Transduction of the Macrophage Colony-stimulating Factor Gene into Human Multidrug Resistant Cancer Cells: Enhanced Therapeutic Efficacy of Monoclonal Anti-P-glycoprotein Antibody in Nude Mice

To develop a therapeutic modality for overcoming multidrug-resistant (MDR) cancer with anti-MDR1 antibody, we examined the effect of macrophage colony-stimulating factor (M-CSF) gene transfection into MDR AD10 cells on therapy of MDR cancer with anti-MDR1 antihody (MRK17) in nude mice. MDR human ovarian cancer (AD10) cells were transduced with the human M-CSF gene inserted into an expression vector to establish gene-modified cells capable of producing low (ML-AD10), intermediate (MM-AD10) and high (MH-AD10) amounts of M-CSF. Systemic administration of MRK17 resulted in significant dose-dependent inhibition of subcutaneous growth of ML-AD10 tumors. In contrast, systemic administration of recombinant M-CSF in combination with MRK17 did not augment the therapeutic efficacy of MRK17 alone, but rather promoted the growth of the parent AD10 cells. To test the efficacy of in vivo M-CSF gene therapy combined with antibody, we mixed the parent AD10 cells with MH-AD10 cells producing a large amount of M-CSF, and inoculated the mixed cells subcutaneously. Treatment with MRK17 inhibited growth of the mixed cells more than that of the parent cells alone. Thus, combined therapy with anti-MDR1 mAb and M-CSF gene modification of MDR cancer cells may provide a new immunotherapeutic modality for overcoming MDR in humans.     

Combined therapy of multidrug-resistant human lung cancer with anti-P-glycoprotein antibody and monocyte chemoattractant protein-1 gene transduction: The possibility of immunological overcoming of multidrug resistance

We determined whether transduction of the monocyte chemoattractant protein-I (MCP-I) gene into MDR human lung cancer cells affected their tumorigenicity and sensitivity to antibody-dependent cellular cytotoxicity (ADCC) reaction mediated by the anti-P-glycoprotein (P-gp) monoclonal antibody MRK 16. The human MCP-I gene inerted into an expression vector (BCMGSNeo) was transfected into MDR human small-cell lung cancer (H69/VP) cells. Monocyte chemotactic activity was found in culture supernatants collected from MCP-I-transfected H69/VP cells, but not in supernatants of parent and mock-transfected cells. In an in vitro experiment, recombinant MCP-I did not affected monocytemediated ADCC against H69/VP cells when added to the monocyte culture in either the activation or the effector phase at sufficient concentrations to attract and activate monocytes. Tumorigenicity and growth rates of MCP-I-producing H69/VP cells in nude mice were similar to those of parental cells and mock-transfected cells. However, systemic treatment with MRK16 was move effective in inhibiting the formation of tumors by MCP-I-gene-transfected cells than by mock-transfected cells. Systemic treatment with MRK16 also inhibited the growth of a mixture (1:1) of MCP-I-producing cells and mock-transfected cells. These results suggest that combination therapy with MRK16 and MCP-I gene transduction may be a useful immunological strategy to inhibit the growth of human MDR cancer cells expressng P-gp. Int. J. Cancer 71:170–177, 1997. © 1997 Wiley-Liss, Inc.     

M-CSF gene transduction in multidrug-resistant human cancer cells to enhance anti-P-glycoprotein antibody-dependent macrophage-mediated cytotoxicity

A human macrophage-colony-stimulating-factor(M-CSF) gene inserted into an expression vector (pRc/CMV-MCSF) was transfected into multidrug-resistant (MDR) human ovarian cancer cells (AD 10) to induce secretion of human M-CSF into the medium. The M-CSF level in the culture medium of the transfected cells reached 100 ng/ml after 7 days, and the ability of the cells to secrete M-CSF was stable for at least 3 months. Transfection of the M-CSF gene did not result in any change in expression of MDRI (P-glycoprotein), proliferation or chemosensitivity of the cells from those of the parent cells. There was also no difference between the transfected and the parent cells in susceptibility to NK cell- or interleukin-2-activated killer-cell-mediated cytotoxicity. Human blood monocytes that had been incubated for 4 days in medium with the culture supernatant of MH-AD 10 cells exhibited higher ADCC activity than untreated monocytes against MDRI-positive cancer cells. This effect of the supernatant of AD 10 cells was completely abolished by its treatment with a monoclonal anti-M-CSF antibody (MAb). When transfected human MDR cells were injected into nude mice, an inverse correlation was seen between the ability of the cells to produce M-CSF and their tumorigenicity. Thus, gene modification of MDR cancer cells seems hopeful as a therapeutic method for enhancing anti-MDRI -MAb-dependent macrophage-mediated cytotoxicity against human MDR cancer cells.     

