Oncolytic herpes simplex virus delivery of dual CAR targets of CD19 and BCMA as well as immunomodulators to enhance therapeutic efficacy in solid tumors combined with CAR T cell therapy.

Background: The CAR T-cell therapy is a promising approach to treating hematologic malignancies. However, the application in solid tumors still has many tough challenges, including heterogenicity in antigen expressions and immunosuppressive tumor microenvironment (TME). As a new cancer treatment modality, oncolytic virotherapy can be engineered to circumvent these obstacles for CAR T cell therapy in solid tumors. Methods: In this study, an oHSV T7011 is engineered to drive ectopic expression of dual-antigens, extracellular domains of CD19 and BCMA, on the solid tumor cell surface to be targeted by approved CAR T cells. In addition, multiple immunomodulators, CCL5, IL-12, and anti-PD-1 antibody are also included to modulate the TME. The antitumor activities of T7011 in combination with CD19 or BCMA CAR T-cell were evaluated in vitro and in vivo. Results: The expression of CD19 or BMCA on the tumor cell surface could be detected after T7011 infection. The level of CCL5 in TME was also increased. Efficacy studies demonstrated that combination with T7011 and CAR-TCD19 or CAR-TBCMA cells showed significant synergistic anti-tumor responses in several solid tumor models. Conclusion: These studies indicated that the new generation of oHSV T7011 can be a promising combinational therapy with CD19 or BCMA-specific CAR T cells for the treatment of a broad range of solid tumors.

[Mechanical properties of rat HCC adhesion to collagen I and its relationship with cell cycle].

The mechanical properties of tumor cells adhering to extracellular matrix (ECM) are closely related with their invasion and metastesis. In this study we investigated the adhesive mechanical properties between hepatocellular carcinoma cells(HCC) and the collagen I coated surfaces from the viewpoint of cell cycle by coupling cellular biology and cellular mechanics, using micropipette aspiration and cell synchronization technique. The results showed that the synchronous G1 and S phase HCC cells were achieved by use of thymine-2-desoryriboside, colchicines sequential blockage method and double thymine-2-desoryriboside blockage method, and that the synchronous rates of G1 and S phase HCC amounted to 74.09% and 90.39% respectively. Within the ranges of dosing and timing in this study, the adhesion of HCC cells to collagen I displayed dose dependent and time dependent patterns. S phase cells had small force of adhesion to collagen I as compared with G1 phase and controlled cells(P<0.001), which suggested that G1 phase HCC may play an important role in the step of invading interstitial connective tissue in the metastasis pathway of HCC through blood circulation. These are of significance to unveiling the mechanism of HCC metastasis.

Adhesion of different cell cycle human hepatoma cells to endothelial cells and roles of integrin beta1.

AIM: To investigate the adhesive mechanical properties of different cell cycle human hepatoma cells (SMMC-7721) to human umbilical vein endothelial cells (ECV-304), expression of adhesive molecule integrinbeta1 in SMMC-7721 cells and its contribution to this adhesive course. METHODS: Adhesive force of SMMC-7721 cells to endothelial cells was measured using micropipette aspiration technique. Synchronous G1 and S phase SMMC-7721 cells were achieved by thymine-2-deoxyriboside and colchicines sequential blockage method and double thymine-2-deoxyriboside blockage method, respectively. Synchronous rates of SMMC-7721 cells and expression of integrinbeta1 in SMMC-7721 cells were detected by flow cytometer. RESULTS: The percentage of cell cycle phases of general SMMC-7721 cells was 11.01% in G2/M phases, 53.51% in G0/G1 phase, and 35.48% in S phase. The synchronous rates of G1 and S phase SMMC-7721 cells amounted to 74.09% and 98.29%, respectively. The adhesive force of SMMC-7721 cells to endothelial cells changed with the variations of adhesive time and presented behavior characteristics of adhesion and de-adhesion. S phase SMMC-7721 cells had higher adhesive forces than G1 phase cells ((307.65+/-92.10) x 10(-10) N vs (195.42+/-60.72) x 10(-10) N, P<0.01). The expressive fluorescent intensity of integrinbeta(1) in G(1) phase SMMC-7721 cells was depressed more significantly than the values of S phase and general SMMC-7721 cells. The contribution of adhesive integrinbeta1 was about 53% in this adhesive course. CONCLUSION: SMMC-7721 cells can be synchronized preferably in G1 and S phases with thymine-2-deoxyriboside and colchicines. The adhesive molecule integrinbeta1 expresses a high level in SMMC-7721 cells and shows differences in various cell cycles, suggesting integrin beta1 plays an important role in adhesion to endothelial cells. The change of adhesive forces in different cell cycle SMMC-7721 cells indicates that S phase cells play predominant roles possibly while they interact with endothelial cells.