JP5527573B2 - MCF7-derived cells - Google Patents

Description

  The present invention relates to a highly invasive or highly metastatic MCF7-derived cell obtained by subculturing MCF7 cells, which are a low-metastatic human breast cancer-derived established cell line, under predetermined conditions.

In recent years, advancement of medical devices has enabled extremely early cancer diagnosis, and the cure rate of cancer, especially the 5-year survival rate after surgery, has gradually increased, and the cancer mortality rate has gradually decreased since 1975. However, metastatic epithelial cancer including breast cancer is not in that category. Currently, the number of breast cancer patients in Japan exceeds 40,000, and the number is still increasing. Moreover, there is a statistic that about 40% of breast cancer sufferers die even though the 5-year survival rate after resection for the first breast cancer is 90% or more.
The main cause of death of patients with epithelial cancer including breast cancer is due to distant metastasis or recurrence of the cancer, but because metastasis and recurrence cannot be accurately predicted, originally unnecessary anticancer drug treatment is performed for a long time, and side effects There are many patients who suffer from. For example, in the case of breast cancer, there are prognostic markers such as tumor size and presence or absence of axillary lymph node metastasis, but the determination accuracy is low and only about 30% of patients can predict the risk of recurrence of metastasis. In addition, because early detection of cancer is possible, the primary lesion is small, and even if there is a metastatic lesion at that time, it is very likely that it is very small or is floating in the blood as small disseminated cancer cells. It is very difficult to capture metastasis, and prognostic markers as described above are becoming ineffective. It is therefore important to capture changes that occur very early in cancer cells acquiring metastatic potential.
The search for biomarkers has attracted worldwide attention as a multi-billion dollar market, and research has been conducted with many researchers, but it is extremely difficult to find disease-specific markers. Yes. Of course, cancer metastasis markers and prognostic markers are no exception. Recently, it was reported by analysis of DNA microarrays that not only gene expression profiles differ between primary and metastatic lesions, but also cancers with poor prognosis have acquired gene mutations at an early stage to acquire metastatic potential. In addition, we examined the expression patterns of wound response genes in breast cancer patients based on similarities between wound and tumor physiology (matrix remodeling, cell motility, angiogenesis activation), and these genes predicted poor prognosis. The possibility as a possible marker was shown. From the analysis result of such a DNA microarray, it has been found that the expression profile of about 70 genes is linked to cancer metastasis (see, for example, Non-Patent Document 1). However, the determination accuracy is not stable due to the influence on the gene expression due to the heterogeneity of the disease, individual differences, and the complexity of the analysis method, and clinical application has not been made.
HER2 discovered by identification of drug-inducible genes has been shown to be effective as a prognostic marker for breast cancer. In particular, it has been reported that the monoclonal antibody trastuzumab against this receptor has an effect of reducing the risk of recurrence and prolonging life by administration to HER2-positive early breast cancer patients. In addition, plasminogen activator whose expression level is increased during cancer invasion and its inhibitory factor are also effective as prognostic markers, and have come to be clinically applied particularly as a factor defining sensitivity to chemotherapy.
However, distant metastasis and recurrence occur even in breast cancer patients who do not express these markers, and distant metastasis and recurrence occur in breast cancer patients that are less sensitive to trastuzumab and chemotherapy. In order to capture changes in the initial stage of acquiring metastatic potential and to search for prognostic markers such as cancer metastasis and recurrence, a model for acquiring high metastatic potential of breast cancer-related cells has been required.
Laura J. et al. van't Veer, Hongyu Dai, Mark J. et al. van de Vijver et al. (2002) Nature, Vol 415, 530-536.

In cancer metastasis, the steps of cancer cell adhesion, invasion, and migration are repeated. Cancer cells with high metastatic potential have high adhesion, invasiveness, and mobility. In particular, since the first step of cancer metastasis is invasion from the basement membrane to surrounding tissues, cell invasion is deeply involved in the mechanism of metastasis generation and the initial stage of acquiring metastatic potential. Conceivable.
Therefore, an object of the present invention is to create a model for acquiring high metastatic ability or high invasive ability of breast cancer-related cells.
As a result of repeated studies in view of the above-mentioned problems, the present inventors seeded MCF7 cells, a low-metastatic human breast cancer-derived established cell line, on Matrigel (trademark; the same applies hereinafter), and recovered cells having the ability to pass Matrigel. Then, by repeating the seeding process on Matrigel again, the inventors succeeded in obtaining a novel cell line having high invasion and metastatic potential and having a morphology different from that of MCF7 cells, thereby completing the present invention.
