N-dihydrogalactochitosan-supported tumor control by photothermal therapy and photothermal therapy-generated vaccine

Abstract

Photothermal therapy (PTT) is recently clinically established cancer therapy that uses near-infrared light for thermal ablation of solid tumors. The biopolymer N-dihydrogalactochitosan (GC) was shown in multiple reports to act as a very effective adjunct to tumor PTT. In the present study, mouse tumor model SCCVII (squamous cell carcinoma) was used with two protocols, in situ tumor PTT and therapeutic PTT vaccine for tumors, for investigating the effects of GC. The results reveal that GC can potentiate tumoricidal action of PTT through both direct and indirect mechanisms. In addition to previously known capacity of GC for activating immune effector cells, the indirect means is shown to include reducing the populations of immunoregulatory T cells (Tregs) in PTT-treated tumors. Testing the effects of GC on PTT-treated SCCVII tumor cells in vitro uncovered the existence of a direct mechanism evident by reduced colony survival of these cells. Fluorescence microscopy demonstrated increased binding of fluorescein-labeled GC to PTT-treated compared to untreated SCCVII cells that can be blocked by pre-exposure to annexin V. The results of additional in vitro testing with specific inhibitors demonstrate that these direct mechanisms do not involve the engagement of death surface receptors that trigger extrinsic apoptosis pathway signaling but may be linked to pro-survival activity of caspase-1. Based on the latter, it can be suggested that GC-promoted killing of PTT-treated cells stems from interference of GC bound to damaged membrane components with the repair of these structures that consequently hinders cell survival.