Inhibition of multidrug-resistant human tumor growth in athymic mice by anti-P-glycoprotein monoclonal antibodies

In an effort to devise an effective treatment for human drug-resistant cancers, we have developed monoclonal antibodies, MRK16 and 17, reactive to the multidrug transporter protein, P-glycoprotein. The monoclonal antibodies given intravenously effectively prevented tumor development in athymic mice inoculated subcutaneously with drug-resistant human ovarian cancer cells 2780AD. Treatment with MRK16 induced rapid regression of established subcutaneous tumors and apparent cures of some animals. Complement-dependent cytotoxicity (MRK16) and antibody-dependent cell-mediated cytolysis (MRK16 and 17) were observed with these antibodies. These monoclonal antibodies may have potential as treatment tools against multidrug resistant human tumors possessing the P-glycoprotein.     

Monoclonal antibody MRK16 reverses the multidrug resistance of multidrug-resistant transgenic mice.

Using multidrug-resistant (MDR)-transgenic mice, whose bone marrow cells express the human MDR1 gene at a level approximately equal to that found in many human cancers, we determined the efficacy of human-specific anti-P-glycoprotein monoclonal antibody MRK16 in overcoming multidrug resistance in an intact animal. MRK16 alone (2 mg) did not significantly affect the WBC counts of the MDR-transgenic mice, but MRK16, as well as the F(ab')2 fragments of MRK16, led to a dose-dependent circumvention of bone marrow resistance against daunomycin, doxorubicin, vincristine, vinblastine, etoposide, and taxol. This sensitizing effect could not be enhanced by combining MRK16 with low molecular weight chemosensitizing agents such as verapamil, quinine, quinidine, or cyclosporin A. We also investigated the concept of specifically targeting and killing multidrug-resistant cells by using MRK16 coupled to Pseudomonas exotoxin (PE). MRK16-PE resulted in a dose-dependent killing of bone marrow cells in MDR-transgenic mice, whereas no bone marrow toxicity was observed in normal control mice. Administration of excess MRK16 prior to injection of MRK16-PE successfully blocked the effect of MRK16-PE. MOPC-PE, a non-MDR-related control monoclonal antibody conjugate, did not target and kill multidrug-resistant bone marrow cells in MDR-transgenic mice. Thus, these immunological approaches to reversing multidrug resistance appear to be both specific and effective.     

Monocyte chemoattractant protein-1 gene modification of multidrug-resistant human lung cancer enhances antimetastatic effect of therapy with anti-P-glycoprotein antibody in SCID mice

Distant metastases and multidrug resistance are critical problems in the therapy of human small cell lung cancer (SCLC). In this study, we investigated whether transduction of the monocyte chemoattractant protein-1 (MCP-1) gene into multidrug-resistant (MDR) human lung cancer cells affected the formation of metastases or their inhibition by the anti-P-glycoprotein (P-gp) monoclonal antibody (MAb) MRK16. MDR human SCLC (H69/VP) cells were transduced with the human MCP-1 gene inserted into the expression vector BCMGSNeo. MCP-1 gene transduction had no effect on drug sensitivity, the expression of surface antigens or the in vitro proliferation of H69/VP cells. Using the metastatic model of NK cell-depleted SCID mice, H69/VP cells transduced with the MCP-1 gene were inoculated intravenously (i.v.) and formed metastatic colonies in the liver, kidneys and lymph nodes, similar to those formed by parent or mock-transduced cells. However, systemic treatment of the mice with MRK16 reduced the metastases of H69/VP cells in the liver, kidneys and lymph nodes, and was significantly more effective in inhibiting the metastases of MCP-1 producing H69/VP than those of mock-transduced cells. MCP-1 gene transduction significantly prolonged the survival of tumor-bearing mice treated with MRK16. Our findings suggest that local production of MCP-1 in the tumor site increases the anti-P-gp antibody-dependent cell-mediated cytotoxicity, and the MCP-1 gene-induced modification of MDR human SCLC cells thereby enhances the antimetastatic effect of therapy with anti-P-gp antibody. Thus, the accumulation of effector cells in the tumor site is a very important factor in the therapy using the anti-P-gp antibody.     

