Apoptosis-inducing proteins in chicken anemia virus and TT virus.

Torque teno viruses (TTVs) share several genomic similarities with the chicken anemia virus (CAV). CAV encodes the protein apoptin that specifically induces apoptosis in (human) tumor cells. Functional studies reveal that apoptin induces apoptosis in a very broad range of (human) tumor cells. A putative TTV open reading frame (ORF) in TTV genotype 1, named TTV apoptosis inducing protein (TAIP), it induces, like apoptin, p53-independent apoptosis in various human hepatocarcinoma cell lines to a similar level as apoptin. In comparison to apoptin, TAIP action is less pronounced in several analyzed human non-hepatocarcinoma-derived cell lines. Detailed sequence analysis has revealed that the TAIP ORF is conserved within a limited group of the heterogeneous TTV population. However, its N-terminal half, N-TAIP, is rather well conserved in a much broader set of TTV isolates. The similarities between apoptin and TAIP, and their relevance for the development and treatment of diseases is discussed.

Inhibition of hepatocarcinoma by systemic delivery of Apoptin gene via the hepatic asialoglycoprotein receptor.

Specificity is a prerequisite for systemic gene therapy of hepatocarcinoma. In vitro, the tumor-specific viral death effector Apoptin selectively induces apoptosis in malignant hepatic cells. Intratumoral treatment of xenografted subcutaneous hepatomas with Apoptin results in tumor regression. Here, we report a systemic delivery vehicle containing the Apoptin gene linked to asialoglycoprotein (Asor), which targets asialoglycoprotein receptor (ASGPR) present only on the surface of hepatocytes. In vitro, the protein-DNA complex Asor-Apoptin induced apoptosis in HepG2 hepatocarcinoma cells but not in normal L-02 hepatocytes. Non-hepatocyte-derived tumorigenic human A549 cells lacking the membrane ASGPR were not affected by Asor-Apoptin. In vivo systemic delivery of Asor-Apoptin via the tail vein into mice bearing in situ hepatocarcinoma resulted in specific and efficient distribution of Apoptin in both hepatocarcinoma cells and normal hepatocytes. Five days after injection of Asor-Apoptin, the in situ hepatocarcinomas showed significant signs of regression, whereas the surrounding normal hepatocytes did not. Systemically delivered Asor-LacZ expressing non-apoptotic LacZ gene did not inhibit tumor growth. Our data reveal that systemic delivery of Asor-Apoptin specifically induces apoptosis in malignant hepatocytes and thus constitutes a powerful and safe therapeutics against hepatocarcinomas.

Fibroblast-like synoviocytes from patients with rheumatoid arthritis are more sensitive to apoptosis induced by the viral protein, apoptin, than fibroblast-like synoviocytes from trauma patients.

OBJECTIVE: Fibroblast-like synoviocytes (FLS) from patients with rheumatoid arthritis (RA) show characteristics of transformation. Because the chicken anemia virus protein, apoptin, induces apoptosis solely in transformed cells, it was investigated whether FLS from patients were more sensitive to apoptin-induced apoptosis than FLS from normal joints obtained from trauma patients. METHODS: FLS were transduced with maltose-binding protein (MBP)-apoptin recombinant protein or MBP as a control protein by microinjection. After 24 hours, cells were fixed and stained with immunofluorescence to detect apoptin or MBP and the number of dead cells was assessed. Furthermore, phosphorylation of apoptin was analysed in FLS from patients with RA and from trauma patients by in vitro kinase assay. RESULTS: FLS from patients with RA were significantly more sensitive to apoptin-induced apoptosis than FLS from trauma patients (p = 0.0263). Furthermore, MBP-apoptin induced more apoptosis than MBP in RA FLS (p = 0.004). No phosphorylation of apoptin was observed in FLS from patients with RA. DISCUSSION: FLS from patients with RA are more sensitive to apoptin-induced apoptosis than normal FLS, which is consistent with a transformed phenotype of these cells. However, given the lack of phosphorylation of apoptin in RA FLS the mechanism of action of apoptin seems to differ between tumour cells and RA FLS. This study indicates that apoptin may help to identify a new therapeutic pathway against hyperplasia of the synovium and joint destruction in RA.

Human death effector domain-associated factor interacts with the viral apoptosis agonist Apoptin and exerts tumor-preferential cell killing.

Apoptin, a protein from chicken anemia virus without an apparent cellular homologue, can induce apoptosis in mammalian cells. Its cytotoxicity is limited to transformed or tumor cells, making Apoptin a highly interesting candidate for cancer therapy. To elucidate Apoptin's mechanism of action, we have searched for binding partners in the human proteome. Here, we report that Apoptin interacts with DEDAF, a protein previously found to associate with death effector domain (DED)-containing pro-apoptotic proteins, and to be involved in regulation of transcription. Like Apoptin, after transient overexpression, DEDAF induced apoptosis in various human tumor cell lines, but not in primary fibroblasts or mesenchymal cells. DEDAF-induced cell death was inhibited by the caspase inhibitor p35. Together with the reported association of DEDAF with a DED-containing DNA-binding protein in the nucleus and the transcription regulatory activity, our findings may provide a clue for the mechanism of Apoptin's actions in mammalian cells.

Apoptin acts as a tumor-specific killer: potentials for an anti-tumor therapy.