That is, the present invention
[1] A cell derived from MCF7 cells, which has significantly higher invasion ability than MCF7 cells;
[2] A cell derived from MCF7 cells, which has a significantly higher metastatic potential than MCF7 cells;
[3] The MCF7-derived cell according to [1] or [2], which is HER2 negative;
[4] The MCF7-derived cell according to any one of [1] to [3], which is ESTR positive;
[5] The expression level of at least one gene selected from the group consisting of CD44 gene, CXCL12 gene, PLAU gene, and VEGF gene is 1.5 times or more that of MCF7 cells, [1] to [4] The MCF7-derived cell according to any one of
[6] The MCF7-derived cell according to any one of [1] to [5] above, which forms a spheroid;
[7] The MCF7-derived cell according to any one of [1] to [6] above, which has an ability to form a primary tumor nest at a transplantation site when transplanted to an experimental animal;
[8] Derived from MCF7 according to any one of [1] to [7] above, which has the ability to form a metastatic focus in a proximal lymph node, a remote lymph node, or a brain when transplanted to an experimental animal. cell;
[9] From the above [1] obtained by seeding MCF7 cells on a basement membrane preparation or an analog thereof, and recovering cells mutated so as to pass through the basement membrane preparation or an analog thereof. 8] MCF7-derived cells according to any one of the above;
[10] MCF7-derived cells which are MCF7-14 cells (accession number FERM BP-10944);
[11] Any one of [1] to [10] above, wherein at least one gene selected from the group consisting of a GFP gene, a YFP gene, a CFP gene, a β-galactosidase gene, a luciferase gene, and an aequorin gene has been introduced. The MCF7-derived cell according to item 1;
[12] An experimental animal transplanted with the MCF7-derived cell according to any one of [1] to [11] above;
[13] A screening system for a cancer metastasis or recurrence-related factor or an anticancer agent comprising the MCF7-derived cell according to any one of [1] to [11] above;
[14] A screening system for cancer metastasis or recurrence-related factors or anticancer agents, including the experimental animal according to [12] above; and [15] a mutant cell line that has acquired high invasive ability or high metastatic ability from MCF7 cells. A method for establishing MCF7 cells after seeding on a basement membrane preparation or an analogue thereof, and then recovering cells having the ability to pass through the basement membrane preparation or an analogue thereof, It relates to a method characterized in that the step of sowing on the analogue is repeated at least 7 times.

FIG. 1 shows an outline of a method for establishing a highly invasive cell line using a Matrigel invasion chamber.
FIG. 2 shows an image of cells that have passed through the Matrigel invasion chamber fixed and stained with crystal violet.
FIG. 3 shows an image obtained by microscopically observing a cell that has passed through Matrigel and moved downward at a magnification of 100 times.
FIG. 4 shows the average number of cells that have passed through Matrigel and migrated downward.
FIG. 5 shows phase contrast images of MCF7 cells (A) and MCF7-14 cells (B).
FIG. 6 shows the growth curves of MCF7 cells and MCF7-14 cells.
FIG. 7 shows the results of the Wound healing assay for MCF7 cells and MCF7-14 cells.
FIG. 8 shows the results of detecting the MMP activity by the zymogram method when cultured in a cell culture dish containing no matrigel.
FIG. 9 shows the results of detecting the MMP activity when cultured in a Matrigel invasion chamber by the zymogram method.
FIG. 10 shows the results of examining the expression levels of the HER2 gene and the ESTR gene by Western blot analysis.
FIG. 11 shows an outline of a cell transplantation method.
FIG. 12 shows the anatomical results of mice 4 weeks after transplantation of MCF7-GFP cells (A, C) and MCF7-14-GFP cells (B, D). A and B are anatomical images, and C and D are the results of fluorescence observation of the behavior of GFP-expressing cells.
FIG. 13 shows the results of observing lungs excised 4 weeks later from mice transplanted with MCF7-GFP cells (A, C, E) and MCF7-14-GFP cells (B, D, F). A and B are anatomical images of lungs, C and D are fluorescence observation images, and E and F are results of preparing frozen sections from the extracted lungs and immunostaining with anti-GFP antibodies.
FIG. 14 shows the results of observation of the transplantation site (A, C) and the proximal lymph node (B, D) of the mammary gland extracted 4 weeks after the mouse transplanted with MCF7-GFP cells.
