% (HT29-AS33) and 23% (HT29-AS15) of the average of the sense transfected cell lines. This incremental decrease in VEGF mRNA expression correlated with the alteration in Src kinase activity: the transfected cell line that exhibited the greatest decrease in Src kinase activity (HT29-AS15) also exhibited the greatest decrease in VEGF mRNA expression.
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Effect of Src on Expression of Various Isoforms of VEGF-- Semiquantitative PCR of the various isoforms of VEGF demonstrated a decrease in overall VEGF expression in both HT29-AS33 and HT29-AS15 cells (Fig. 3). The most abundant isoform expressed was VEGF-165. There was a relatively equal decrease in the expression of all VEGF isoforms in the antisense clones. The overall decrease in VEGF expression in the antisense clones by semiquantitative RT-PCR confirmed our findings by Northern blotting.
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Determination of VEGF Protein Levels in Cell Supernatants-- To examine directly the amount of VEGF protein produced in the various clones, supernatants from cultures grown to identical confluencies were harvested, and VEGF expression was determined by enzyme-linked immunosorbent assay. A decrease in VEGF protein was observed in the supernatant of cells with decreased Src activity (Fig. 4). This decrease was proportional to the decrease in Src activity in the two antisense transfected cell lines. These results demonstrate that decreased expression of mRNA corresponds with decreased VEGF protein expression.
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Effects of Hypoxia on VEGF Expression in HT29-P Cells and Transfectants-- The above results demonstrate that the expression of Src in colon tumor cells leads to the constitutive expression of VEGF, a critical factor in tumor cell growth. However, neovascularization of tumors also results from local hypoxia as the tumor volume exceeds its blood supply. As hypoxic stimulation of VEGF in fibroblasts has been associated with activation of Src protein-tyrosine kinase, we examined the response to hypoxia in HT29-P and transfected subclones. Cells were grown to equal densities, transferred to hypoxic chambers, harvested at specific times, and processed for RNA and protein as described under "Experimental Procedures." For these studies, HT29 parental cells were compared with HT29-AS15, the antisense transfectant expressing the least Src. The ability of hypoxia to induce VEGF mRNA in these clones is compared in Fig. 5. VEGF mRNA was markedly induced in a time-dependent manner in HT29-P cells, with a >50-fold increase observed after 24 h. In contrast, a <2-fold increase in VEGF mRNA expression was observed in HT29-AS15 cells. These results demonstrate that not only is the constitutive production of VEGF reduced by lowering Src expression, the ability of hypoxia to induce further expression of VEGF is severely impaired. To confirm that induction of VEGF mRNA by hypoxia was Src-dependent, the expression and activity of Src were compared in these clones under identical conditions. In HT29-P cells, Src kinase activity was stimulated in a time-dependent manner, with a maximum stimulation of 4.5-fold occurring 4 h after the onset of hypoxic conditions, whereas only a 1.1-fold increase in activity was observed in HT29-AS15 cells under identical conditions (data not shown).
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Effect of Src on in Vivo Tumor Vascularity-- For this determination, HT29-P and HT29-AS15 cells were implanted in the subcutis of nude mice as described under "Experimental Procedures." Tumors were harvested when they were ~1 cm in diameter. Mean vessel counts were determined by counting the most vascularized areas of the respective tumors, after immunostaining with rat CD31 antibody, as described. In tumors grown from HT29-AS15 cells, vessel counts were significantly reduced relative to those tumors grown from HT29-P cells (31.8 ± 2.8 versus 53.0 ± 1.5 (mean ± S.E.), respectively; p < 0.0001) (Fig. 6). These results demonstrate that reduction in constitutive and inducible VEGF production in c-src antisense transfected clones corresponds with decreased vascularization of the tumor. However, we cannot rule out that other factors, such as different growth rates and metabolic requirements, contribute to changes in tumor vascularization.
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DISCUSSION |
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Angiogenesis is an essential step in tumor growth and metastasis, and this process is driven by the balance of positive and negative effector molecules (31). In human colon cancers and established cell lines, VEGF appears to be the angiogenic factor most closely associated with neovascularization. Several lines of evidence implicate VEGF production as important to colon tumorigenicity and/or metastatic potential. Increases in VEGF are observed in primary tumors relative to normal tissue (7, 8) and in metastatic tumors relative to nonmetastatic tumors (2, 3). Using colon tumor cell lines in mouse models, Warren et al. (16) found that a VEGF antibody greatly inhibits the growth of subcutaneous xenografts and the number and size of experimental metastases. These results suggest that the production of VEGF is important to colon tumor cell growth and progression. However, other factors have also been implicated in the process of colon cancer angiogenesis. Subcutaneous injection into nude mice of several HT29 subclones with varying degrees of differentiation has demonstrated a positive correlation between vessel counts and the ability of the cells to express platelet-derived growth factor-B in vitro (32). Thus, in different subclones from even the same cell line, different angiogenic factors might be important to induction of neovascularization.
