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A Hammerhead Ribozyme Suppresses Expression of Hepatocyte Growth Factor/Scatter Factor Receptor c-MET and Reduces Migration and Invasiveness of Breast Cancer Cells¹

University Department of Surgery, University of Wales College of Medicine, Cardiff CF14 4XN, United Kingdom [W. G. J., D. G., J. L., T. A. M., R. E. M.], and Department of Neurology, Kennedy Krieger Institute, Johns Hopkins University School of Medicine, Baltimore, Maryland 21205 [R. A., J. L.]

	ABSTRACT

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Purpose: Hepatocyte growth factor/scatter factor (HGF/SF), via its receptor c-MET, has been implicated to play a pivotal role in breast cancer development and progression. This study examined a transgene—consisting of a combination of U1snRNA, hammerhead ribozyme, and antisense, designed to inhibit c-met expression—and its impact on the migration and in vitro invasion of breast cancer cells.

Experimental Design: A hammerhead ribozyme targeting human c-MET was cloned into a modified pZeoU1EcoSpe vector and transfected into breast cancer cells MDA MB 231 and MCF-7 by electroporation. Expression of MET mRNA and protein was determined. Migration and in vitro invasiveness of transfected cells were also analyzed.

Results: Breast cancer cells were transfected with the ribozyme-containing plasmids. Stable transfectants manifested an almost complete loss of MET mRNA and protein, as shown by reverse transcription-PCR, Northern blotting, and Western blotting, respectively, whereas the wild-type plasmid had no effects. Met-ribozyme transfected cells exhibited reduced migration and in vitro invasiveness through extracellular matrix (Matrigel), compared with the wild-type cells and cells transfected with empty plasmid.

Conclusions: These data show that targeting c-MET by way of a hammerhead ribozyme encoding antisense to c-MET is an effective approach in reducing the invasiveness of breast cancer cells.

	INTRODUCTION

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HGF,³ also known as SF, is a cytokine that plays multiple roles in breast cancer (1 , 2) . In vitro studies have demonstrated the cytokine to be able to stimulate the dissociation, migration, motility, adhesion to, and invasion of extracellular matrix via mechanisms such as induction of the phosphorylation of focal adhesion kinase and paxillin (3, 4, 5) . HGF/SF is also a potent angiogenic factor, both in vitro and in vivo (6, 7, 8) . The action of HGF/SF is mediated by c-MET, a proto-oncogene, which has an intrinsic kinase domain (9 , 10) . Upon stimulation of HGF/SF, met becomes phosphorylated and initiates a range of signals that lead to activation of cellular behaviors.

Cancer cells, including breast cancer cells, overexpress HGF/SF receptor (3, 4, 5) . Clinical studies have provided the most direct evidence that HGF/SF and its receptor are powerful factors associated with the progression and prognosis of patients with breast cancer (11, 12, 13) . Breast cancer tissues express a higher level of MET, both at protein and mRNA levels. Breast tissues are rich in stromal cells, particularly fibroblasts that are the main producers of HGF/SF in vivo. Stromal fibroblasts from breast cancer tissues have been shown to express and produce large amounts of bioactive HGF/SF, compared with normal tissue stroma. The level of HGF/SF and MET are among the most relevant factors to predict the prognosis of patients bearing breast cancer (14 , 15) .

Given the clinical importance of HGF/SF and its receptor, to suppress the activity of HGF/SF will have strong clinical bearing. A growing number of agents and molecules are known to have an inhibitory effect on HGF/SF-induced action on cancer cells. These agents include invasion inhibiting factors (16) , -linolenic acid (17 , 18) , IL-4, and IL-12 (19 , 20) via mechanisms that indirectly associate with HGF/SF and its receptor. An antagonist specific to HGF/SF has also found to be able to suppress the action of HGF/SF by competing for the receptor with mature HGF/SF (21, 22, 23) .