FIG. 15 shows the results of observing the transplantation site (A, C) and proximal lymph nodes (B, D) of the mammary gland excised 4 weeks after the mice transplanted with MCF7-14-GFP cells.
FIG. 16 shows the results of observation of the site around the pancreas 4 weeks after transplantation from MCF7-14-GFP cell-transplanted mice.
FIG. 17 shows the results of excision of a pancreatic tumor from an MCF7-14-GFP cell-transplanted mouse 4 weeks after transplantation, preparation of a frozen tissue section, and bright field and fluorescence observation.
FIG. 18 shows the results of preparing frozen sections of MCF7-GFP cell transplanted part, MCF7-14-GFP cell transplanted part and pancreatic mass from mice 4 weeks after transplantation, and immunostaining epithelial markers. Show.
FIG. 19 shows the results of observation of the mouse abdomen (A, B), the excised pancreatic peripheral part (C, D), and the brain (E, F) 12 weeks after transplanting MCF7-14-GFP cells into the mouse. Indicates. In A and B, the arrow indicates the transplant site, and the circled portion indicates the periphery of the pancreas.

Explanation of symbols

  Reference numerals indicate 1 ... Matrigel invasion chamber, 10 ... cell culture insert, 12 ... membrane, 13 ... Matrigel, 14 ... cell, 2 ... dish, respectively.

Hereinafter, preferred embodiments of the present invention will be specifically described.
The MCF7-derived cells according to the present invention are MCF7 cell mutants that have acquired high invasiveness. MCF7 cells derived from human breast cancer are inherently low in invasion and therefore low in metastasis, and even when transplanted into nude mice or the like, primary lesions form but do not metastasize. In contrast, the MCF7-derived cells of the present invention are mutant strains that have acquired significantly higher invasiveness than the original MCF7 cells.
In the present invention, “having significantly higher invasive ability” means that the invasive ability measured by any one of various methods for measuring invasiveness of cells is statistically more significant than the invasive ability of MCF7 cells. Means high. Moreover, the invasiveness of a cell can be evaluated by, for example, the ability to pass through Matrigel that provides an environment similar to a basement membrane in a living body. MCF7-derived cells are seeded on Matrigel, and the ratio of the number of cells that have passed through Matrigel to the number of seeded cells is 50 times or more, preferably 100 times or more, compared to the case where the same test was performed with MCF7 cells. More preferably, it is 500 times or more higher than that.
The MCF7-derived cells of the present invention have a significantly higher metastatic ability than the original MCF7 cells. MCF7 cells are low metastatic, and even when transplanted into nude mice or the like, primary lesions are formed but metastasis is not caused. However, the MCF7-derived cell of the present invention has a mutation that acquires high metastatic ability. In the present invention, “having a significantly high metastatic ability” means that the metastatic ability determined by any one of various methods for evaluating the metastatic ability of cells is statistically significantly higher than the metastatic ability of MCF7 cells. Means high. In addition, for example, when cells are transplanted into a laboratory animal, metastasis to adjacent lymph nodes is observed in at least 50% or more, preferably 60% or more, more preferably 70% or more. Can be said to be expensive.
Moreover, the MCF7-derived cell of the present invention is characterized by being HER2-negative. Here, “HER2 negative” means that the HER2 protein is below the detection limit in the standard Western blotting method. The HER2 gene and protein are frequently expressed in breast cancer-derived malignant tumors with high metastatic potential, and are often used as a tumor marker for diagnosis and treatment determination. Although the MCF7-derived cells of the present invention have high invasion ability and high metastasis ability, they are HER2 negative related to metastasis ability, and therefore are used for studies of metastasis and recurrence as a breast cancer model with low sensitivity to trastuzumab. This suggests that it is likely to be possible.
In addition, the MCF7-derived cells of the present invention are ESTR positive despite having high invasive ability or high metastatic ability. Here, ESTR is an estrogen receptor, and “ESTR positive” means that a clear band can be detected by a standard Western blotting method. Thus, since it is ESTR positive, it is thought that it shows high sensitivity also to hormone treatment, and the MCF7-derived cell of the present invention is used for the study of metastasis and recurrence as a breast cancer model with high sensitivity to hormone treatment. This suggests that it is likely to be available.
