Targeted superantigens for immunotherapy of haematopoietic tumours.

With the exception of childhood common acute lymphoblastic leukaemia (cALL), treatment of other hematopoietic B cell lineage tumours such as non-Hodgkin's lymphoma (B-NHL), adult ALL and multiple myeloma (MM) is unsatisfactory. Similarly, the therapeutic outcome of acute and chronic myeloid leukaemia (AML, CML) is frequently dismal. At the same time, leukaemia/lymphoma cells represent ideal targets for immunotherapy. The present review summarizes our preclinical experience with a novel type of cytotoxic T cell based immunotherapy for B-lineage and myeloid tumours. Staphylococcal enterotoxin-derived superantigens (SAgs) are among the most potent T cell activators known, linking the T cell receptor to HLA-DR on natural target cells. SAgs were genetically engineered to reduce DR binding and were then fused to Fab parts of tumour-directed monoclonal antibodies (mAbs). Using these "targeted" SAgs, highly efficient lysis of B-lineage (B-NHL, B-CLL, ALL, MM) and myeloid (AML, CML) tumour cells by T-cells was achieved in vitro and in an animal model. We are entering an interesting era of innovative cancer therapy based on novel man-made biotherapeutic agents.

Man-made superantigens: Tumor-selective agents for T-cell-based therapy.

Superantigens (SAgs) are a collection of bacterial and viral proteins with potent immunostimulatory properties. SAgs bind to Major Histocompatibility Complex Class II (MHC II) molecules of antigen presenting cells (APCs) and activate a high frequency of T lymphocytes. To target a T-cell attack against tumor cells we genetically linked tumor-specific antibody Fab fragments to the SAg Staphylococcal enterotoxin A (SEA). Fab-SEA fusion protein efficiently targeted to solid tumors and induced a T-cell-mediated eradication of established metastases in animal models. Successful therapy was T-cell-dependent and required tumor specificity of the Fab moiety of the Fab-SEA fusion protein. Due to the high affinity of SAg for MHC II, a limitation of this approach was retention of Fab-SEA proteins in normal tissues expressing MHC II, which caused systemic immune activation and dose limiting toxicity. We recently solved the structure of SEA and applied structure-based drug design to develop a novel generation of 'man-made' SAg with improved pharmacological and pharmacokinetic properties. Mutation of the major MHC II binding site of SEA substantially reduced retention in MHC II(+) tissues and systemic toxicity, while local immune activation at targeted tumor sites was retained. The Fab-SEA mutants display a 10000-fold higher affinity for tumor tissue compared to normal tissue and the therapeutic window was improved >100-fold compared to native Fab-SEA protein. Thus protein engineering can be applied to convert harmful bacterial toxins into tolerable tumor-specific agents.