BiTE-Secreting CAR-γδT as a Dual Targeting Strategy for the Treatment of Solid Tumors.

HLA-G is considered as an immune checkpoint protein and a tumor-associated antigen. In the previous work, it is reported that CAR-NK targeting of HLA-G can be used to treat certain solid tumors. However, the frequent co-expression of PD-L1 and HLA-G) and up-regulation of PD-L1 after adoptive immunotherapy may decrease the effectiveness of HLA-G-CAR. Therefore, simultaneous targeting of HLA-G and PD-L1 by multi-specific CAR could represent an appropriate solution. Furthermore, gamma-delta T (γδT) cells exhibit MHC-independent cytotoxicity against tumor cells and possess allogeneic potential. The utilization of nanobodies offers flexibility for CAR engineering and the ability to recognize novel epitopes. In this study, Vδ2 γδT cells are used as effector cells and electroporated with an mRNA-driven, nanobody-based HLA-G-CAR with a secreted PD-L1/CD3ε Bispecific T-cell engager (BiTE) construct (Nb-CAR.BiTE). Both in vivo and in vitro experiments reveal that the Nb-CAR.BiTE-γδT cells could effectively eliminate PD-L1 and/or HLA-G-positive solid tumors. The secreted PD-L1/CD3ε Nb-BiTE can not only redirect Nb-CAR-γδT but also recruit un-transduced bystander T cells against tumor cells expressing PD-L1, thereby enhancing the activity of Nb-CAR-γδT therapy. Furthermore, evidence is provided that Nb-CAR.BiTE redirectes γδT into tumor-implanted tissues and that the secreted Nb-BiTE is restricted to the tumor site without apparent toxicity.

Inhibition of Bruton's Tyrosine Kinase Suppresses Cancer Stemness and Promotes Carboplatin-induced Cytotoxicity Against Bladder Cancer Cells.

BACKGROUND/AIM: Bruton's tyrosine kinase (BTK) has been discovered to serve a critical role in the survival and infiltration of B-cell lymphoma. Recently, it was reported that BTK inhibitors exerted potential beneficial effects against numerous types of solid tumor, including glioblastoma multiforme and breast cancer; however, whether BTK is crucial for the progression of bladder cancer (BLCA) remains unclear. The present study investigated the in vitro function of BTK in stemness properties of BLCA cells. Furthermore, the therapeutic effects of a standard chemotherapeutic drug, carboplatin in combination with the BTK inhibitor, ibrutinib were also investigated. MATERIALS AND METHODS: The association between BTK and BLCA progression was evaluated using free databases. The in vitro stemness and metastatic properties of BLCA cells were also investigated. Finally, the cytotoxicity of carboplatin in combination with ibrutinib was determined. RESULTS: The meta-survival analysis of the association between BTK and BLCA progression revealed that the expression levels of BTK were associated with a higher risk of BLCA progression. The CD133+-side population of BLCA cells formed spheroids when cultured in serum-free conditioned medium. In addition, expression levels of BTK and activated mTOR signaling in side population cells was up-regulated compared with the parental BLCA cells. Furthermore, the transfection of short hairpin RNA targeting BTK into BLCA cells markedly reduced cell migratory ability. More importantly, in advanced BLCA cells, which were more resistant to carboplatin, it was discovered that the cell viability was significantly reduced in the presence of ibrutinib (p<0.05). CONCLUSION: The findings of the present study suggested that BTK may have a critical role in the progression of BLCA; however, the underlying mechanisms and potential therapeutic strategies involved require further investigations.

Gamma/Delta T-Cells Enhance Carboplatin-induced Cytotoxicity Towards Advanced Bladder Cancer Cells.

BACKGROUND/AIM: Bladder cancer (BLCA, urothelial bladder cancer) is one of the most common malignancies with increasing incidence and mortality worldwide. Poor diagnosis and the limitation of treatment is still an unmet need in clinical practice. γδ T-Cells have been paid increasing attention because of their potent cytotoxicity against tumors. Herein, we investigated the cytolytic effect of γδ T-cells in combination with the chemotherapeutic drug, carboplatin, against BLCA cells. MATERIALS AND METHODS: The standard protocol for the induction and expansion of peripheral blood mononuclear cell-derived γδ T-cells was a zoledronic acid/interleukin-2-based medium system for 2 weeks. The cytotoxicity of γδ T-cells with and without carboplatin against BLCA cells was examined. RESULTS: After incubation, T-cell receptor-positive γδ T-cells showed a natural killer cell-like phenotypic characteristic and dose-dependently increased cytotoxicity against BLCA cells. Interestingly, we found that in advanced BLCA cells, which were more resistant to carboplatin, the cell viability was significantly (p<0.05) reduced in the presence of γδ T-cells. CONCLUSION: Our findings showed that γδ T-cell therapy has potent benefit in cancer treatment.