携带p16基因增殖缺陷型腺病毒对胃癌细胞皮下移植瘤的治疗作用

诱导免疫原性肿瘤细胞死亡是抗肿瘤化疗药物的目标之一,该作用可以通过免疫系统的“旁观者效应”根除对化疗药物抵抗的肿瘤细胞和肿瘤干细胞。蒽环类化疗药物(anthracyclin)在激发机体免疫原性的抗肿瘤反应方面具有显著的效应,但DNA损伤类化疗药物如依托泊苷(etoposide)和丝裂霉素C(mitomycin C)则不能有效地诱导免疫原性的细胞死亡。蒽环类化疗药物是如何使机体免疫系统能够识别肿瘤细胞,继而激发机体抗肿瘤效应呢?该研究的结果表明,蒽环类化疗药物能够快速诱导促凋亡的钙网蛋白(calreticulin,CRT)从胞质转位到胞膜,从而被树突状细胞表…     

IL15 combined with Caspy2 provides enhanced therapeutic efficiency against murine malignant neoplasm growth and metastasis

Interleukin-15 (IL15) is a potential immunotherapeutic treatment for cancer. Caspy2 is an active zebra caspase for inducing apoptosis and immune response in murine tumors. In this study, we aim to evaluate the potential of gene therapy using IL15 and Caspy2 against the murine tumors. Plasmid expressing both Caspy2 and IL15 genes was constructed, encapsulated in DOTAP/cholesterol cationic liposome and injected intratumorally into the mice bearing CT26, B16-F10 and 4T1 carcinoma. We found that coexpression of IL15 and Caspy2 could significant inhibit tumor growth and prolong survival of the mice bearing CT26 or B16F10 tumor. A significant reduction in spontaneous lung metastasis was observed in the 4T1 tumor model. In CT26 model, the mice treated with IL15 and Caspy2 acquired a long-time protective immunity against the parental tumor cell rechallenge. Cytotoxic T lymphocytes and terminal deoxynucleotidyltransferase-mediated nick end labelling assays showed that the combination of capsy2 and IL15 could enhance both the apoptosis and immune response induction, which may account for its extraordinary antitumor effect. Furthermore, we showed that the observed tumor suppression by IL15 and Caspy2 concurred with the Caspy2-mediated downregulation of IL10 and upregulation of interferon-γ and tumor necrosis factor-α. Our results therefore suggested that the combination regimen might be a novel and effective strategy for cancer treatment.     

Antitumor activity and murine pharmacokinetics of parenteral acronycine

The lipophilic antitumor alkaloid acronycine (ACRO) was solubilized in the cosolvent system used for etoposide. ACRO in this etoposide diluent (VPD) was found to be cytotoxic (less than or equal to 50% colony formation in soft agar) in fresh human tumors from patients with renal cell cancer, ovarian cancer, uterine cancer, and metastatic tumors of unknown primary. In P-glycoprotein-positive, multidrug-resistant (MDR) cell lines, ACRO in VPD was active in MDR Chinese hamster ovary cells but not against MDR L1210 murine leukemia cells, 8226 human myeloma cells, or human CCRF-CEM lymphoblasts. In mice, ACRO in VPD was active in two solid tumor models and an i.p. MOPC-315 plasmacytoma model. ACRO i.p. in 10% VPD (v/v%) produced significant tumor growth delays in (a) nude mice bearing human MCF-7 breast cancer xenografts and (b) C57BL mice bearing colon 38 tumor. In MOPC-315-bearing mice, a single i.p. ACRO dose of 25 mg/kg was as effective as melphalan (15 mg/kg) at prolonging life span. Finally, ACRO pharmacokinetics was evaluated in mice given single 25-mg/kg doses i.p. or p.o. The oral bioavailability of an ACRO solution in VPD was only 50% but both i.p. and p.o. regimens achieved plasma levels greater than 1.0 micrograms/ml. The plasma half-life was just under 2 h. These results show that parenteral ACRO in VPD comprises a cytotoxic antitumor agent with improved bioavailability over p.o. administration. ACRO is active in vitro against several human solid tumors but is cross-resistant in 3 of 4 MDR tumor cell lines. The prior clinical activity of p.o. ACRO in myeloma and the new results in MOPC-315 plasmacytomas in mice suggest that ACRO in VPD could have activity against human multiple myeloma.     

