Anti-MUC-1 immunoliposomal doxorubicin in the treatment of murine models of metastatic breast cancer.

The fate of breast cancer patients is dependent upon elimination or control of metastases. We studied the effect of antibody-targeted liposomes containing entrapped doxorubicin (DXR) on development of tumours in two models of breast cancer, pseudometastatic and metastatic, in mice. The former used the mouse mammary carcinoma cell line GZHI, which expresses the human MUC-1 gene (L. Ding, E.N. Lalani, M. Reddish, R. Koganty, T. Wong, J. Samuel, M.B. Yacyshyn, A. Meikle, P.Y.S. Fung, J. Taylor-Papadimitriou, B.M. Longenecker, Cancer Immunol. Immunother. 36 (1993) 9--17). GZHI cells seed into the lungs of Balb/c mice following intravenous injection. The latter used the 4T1-MUC1 cell line, a MUC-1 transfectant of the mouse mammary carcinoma cell line 4T1, which metastasizes from a primary mammary fatpad (mfp) implant to the lungs (C.J. Aslakson, F.R. Miller, Cancer Res. 52 (1992) 1399--1405). B27.29, a monoclonal antibody against the MUC-1 antigen, was used to target sterically stabilized immunoliposomes (SIL[B27.29]) to tumour cells. In vitro, SIL[B27.29] showed high specific binding to both GZHI and 4T1-MUC1 cells. The IC(50) of DXR-loaded SIL[B27.29] was similar to that of free drug for GZHI cells. In the pseudometastatic model, mice treated with a single injection of 6 mg DXR/kg in DXR-SIL[B27.29] at 24 h after cell implantation had longer survival times than those injected with non-targeted liposomal drug. In the metastatic model, severe combined immune deficiency mice given weekly injectionsx3 of 2.5 mg DXR/kg encapsulated in either targeted or non-targeted liposomes were almost equally effective in slowing growth of the primary tumour and reducing development of lung tumours. Surgical removal of the primary tumour from mfp, followed by various chemotherapy regimens, was attempted, but removal of the primary tumour was generally incomplete; tumour regrowth occurred and metastases developed in the lungs in all treatment groups. DXR-SL reduced the occurrence of regrowth of the primary tumour, whereas neither targeted liposomal drug or free drug prevented regrowth. We conclude that monoclonal antibody-targeted liposomal DXR is effective in treating early lesions in both the pseudometastatic and metastatic models, but limitations to the access of the targeted liposomes to tumour cells in the primary tumour compromised their therapeutic efficacy in treating the more advanced lesions.

A low-level expression of human MUC1 mucin enhances lethality of murine tumor cells.

We report here the development of a mouse mammary adenocarcinoma cell line containing full-length human MUC1 cDNA that can be more lethal than the parental cell line. The metastatic murine mammary adenocarcinoma cell line 410.4 was transfected with cDNA coding for a 42-tandem-repeat version of human MUC1. Two cell lines were selected, one for stable, high expression in vitro of cell-surface MUC1 (GZHi) and one for stable, low expression in vitro of cell-surface MUC1 (GZLo). Following subcutaneous challenge of CB6F1 mice with various doses of tumor cells, GZHi tumors showed loss of MUC1 expression; negligible amounts of serum MUC1 mucin were detected and the mice survived longer than mice challenged with GZLo or wild-type (410.4) tumor cells. Mice challenged with GZLo tumor cells had shorter survival times than mice challenged with either GZHi or 410.4 tumor cells. GZLo-challenged mice that showed rapidly increasing serum MUC1 mucin levels several weeks prior to death had a shorter survival than mice without detectable rising MUC1 serum levels. Surprisingly, SCID-BEIGE mice challenged with GZLo cells also survived for a shorter time than those challenged with either GZHi or 410.4 cells. This suggests that MUC1 mucin may also enhance the aggressiveness of GZLo tumors by non-immune mechanisms.

Immunogenicity and antitumor activity of a liposomal MUC1 peptide-based vaccine.

A human MUC1-transfected mouse mammary adenocarcinoma cell line (GZHI) was used to develop both subcutaneous and intravenous tumor models. A vaccine formulation comprised of a 24 mer (human MUC1) synthetic peptide encapsulated with monophosphoryl lipid A adjuvant (MPLA) in multilamellar liposomes was tested for immunogenicity and anti-tumor activity. A low dose of the human MUC1 peptide (5 microg) administered in liposomes provided excellent protection of mice in both tumor challenge models. The protective antitumor activity mediated by the liposome formulation correlated with anti-MUC1-specific T-cell proliferation, gamma-interferon (IFN-gamma) production and IgG2a anti-MUC1 antibodies, suggesting a type 1 (T1) T-cell response. In contrast, lack of protection in mice immunized with negative control vaccines correlated with IgG1 anti-MUCI antibody formation, low or no anti-MUC1 IgG2a and low antigen-specific T-cell proliferation, consistent with a type 2 (T2) T-cell response to the tumor.