Joohee Jung

Use of macrophages to deliver therapeutic and imaging contrast agents to tumors

Drug targeting to tumors with limited toxicity and enhanced efficacy of drug is one of the important goals for cancer treatment pharmaceutics. Monocytes/macrophages are able to migrate to tumor sites across the blood barriers by acting as Trojan horses carrying drug cargoes. Taking this advantage, we have intended to develop an efficient administration system using a biologically active carrier of mouse peritoneal macrophage bearing liposomal doxorubicin (macrophage-LP-Dox). We expect that this system could improve the cancer therapeutic efficacy through deeper penetration into tumor even hypoxic region behind tumor blood vessel. We first confirmed that macrophages containing iron oxides could migrate and infiltrate into tumors effectively by MR imaging. Next, we showed that doxorubicin (Dox) encapsulated with liposomes (LP-Dox) was successfully loaded into macrophages, in which the biological activity of macrophage and cytotoxicity of Dox against tumor cells were well preserved. Delivery of Dox into tumor tissue by systemic administration of macrophage-LP-Dox was verified in both subcutaneous and metastasis xenograft tumor models. Importantly, the effective inhibition of in vivo tumor growth was proved with this system. Our results provide the feasibility of macrophages-LP-drug as an active biocarrier for the enhancement of therapeutic effects in cancer treatment and open new perspectives for the active delivery of drugs.

Bio-nanocapsule conjugated with liposomes for in vivo pinpoint delivery of various materials.

Bio-nanocapsules (BNCs) consisting of hepatitis B virus (HBV) surface antigen (HBsAg) are approximately 50-nm hollow particles displaying a human hepatocyte-recognizing molecule (pre-S1 peptide). They have been used as an HB vaccine for the last two decades. Original BNC can incorporate various payloads (e.g., drugs, genes) by electroporation and deliver them to human hepatocytes specifically by utilizing the HBV infection mechanism. Here, we developed a new BNC conjugated with liposomes and succeeded in incorporating large materials (100-nm fluorescence-labeled polystyrene beads and >30 kbp plasmids) into the BNC-liposome complex. The complex delivered these large materials to human hepatocytes specifically ex vivo and in vivo. The transfection efficiency of the BNC-liposome complex was significantly higher than that of the original BNC. These results indicated that BNC confers the tissue- and cell-specificity on the conventional liposomes and raises new possibilities for drug delivery systems, gene delivery systems, and bio-imaging systems in vivo.

Systemic delivery and preclinical evaluation of Au nanoparticle containing β-lapachone for radiosensitization

Effective delivery of radiosensitizer to target tumor cells, causing preferentially increased tumor cytotoxicity, while simultaneously minimizing damage to healthy cells around the tumor, is an ideal strategy for the improvement of radiotherapeutic efficacy against human cancer. We aimed to enhance radiotherapeutic efficacy by using biocompatible gold nanoparticles (AuNP) as a vehicle for systemic delivery of ss-lapachone (lap). Lap is a novel anticancer agent displaying potent cytotoxicity against cancer cells expressing NAD(P)H:quinone oxidoreductase-1 enzyme (NQO1). Although lap is expected to be a very promising radiosensitizer, its poor solubility and non-specific distribution obstruct preclinical evaluation and clinical application. In this study, the property of AuNPs carrying lap (AuNPs/lap) for active-targeting tumor cells and improving in vivo radiotherapeutic efficacy was evaluated. Murine monoclonal anti-EGFR antibody was conjugated to the AuNPs/lap as a ligand for active targeting. The active tumor-targeting property of AuNPs/lap conjugating anti-EGFR antibody was validated in vitro experiments using cell lines expressing EGFR at different levels. In mice bearing xenograft human tumors, the intravenous injection of AuNPs/lap exhibited highly enhanced radiotherapeutic efficacy. AuNPs/lap offers a new modality for improvement of radiotherapeutic efficacy and feasibility of further clinical application for human cancer treatment.

Nanocapsules incorporating IgG Fc-binding domain derived from Staphylococcus aureus protein A for displaying IgGs on immunosensor chips.

To enhance the sensitivities and antigen-binding capacities of immunosensors, oriented immobilization of antibodies on the surface of the sensor chip is critical, but to date, this has not been adequately achieved. We describe a way of adsorbing immunoglobulin (Ig) proteins onto 32-nm bio-nanocapsules (BNCs) through IgG Fc-binding domains derived from Staphylococcus aureus protein A (ZZ-BNC). This arrangement permits approximately 60 molecules of mouse total IgG bind to ZZ-BNC and all the IgG Fv regions to be displayed outwardly for the effective binding of antigens. ZZ-BNCs adsorbed onto the gold surface of the sensor chip of the quartz crystal microbalance (QCM) could markedly enhance the sensitivity and antigen-binding capacity of the chip. On the sensor chip of surface plasmon resonance (SPR), antibodies on the ZZ-BNCs showed higher affinities to each antigen than those on protein A. The BNC-coated sensor chip is very stable, and should prove useful for various immunosensor applications due to oriented immobilization of antibodies.