Effector Cell Analysis of Human Multidrug-resistant Cell Killing by Mouse-Human Chimeric Antibody against P-Glycoprotein

A mouse-human chimeric monoclonal antibody (mAb), MH162, against P-glycoprotein was previously found to be more effective than an all-mouse mAb (MRK16) in lysis of multidrug-resistant (MDR) tumor cells by blood mononuclear cells. The present study was performed to identify the effector cells responsible for the chimeric mAb-dependent cell-mediated cytotoxicity (ADCC) against MDR cells. The ADCC reaction was assessed by a 6-h ⁵¹Cr release assay. Highly purified lymphocytes (>99%), monocytes (>99%) and neutrophils (>96%) were obtained from peripheral blood of the same healthy donors. A comparison of these three effector cell populations showed no difference between MH162 and its all-murine counterpart MRK16 in MDR cell lysis by monocytes or neutrophils. But MH162 was more effective than MRK16 in lymphocyte-mediated lysis of the MDR cells. The lymphocytes responsible for this ADCC had CD16+ Fc receptors. Pretreatment of monocytes with colony-stimulating factors (IL-3, GM-CSF and M-CSF) caused significant increase in their MH162-mediated lysis of MDR cells. Another anti-P-glycoprotein chimeric mAb (MH171) was also more effective than its murine counterpart MRK17 in lymphocyte-mediated lysis of MDR cells. These findings suggest that mouse-human chimeric mAbs may be useful therapeutically for in vivo destruction of MDR cancer cells by the ADCC reaction.     

导向逆转剂Ab-IL2体外偶联以及协同抑瘤作用的研究

探讨利用乳腺癌单克隆抗体作为导向载体,将逆转剂IL2特异性地导向肿瘤细胞,使其发挥逆转作用的临床应用价值,为将此方法用于肿瘤的临床治疗提供医学依据。方法:分别制备人基因重组白细胞介素2（IL-2）以及人乳腺癌单克隆抗体（记为Ab）,将其经过体外的偶联与纯化,并对偶联产物进行严格的质量检测,最终得到导向多药耐药（MDR）逆转剂Ab-IL2,并通过体外MDR逆转作用检测其活性保留。将对阿霉素（ADM）耐药的人乳腺癌细胞系MCF-7/ADM,种植于BALB/c裸鼠皮下,每只小鼠注射量为106个细胞,将得到的荷瘤小鼠分为三组,并于接种后的第14,19天分别进行如下处理:1）对照组:腹腔注射生理盐水;2）ADM组:腹腔注射阿霉素（1 mg/kg体重）;3）协同用药组:同时注射阿霉素（1 mg/kg体重）和前述实验获得的多药耐药逆转剂Ab-IL2（1 mg/kg体重）。分别于14、16、18、20天测量肿瘤大小,并于第20天处死小鼠,取出瘤块并称重,据此计算肿瘤抑瘤率。结果:Ab-IL2的质量合格,活性保留为90.7%。多药耐药逆转剂Ab-IL2与阿霉素联合应用显示出体内协同抑瘤作用,至第20天处死小鼠时,协同用药组的抑瘤率为60.48%,是ADM组（抑瘤率19.44%）的3.11倍。结论:将单克隆抗体介导技术应用于肿瘤MDR导向逆转,可以促进逆转剂有效地发挥其应有的作用,本研究为实现临床上MDR逆转剂的成功应用提供了有力保证。      