Recently, a powerful approach has been reported to target the receptor, c-MET, using U1/ribozyme, a hammerhead ribozyme the encodes a specific antisense sequence to c-MET (24) . It was shown that the U1/ribozyme was able to reverse the malignancy of glioblastoma cells both in vitro and in vivo, thus offering a possible approach of gene therapy specifically targeting HGF/SF pathways. The current study examined whether the ribozyme was effective in manipulating the invasiveness of breast cancer cells.

	MATERIALS AND METHODS

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Human breast cancer cells, MDA MB 231 and MCF-7, were from the European Collection of Animal Cell Culture (Salisbury, United Kingdom) and maintained routinely in DMEM with 10% FCS. Rabbit antibody to human c-MET (C28), mouse anti-ß-actin, and chemiluminescence kit were obtained from Santa Cruz Biotechnology (Santa Cruz, CA). Horseradish peroxidase-conjugated antimouse and antirabbit antibodies were from Sigma Chemical Co. (Poole, Dorset, United Kingdom). Zeocin was from Invitrogen, Ltd. Recombinant human HGF/SF was a generous gift from Dr. T. Nakamura (Osaka, Japan). Matrigel (reconstituted basement membrane) was purchased from Collaborative Research Products (Bedford, MA). A transwell plate equipped with a porous insert (pore size, 8 µm) was from Becton Dickinson Labware (Oxford, United Kingdom).

U1/Ribozyme Targeting Human c-MET.
This was constructed as reported previously (24 , 25) . Briefly, pZeoU1EcoSpe parent vector was derived from wild-type U1snRNA, which is an essential component of the spliceosome complex and is stable and abundant in the nucleus. The U1 promoter is cloned in a BamHI site of a modified pZeo-EcoSpe vector, which is zeocin resistant. A hammerhead ribozyme that recognizes and cleaves the GUC sequence was used. The complementary pair of ribozyme oligonucleotides that span between 540 and 580 with a GUC sequence at position 560 of human c-MET was synthesized, annealed at 40°C, and ligated into pU1 at the EcoRI and SpeI site to create MET560 vector and referred to as MET560 in the text (Fig. 1) . An irrelevant sequence was also cloned into pU1 between EcoRI and SpeI sites as control empty vector and is referred to as pU1 in the text (Fig. 1) . Vectors were transfected into chemically competent Escherichia coli. Plasmid was extracted using a plasmid extraction kit (Qiafilter; Qiagen).

View larger version (19K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Structure of ribozyme and U1snRNA. A, the secondary structure of U1snRNA. B, the structure of MET560 hammerhead and pU1. Antisense sequence is indicated. The hammerhead structure recognizes and cleaves the GUC position (MET560) at position 560, as indicated. In the control plasmid, a sequence as indicated replaces the antisense and hammerhead structure. Arrows, cloning sites for the ribozyme and control sequence.

Extraction of RNA, RT-PCR, and Northern Blotting.
Cellular RNA was extracted using an RNA extraction kit (AbGene, Ltd., London, United Kingdom) and quantified using a spectrophotometer (Wolf Laboratories). cDNA was synthesized using a first-strand synthesis with an oligo dt primer (AbGene). The PCR primers used were as follows: for c-MET, 5'-GTC CAG GCA GTG CAG CAT GTA-'3 and 5'ACT ATA GTA TTC TTT ATC ATA CAT GTC'3. The PCR was performed using a Perkin-Elmer thermocycler and PCR mastermix reaction mixture (Abgene, Surrey, United Kingdom): 5 min at 95°C and then 30 s at 94°C-60 s at 64°C (60°C for c-MET), 60 s at 72°C for 36 cycles, and finally 72°C for 7 min. For hammerhead structure, primers used were UBAMHF and UBAMHR. ß-actin was amplified simultaneously using primers 5'-gctgatttgatggagttgga-3' and 5'-tcagctacttgttcttgagtgaa-3'. PCR products were then separated on a 0.8% agarose gel, visualized under UV light, photographed using a Unisave camera (Wolf Laboratories), and documented with Photoshop software.

