Targeted Regression of Hepatocellular Carcinoma by Cancer-Specific RNA Replacement through MicroRNA Regulation.

Hepatocellular carcinoma (HCC) has a high fatality rate and limited therapeutic options with side effects and low efficacy. Here, we proposed a new anti-HCC approach based on cancer-specific post-transcriptional targeting. To this end, trans-splicing ribozymes from Tetrahymena group I intron were developed, which can specifically induce therapeutic gene activity through HCC-specific replacement of telomerase reverse transcriptase (TERT) RNA. To circumvent side effects due to TERT expression in regenerating liver tissue, liver-specific microRNA-regulated ribozymes were constructed by incorporating complementary binding sites for the hepatocyte-selective microRNA-122a (miR-122a), which is down-regulated in HCC. The ribozyme activity in vivo was assessed in mouse models orthotopically implanted with HCC. Systemic administration of adenovirus encoding the developed ribozymes caused efficient anti-cancer effect and the least hepatotoxicity with regulation of ribozyme expression by miR-122a in both xenografted and syngeneic orthotopic murine model of multifocal HCC. Of note, the ribozyme induced local and systemic antitumor immunity, thereby completely suppressing secondary tumor challenge in the syngeneic mouse. The cancer specific trans-splicing ribozyme system, which mediates tissue-specific microRNA-regulated RNA replacement, provides a clinically relevant, safe, and efficient strategy for HCC treatment.

Selective and efficient retardation of cancers expressing cytoskeleton-associated protein 2 by targeted RNA replacement.

Human cytoskeleton-associated protein 2 (hCKAP2) is upregulated and highly expressed in various human malignances. hCKAP2 has microtubule-stabilizing characteristics and potentially regulates the dynamics and assembly of the mitotic spindle and chromosome segregation, indicating that hCKAP2 plays important functions during mitosis. In this study, we evaluated hCKAP2 as a plausible anticancer target through development and validation of a targeted cancer gene therapy strategy based on targeting and replacement of hCKAP2 RNA using a trans-splicing ribozyme. This targeted RNA replacement triggered transgene activity via accurate trans-splicing reaction selectively in human cancer cells expressing the hCKAP2 RNA and simultaneously reduced the expression level of the RNA in the cells. Adenoviral vector encoding the hCKAP2-specific trans-splicing ribozyme selectively induced cytotoxicity in tumor cells expressing hCKAP2. Moreover, intratumoral injection of the virus produced selective and efficient regression of tumor that had been subcutaneously inoculated with hCKAP2-positive colon cancer cells in mice with minimal liver toxicity. Furthermore, orthotopically multifocal hCKAP2-positive hepatocarcinoma established in mice were efficiently regressed by systemic delivery of adenoviral vector encoding the specific ribozyme under the control of a liver-selective phosphoenolpyruvate carboxykinase promoter with least hepatotoxicity. The results indicate that hCKAP2 RNA is a promising target for anticancer approach based on trans-splicing ribozyme-mediated RNA replacement.

Cancer cell targeting with mouse TERT-specific group I intron of Tetrahymena thermophila.

Telomerase reverse transcriptase (TERT), which prolongs the replicative life span of cells, is highly upregulated in 85-90% of human cancers, whereas most normal somatic tissues in humans express limited levels of the telomerase activity. Therefore, TERT has been a potential target for anticancer therapy. Recently, we described a new approach to human cancer gene therapy, which is based on the group I intron of Tetrahymena thermophila. This ribozyme can specifically mediate RNA replacement of human TERT (hTERT) transcript with a new transcript harboring anticancer activity through a trans-splicing reaction, resulting in selective regression of hTERT-positive cancer cells. However, to validate the therapeutic potential of the ribozyme in animal models, ribozymes targeting inherent transcripts of the animal should be developed. In this study, we developed a Tetrahymena-based trans-splicing ribozyme that can specifically target and replace the mouse TERT (mTERT) RNA. This ribozyme can trigger transgene activity not only also in mTERT-expressing cells but hTERT-positive cancer cells. Importantly, the ribozyme could selectively induce activity of the suicide gene, a herpes simplex virus thymidine kinase gene, in cancer cells expressing the TERT RNA and thereby specifically hamper the survival of these cells when treated with ganciclovir. The mTERT-targeting ribozyme will be useful for evaluation of the RNA replacement approach as a cancer gene therapeutic tool in the mouse model with syngeneic tumors.

Selective regression of cells expressing mouse cytoskeleton-associated protein 2 transcript by trans-splicing ribozyme.

Cytoskeleton-associated protein 2 (CKAP2) is known to be highly expressed in primary human cancers as well as most cancer cell lines. CKAP2 functions as microtubule stabilizer and probably as cell proliferation inducer, indicating that CKAP2 might be a potential anticancer target. In this study, we developed a specific ribozyme that can replace mouse CKAP2 (mCKAP2) RNA with new transcripts through trans-splicing reaction. This specific RNA replacement resulted in triggering of transgene activity selectively in mammalian cells that express the mCKAP2 RNA. Simultaneously, the ribozyme reduced the expression level of the target RNA in the cells. Noticeably, the ribozyme selectively induced activity of the suicide gene herpes simplex virus thymidine kinase in cells expressing the mCKAP2 RNA and thereby specifically retarded the survival of these cells with ganciclovir treatment. This mCKAP2-specific ribozyme will be useful for validation of the RNA replacement as cancer gene therapy approach in mouse model with syngeneic tumors.