Masumi Yoshimura

In vitro and in vivo anti-tumour effects of a humanised monoclonal antibody against c-erbB-2 product.

The c-erbB-2 product is thought to be a unique and useful target for antibody therapy of cancers overexpressing the c-erbB-2 gene. In vitro and in vivo anti-tumour effects of a humanised antibody against the extracellular domain of the c-erbB-2 gene product, rhu4D5, were examined. Rhu4D5 was less effective than its murine counterpart, mu4D5, for the direct antiproliferative activity against the c-erbB-2-overexpressing SK-BR-3 cell line. In vivo treatment of severe combined immunodeficient (SCID) mice carrying the c-erbB-2-overexpressing 4-1ST human gastric carcinoma xenograft with 4hu4D5 revealed that the recombinant protein had potent anti-tumour activity. Furthermore, cytotoxicity of human peripheral blood mononuclear cells against 4-1ST was significantly augmented with rhu4D5, but not with mu4D5. These results indicate that rhu4D5 might perform better in patients than predicted from preclinical studies.

Prolonged survival of mice with human gastric cancer treated with an anti-c-ErbB-2 monoclonal antibody.

A monoclonal antibody (MAb), 4D5, specifically recognising an extracellular epitope of the c-ErbB-2 protein, inhibited the growth of human gastric cancer overexpressing c-ErbB-2 severe combined immunodeficient (SCID) mice. This antibody also reduced the mass of established tumours xenografted into SCID mice, whereas gastric cancer not expressing c-ErbB-2 exhibited no regression in response to 4D5 treatment. In addition, administration of 4D5 prevented colonisation of cancer cells and prolonged the survival of host SCID mice inoculated i.v. with c-ErbB-2-overexpressing tumour cells. This is the first reported study to show that treatment with a single antibody specific to c-ErbB-2 prolongs the survival of host SCID mice bearing xenotransplanted tumours.

Growth Stimulation of Non-small Cell Lung Cancer Xenografts by Granulocyte-macrophage Colony-stimulating Factor (GM-CSF)

Granulocyte-macrophage colony-stimulating factor (GM-CSF) has been suggested to be involved in the carcinogenesis of some types of tumours by autocrine or paracrine mechanisms. We examined GM-CSF/GM-CSF receptor (GM-CSFR) gene expression in 20 human non-small cell lung cancer (NSCLC) xenografts. The stimulatory effects of GM-CSF were examined using GM-CSF transgenic severe combined immunodeficient (SCID) mice (GM-Tg-SCID), which produce abundant human GM-CSF. A NSCLC xenograft (LC11-JCK), expressed GM-CSFR but not GM-CSF, and showed more rapid growth in GM-Tg-SCID than non-GM-CSF transgenic SCID mice (non-Tg-SCID). GM-CSF gene expression was detected in 48 of 90 (53%) primary NSCLC human specimens and GM-CSFR gene expression was detected in 42 specimens (47%). GM-CSF expression was detected in 13 of 30 squamous cell carcinoma specimens (43%) and GM-CSFR expression was detected in 10 specimens (33%). Patients with squamous cell carcinoma coexpressing GM-CSF and GM-CSFR showed significantly poorer prognosis than those expressing neither GM-CSF nor GM-CSFR (P < 0.05, Cox-Mantel test). These results suggest that GM-CSF can have a stimulatory effect on some NSCLC.

P-glycoprotein-mediated acquired multidrug resistance of human lung cancer cells in vivo.

We examined whether the increased expression of P-glycoprotein (P-gp) encoded by the human multidrug resistance gene MDR1 is related to the acquired multidrug resistance of lung cancer in vivo. We estimated the chemosensitivity of lung cancer xenografts (LC-6, adenocarcinoma; Lu-24, small-cell cancer) by calculation of relative tumour growth (T/C%, treated/control) in vivo, based on statistical significance determined by the Mann-Whitney U test (P < 0.01, one-sided). MDR1 gene expression levels were evaluated by reverse transcription-polymerase chain reaction (RT-PCR) assay. P-gp production and P-gp localisation were examined by Western blotting and by immunohistochemical analysis respectively. LC-6 and Lu-24 were initially sensitive to both vincristine (VCR, 1.6 mg kg-1: LC-6, 45%; Lu-24, 39%) and doxorubicin (DOX, 12 mg kg-1: LC-6, 26%; Lu-24, 27%) in vivo. VCR-resistant variants (LC-6R, 66% and Lu-24R, 68%) selected with VCR (0.4 mg kg-1, x 9) significantly acquired cross-resistance to DOX (LC-6R, 55% and Lu-24R, 55% respectively). RT-PCR assay showed increased levels of MDR1 expression in LC-6R and Lu-24R with stable MDR1 expression levels. P-gp expression levels were elevated, and the percentage of P-gp-positive tumour cells increased in both LC-6R and Lu-24R. These results suggest that P-gp/MDR1 overexpression is related to acquired multidrug resistance in lung cancer in vivo.

A Humanized Anti-c-erbB-2 Monoclonal Antibody for the Treatment of Breast Cancer.

The c-erbB-2 product is thought to be a unique and useful target for antibody therapy of cancers that overexpress the c-erbB-2 gene. Its overexpression is also speculated to be correlated with chemoresistance to doxorubicin. The in vitro and in vivo anti-tumor effects of a humanized antibody directed against the extracellular domain of the c-erbB-2 gene product, rhu4D5, were examined. Rhu4D5 had direct antiproliferative activity against the SK-BR-3 cell line which overexpresses c-erbB-2. The in vivo treatment, using rhu4D5, of SCID mice carrying xenografts of 4-1ST human gastric carcinoma, which overexpresses c-erbB-2, revealed that the recombinant protein had potent anti-tumor activity. Furthermore, the cytotoxic action of human peripheral blood mononuclear cells against the SK-BR-3 cell line was significantly augmented with the administration of rhu4D5, but not with mu4D5. These results indicate that rhu4D5 might be a more efficacious treatment than previously predicted by preclinical studies.

Practical role of genetic profiling and preservation stock of human tumour xenograft lines as a tool in animal experiments for antitumour drug evaluation

Human tumour xenografts (HTXs) are a useful tool for animal experiments especially for evaluation of new antitumour drugs. We have been establishing HTXs, and have developed tumour chemosensitivity panels for new drug evaluation using them. With regard to quality control (problems in changes into mouse-type tumours and/or artificial cross-contamination among tumour lines), we studied genetic profiling, and effects of long-term passaging on tumour properties such as growth and chemosensitivities, and we discuss the use of cryopreservation stock of HTXs and periodic replacement in order to maintain reproducibility of the experimental results. We examined isozyme markers and DNA fingerprinting to identify species and individuality of the tumours, respectively. Growth curves and sensitivities to antitumour drugs were examined using HTXs with different passaging in nude mice. Among the tumours we maintained, five human tumours were found to have changed to mouse origin from their isozyme markers and were excluded. We identified the individuality of tumours which we used for the chemosensitivity panels by DNA fingerprinting, and their properties were stable for long-term passaging in nude mice. However, growth speed and chemosensitivities to drugs were altered with long-term passaging, although DNA fingerprint analysis did not show any obvious changes with passaging. Genetic profiling, such as isozyme markers and DNA fingerprinting, is useful to identify individuality of experimental HTXs, and tumours should be renewed periodically even when there are no signs of artificial contamination when they are used in experiments which require continuous reproducibility of experimental results.