Polymeric Nanoparticles Containing Taxanes Enhance Chemoradiotherapeutic Efficacy in Non-small Cell Lung Cancer

PURPOSEnTo reduce the side effects and improve the efficacy of chemoradiation therapy, taxanes were incorporated into polymeric nanoparticles (PNP), and their synergic effect on radiation therapy in non-small cell lung cancer was evaluated.nnnMETHODS AND MATERIALSnThe properties of PNP-taxanes were characterized by transmission electron microscopy and dynamic light scattering. The chemoradiotherapeutic efficacy of PNP-taxanes was determined by clonogenic assay, cellular morphology, and flow cytometry in A549 cells. In mice bearing A549-derived tumors, the tumor growth delay was examined after the treatment of PNP-taxanes and/or ionizing radiation (IR).nnnRESULTSnThe PNP-taxanes were found to be approximately 45 nm in average diameter and to have high solubility in water. They showed the properties of active internalization into cells and preserved the anticancer effect of free taxanes. The survival fraction of A549 cells by clonogenic assay was significantly reduced in the group receiving combined treatment of PNP-taxanes and IR. In addition, inxa0vivo radiotherapeutic efficacy was markedly enhanced by the intravenous injection of PNP-taxanes into the xenograft mice.nnnCONCLUSIONSnWe have demonstrated the feasibility of PNP-taxanes to enhance the efficacy of chemoradiation therapy. These results suggest PNP-taxanes can hold an invaluable and promising position in treating human cancers as a novel and effective chemoradiation therapy agent.

Efficient and rapid purification of drug- and gene-carrying bio-nanocapsules, hepatitis B virus surface antigen L particles, from Saccharomyces cerevisiae

Bio-nanocapsules (BNCs) are hollow particles (approx. 50 nm diameter) consisting of hepatitis B virus surface antigen (HBsAg) large (L, pre-S1+pre-S2+S) proteins embedded in a unilamellar liposome, sharing the same transmembrane S region with an immunogen of hepatitis B vaccine (i.e., HBsAg small (S) protein particle). BNCs can incorporate drugs and genes into the hollow space and systemic administration of the BNCs can deliver the products to human liver via the human hepatocyte-specific receptor within the pre-S (pre-S1+pre-S2) region displayed on BNCs surface. Thus, BNCs are expected to offer efficient and safe non-viral nanocarriers to deliver human liver-specific genes and drugs. To date, BNCs have been purified from the crude extract of BNC-overexpressing yeast cells by fractionation with polyethylene glycol followed by one CsCl equilibrium and two sucrose density gradient ultracentrifugation steps. However, the process was inefficient in terms of yield and time, and was not suitable for mass production because of the ultracentrifugation step. Furthermore, trace contamination with yeast-derived proteinases degraded the pre-S region, which is indispensable for liver-targeting, during long-term storage. In this study, we developed a new purification method involving heat treatment and sulfated cellulofine column chromatography to facilitate rapid purification, completely remove proteinases, and enable mass production. In addition, the BNCs were functional for at least 14 months after lyophilization with 5% (w/v) sucrose as an excipient. This new process will significantly contribute to the development of forthcoming BNC-based nanomedicines as well as hepatitis B vaccines.

c-Myc down-regulation is involved in proteasome inhibitor-mediated enhancement of radiotherapeutic efficacy in non-small cell lung cancer

In this study, the effect of MG132 (carbobenzoxyl-leucinyl-leucinyl-leucinal-H) at a low dose on radiotherapeutic efficacy and its accurate mechanism of radiosensitization were investigated in human non-small cell lung cancer. The effect of MG132 on ionizing radiation (IR)-induced cytotoxicity, cell proliferation and survival of A549 cells was evaluated. The protein expression modulated by MG132 and IR were inspected by Western blot analysis. To determine in vivo radiotherapeutic efficacy, tumor growth delay was analyzed in a A549 tumor-bearing xenograft mouse model after single or repeated treatment of MG132 and/or IR. Induction of apoptosis and change of c-Myc expression in the tumor tissue was explored by histological analysis. MG132 at a non-toxic dose enhanced the radiation-induced cytotoxicity of A549 cells, accompanying a significant decrease of c-Myc expression. Suppression of c-Myc expression by small interfering RNA (siRNA) displayed enhancement of radiosensitivity similarly to MG132 treatment. Tumor growth in the xenograft mice was markedly delayed by systemic administration of MG132 combined with IR. In vivo down-regulation of c-Myc and increased induction of apoptosis were simultaneously observed in the tumor tissues followed by combinational treatment of MG132 and IR. The results reveal a novel mechanism for proteasome inhibitor-mediated radiosensitization in which c-Myc down-regulation is involved.

