Monoclonal antibody-polyethyleneimine conjugates targeting Her-2/neu or CD90 allow cell type-specific nonviral gene delivery.

We have developed an efficient and cell-specific nonviral gene delivery system using monoclonal antibodies (mAb) coupled with branched 25-kDa polyethyleneimine (PEI). The system was evaluated for two model antibodies with different well-characterized antigen specificities: the mouse anti-human IgG1 mAb AS02 recognizing human CD90 (hThy-1) which is expressed on human fibroblasts, and the humanized anti-Her-2/neu mAb Trastuzumab recently introduced for the treatment of Her-2/neu-positive breast cancer. Efficacy and selectivity of gene delivery were evaluated for covalent mAb-PEI conjugates coupled with N-succinimidyl-3-(2-pyridyldithio)proprionate (SPDP) or N-succinimidyl-4-(maleimidomethyl)-cyclohexancarboxylate (SMCC), or, as a newly introduced coupling reagent, noncovalent complexes of mAb with 3-(2-(2-(vinylsulfonyl)ethylthio)ethyl)quinazoline-2,4(1H,3H)-dione (IBFB 110001) coupled to PEI. An enhanced green fluorescent protein (EGFP)-expressing reporter plasmid was used to monitor transfection efficiencies of cell lines expressing different levels of hCD90 or Her-2/neu. While mAb-PEI conjugates coupled with SPDP resulted in antigen-nonspecific EGFP expression, conjugates coupled with SMCC or IBFB 110001 enabled antigen-specific gene delivery. Thus, Her-2/neu-PEI conjugates prepared with IBFB 110001 allowed to transfect 23+/-2% of Her-2/neu-positive SKOV-3 versus 0.5+/-2% of Her-2/neu-negative MB-468 cells. Proof of principle for specific antibody-mediated gene transfer was demonstrated by saturating the Her-2/neu receptor with free anti-Her-2/neu, thereby blocking subsequent transfection with anti-Her-2/neu-PEI/DNA complexes.

Apoptotic genes in cancer therapy.

Induction of apoptosis in malignant cells is a major goal of cancer therapy in general and of certain cancer gene therapy strategies in particular. Numerous apoptosis-regulating genes have been evaluated for this purpose. Besides the most prominent p53 gene others include p16, p21, p27, E2F genes, FHIT, PTEN and CASPASE genes. Recently, the potential for therapy of an adenoviral gene, E1A, known for a long time for its apoptosis-inducing activity, has been discovered. In experimental settings, these genes have proven their tumor-suppressive and apoptosis-inducing activity. Clinical trials are currently being performed with selected genes. By far the most studies transfer the p53 gene using retro- or adenoviral vectors. Disease stabilization or other benefits were observed in a limited number of patients when p53 was applied alone or in combination with cytotoxic drugs. A second proapoptotic gene that has entered clinical trials is adenovirus E1A. Here, too, disease stabilization as well as/or local regression in one case have been demonstrated in selected patients. In all cases, side effects were tolerable. To further improve E1A as a therapeutic transgene, we have deleted transforming domains from the adenovirus 5 and 12 13S cDNAs. Mutants were derived which had completely lost their transforming activity in combination with the E1B oncogene but retained a pronounced tumor-suppressive activity. Cells transduced with these constructs showed a highly reduced ability to grow in soft agar, and tumor growth in nude mice could be substantially suppressed. Outgrowing tumors had lost E1A expression when analyzed in Western blots. These E1A constructs may represent valuable tools for cancer gene therapy in the future.

Tumor-specific activation of hTERT-derived promoters by tumor suppressive E1A-mutants involves recruitment of p300/CBP/HAT and suppression of HDAC-1 and defines a combined tumor targeting and suppression system.

Adenovirus (Ad) E1A proteins are transcriptional regulators with antioncogenic but also transforming properties. We have previously shown that transformation-defective Ad5 E1A-derivatives are excellent tumor suppressors. For tumor-specific expression of the E1A-derivatives we intend to use tumor specific human telomerase reverse transcriptase (hTERT) core promoters. Here, we show that Spm2 and other E1A proteins with an intact amino terminus activated all hTERT constructs 10-20-fold in malignant tumor cells but not in primary fibroblasts, without affecting the activity of endogenous telomerase. The transcription rate in tumor cells was in the range of transcription from the SV40 promoter, which qualifies an E1A-hTERT system as a putative tumor targeting/expression system. The activation of the hTERT promoter by E1A was enhanced upon deletion of the Wilms' tumor 1 negative regulatory element and maintained high after deletion of the adjacent c-Myc-responsive E-box, demonstrating an important role of the remaining sequences that contain several Sp1-motifs. E1A-mediated hTERT activation was independent from the presence of the conserved region 3 (CR3) of E1A but dependent on E1A's binding to p300/CBP and recruitment of its histone acetyltransferase activity. Moreover, E1A-Spm2 and histone deacetylase-1 behaved as antagonists with respect to the regulation of transcription from the hTERT promoter. Overall, hTERT promoter/E1A-Spm2 systems may turn out to be excellent tools for transcriptionally targeted anticancer gene therapy.