Nejat K. Egilmez

Human-SCID mouse chimeric models for the evaluation of anti-cancer therapies.

The ability to engraft human tumors and human immunocompetent cells successfully in severe combined immunodeficient (SCID) mice has spawned the development and use of human-mouse chimeric models to evaluate anti-cancer therapies. The lack of standardization and many other potential pitfalls have contributed to the current controversy surrounding the reliability of these different models. Five frequently used SCID mouse models and their specific applications are summarized with the specific aim of providing an objective discussion of the strengths and limitations of each model, together with suggestions for overcoming some of the variabilities and for improving the design and use of future models.

The next generation of liposome delivery systems: recent experience with tumor-targeted, sterically-stabilized immunoliposomes and active-loading gradients.

ABSTRACT Three topics are discussed. Enhanced anti-tumor efficacy of targeted doxorubicin-containing sterically-stabilized liposomes using an anti-β1 integrin Fab’ ligand. Use of tumor targeting with an internalizing ligand to improve the efficacy of a non-leaky cisplatin-containing sterically-stabilized liposome formulation. Formulation variables (remote-loading with dextran ammonium sulfate, rigid lipid bilayer) used to optimize in vivo performance of a liposomal camptothecin analog.

Cytokine immunotherapy of cancer with controlled release biodegradable microspheres in a human tumor xenograft/SCID mouse model.

Abstract A novel biodegradable poly(lactic acid) microsphere formulation was evaluated for in vivo cytokine immunotherapy of cancer in a human tumor xenograft/severe combined immunodeficiency (SCID) mouse model. Co-injection of interleukin-2 (IL-2)-loaded microspheres with tumor cells into a subcutaneous site resulted in the complete suppression of tumor engraftment in 80% of animals. In contrast, bovine-serum-albumin(BSA)-loaded particles or bolus injections of poly(ethylene glycol)/IL-2 were ineffective in preventing tumor growth. The antitumor effect of IL-2 released by the microspheres was shown to be mediated by the mouse natural killer cells. This is the first evidence that the rejection of human tumor xenografts can be provoked by the sustained in vivo delivery of IL-2 from biodegradable microspheres. The use of poly(lactic acid) microspheres to deliver cytokines to the tumor environment could provide a safer and simpler alternative to gene therapy protocols in the treatment of cancer.

SCID mouse models to study human cancer pathogenesis and approaches to therapy: potential, limitations, and future directions.

The successful engraftment of human tumors and human immunocompetent cells into severe combined immunodeficient (SCID) mice has led to the generation of a wide array of different experimental designs that have proven useful in studying the cell biology of human cancer, and for evaluating novel therapeutic approaches to the treatment of cancer. In this review five of the most frequently used embodiments of the SCID model are presented. The goals of this review are to discuss how each model has been utilized to study human cancer and its response to many different novel therapies, to provide an assessment of the strengths and limitations of each model, and to outline future directions with a focus on what is needed to overcome some of the current limitations and pitfalls of the SCID models.

Interleukin‐12 delivered by biodegradable microspheres promotes the antitumor activity of human peripheral blood lymphocytes in a human head and neck tumor xenograft/SCID mouse model

The role of cytokines in tumor regression is now well established. The major limitation for the clinical use of cytokines is the lack of a simple and effective protocol for the local and sustained delivery of cytokines to the tumor milieu. This study reports suppression of human head and neck squamous cell carcinoma (HNSCC) by human peripheral blood lymphocytes (HuPBL) following local, sustained delivery of interleukin‐12 (IL‐12) to tumors with biodegradable microspheres in a human/SCID mouse chimeric model.

CD40-CD40 ligand (CD154) engagement is required but not sufficient for modulating MHC class I, ICAM-1 and Fas expression and proliferation of human non-small cell lung tumors.