For Northern analysis, 10 µg of total RNA were resolved on a 0.8% denaturing agarose gel and transferred to a nylon membrane. A cDNA probe for human c-MET was used for subsequent hybridization overnight at 45°C in the presence of formamide. Membranes were washed under stringent conditions and then exposed to X-ray film. All blots were subsequently reprobed with a human ß-actin cDNA to correct for loading errors. mRNA band densities of both c-MET and ß-actin were determined using a volume analysis function of Molecular Analyst (Bio-Rad). c-MET levels are shown here as the ratio c-MET:ß-actin.

Western Blotting Analysis of MET.
Cells were lysed in HCMF buffer containing 1% Triton, 0.1% SDS, 2 mM CaCl₂, 100 µg/ml phenylmethylsulfonyl fluoride, 1 µg/ml leupeptin, and 1 µg/ml aprotinin for 30 min before clarification at 13,000 x g for 10 min. Protein concentrations were measured using fluorescamine (Sigma Chemical Co.) at 200 µg/ml and quantified by using a multifluoroscanner (Denly, Sussex, United Kingdom). Equal amounts of protein from each cell sample (15 µg/lane) were added onto a 8% polyacrylamide gel. After electrophoresis, proteins were blotted onto nitrocellulose sheets and blocked in 10% skimmed milk for 60 min before probing with the antihuman MET or antihuman ß-actin antibody and peroxidase-conjugated secondary antibodies. A molecular weight marker mixture (SDS-6H; Sigma Chemical Co.) was used to determine the protein size. Protein bands were visualized with a chemiluminescence system (Santa Cruz Biotechnology). Exposed films were scanned with a scanner, and the density of protein bands was analyzed with the software Optimas [Optimas (UK) Ltd., Milton Keynes, United Kingdom].

In Vitro Invasion Analysis.
This was done as previously reported and modified in our laboratory (25 , 26 , 27) . Briefly, transwell inserts with 8-µm pore size were coated with 50 µg of Matrigel and dried, before being rehydrated. Cells (20,000) were added to each well with or without HGF/SF. After 96 h, cells that had migrated through the matrix and stuck to the other side of the insert were fixed, stained with 0.5% (w/v) crystal violet, and counted under microscope.

Cell Migration Motion Analysis and Colony Dissociation Assay.
Cells were plated out at 10,000 and 20,000/well for colony scattering assay (MCF-7 cells) and for motion analysis (23 , 28 , 29) . For cell scattering, MCF-7 cells only were tested as they formed tight colonies, whereas MDA MB 231 grew in monolayers and were not suitable for the test. Cells were allowed to adhere for an additional 24 h to form colonies. Medium or HGF/SF (40 ng/ml) was then added. After an additional 24 h, cells were fixed and stained with 0.5% w/v crystal violet and either photographed or analyzed as reported previously (28). For cell motion analysis, cells were first overlaid with light mineral oil and then placed on a stage heated to 37°C. Culture medium or HGF/SF (to the final concentration at 40 ng/ml) was added to the medium under the mineral oil. Cells were then subjected to continuous monitoring using a digital camera (Panasonic Digital) and time lapse video recorder. Images were subsequently obtained at 10-min intervals and analyzed using a motion analysis package (Optimas 6). The accumulated distance that a cell traveled and the average speed over a period of 10 min were analyzed. Over 20 cells were analyzed in each setting, and data were automatically processed with Excel.

Statistics.
Statistical analysis was carried out using the Mann-Whitney U test, and a significant difference was taken at P < 0.05.

	RESULTS

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Introduction of Plasmid DNA into Breast Cancer Cells and Selection of Stable Transfectants.
After electroporation, a majority of cells were recovered and allowed to grow in plain medium for an additional 24 h. Zeocin at a concentration of 100 µg/ml was added to the cells, and medium was changed every 3–4 days. Cells without plasmid began to die from the second week of selection, and by the end of 4 weeks selection, cells were changed into maintenance medium (zeocin at 25 µg/ml).