Detection of multidrug resistant phenotype in leukemia and lymphoma by monoclonal antibodies

Two monoclonal antibodies, MRK16 and MRK20 that recognize P-glycoprotein and P-85 kd protein on the surface of adriamycin (ADM) resistant cells, respectively, were tested for the reactivity with 40 cultured leukemia/lymphoma cell lines. F(ab')2 form is essential to avoid false reaction through Fc gamma-R. Drug sensitivity of 19 representative cell lines were also examined in vitro. From this study, it was found that these cell lines were classified into 4 groups. Group 1 (4 cell lines) was insensitive to ADM, mitoxantron (MXT), etoposide (VP-16) and vincristine (VCR), and reactive to MRK16 and MRL20. Group II (1 cell line) was insensitive to the 4 drugs, but not reactive to both antibodies. Group III (3 cell lines) was insensitive to ADM, MXT and VP-16, but sensitive to VCR, and reactive to MRK20, but not to MRK16. Group IV (all other cell lines) was sensitive to these drugs, and not reactive to both antibodies. From these results, MRK16 detects P-glycoprotein-associated multidrug resistance (MDR), while MRK20 does P 85-kd-associated another type MDR (cross resistance to ADM, MXT and VP-16, but not to VCR). MRK20 reacted with monocytes, but MRK16 did not with any WBC type. One hundred and ninety eight clinical samples obtained from blood cancer were tested for the reactivity with MRK16. MRK16 did not react with any of 98 samples obtained before treatment, but did with 9 of 100 obtained at relapse or refractory stage after chemotherapy. The results indicate that MRK16 is useful to detect drug resistance phenotype of leukemia and lymphoma.     

Transduction of the IL-21 and IL-23 genes in human pancreatic carcinoma cells produces natural killer cell-dependent and -independent antitumor effects

We examined whether novel cytokines, interleukin (IL)-21 and IL-23, that were expressed in tumors could produce antitumor effects in the inoculated mice. Human pancreatic cancer AsPC-1 cells were retrovirally transduced with murine IL-21 or IL-23 (p19-linked p40) gene (AsPC-1/IL-21, AsPC-1/IL-23) and were injected into nude or severe combined immunodeficiency (SCID) mice. Although the proliferation in vitro of the transduced cells remained the same as that of parent cells, growth of AsPC-1/IL-21 and AsPC-1/IL-23 tumors developed in nude mice was retarded compared with that of parent tumors. Treatment of nude mice with anti-asialo GM(1) antibody temporally abrogated the growth retardation of AsPC-1/IL-21, but not AsPC-1/IL-23 tumors; however, the growth of AsPC-1/IL-21 tumors came to be retarded thereafter with the regeneration of natural killer (NK) cells. The growth of AsPC-1/IL-21 tumors developed in SCID mice was also retarded compared with parent tumors and the growth retardation was abrogated by treatment with anti-asialo GM(1) antibody. The growth of AsPC-1/IL-23 tumors in SCID mice was not different from that of parent tumors. Cytotoxic activity and secretion of interferon-gamma in response to AsPC-1 cells were induced in spleen cells of the mice bearing AsPC-1/IL-21 or AsPC-1/IL-23 tumors. When nude mice were injected with a mixed population of AsPC-1/IL-21 and AsPC-1/IL-23 cells, no synergistic effects were observed. These data collectively suggest that expression of IL-21 and IL-23 in tumors can produce NK cell-dependent and -independent antitumor effects in an alpha beta T cell-defective condition, respectively.     

Loss of tumorigenicity of human breast cancer cells engineered to produce IL-2, IL-4 or GM-CSF in nude mice.