Apoptin, a protein encoded by an avian virus, induces apoptosis in a tumor-specific way, acts p53-independently and is even stimulated by the anti-apoptotic protein Bcl-2. Activation of upstream caspases is not required, whereas the activation of downstream caspases is involved in rapid Apoptin-induced cell death. Yet, in a caspase-3-negative human breast cancer cell line, Apoptin can induce apoptosis, but delayed. These features indicate that Apoptin can induce apoptosis via multiple pathways in tumor cells when other agents might fail. Apoptin is biologically active as a highly stable, multimeric complex, consisting of 30 to 40 monomers and forms cooperatively distinct superstructures upon binding to DNA. In tumor cells, Apoptin is imported into the nucleus prior to the induction of apoptosis; this contrasts with the situation in primary, normal cell cultures where nuclear import of Apoptin is very rare. Apoptin contains two different domains that induce apoptosis independently, and for both domains, a strong correlation exists between nuclear localization and killing activity. Apoptin is regulated by a kinase activity present in cancer cells but negligible in normal cells. Apoptin interacts with various partners of the human proteome such as DEDAF, which when overexpressed induces apoptosis in various human tumor cell lines but not in primary human cells, similar to Apoptin. In normal cells, Apoptin becomes aggregated, epitope shielded and eventually degraded in the cytoplasm. Furthermore, Apoptin-transgenic mice and other animal models have revealed Apoptin as a safe and efficient anti-tumor agent. These in vitro and in vivo tumor-specific features of Apoptin imply that it can form the basis of future anti-tumor therapies.

Apoptin's functional N- and C-termini independently bind DNA.

Apoptin induces apoptosis specifically in tumour cells, where Apoptin is enriched in the DNA-dense heterochromatin and nucleoli. In vitro, Apoptin interacts with dsDNA, forming large nucleoprotein superstructures likely to be relevant for apoptosis induction. Its N- and C-terminal domains also have cell-killing activity, although they are less potent than the full-length protein. Here, we report that both Apoptin's N- and C-terminal halves separately bound DNA, indicating multiple independent binding sites. The reduced cell killing activity of both truncation mutants was mirrored in vitro by a reduced affinity compared to full-length Apoptin. However, none of the truncation mutants cooperatively bound DNA or formed superstructures, which suggests that cooperative DNA binding by Apoptin is required for the formation of nucleoprotein superstructures. As Apoptin's N- and C-terminal fragments not only share apoptotic activity, but also affinity for DNA, we propose that both properties are functionally linked.

Mitotic catastrophe triggered in human cancer cells by the viral protein apoptin.

Mitotic catastrophe is an oncosuppressive mechanism that senses mitotic failure leading to cell death or senescence. As such, it protects against aneuploidy and genetic instability, and its induction in cancer cells by exogenous agents is currently seen as a promising therapeutic end point. Apoptin, a small protein from Chicken Anemia Virus (CAV), is known for its ability to selectively induce cell death in human tumor cells. Here, we show that apoptin triggers p53-independent abnormal spindle formation in osteosarcoma cells. Approximately 50% of apoptin-positive cells displayed non-bipolar spindles, a 10-fold increase as compared to control cells. Besides, tumor cells expressing apoptin are greatly limited in their progress through anaphase and telophase, and a significant drop in mitotic cells past the meta-to-anaphase transition is observed. Time-lapse microscopy showed that mitotic osteosarcoma cells expressing apoptin displayed aberrant mitotic figures and/or had a prolonged cycling time during mitosis. Importantly, all dividing cells expressing apoptin eventually underwent cell death either during mitosis or during the following interphase. We infer that apoptin can efficiently trigger cell death in dividing human tumor cells through induction of mitotic catastrophe. However, the killing activity of apoptin is not only confined to dividing cells, as the CAV-derived protein is also able to trigger caspase-3 activation and apoptosis in non-mitotic cancer cells.

The viral death effector Apoptin reveals tumor-specific processes.

Several natural proteins, including the cellular protein TRAIL and the viral proteins E4orf4 and Apoptin, have been found to exert a tumor-preferential apoptotic activity. These molecules are potential anti-cancer agents with direct clinical applications. Also very intriguing is their possible utility as sensors of the tumorigenic phenotype. Here, we focus on Apoptin, discussing recent research that has greatly increased our understanding of its tumor-specific processes. Apoptin, which kills tumor cells in a p53- and Bcl-2-independent, caspase-dependent manner, is biologically active as a highly stable, multimeric complex consisting of 30 to 40 monomers that form distinct superstructures upon binding cooperatively to DNA. In tumor cells, Apoptin is imported into the nucleus prior to the induction of apoptosis; this contrasts with the situation in primary or low-passage normal cell cultures where nuclear translocation of Apoptin is rare and inefficient. Apoptin contains two autonomous death-inducing domains, both of which exhibit a strong correlation between nuclear localization and killing activity. Nevertheless, forced nuclear localization of Apoptin in normal cells is insufficient to allow induction of apoptosis, indicating that another activation step particular to the tumor or transformed state is required. Indeed, a kinase activity present in cancer cells but negligible in normal cells was recently found to regulate the activity of Apoptin by phosphorylation. However, in normal cells, Apoptin can be activated by transient transforming signals conferred by ectopically expressed SV40 LT antigen, which rapidly induces Apoptin's phosphorylation, nuclear accumulation and the ability to induce apoptosis. The region on LT responsible for conferring this effect has been mapped to the N-terminal J domain. In normal cells that do not receive such signals, Apoptin becomes aggregated, epitope-shielded and is eventually degraded in the cytoplasm. Finally, Apoptin interacts with various partners of the human proteome including DEDAF, Nmi and Hippi, which may help to regulate either Apoptin's activation or execution processes. Taken together, these recent advances illustrate that elucidating the mechanism of Apoptin-induced apoptosis can lead to the discovery of novel tumor-specific pathways that may be exploitable as anti-cancer drug targets.