The presence of plasmid DNA was verified using RT-PCR with primers specific to the Hammerhead ribozyme (UBAMHF and UBAMHR). MET560 was seen in MDA MB 221 (MET-MDA MB 231) and MCF-7 (MET-MCF-7) cells (Fig. 2 , middle panel). Wild-type PU1 were successfully introduced into the cells and referred to as PU1-MDA MB 231 and PU1-MCF-7, respectively. In contrast, wild-type cells had no signal for the presence of plasmid.

View larger version (62K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Presence of hammerhead ribozyme plasmid in stable transfectants. After 4 weeks selection with zeocin, cells were pelleted, and RNA was extracted. RT-PCR was carried out with primers to detect c-MET (top panels), Hammerhead sequence (middle panels), and ß-actin in MDA MB 231 cells (left panels) and MCF-7 cells (right panels). Cells carrying MET560 almost completed inhibited c-MET mRNA, whereas control plasmid had no effects on the expression.

View larger version (51K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Northern blotting for c-MET mRNA in MDA MB 231 cells. Top panel: A, membrane probed with specific human c-MET cDNA; B, membrane probed with ß-actin cDNA. Bottom panel, right, band volume of ß-actin, quantified by Molecular Analyst (Bio-Rad); middle, band volume of c-MET; left, volume ratio (c-MET:ß-actin). MET560 greatly decreased the expression of c-MET mRNA.

View larger version (54K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. Western blotting for Met in MDA MB 231 (left) and MCF-7 cells (right). MET was detected using a polyclonal antihuman MET antibody (rabbit, C28) and ß-actin using a monoclonal antihuman ß-actin antibody. MET560 reduced the level of MET in both cells, whereas the control plasmid (pU1) had no effects. The level of ß-actin was not affected by either of the plasmids.

View larger version (46K): [in this window] [in a new window] [Download PPT slide]   Fig. 5. Migration of MDA MB 231 cells. Wild-type (left), MET560 transfected (middle), and pU1 control plasmid (right) transfected MDA MB 231 cells were plated in a 24-well plate and allowed to adhere for overnight. They were then overlaid with light mineral oil and either HGF/SF or medium (control) was added. Cells were then subject to continuous time-lapse video recording on a heated stage (37°C). Series digitized images were analyzed using a motion analysis function in Optimas 6. The accumulated migration distance (µm; top panel) and average migration speed (µm/min; bottom) are shown here. HGF/SF increased the migration in both wild-type and pU1 transfected cells but not in the MET560 transfectant. Bars, SE.

View larger version (43K): [in this window] [in a new window] [Download PPT slide]   Fig. 6. Migration of MCF-7 cells. The setting is similar to that mentioned in Fig. 5 . HGF/SF increased the migration in both wild-type and pU1 transfected cells but not in the MET560 transfectant. Bars, SE.

View larger version (25K): [in this window] [in a new window] [Download PPT slide]   Fig. 7. Reduction of colony scattering of MCF-7 cells. MCF-7 cells were plated in a 24-well plate and allowed to form colonies. HGF/SF or medium was then added for an additional 24 h. Colonies were captured as digitized images, and sizes were analyzed using area morphometry. HGF/SF increased the size of colonies in both wild-type and pU1 transfected cells. However, MET560 transfected cells lost their response to the stimulus. Bars, SE.

View larger version (26K): [in this window] [in a new window] [Download PPT slide]   Fig. 8. In vitro invasion of MDA MB 231 (left) and MCF-7 (right). Matrigel (50 µg/insert)-coated inserts were added with cancer cells, together with HGF/SF or medium for 96 h. The number of invaded cells was given as number/high power field. *, P < 0.05 versus without HGF/SF. HGF/SF increased invasiveness in wild-type and pU1 transfected cells but not in MET560 transfected cells. Bars, SE.