Bio-Nanocapsule–Liposome Conjugates for In Vivo Pinpoint Drug and Gene Delivery

A bio-nanocapsule (BNC) is an ~50-nm hepatitis B virus (HBV) subviral particle comprising HBV envelope L proteins and a lipid bilayer, and is synthesized in recombinant Saccharomyces cerevisiae. When BNCs are administered intravenously in a mouse xenograft model, they can accumulate specifically in human liver-derived tissues and enter cells efficiently by the HBV-derived human liver-specific infection machinery, localized at the outer-membrane pre-S region of the L protein. BNC specificity for the human liver can be altered to other tissues by substituting the pre-S region using targeting molecules (e.g., antibodies, lectins, cytokines). BNCs can spontaneously form complexes with liposomes (LPs) by the membrane fusogenic activity of the pre-S region. LPs containing various therapeutic materials (e.g., chemicals, proteins, DNA, RNA) can therefore be covered with BNCs to form an ~150-nm BNC-LP conjugate. BNC-LP conjugates injected intravenously can deliver incorporated materials to target tissues specifically and efficiently by utilizing the HBV-derived infection machinery. The stability of BNC-LP conjugates in the blood circulation is similar to that of PEGylated LPs. In this chapter, we describe the preparation and in vivo application of BNC-LP conjugates, and the potential of BNC-LP conjugates as in vivo pinpoint drug delivery systems.

Hepatitis B virus envelope L protein-derived bio-nanocapsules: Mechanisms of cellular attachment and entry into human hepatic cells

A bio-nanocapsule (BNC) is a hollow nanoparticle consisting of an approximately 100-nm-diameter liposome with about 110 molecules of hepatitis B virus (HBV) surface antigen L protein embedded as a transmembrane protein. BNC can encapsulate various drugs and genes and deliver them specifically to human hepatic cells based on the ability of HBV to recognize human hepatocyte, which is integrated in the N-terminal region of L protein. However, it is elusive whether the cellular attachment and entry into hepatic cells of BNC utilize the early infection mechanism of HBV. In this study, we have found that while all human hepatic cells show distinct affinities for BNC compared to non-hepatic cells, primary hepatocytes shows the highest efficiency for cellular binding and incorporation of BNC. Amounts of BNCs bound weakly and strongly to cell membranes and those entered into the cells varied significantly depending on the types of human hepatic cells. The weak and strong binding modes of BNC are likely mediated through binding to two distinct HBV receptors (heparin-mediated low-affinity and unidentified high-affinity receptors), which play major roles in the early infection mechanism of HBV. The rates of cellular uptake of BNC are similar to those reported for HBV. The BNCs incorporated into the cells are swiftly sorted to either early endosomes or macropinosomes and then to late endosomes and/or lysosomes. These findings strongly suggest that BNC is bound to and incorporated into human hepatic cells according to the early infection mechanism of HBV.

Immunocytes as a biocarrier to delivery therapeutic and imaging contrast agents to tumors

Radiotherapy for cancer treatment has been used for primary or adjuvant treatment in many types of cancer, and approximately half of all cancer patients are undergoing radiation. However, ionizing radiation exposure induces genetic alterations in cancer cells and results in recruitment of monocytes/macrophages by triggering signals released from these cells. Using this characteristic of monocytes/macrophages, we have attempted to develop a biocarrier loading radiosensitizing anticancer agents that can lead to enhance the therapeutic effect of radiation in cancer treatment. The aim of this study is to demonstrate the proof of this concept. THP-1 labeled with Qdot 800 or iron oxide (IO) effectively migrated into tumors of subcutaneous mouse model and increased recruitment after ionizing radiation. Functionalized liposomes carrying a radiosensitizing anticancer agent, doxorubicin, are successfully loaded in THP-1 (THP-1-LP-Dox) with reduced cytotoxicity, and THP-1-LP-Dox also was observed in tumors after intravenous administration. Here, we report that monocytes/macrophages as a biocarrier can be used as a selective tool for amplification of the therapeutic effects on radiotherapy for human cancer treatment.