The signal transduction pathways by which VEGF is induced remain to be elucidated fully. However, recent experiments have implicated specific activation of the protein-tyrosine kinase activities of the src family of proto-oncogenes as important in the induction of VEGF. Mukhopadhyay et al. (18) examined the role of activated c-src in hypoxic induction of VEGF. Hypoxia was found to increase VEGF expression in U87 glioma cells and 293 kidney cells, and this induction was inhibited by genistein, an inhibitor of tyrosine kinases. When the effects of hypoxia on src family protein-tyrosine kinases were analyzed, Src activity, but not Yes or Fyn activity, was increased. Transfection of v-src into U87 glioma cells and 293 kidney cells also increased the hypoxic induction of VEGF, whereas transfection of cells with a dominant-negative form of c-src partially inhibited VEGF induction. To examine the potential role of Src in hypoxic induction of VEGF, fibroblasts derived from mice with a c-src disruption were employed. These cells exhibited a 50-70% decrease in hypoxic induction of VEGF mRNA, with a compensatory activation of Fyn. These results strongly suggest a specific role for Src in promoting angiogenesis. In addition, Rak et al. (33) demonstrated that transfection with v-src increased VEGF expression and induced tumorigenicity in an immortalized rat intestinal epithelial cell line. Conditioned media from cells transfected with v-src were able to increase endothelial cell proliferation, and this increase was blocked by the addition of antibodies to VEGF. These results suggest that activation of Src is important to VEGF induction in several cell systems. In contrast, in HEP3b hepatoma cells, hypoxic induction of VEGF did not appear to be Src-dependent (25).
Several laboratories have demonstrated that the specific activity of Src is greatly increased in the majority of colon tumors and cell lines (22, 23, 34). The importance of this activation to colon cell tumorigenicity has been uncertain. Recently, we developed cell lines from HT29-P cells with reduced c-src expression and activity by transfection with an antisense expression vector specific for c-src (26). These cells proliferate more slowly than parental cells in vitro, and tumorigenicity in nude mice is reduced (26). Furthermore, tumors from antisense transfectants were limited in size, even after >1 year of growth in mice. Therefore, the present study was undertaken to determine whether limited growth, in part, resulted from reduced expression and/or induction of VEGF in the antisense transfected cell lines. The results in this paper demonstrate that reduction of Src expression and activity, but not those of the related Yes, directly corresponds to decreased levels of VEGF mRNA and decreased biologic activity of VEGF. Furthermore, fewer blood vessels are observed in tumors that form after injection of the cell lines transfected with the Src antisense constructs. These results suggest that in addition to the role of Src in regulating cell proliferation, activation of Src in colon tumorigenesis may promote tumor growth via induction of VEGF, which in turn induces neovascularization. Further evidence for this possibility was derived from studies on the effect of hypoxia on induction of VEGF mRNA expression in HT29 parental cells and the antisense transfected clone HT29-AS15. In the HT29 parental cells, a >50-fold induction of VEGF mRNA was observed. This induction far exceeded that observed by Mukhopadhyay et al. (18) in fibroblasts, where hypoxia resulted in a maximum 4.5-fold induction of VEGF mRNA. Our results therefore suggest that the higher expression and specific activity of Src kinase in colon tumor cells can augment the ability of hypoxia to induce VEGF. However, in HT29-AS15 cells, in which c-src expression has been reduced 4-fold, the ability of hypoxia to induce VEGF mRNA is severely impaired. These results suggest that in this colon tumor cell system, Src kinase regulates both inducible and constitutive pathways leading to VEGF production. Further confirmation of the ability of Src kinase to regulate inducible VEGF expression was derived from a study of Fleming et al. (30), in which the ability of cell density to up-regulate VEGF expression was diminished in the antisense transfected clones relative to HT29 parental cells.
While our results suggest that constitutive Src activation may be a primary pathway leading to production of angiogenic factors in colon cancer, other pathways resulting from genetic changes in colon cancer may also be responsible for the induction of angiogenic factors. For example, 40-50% of colon tumors are known to have activating ras mutations (35, 36), and previous studies have demonstrated that Ras activation is sufficient to induce VEGF (33, 37). Additionally, in 293 kidney cells, induction of the promoter of VEGF by transfection of v-src is inhibited by overexpression of wild-type p53 (21). Approximately 50-60% of colon cancers exhibit p53 mutations (38), whereas >80% contain activated Src kinase. The relationship between p53 status, Src activation, and VEGF production in colon tumor cells thus requires further study. Nevertheless, the data presented in this paper suggest an important role for Src activation and VEGF expression in the tumorigenicity, progression, and vascularization of human colon tumors.
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ACKNOWLEDGEMENT |
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We thank Melissa Burkett for editorial assistance.
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FOOTNOTES |
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* The work was supported in part by the Gillson Longenbaugh Foundation, American Cancer Society Career Development Award 94-21 (to L. M. E.), and National Institutes of Health Grant T-32 CA09599 (to R. Y. D. F.) and Grants CA65527 and CA53617 (to G. E. G).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: Dept. of Tumor Biology, University of Texas M. D. Anderson Cancer Center, 1515 Holcombe Blvd., P. O. Box 108, Houston, TX 77030. Tel.: 713-792-3657; Fax: 713-794-4784.
1 The abbreviations used are: VEGF, vascular endothelial growth factor; PCR, polymerase chain reaction; HT29-P cells, HT29 parental cells; DMEM, Dulbecco's modified Eagle's medium; FBS, fetal bovine serum; PBS, phosphate-buffered saline; RT, reverse transcription.
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REFERENCES |
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