	DISCUSSION

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HGF/SF is a known invasion and migration stimulus to cancer cells (36 , 37) . This was shown clearly in the current study, in which wild-type cells became highly motile after stimulation with HGF/SF, exhibiting faster migration and longer traveling distance, and acquired invasiveness after stimulation. In the case of MCF-7 cells, which grow in colonies, they increased their scattering in response to HGF/SF. However, in cells that were transfected with MET560 plasmid and removed of their c-MET, they almost completely lost their response to HGF/SF. This not only indicates that HGF/SF is a powerful motility and invasion promoter in breast cancer cells, it also points to the possibility that targeting the HGF/SF receptor, c-MET, is a powerful approach in combating the action of HGF/SF in breast cancer.

Breast cancer is a tumor type that has high levels of c-MET in tumor cells and a high level of HGF/SF associated with the tumor (10, 11, 12, 13 , 36) . In various studies, the majority of cancer cells in breast tumor overexpress c-MET, at both protein and mRNA levels. Furthermore, HGF/SF has been found to be expressed at a high level in breast tissues. The HGF/SF found in breast cancer tissues has been demonstrated to be bioactive. The source of HGF/SF in this case is also worth noting. Breast tissue, particularly breast tumor tissues, is known to be stroma rich. Histology easily reveals that the stromal cells in these tissues are mainly fibroblasts. It is the fibroblasts that contribute mainly to the high level of bioactive HGF/SF in breast cancer tissues. It has been sparsely reported that some breast cancer cells may also express and produce bioactive HGF/SF. However, the latter is a minor part of the contribution to the high level. The importance of HGF/SF and c-MET in breast cancer is particularly reflected in its correlation with the prognosis of patients. In a large scale study, HGF/SF and c-MET levels are found to be closely related with the prognosis of patients with breast cancer and perhaps the most powerful independent prognostic factors.

Strategies to counteract the action of HGF/SF have been long sought. The known approaches include using specific antagonist to HGF/SF, such as NK4, specific inhibitors to MET, and inhibitors that exert inhibition to HGF/SF in a nonspecific fashion such as -linolenic acid, IL-12, retinoic acid, and IL-4. The approach reported here may provide another important method to specifically target c-MET at the mRNA level. It also provides an opportunity to target the molecule for long-term gene therapy. Indeed, it has been reported that the approach has yielded promising results in glioblastoma in animal studies, in which the U1/ribozyme targeting c-MET mRNA reverses the malignant nature of neuroblastoma (24) . Taken together, U1/ribozyme is a powerful tool to eliminate human c-MET from cancer cells. Targeted cancer cells exhibit a reduction of migration and invasion in response to HGF/SF, as demonstrated in the current study and other studies (24) . Such an approach would be interesting in targeting tumor cells in vivo. However, conventional bacterial plasmids, such as the one used in the current study, offer very limited space in direct in vivo studies because of the low capacity of the bacterial plasmids to enter cells. We are currently developing a viral form of these ribozymes, aiming at direct delivery of these ribozymes in vivo.

In summary, this study reports that U1/ribozyme designed to target human c-MET is a powerful approach to inhibit the action of HGF/SF in human breast cancer cells. It specifically reduced the expression of c-MET at the mRNA and subsequently protein levels, and cells carrying the plasmid exhibited low invasive and low migratory properties in response to HGF/SF. It is further indicated that the ribozyme may be a powerful approach in suppressing the sinister action of HGF/SF in breast cancer.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Support for this work came from the Susan G. Komen Breast Foundation (99003036), Breast Cancer Campaign (1999:73), and National Institute of Health (NIH ROINS32148 to J.L.).

² To whom requests for reprints should be addressed, at Metastasis Research Group, University Department of Surgery, University of Wales College of Medicine, Cardiff CF14 4XN, United Kingdom. Phone: 44-29-2074-2895; Fax: 44-29-2076-1623; E-mail: jiangw{at}cf.ac.uk

³ The abbreviations used are: HGF, hepatocyte growth factor; SF, scatter factor; U1snRNA, U1 small nuclear RNA; RT-PCR, reverse transcription-PCR; IL, interleukin.

Received 1/11/01; revised 5/11/01; accepted 5/31/01.

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