In the MCF7-derived cell of the present invention, the expression level of at least one gene selected from the group consisting of CD44 gene, CXCL12 gene, PLAU gene, and VEGF gene is 1.5 times or more that of MCF7 cells. There are various methods for measuring the expression level of a gene, and it may be 1.5 times or more of MCF7 cells when measured by any method. The CD44 gene is preferably 2 times or more, the CXCL12 gene is preferably 5 times or more, the PLAU gene is preferably 10 times or more, and the VEGF gene is preferably 1.8 times or more. All of these genes are known to have high expression levels in cells having metastatic potential.
Further, unlike the MCF7 cells, the MCF7-derived cells of the present invention form spheroids. When MCF7 cells are cultured, they usually become confluent in 4 to 5 days and are peeled off from the container and die. However, the MCF7-derived cells of the present invention form spheroids and can be cultured for 10 days or longer.・ It is estimated that high-density culture is possible. Such a property is useful when a specific substance such as protein or nucleic acid is extracted from the MCF7-derived cell of the present invention for research.
Further, the MCF7-derived cells of the present invention have the ability to form a primary tumor nest at the transplantation site when transplanted into an experimental animal. In general, cancer cells such as MCF7 cells are known to often detach in several days even after transplantation due to increased expression of cancer-specific antigens, etc. Stabilized in the individual. Here, stable establishment means, for example, a case where at least 50%, preferably 60%, more preferably 70%, more preferably 80% of transplanted individuals do not peel for 28 days or more.
In addition, the MCF7-derived cells of the present invention have the ability to form metastatic foci in the proximal lymph nodes, distant lymph nodes, or brain when transplanted into experimental animals.
Such MCF7-derived cells have, for example, a mutation that allows MCF7 cells to be seeded on a basement membrane preparation having the same properties as the basement membrane or the like and pass through the basement membrane preparation or the like. It can be obtained by collecting spontaneously generated cells. Further, the step of seeding cells having the ability to pass through the basement membrane preparation or the like again on the basement membrane preparation or the like, and collecting the cells having the ability to pass through the basement membrane preparation or the analogues is repeated. Thus, an MCF7-derived cell line having higher invasive ability or metastatic ability can be produced. Examples of basement membrane preparations or the like can include, for example, Matrigel, where Matrigel is a solubilized basement membrane extracted from EHS mouse tumor cells rich in extracellular matrix protein (ECM). It is a preparation and provides an environment similar to the in vivo basement membrane. When using Matrigel, the step of seeding MCF7 cells on Matrigel, then collecting the cells passing through Matrigel and seeding again on Matrigel is at least 7 times, preferably 8 times, more preferably 9 times. Preferably, by repeating 10 times, MCF7-derived cells that have acquired sufficiently high invasive ability or metastatic ability can be obtained. Examples of analogs of basement membrane preparations include agarose or collagen gel. MCF7-derived cell lines are thought to have limited ability to migrate due to fiber components in the medium during culture, resulting in low invasive and metastatic potentials. MFC7-derived cells are considered to be similar to basement membrane preparations. It is also possible to obtain.
Examples of such MCF7-derived cells of the present invention include the MCF7-14 cell line deposited at the National Institute of Advanced Industrial Science and Technology, Patent Organism Depositary.
[Reference to deposited biological materials]
1) Name and address of the depository organization National Institute of Advanced Industrial Science and Technology Patent Organism Depositary Center 1st, 1st Street, Tsukuba, Ibaraki, Japan 1st 6th (zip code 305-8666)
2) Date of deposit January 10, 2007 (original deposit date)
3) Accession number FERM BP-10944
These cells are likely to give useful information in cancer metastasis research, prognostic markers, drug discovery target searches, and the like. For example, in addition to gene-level analysis such as DNA microarray and subtraction method, detailed analysis at protein level such as two-dimensional electrophoresis-mass spectrometry makes it possible to acquire high metastatic potential and high invasion ability. There is a high probability that a factor that is considered to be identified. In addition, by capturing factors that mutate in the early stage of metastasis, it becomes possible to predict the prognosis of whether the cancer is metastatic at the same time as the discovery of the initial cancer, and it can be a useful diagnostic criterion in formulating treatment strategies such as the administration method of anticancer agents High nature. In addition to its potential as a new prognostic marker, the identified factor itself may be a target molecule for cancer treatment. If a factor that specifically expresses metastatic cells can be discovered, it will contribute to drug discovery, such as the development of a drug delivery system that targets disseminated cancer cells floating in the blood before the formation of metastatic foci and induces cell death. large. Furthermore, much information obtained by comprehensive analysis of metastasis from various angles such as gene level and protein level is thought to provide many clues to elucidate the mechanism of metastasis. A better understanding of the molecular mechanism of metastatic focus formation will lead to the development of new cancer treatment strategies.