Human breast cancer cells (OCUB-M), retrovirally transduced with granulocyte macrophage-colony stimulating factor (GM-CSF), interleukin-2 (IL-2) or IL-4 gene were examined for their antitumor activities in nude mice. Although cell proliferation rates in vitro of these cytokine-producing cells were not significantly different from that of wild-type cells, nude mice that were subcutaneously inoculated with cytokine-producing cells did not develop tumors in contrast to mice that were injected with wild-type cells. Injection of GM-CSF-producing cells into the vicinity of growing wild-type tumors retarded subsequent growth of wild-type tumors. Histological examination of tumors which received GM-CSF-producing cells revealed marked infiltration of mononuclear cells around the tumors. Irradiation of cytokine-producing cells diminished their proliferation capacity but production of cytokine(s) was retained. Therefore, inoculation of irradiated cytokine producer cells into growing tumors can be used as a therapeutic maneuver for breast cancer.     

Inhibition of Multidrug-resistant Human Tumor Growth in Athymic Mice by Anti-P-glycoprotein Monoclonal Antibodies

In an effort to devise an effective treatment for human drug-resistant cancers, we have developed monoclonal antibodies, MRK16 and 17, reactive to the multidrug transporter protein, P-glycoprotein. The monoclonal antibodies given intravenously effectively prevented tumor development in athymic mice inoculated subcutaneously with drug-resistant human ovarian cancer cells 2780^AD. Treatment with MRK16 induced rapid regression of established subcutaneous tumors and apparent cures of some animals. Complement-dependent cytotoxicity (MRK16) and antibody-dependent cell-mediated cytolysis (MRK16 and 17) were observed with these antibodies. These monoclonal antibodies may have potential as treatment tools against multidrug resistant human tumors possessing the P-glycoprotein.     

Effector cell analysis of human multidrug-resistant cell killing by mouse-human chimeric antibody against P-glycoprotein.

A mouse-human chimeric monoclonal antibody (mAb), MH162, against P-glycoprotein was previously found to be more effective than an all-mouse mAb (MRK16) in lysis of multidrug-resistant (MDR) tumor cells by blood mononuclear cells. The present study was performed to identify the effector cells responsible for the chimeric mAb-dependent cell-mediated cytotoxicity (ADCC) against MDR cells. The ADCC reaction was assessed by a 6-h 51Cr release assay. Highly purified lymphocytes (greater than 99%), monocytes (greater than 99%) and neutrophils (greater than 96%) were obtained from peripheral blood of the same healthy donors. A comparison of these three effector cell populations showed no difference between MH162 and its all-murine counterpart MRK16 in MDR cell lysis by monocytes or neutrophils. But MH162 was more effective than MRK16 in lymphocyte-mediated lysis of the MDR cells. The lymphocytes responsible for this ADCC had CD16+ Fc receptors. Pretreatment of monocytes with colony-stimulating factors (IL-3, GM-CSF and M-CSF) caused significant increase in their MH162-mediated lysis of MDR cells. Another anti-P-glycoprotein chimeric mAb (MH171) was also more effective than its murine counterpart MRK17 in lymphocyte-mediated lysis of MDR cells. These findings suggest that mouse-human chimeric mAbs may be useful therapeutically for in vivo destruction of MDR cancer cells by the ADCC reaction.     

Cyclosporin A Enhances Susceptibility of Multi-drug Resistant Human Cancer Cells to Anti-P-glycoprotein Antibody-dependent Cytotoxicity of Monocytes, but Not of Lymphocytes

Cyclosporin A (CsA) was previously found to bind to P-glycoprotein expressed on multidrug-resistant (MDR) cancer cells. In the present study, the effect of CsA on anti-P-glycoprotein monoclonal antibody (mAb)-dependent cell-mediated cytotoxicity (ADCC) against human MDR cells was examined. The ADCC reaction was assessed by 4-h ⁵¹Cr-release assay. Highly purified lymphocytes (> 99%) and monocytes (>99%) obtained from blood mononuclear cells (MNC) of healthy donors were used as effector cells. CsA decreased the cytotoxic activity of MNC against MDR cells, but enhanced their ADCC activity in the presence of anti-P-glycoprotein mAb MRK16. Lymphocyte-mediated ADCC and natural killer activity against MDR cells were also suppressed by addition of CsA. CsA induced a significant dose-dependent increase in monocyte-mediated ADCC activity. Interestingly, pretreatment of MDR cancer cells, but not of monocytes, with CsA significantly enhanced ADCC activity mediated by monocytes, but not by lymphocytes. A CsA analog (PSC833) and FK-506, but not verapamil also increased the sensitivity of MDR cells to ADCC by monocytes. CsA did not affect the binding of monocytes to MDR cells in the presence of MRK16 mAb. These results indicate that CsA may directly enhance the susceptibility of MDR cancer cells to the monocyte-mediated ADCC reaction.     