Cytokine-induced Killer T Cells Enhance the Cytotoxicity Against Carboplatin-resistant Ovarian Cancer Cells.

BACKGROUND/AIM: Ovarian cancer (OC) is typically diagnosed at an advanced stage with limitations for cure. Cytokine-induced killer (CIK) T cell therapy exerts significant cytotoxic effects against cancer cells and reduces the adverse effects of chemotherapy. Herein, we performed a flow cytometry-based method to evaluate the cytotoxicity of peripheral blood mononuclear cells-derived CIK cells against OC cells. MATERIALS AND METHODS: The CIK cells were induced and expanded using an interferon-γ/IL-2-based xeno-free medium system. The cytotoxicity of CIK cells or carboplatin against OC cells was examined. RESULTS: The CIK cells showed an NK-like phenotypic characteristic and dose-dependently increased cytotoxicity against OC cells. We found that the number of advanced OC cells, which were more resistant to carboplatin, was dramatically decreased by an additional one-shot CIK treatment. CONCLUSION: CIK cells have a potent cytotoxic ability that would be explored as an alternative strategy for cancer treatment in the near future.

Isolation and Expansion of Cytotoxic Cytokine-induced Killer T Cells for Cancer Treatment.

Adoptive cellular immunotherapy focuses on restoring cancer recognition via the immune system and improves effective tumor cell killing. Cytokine-induced killer (CIK) T cell therapy has been reported to exert significant cytotoxic effects against cancer cells and to reduce the adverse effects of surgery, radiation, and chemotherapy in cancer treatments. CIK can be derived from peripheral blood mononuclear cells (PBMCs), bone marrow, and umbilical cord blood. CIK cells are a heterogeneous subpopulation of T cells with CD3+CD56+ and natural killer (NK) phenotypic characteristics that include major histocompatibility complex (MHC)-unrestricted antitumor activity. This study describes a qualified, clinically applicable, flow cytometry-based method for the quantification of the cytolytic capability of PBMC-derived CIK cells against hematological and solid cancer cells. In the cytolytic assay, CIK cells are co-incubated at different ratios with prestained target tumor cells. After the incubation period, the number of target cells are determined by a nucleic acid-binding stain to detect dead cells. This method is applicable to both research and diagnostic applications. CIK cells possess potent cytotoxicity that could be explored as an alternative strategy for cancer treatment upon its preclinical evaluation by a cytometer setup and tracking (CS & T)-based flow cytometry system.

The Effect of Electrode Topography on the Magnetic Properties and MRI Application of Electrochemically-Deposited, Synthesized, Cobalt-Substituted Hydroxyapatite.

Magnetic nanoparticles are used to enhance the image contrast of magnetic resonance imaging (MRI). However, the development of magnetic nanoparticles with a low dose/high image contrast and non-toxicity is currently a major challenge. In this study, cobalt-substituted hydroxyapatite nanoparticles deposited on titanium (Ti-CoHA) and cobalt-substituted hydroxyapatite nanoparticles deposited on titanium dioxide nanotubes (TNT-CoHA) were synthesized by the electrochemical deposition method. The particle sizes of Ti-CoHA and TNT-CoHA were 418.6 nm and 127.5 nm, respectively, as observed using FE-SEM. It was shown that CoHA can be obtained with a smaller particle size using a titanium dioxide nanotube (TNT) electrode plate. However, the particle size of TNT-CoHA is smaller than that of Ti-CoHA. The crystal size of the internal cobalt oxide of CoHA was calculated by using an XRD pattern. The results indicate that the crystal size of cobalt oxide in TNT-CoHA is larger than that of the cobalt oxide in Ti-CoHA. The larger crystal size of the cobalt oxide in TNT-CoHA makes the saturation magnetization (Ms) of TNT-CoHA 12.6 times higher than that of Ti-CoHA. The contrast in MRIs is related to the magnetic properties of the particles. Therefore, TNT-CoHA has good image contrast at low concentrations in T2 images. The relaxivity coefficient of the CoHA was higher for TNT-CoHA (340.3 mM-1s-1) than Ti-CoHA (211.7 mM-1s-1), and both were higher than the commercial iron nanoparticles (103.0 mM-1s-1). We showed that the TNT substrate caused an increase in the size of the cobalt oxide crystal of TNT-CoHA, thus effectively improving the magnetic field strength and MRI image recognition. It was also shown that the relaxivity coefficient rose with the Ms. Evaluation of biocompatibility of CoHA using human osteosarcoma cells (MG63) indicated no toxic effects. On the other hand, CoHA had an excellent antibacterial effect, as shown by E. coli evaluation, and the effect of TNT-CoHA powder was higher than that of Ti-CoHA powder. In summary, TNT-CoHA deposited electrochemically on the TNT substrates can be considered as a potential candidate for the application as an MRI contrast agent. This paper is a comparative study of how different electrode plates affect the magnetic and MRI image contrast of cobalt-substituted hydroxyapatite (CoHA) nanomaterials.