Furthermore, the present invention also provides an MCF7-derived cell into which at least one gene selected from the group consisting of GFP gene, YFP gene, CFP gene, β-galactosidase gene, luciferase gene, and aequorin gene has been introduced. Such cells can be prepared by a known gene transfer method or a method similar thereto, and are useful because the phenotype of each gene can be used for various studies.
The present invention also provides an experimental animal into which the aforementioned MCF7-derived cells have been transplanted. Such an experimental animal can be produced by a known method or a method according thereto. As described above, since the MCF7-derived cells according to the present invention have high invasion ability, metastasis ability and high transplantation ability, the experimental animal is useful for studies of metastasis and recurrence as a breast cancer model. . Examples of experimental animals that can be used include mice, rats, hamsters, gerbils, guinea pigs, rabbits, dogs, cats, pigs, monkeys, birds, fishes, and amphibians.
The present invention also provides a screening system for cancer metastasis or recurrence-related factors or anticancer agents comprising the above-mentioned MCF7-derived cells. A screening system containing cells can be prepared by a known method or a method according thereto. Since this screening system includes MCF7-derived cells that are less sensitive to conventional methods for treating breast cancer, it is possible to screen for invasion inhibitors, discover new factors related to breast cancer metastasis or recurrence, It is useful to contribute to the discovery of preventive drugs.
The present invention also provides a screening system for cancer metastasis or recurrence-related factors or anticancer agents, including experimental animals transplanted with the aforementioned MCF7-derived cells. A screening system including such experimental animals can be prepared by a known method or a method according thereto. This screening system is useful for screening metastasis-inhibiting substances.
The present invention also provides a screening method for establishing a mutant cell line that has acquired high invasiveness or high metastatic ability from MCF7 cells. In this method, after MCF7 cells are seeded on a basement membrane preparation or an analogue thereof, cells having the ability to pass through the basement membrane preparation or an analogue thereof are collected and then again on the basement membrane preparation or an analogue thereof. The step of sowing is repeated at least 7 times. As a method for improving the invasiveness / metastasis of MCF7-derived cells, there is a method using an artificial mutagenesis agent such as inducing a point mutation, but the invasiveness is sufficient because the patterns of mutations that can be introduced are limited. Can't be high. Moreover, since there is a possibility that a mutation that does not occur in a living body may occur, it may not be suitable as a breast cancer model. However, according to the screening method of the present invention, it is possible to obtain MCF7-derived cells having extremely high invasiveness without inducing mutation by a drug or the like. Useful for research that captures stage changes. As the basement membrane preparation or the like, for example, Matrigel can be used.

The present invention will be described in more detail with reference to the following examples, but the scope of the present invention is not limited thereto.
1. Cell Culture MCF7 cells (Breast adenocarcinoma; Human) were cultured in RPMI 1640 (SIGMA) medium containing 10% FBS (Equitech BIO). Cells were passaged every 3 days according to known methods.
2. In Vitro Invasion Assay and Establishment of Highly Infiltrating Cells from Low Invasion Capability Cells As shown in FIG. 1, MCF7 cells 14 were seeded in a cell culture insert 10 of Matrigel Invasion Chamber 1 (Becton Dickinson) according to a known method. . At the bottom of the cell culture insert 10, the matrigel 13 is coated on the membrane 12, and only the cells 14 having the ability to pass through the matrigel move to the lower side of the membrane 12. After 60 hours, cells (infiltrating cells) that migrated to the lower side of the membrane 12 were collected by trypsin-EDTA treatment. The collected cells 14 were cultured in the dish 2 until they became subconfluent, and were seeded again in the Matrigel invasion chamber 1. The above operation was repeated 14 times. In addition, the cells that migrated to the lower side of the membrane 12 were stained with crystal violet, the whole image was observed, and five visual fields were selected under the microscope, and the number of migrated cells was counted.
The results are shown in FIGS. 2 shows a crystal violet-stained image, FIG. 3 shows a microscopic image observed at a magnification of 100 times, and FIG. 4 shows the number of migrated cells. The control indicates MCF7 cells, and the number indicates the number of passes through Matrigel. As a result of repeating the cycle of seeding and passing the cells that passed through Matrigel 13 again on Matrigel 14 times, a cell group having high invasive ability (MCF7-14 cells) was obtained.