To determine the possible functional significance of CD40 expression on human non‐small cell lung carcinomas and to assess the potential of CD40 as a therapeutic target, 18 lung tumor cell lines were established from biopsy tissues and were monitored for phenotypic changes on the cell surface and alterations in tumor cell proliferation after the ligation of CD40 with a trimeric fusion protein complex of CD40 ligand (CD40Lt). CD40 cross‐linking resulted in up to a 6‐fold increase in the surface expression of major histocompatibility complex (MHC) class I, Fas and intracellular adhesion molecule (ICAM)‐1 in a subset of tumors expressing the highest levels of CD40. Suppression of tumor proliferation was seen after the ligation of CD40 on CD40Lt‐responsive cell lines. The suppression was dose dependent, reversible and resulted from a delay of the tumor cells entering S‐phase. No change in the cell phenotype or in proliferation were observed in CD40‐negative tumors or in tumors expressing moderate‐to‐low levels of CD40 after incubation with CD40Lt. CD40‐negative tumors transfected with the CD40 gene expressed high levels of CD40 on their surface, but were also unresponsive to CD40Lt cross‐linking of CD40. Our data establish that CD40 is required (but not sufficient) for transducing a signal that results in phenotypic changes in human lung tumors and suppression in their proliferation. We conclude that CD40 on non‐small cell lung tumors may represent a potential therapeutic target, but only on a subset of the CD40+ tumors.

Growth of human tumor xenografts in SCID mice quantified using an immunoassay for tumor marker protein in serum

The accurate measurement of the response of a tumor to a given treatment is critical to evaluating novel therapeutic modalities. An experimental design is reported here that can be generally applied to monitoring human tumor xenografts growing in immunodeficient mice. A human non-small cell lung tumor cell line was transfected with a mammalian expression vector containing the gene encoding human prostate specific antigen (PSA) and has been shown to grow progressively following the subcutaneous, intraperitoneal and intravenous inoculation of the tumor into severe combined immunodeficient (SCID) mice. The transfected human tumor cells produce PSA that accumulates in the sera of all tumor inoculated SCID mice. An enzyme-linked immunoassay using a rabbit polyclonal and a mouse monoclonal antibody specific for PSA was designed and tested for the detection and quantification of serum PSA in tumor-bearing mice. Over a 5-week period, the serum levels of PSA of mice inoculated subcutaneously with the tumor increased progressively, and the estimated tumor volumes correlated with the amount of PSA detected in the serum. Serum PSA levels correlated even better with total tumor mass following the intraperitoneal inoculation of tumor cells into SCID mice. Serum PSA levels fell rapidly following the surgical debulking of tumor xenograft, reaching background levels of PSA in the serum 1 week after tumor removal. Serum PSA levels were also observed in SCID mice inoculated intravenously with a PSA transfected human lung tumor cell line adapted to grow orthotopically in the lung. The transfection of human tumors with a tumor marker and the use of an immunoassay to detect this marker establish an experimental design that provides a reliable, non-invasive, accurate and simple approach to monitor and quantify the growth of human tumor xenografts in SCID mice.

Comparison of human lung cancer/SCID mouse tumor xenografts and cell culture growth with patient clinical outcomes.

Leukemic cell growth in SCID mice has been reported as a predictor of disease relapse. However, there is a paucity of literature regarding xenograft growth and clinical outcomes in non-small cell lung cancer (NSCLC). Seventy-nine specimens from patients with NSCLC were either subcutaneously implanted into SCID mice and/or placed in tissue culture. Retrospective chart review was correlated with stage, histology, necrosis, disease-free interval, and survival. Tumor xenografts were successfully established with 17 of 37 (46%) tumor biopsy tissues. Thirteen of 59 (22%) specimens grew in cell culture. Patients whose tumors grew in SCID mice had no difference in survival compared to those with no growth (n=20, p=0.42). Median survival was 36 months in 13 patients whose tumors grew in cell culture compared to 39 months in 46 patients without growth. Eight of 12 (67%) patients with metastasis showed SCID/human xenograft growth, whereas nine of 25 (36%) without metastases did so (p=0.08). Growth of tumor cells in vitro occurred in 11 of 31 (35%) adenocarcinomas, one of 25 (4%) squamous cell carcinomas, and one of three (33%) large cell carcinomas (p=0.02). Well or moderately differentiated tumors grew in cell culture in only two of 22 (9%), whereas poorly or undifferentiated tumors grew in 11 of 32 (34%) cases (p=0.03). We conclude that neither the ability of a tumor to engraft and grow in SCID mice nor its ability to grow in vitro in cell culture is a reliable predictor of disease outcome or survival in patients with NSCLC. The ability to propagate tumors in vitro appears to be more dependent upon the histological type of tumor and its degree of differentiation.