Photoimmunotherapy was introduced two decades ago but has been studied infrequently in vivo and is virtually untested clinically. Progress has been limited because high-quality, well-characterized photosensitizer immunoconjugates (PICs) have been difficult to make. Here, we describe the development of an innovative conjugation method for producing water-soluble PICs that are free of insoluble aggregates and free of unacceptable amounts of noncovalently associated photosensitizer impurities. The method exploits two procedures previously untried in this research area. First, a small number of antibody lysines (<3 per antibody) are polyethylene glycolated (PEGylated) using a 10 kDa branched polyethylene glycol (PEG), which dramatically enhances PIC solubility and reduces PIC aggregation. Second, a 50% dimethyl sulfoxide-50% aqueous two-solvent system is used to prevent photosen-sitizer aggregation and noncovalent interactions. These measures allow efficient covalent linkage of the photosensitizer BPD Verteporfin (BPD) to antibody lysines, thorough purification of the resulting PICs (verified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis), maintenance of PIC antigen-binding activity (verified by cellular binding-uptake assays) and reduction of nonspecific cellular uptake (e.g. macrophage capture) of the PICs. Loading levels could be varied controllably in the range <11 BPD/antibody. PICs of the C225 anti-epidermal growth factor receptor (EGFR) chimeric monoclonal antibody killed EGFR-overexpressing A-431 cells photodynamically but did not significantly affect EGFR-negative NR6 cells. Although fluorescence measurements demonstrated that the PICs were quenched by as much as an order of magnitude compared with free BPD, an impressive 90% reduction in A-431 cell viability was achieved using 20 J/cm 2 of 690 nm light after a 40 h incubation with the C225 PICs. The results suggest that PEGylated BPD-C225 PICs merit further investigation in animal models of EGFR-overexpressing cancers.
Purpose: Photoimmunotherapy may allow target-specific photodynamic destruction of malignancies and may also potentiate anticancer antibody therapies. However, clinical use of either of the two modalities is limited for different reasons. Antibody therapies suffer from being primarily cytostatic and the need for prolonged administration with consequent side effects. In the case of photoimmunotherapy, a major impediment has been the absence of well-characterized photosensitizer immunoconjugates (PIC). In this investigation, we suggest a strategy to overcome these limitations and present the successful targeting of epidermal growth factor receptor (EGFR) using a well-characterized PIC. Experimental Design: The PIC consisted of the EGFR-recognizing chimeric monoclonal antibody, C225, conjugated with a two-branched polyethylene glycol and benzoporphyrin derivative (BPD, Verteporfin). Mechanistic studies included photophysics, phototoxicity, cellular uptake, and catabolism experiments to yield dosimetric parameters. Target cells included two EGFR-overexpressing human cancer cell lines, OVCAR-5 and A-431. Nontarget cells included an EGFR-negative fibroblast cell line, 3T3-NR6, and a monocyte-macrophage cell line, J774. Results: BPD-C225 PICs targeted and photodynamically killed EGFR-overexpressing cells, whereas free BPD exhibited no specificity. On a per mole basis, PICs were less phototoxic than free BPD, but PICs were very selective for target cells, whereas free BPD was not. Phototoxicity of the PICs increased at prolonged incubations. Photodynamic dose calculations indicated that PIC photophysics, photochemistry, catabolism, and subcellular localization were important determinants of PIC phototoxic potency. Conclusions: This study shows the efficacy of EGFR targeting with PIC constructs and suggests approaches to improve PIC designs and targeting strategies for in vivo photoimmunotherapy. The approach offers the possibility of dual effects via antibody-mediated cytostasis and photoimmunotherapy-based cytotoxicity.
Targeted photosensitizer delivery to EGFR expressing cells was achieved in the present study using a high purity, targeted photoimmunoconjugate (PIC). When the PDT agent, benzoporphyin monoacid ring A (BPD) was coupled to an EGFR-targeting antibody (cetuximab), we observed altered cellular localization and selective phototoxicity of EGFR-positive cells, but no phototoxicity of EGFR-negative cells. Cetuximab in the PIC formulation blocked EGF-induced activation of the EGFR and downstream signaling pathways. Our results suggest that photoimmunotargeting is a useful dual strategy for the selective destruction of cancer cells and also exerts the receptor-blocking biological function of the antibody.
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