FIG. 5 shows phase contrast images of MCF7 cells and MCF7-14 cells. Comparing MCF7 cells (FIG. 5A) and MCF7-14 cells (FIG. 5B), the MCF7-14 cells were more rounded. In addition, MCF7 cells detach when confluent, but MCF7-14 cells formed spheroids and continued to proliferate.
3. Cell proliferation curve MCF7 cells and MCF7-14 cells were seeded in a 96-well plate at 5 × 10 ³ cells / well, and the number of cells after 1, 2, 3, and 4 days was counted by the MTT method.
The results are shown in FIG. The vertical axis represents the number of cells, and the horizontal axis represents the number of culture days. There was no significant difference in cell growth rate between MCF7 cells and MCF7-14 cells.
4). Wound healing assay In order to compare the ability of cells to migrate, a wound healing assay was performed. MCF7 cells and MCF7-14 cells were cultured to a confluent state in a 10 cm dish, and grooves were formed with a micropipette tip. The state in which the cells moved after 1, 2, 3, and 4 days (each with the same visual field at three locations) was observed with a phase contrast microscope and photographed with a camera. In order to examine the mobility of cells, analysis was performed using image analysis software, and the groove width was measured.
The results are shown in FIG. When MCF7 cells (FIG. 7A) and MCF7-14 cells (FIG. 7B) at 0, 1, 2, 3, and 4 days after the formation of the groove were compared, the groove was filled earlier in MCF7-14 cells. FIG. 7C shows the average (%) of the three fields of distance traveled by the cells. 7D and 7E are enlarged images of MCF7 cells and MCF7-14 cells after 3 days, respectively. In MCF7-14 cells (FIG. 7E), actin stress fibers were actively extended.
5. Verification of MMP activity by zymogram Next, matrix metaprotease (MMP) activity in MCF7 cells and MCF7-14 cells was measured. MMP is an enzyme that degrades extracellular matrix as a substrate and plays a major role in the formation of cancer cell invasion and metastasis.
In a 12-well plate, MCF7 cells and MCF7-14 cells were seeded at a concentration of 2.5 × 10 ⁵ cells / well in a normal medium not containing Matrigel and a medium containing Matrigel. The next day, the medium was replaced with 500 μl of serum-free medium, and the medium was collected after 1, 2, 3 hours. The collected medium was concentrated by centrifugation using Microcon (registered trademark) YM30 (Millipore). The concentrated medium and sample buffer were mixed, and electrophoresed at 25 mA for 2 hours at 4 □ using a 10% polyacrylamide gel. The gel was placed in a vat filled with a 2.5% triton X-100-containing buffer, and the SDS was removed twice while slowly permeating at room temperature for 30 minutes. Further, it was incubated with gelatinase activation solution for 37 □ for 24 hours. Then, it dye | stained for 30 minutes with the CBB dyeing liquid, and also decolored with the decoloring liquid for 30 minutes.
FIG. 8 shows the results when cultured in a cell culture dish not containing Matrigel, and FIG. 9 shows the results when cultured in a Matrigel invasion chamber. Each figure A is a stained image of the gel used in the zymogram method, and each figure B and C is the result of analyzing the activities of MMP9 and MMP2 by analysis with image analysis software. As shown in the figure, the expression level of the active MMP was higher in the MCF7-14 cells both in the state where the medium was cultured without containing Matrigel or in the case where the medium was cultured while infiltrating containing Matrigel. .
6). Oligomicroarray RNA was extracted from MCF7 cells and MCF7-14 cells according to a known method, and analyzed by GeneChip (registered trademark) Human Genome U 133 Plus 2.0 Array (manufactured by Affymetrix). Then, genes involved in “cancer” and “metastasis” were searched by Gene spring for genes that fluctuated more than 2 times and genes that fluctuated less than 2 times.
The results are shown in Tables 1-4. Among the 1495 genes that fluctuated more than twice, 13 genes (Table 1) were involved in cancer, and 13 genes (Table 2) were involved in metastasis. Moreover, among 1363 genes which fluctuated 0.5 times or less, 7 genes (Table 3) were involved in cancer, and 0 genes were involved in metastasis. Furthermore, 14 genes of the 231 genes (see Non-Patent Document 1) suggested to be involved in breast cancer were confirmed (Table 4).
