One-Step Method for Instant Generation of Advanced Allogeneic NK Cells.

Conventional combinatorial anticancer therapy has shown promising outcomes; still, a significant interest in developing new methods to reinforce and possibly merge chemotherapy and immunotherapy persists. Here, a new one-step method that immediately modifies immune cells into a targeted form of chemoimmunotherapy through spontaneous and rapid incorporation of hydrophobized antibody-drug conjugates (ADCs) on the surface of immune cells is presented. Therapeutic objectives of this approach include targeted delivery of a potent chemotherapeutic agent to avoid adverse effects, enhancing the mobilization of infused immune cells toward tumor sites, and preserving the intense cytotoxic activities of immune cells against tumor cells. The embedding of hydrophobized ADCs on the immune cell membrane using the strategy in this study provides noninvasive, nontoxic, and homogenous modifications that transiently arm immune cells with highly potent cytotoxic drugs targeted toward cancer cells. The resulting surface-engineered immune cells with ADCs significantly suppress the tumor growth and drive the eradication of target cancer cells through combinatorial anticancer effects. This novel strategy allows convenient and timely preparation of advanced chemoimmunotherapy on a single immune cell to treat various types of cancer.

Direct Incorporation of Functional Peptides into M-DNA through Ligand-to-Metal Charge Transfer.

Conventional nonviral gene delivery methods suffer from the toxicity of the cationic nature of polymeric carriers. There is a significant need for a new method of gene delivery that overcomes the limitations and allows targeted gene delivery. In this study, we have developed a new method to incorporate functional peptides into DNA without the need for chemical conjugations by utilizing a ligand-to-metal charge transfer (LMCT) transition, which occurs between divalent metal ions and the sulfhydryl group in cysteine. To apply the LMCT transition to the incorporation of cysteine-containing targeting peptides into DNA, divalent metal ions must be first introduced to DNA. Zn2+ ions spontaneously intercalate into the DNA base pairs in the pH range of 7.0-8.5, resulting in the conversion of normal B-DNA to metal-bound DNA (M-DNA). We found that the Zn2+ ions present in M-DNA could interact with the sulfhydryl groups in cysteines of targeting peptides through the LMCT transition, and the M-DNA/peptide complex could specifically transfect the target cells.

Cell surface-engineering to embed targeting ligands or tracking agents on the cell membrane.

The key challenge to improve the efficacy of cell therapy is how to efficiently modify cells with a specific molecule or compound that can guide the cells to the target tissue. To address this, we have developed a cell surface engineering technology to non-invasively modify the cell surface. This technology can embed a wide variety of bioactive molecules on any cell surface and allow for the targeting of a wide range of tissues in a variety of disease states. Using our cell surface engineering technology, mesenchymal stem cells (MSC)s were modified with: 1) a homing peptide or a recombinant protein to facilitate the migration of the cells toward a specific molecular target; or 2) magnetic resonance imaging (MRI) contrast agents to allow for in vivo tracking of the cells. The incorporation of a homing peptide or a targeting ligand on MSCs facilitated the migration of the cells toward their molecular target. MRI contrast agents were successfully embedded on the cell surfaces without adverse effects to the cells and the contrast agent-labeled cells were detectable by MRI. Our technology is a promising method of cell surface engineering that is applicable to a broad range of cell therapies.