ABSTRACT
Immunotherapy has become another effective tumor treatment after surgical resection, chemotherapy, radiotherapy and targeted therapy. However, due to the low immunogenicity of tumor cells and immunosuppressive tumor microenvironment, antigen-presenting cells inefficiently process and present tumor antigens, thus leading to insufficient activation of cytotoxic T lymphocytes and tumor infiltration, which significantly affects the effectiveness of tumor immunotherapy. In recent years, it has been demonstrated that multiple metal ions exhibit distinguished modulatory effects in activating innate immune stimulation and conquering acquired immune tolerance. Based on this, scientists have designed a series of nano-adjuvant delivery systems with metal ions or metal nanoparticles to enhance the targeted accumulation of metal ions in tumor tissues or lymphoid organs for efficiently inducing immunogenic cell death or directly activating antigen-presenting cells to initiate anti-tumor specific immune response. This review briefly outlines the role of various metal ions in anti-tumor immunomodulation, summarizes the research progress in using metal nanoadjuvant delivery systems to achieve efficient anti-tumor immunotherapy, and provides foresight on the main challenges and potential directions in this field.
ABSTRACT
Immunotherapy has emerged as one of the major modalities for clinical cancer therapy, along with surgery, chemotherapy, radiotherapy and targeted therapy. However, tumor-targeted delivery of immune therapeutics is challenged by a series of barriers including non-specific release, poor tumor penetration capacity, and insufficient cellular uptake of the therapeutic regimens, which seriously restricted the efficiency and efficacy of immunotherapy. To address above challenges, nanosized drug delivery systems (NDDS) have been extensively exploited to achieve tumor-targeted delivery of immunotherapy drugs. It has been well investigated that solid tumors are of unique characteristics including acidic, hypoxic and enzymatic extracellular microenvironment. Meanwhile, the tumor cells are of acidic, reductant and reactive oxygen species intracellular microenvironment. In recent years, a large variety of tumor microenvironment-activatable NDDS have been exploited to respond specifically to the stimulus of extracellular or intracellular tumor microenvironment for enhancing the accumulation, retention and penetration in the tumor tissue. These NDDS were also employed to promote intracellular uptake and tunable drug release inside the tumor cells. In this review article, we summarized the recent progress of our laboratory using the tumor microenvironment-activatable NDDS for immune efficient therapeutics delivery, and improved cancer immunotherapy. We also briefly discussed the challenges and provided perspective of NDDS-based cancer immunotherapy.
ABSTRACT
This study was aimed to build a new photo-sensitive co-delivery liposomes which combine photodynamic therapy with chemotherapy to reverse drug resistance of breast cancer. Photodynamic photosen-sitizer chlorin e6 trimethyl ester (Ce6tM) and chemotherapeutic drug doxorubicin hydrochloride (DOX) were loaded into the liposomes (liposomes loaded with Ce6tM and DOX, CDL) by thin-film hydration extrusion and ammonium sulfate active loading methods. CDL was characterized with cryo-transmission electron microscopy (Cryo-TEM), dynamic light scattering particle size, zeta potentials and photo-sensitive DOX release behaviors in vitro. CDL cytotoxicity, singlet oxygen production, DOX accumulation, intracellular ATP level and cell cycle analysis in MCF7/ADR cells were evaluated. Finally, the tissue distribution of DOX and antitumor effects of CDL in BALB/c-nu nude mice bearing MCF7/ADR tumor were investigated. The results showed that the particle size of obtained CDL was 90.7 ± 1.1 nm and distributed uniformly. CDL possessed outstanding properties of photo-sensitive drug release profile. The accumulated release of DOX reached (96.52 ± 0.11)% in 2 min under 671 nm laser irradiation (2 W·cm-2). Interestingly, DOX in CDL could maintain rapid release after 671 nm laser irradiation with low power and short time (15 s, 0.25 W·cm-2). This phenomenon was caused by oxidation of unsaturated phospholipids in CDL under 671 nm laser irradiation and had nothing to do with the slightly elevated temperature. Photo-sensitive drug release behavior contributed to increased DOX accumulation in MCF7/ADR cells. The half inhibition concentration (IC50) of DOX in CDL laser group in MCF7/ADR cells was decreased by 601.9-fold compared with no laser group, which could be related to increased accumulation of DOX, decreased ATP levels and cell cycle arrest in MCF7/ADR cells. With the help of CDL, DOX accumulation in tumor was increased and in cardiac toxicity was reduced in vivo. CDL laser group showed a good anti-tumor effect. The tumor inhibition rate was (94.7 ± 6.2)%. These results suggest that CDL has a promising potential in reversing drug resistance of breast cancer.
ABSTRACT
<p><b>OBJECTIVE</b>To construct an eukaryotic expression vector of human telomerase reverse transcriptase (hTERT) gene specific shRNA, and investigate the effect of pshRNA-hTERT combined with gamma-irradiation on cell survival and telomerase activity.</p><p><b>METHODS</b>According to the coding sequence of hTERT mRNA, the target of RNAi was designed, and recombinant expression plasmid pshRNA-hTERT was constructed. The vector was transfected into Hep-2 cells. The radiosensitivity of Hep-2 cells was determined by clonogenic assay. Telomeric repeat amplification protocol (TRAP-PCR-ELISA) was used to observe the telomerase activity in each group. Results Recombinant expression vector pshRNA-hTERT was successfully transfected into Hep-2 cells. The hTERT expression inhibition rate reached 60. 8%. pshRNA-hTERT not only inhibited telomerase activity of Hep-2, but also inhibited the raise of telomerase activity induced by gamma-irradiation. Exposure of Hep-2 cells to pshRNA-hTERT for 24 hrs before irradiation resulted in a decrease in mean surviving fraction of Hep-2 cells compared with cells of group with irradiation alone (67. 7% vs 85. 7%, P <0. 05) .</p><p><b>CONCLUSION</b>RNAi showed a significant inhibitory effect to the expression of hTERT. The results indicate that pshRNA-hTERT can effectively inhibit telomerase activity of Hep-2 cells treated or untreated with 2 Gy gamma-irradiation and significantly enhance the radiosensitivity of Hep-2 cells in vitro. The role of radiosensitization of pshRNA-hTERT may be related with the inhibition of telomerase activity.</p>