7). Preparation of stable GFP expression strain A GFP expression plasmid vector was introduced into MCF7-14 cells established with MCF7 cells according to a known method, and GFP expression cells were screened for about 1 week. 30 clones were cloned using a cloning ring, and repeatedly cultured for about 3 weeks in selective medium (medium supplemented with 400 μg / ml G418 (manufactured by SIGMA)) and maintenance medium (medium supplemented with 50 μg / ml G418). An expression stable strain was established. Hereinafter, they are referred to as MCF7-GFP cells and MCF7-14-GFP cells, respectively.
8). Western Blot Analysis Proteins are extracted from MCF7 cells, MCF7-14 cells, MCF7-GFP cells, MCF7-14-GFP cells, and SDS polyacrylamide is used according to a known method using a polyacrylamide gel having a concentration gradient of 2 to 15%. Gel electrophoresis was performed. The separated protein was transferred to a PVDF membrane, blocked with 5% skim milk, and reacted with an anti-HER2 antibody or an anti-estrogen receptor antibody. Further, it was reacted with an HRP cross-linked secondary antibody and detected by ECL.
The results are shown in FIG. Using proteins extracted from MCF7 cells (lane 1), MCF7-14 cells (lane 2), MCF7-GFP cells (lane 3), MCF7-14-GFP cells (lane 4), anti-HER2 antibody (upper) and anti-HER2 antibody The result of having performed the Western blotting analysis by an ESTR antibody (lower stage) is shown. In general, it is known that when the expression level of HER2 increases, metastasis is high, and when the expression level of ESTR decreases, malignancy increases (high metastasis), but MCF7-14 has the opposite properties (HER2 negative, ESTR positive). )showed that.
9. Cell transplantation MCF7-GFP cells (control) and established MCF7-14-GFP cells were grown 1: 1 with growth factor reduced matrigel (Becton Dickinson) to a final concentration of 8.6 × 10 ⁷ cells / ml. To prepare a transplanted cell solution. As shown in FIG. 11, 100 μl of the transplanted cell solution was transplanted into the fourth mammary gland of a female BALB / cALcl-nu / nu strain mouse. After transplantation, the behavior of GFP-expressing cells was analyzed during dissection.
The results of observing mice 4 weeks after transplantation are shown in FIG. 12A and C are MCF7-GFP cells, B and D are mice transplanted with MCF7-14-GFP cells, A and B are mouse whole images, and C and D are fluorescence observation images of A and B, respectively. In MCF7-GFP cells, although a tumor was formed at the transplantation site, no metastatic lesion was observed. On the other hand, in addition to the formation of the primary tumor nest at the transplant site, MCF7-14-GFP cells were observed to localize GFP-expressing cells seeded in the peritoneum and to observe a relatively large cell mass of GFP-expressing cells in the abdomen. It was.
10. Confirmation of metastasis by staining Four weeks after transplantation, the mammary gland was removed, and frozen sections were prepared according to a known method. This section was subjected to HE staining and immunostaining with an anti-GFP polyclonal antibody and an anti-BRCA2 monoclonal antibody according to a known method.
FIG. 13 shows the results of observing the whole lung region of MCF7-GFP cells and MCF7-14-GFP cell-transplanted mice and the tissue sections immunostained with anti-GFP antibody. In FIG. 13, A, C and E relate to MCF7-GFP cells, B, D and F relate to MCF7-14-GFP cells. In FIG. 13, A and B are anatomical images of lungs, and C and D are fluorescence. Observed images, E and F are results of immunostaining the frozen section with an anti-GFP antibody. As shown, no tumor or GFP expressing cells were observed in the mouse lung region.
FIG. 14 shows the results of observation of the transplantation site (A, C) and the proximal lymph node (B, D) of the mammary gland extracted from a mouse 4 weeks after transplantation of MCF7-GFP cells. A and B show the results of HE staining, and C and D show the results of immunostaining with an anti-GFP antibody. Although many GFP-expressing cells were observed at the transplantation site of the mice transplanted with MCF7-GFP cells, it was observed that there was no metastasis in the mammary lymph nodes.
FIG. 15 shows the results of observation of the transplantation site (A, C) and proximal lymph node (B, D) of the mammary gland extracted from a mouse 4 weeks after transplantation of MCF7-14 GFP cells. A and B show the results of HE staining, and C and D show the results of immunostaining with an anti-GFP antibody. In the MCF7-14-GFP cell-transplanted mice, GFP-expressing cells were observed both at the transplantation site and the mammary lymph node, and it was observed that proximal lymph node metastasis, which is also a prognostic marker for metastasis, occurred.