Cannabinoid 2 receptor induction by IL-12 and its potential as a therapeutic target for the treatment of anaplastic thyroid carcinoma

Anaplastic thyroid carcinoma is the most aggressive type of thyroid malignancies. Previously, we demonstrated that tumorigenicity of anaplastic thyroid carcinoma cell line ARO was significantly reduced following interleukin (IL)-12 gene transfer. We suspected that tumor target structure in ARO/IL-12 cells might be changed and such a change may make them more susceptible to be killed through mechanisms apart from natural killer-dependent pathway. To identify genes involved, we examined gene expression profile of ARO and ARO/IL-12 by microarray analysis of 3757 genes. The most highly expressed gene was cannabinoid receptor 2 (CB2), which was expressed eightfold higher in ARO/IL-12 cells than ARO cells. CB2 agonist JWH133 and mixed CB1/CB2 agonist WIN-55,212-2 could induce significantly higher rate of apoptosis in ARO/IL-12 than ARO cells. Similar results were obtained when ARO cells were transfected with CB2 transgene (ARO/CB2). A considerable regression of thyroid tumors generated by inoculation of ARO/CB2 cells was observed in nude mice following local administration of JWH133. We also demonstrated significant increase in the induction of apoptosis in ARO/IL12 and ARO/CB2 cells following incubation with 15 nM paclitaxel, indicating that tumor cells were sensitized to chemotherapy. These data suggest that CB2 overexpression may contribute to the regression of human anaplastic thyroid tumor in nude mice following IL-12 gene transfer. Given that cannabinoids have shown antitumor effects in many types of cancer models, CB2 may be a viable therapeutic target for the treatment of anaplastic thyroid carcinoma.     

Mouse-Human Chimeric Antibody MH171 against the Multidrug Transporter P-Glycoprotein

We have developed a mouse-human chimeric antibody MH171, in which the antigen-recognizing variable regions of the mouse monoclonal antibody MRK17 are joined with the constant regions of human IgG1 antibodies. The MRK17 recognizes specifically the multidrug transporter P-glycoprotein and inhibits the growth of human multidrug resistant (MDR) tumor cells in vitro and in the xenograft nude mouse model system. The established chimeric MH171 antibody forms an apparently intact IgG composed of heavy and light chains covalently assembled via disulfide bonds in sodium dodecyl sulfate polyacrylamide gel electrophoresis analysis and is specific to MDR cell lines with a similar affinity to the original mouse MRK17. MH171 also displays strong antibody-dependent cell-mediated cytotoxicity to the target cells in vitro , when human mononuclear cells are used as effector cells. The chimeric antibody against P-glycoprotein, MH171, should be a useful agent in the treatment of human drug-resistant tumors.     

Mouse-human chimeric antibody MH171 against the multidrug transporter P-glycoprotein.

We have developed a mouse-human chimeric antibody MH171, in which the antigen-recognizing variable regions of the mouse monoclonal antibody MRK17 are joined with the constant regions of human IgG1 antibodies. The MRK17 recognizes specifically the multidrug transporter P-glycoprotein and inhibits the growth of human multidrug resistant (MDR) tumor cells in vitro and in the xenograft nude mouse model system. The established chimeric MH171 antibody forms an apparently intact IgG composed of heavy and light chains covalently assembled via disulfide bonds in sodium dodecyl sulfate polyacrylamide gel electrophoresis analysis and is specific to MDR cell lines with a similar affinity to the original mouse MRK17. MH171 also displays strong antibody-dependent cell-mediated cytotoxicity to the target cells in vitro, when human mononuclear cells are used as effector cells. The chimeric antibody against P-glycoprotein, MH171, should be a useful agent in the treatment of human drug-resistant tumors.