In order to investigate in more detail the metastatic lesion of the MCF7-14-GFP cell-transplanted mouse shown in FIG. In FIG. 16, A is the whole mouse image, B is the anatomical image around the excised pancreas, and C and D are the results of fluorescence observation of the parts corresponding to A and B, respectively. It was observed that the lymph nodes of the pancreas were enlarged and many GFP-expressing cells were localized.
For further analysis, a pancreatic tumor (FIG. 17A, B) was excised from MCF7-14-GFP cell-transplanted mice, frozen tissue sections (thickness 6 μm) were prepared, HE-stained (FIG. 17C), methyl green Bright field observation by pyronin staining (FIG. 17D) and fluorescence observation of GFP (FIG. 17E) were performed. Since GFP emission was observed in the tumor of the pancreas, it was considered to be a metastatic focus of the transplanted MCF7-14 cells.
As shown in FIG. 18, transplanted part (AC) from MCF7-GFP cell transplanted mice 4 weeks after transplantation, transplanted part (DF) from MCF7-14-GFP cell transplanted mice 4 weeks after transplantation. Then, the tumor (GI) of the pancreas was removed, frozen sections were prepared, and cytokeratin 7 (KRT7; A, D, G), KRT19 (B, E, H), KRT20 (C, F) as epithelial markers , I) was immunostained. As primary antibodies, mouse anti-KRT7 monoclonal antibody (ZYMED Laboratories, 18-0234; dilution factor 50 times), mouse anti-KRT19 monoclonal antibody (SANTA CRUZ, sc-6278; 50 times) and mouse anti-KRT20 monoclonal antibody (SANTA CRUZ, sc -52320; 50 times), a histofine mouse stain kit (Nichirei) was used as a blocking and sensitizing reagent, and 3,3′-diaminobenzidine tetrahydrochloride (DAKO) was used as a chromogenic substrate. Many of the cells contained in the masses found in the pancreas showed the same expression pattern of epithelial markers as the GFP-introduced strain of MCF7 cells (MCF7-GFP) and the transplanted MCF7-14-GFP cells. From these results, it was confirmed that MCF7-14-GFP cells transplanted into the mammary gland had metastasized and formed a metastatic focus.
FIG. 19 shows the results of observation of mice 12 weeks after MCF7-14-GFP cell transplantation. The peripheral part of the pancreas (C, D) was removed from the mouse abdomen (A, B), and the brain (E, F) was further removed. A, C, and E are anatomical images, and B, D, and F are fluorescence observation images. From these results, a metastatic tumor nest having a diameter of 1 cm or more was observed in the lymph nodes near the pancreas, and the localization of GFP-expressing cells could be confirmed in the brain.

The MCF7-derived cells according to the present invention have high invasive ability or high metastatic ability despite being derived from MCF7 cells. Since such a mutation is induced in an environment close to nature without using a drug or the like, the mechanism of metastasis generation and the MCF7-derived cell according to the present invention are in the initial stage of acquiring metastatic ability. It is suitable for research to detect prognostic markers such as metastasis and recurrence, and to detect invasion / metastasis-specific factors and to develop diagnostic kits for predicting cancer metastasis and prognosis. It can be done.
In addition, since conventional cancer metastasis studies target tissues derived from various races and various disease symptoms, or cell lines derived from these tissues, it is not possible to discover a large number of causative factors. However, it was difficult to identify factors that were commonly present and could serve as markers. However, if the MCF7-derived cells of the present invention are used, it is highly possible that a highly accurate marker can be screened by comparing subcell lines derived from cell lines having the same genetic background. The identification factor itself is highly likely to be a drug discovery target.

Claims (5)

  MCF7-derived cells, which are MCF7-14 cells (Accession No. FERM BP-10944).   The MCF7-derived cell according to claim 1, wherein at least one gene selected from the group consisting of a GFP gene, a YFP gene, a CFP gene, a β-galactosidase gene, a luciferase gene, and an aequorin gene is introduced. An experimental non-human animal into which the MCF7-derived cell according to claim 1 or 2 is transplanted.   A screening system for a cancer metastasis or recurrence-related factor or an anticancer agent comprising the MCF7-derived cell according to claim 1 or 2. A screening system for cancer metastasis or recurrence-related factors or anticancer agents, comprising the experimental non-human animal according to claim 3.