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 Apoptins 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 Apoptins 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.     

Recombinant Apoptin multimers kill tumor cells but are nontoxic and epitope-shielded in a normal-cell-specific fashion

Apoptin, a protein derived from chicken anemia virus, induces apoptosis in human transformed or tumor cells but not in normal cells. When produced in bacteria as a recombinant fusion with maltose-binding protein (MBP-Apoptin), Apoptin forms a distinct, stable multimeric complex that is remarkably homogeneous and uniform. Here, using cytoplasmic microinjection, we showed that recombinant MBP-Apoptin multimers retained the characteristics of the ectopically expressed wild-type Apoptin; namely, the complexes translocated to the nucleus of tumor cells and induced apoptosis, whereas they remained in the cytoplasm of normal, primary cells and exerted no apparent toxic effect. In normal cells, MBP-Apoptin formed increasingly large, organelle-sized globular bodies with time postinjection and eventually lost the ability to be detected by immunofluorescence analysis. Costaining with an acidotrophic marker indicated that these globular structures did not correspond to lysosomes. Immunoprecipitation studies showed that MBP-Apoptin remained fully antibody-accessible regardless of buffer stringency when microinjected into tumor cells. In contrast, MBP-Apoptin in normal cells was only recoverable under stringent lysis conditions, whereas under milder conditions they became fully shielded with time on two epitopes spanning the entire protein. Further biochemical analysis showed that the long-term fate of Apoptin protein aggregates in normal cells was their eventual elimination. Our results provide the first example of a tumor-specific apoptosis-inducing aggregate that is essentially sequestered by factors or conditions present in the cytoplasm of healthy, nontransformed cells. This characteristic should reveal more about the cellular interactions of this viral protein as well as further enhance its safety as a potential tumor-specific therapeutic agent.     

Apoptin T108 phosphorylation is not required for its tumor-specific nuclear localization but partially affects its apoptotic activity

Apoptin, a chicken anemia virus-encoded protein, induces apoptosis in human tumor cells but not in normal cells. In addition, Apoptin also exhibits tumor-specific nuclear localization and tumor-specific phosphorylation on threonine 108 (T108). Here, we studied the effects of T108 phosphorylation on the tumor-specific nuclear localization and apoptotic activity of Apoptin. We first showed that a hemagglutinin (HA)-tagged Apoptin, but not the green fluorescent protein-fused Apoptin used in many previous studies, exhibited the same intracellular distribution pattern as native Apoptin. We then made and analyzed an HA-Apoptin mutant with its T108 phosphorylation site abolished. We found that Apoptin T108 phosphorylation is not required for its tumor-specific nuclear localization and abolishing the T108 phosphorylation of Apoptin does affect its apoptotic activity in tumor cells but only partially. Our results support the previous finding that Apoptin contains two distinct apoptosis domains located separately at the N- and C-terminal regions and suggest that the T108 phosphorylation may only be required for the apoptotic activity mediated through the C-terminal apoptosis domain.     

Apoptin: Specific killer of tumor cells?

In the early 1990s it was discovered that the VP3/Apoptin protein encoded by the Chicken Anemia virus (CAV) possesses an inherent ability to specifically kill cancer cells. Apoptin was found to be located in the cytoplasm of normal cells while in tumor cells it was localized mainly in the nucleus.¹ These differences in the localization pattern were suggested to be the main mechanism by which normal cells show resistance to Apoptin-mediated cell killing. Although the mechanism of action of Apoptin is presently unknown, it seems to function by the induction of programmed cell death (PCD) after translocation from the cytoplasm to the nucleus and arresting the cell cycle at G₂/M, possibly by interfering with the cyclosome.² In addition, cancer specific phosphorylation of Threonine residue 108 has been suggested to be important for Apoptin’s function to kill tumor cells.³ In contrast to the large number of publications reporting that nuclear localization, induction of PCD and phosphorylation of Apoptin is restricted to cancer cells, several recent studies have shown that Apoptin has the ability to migrate to the nucleus and induce PCD in some of the normal cell lines tested. There is evidence that high protein expression levels as well as the cellular growth rate may influence Apoptin’s ability to specifically kill tumor cells. Thus far both in vitro and in vivo studies indicate that Apoptin is a powerful apoptosis inducing protein with a promising prospective utility in cancer therapy. However, here we show that several recent findings contradict some of the earlier results on the tumor specificity of Apoptin, thus creating some controversy in the field. The aim of this article is to review the available data, some published and some unpublished, which either agree or contradict the reported “black and white” tumor cell specificity of Apoptin. Understanding what factors appear to influence its function should help to develop Apoptin into a potent anti-cancer agent.     

Interaction with Ppil3 leads to the cytoplasmic localization of Apoptin in tumor cells

Apoptin, a small protein encoded by chicken anemia virus (CAV), induces cell death specifically in cancer cells. In normal cells, Apoptin remains in the cytoplasm; whereas in cancerous cells, it migrates into the nucleus and kills the cell. Cellular localization appears to be crucial. Through a yeast two-hybrid screen, we identified human Peptidyl-prolyl isomerase-like 3 (Ppil3) as one of the Apoptin-associated proteins. Ppil3 could bind Apoptin directly, and held Apoptin in cytoplasm even in tumor cells. We then demonstrated that the nuclearcytoplasmic distribution of Apoptin is related to the expression level of intrinsic Ppil3. Moreover, extrinsic modifying of Ppil3 levels also resulted in nuclearcytoplasmic shuffling of Apoptin. The Apoptin P109A mutant, located between the putative nuclear localization and export signals, could significantly impair the function of Ppil3. Our results suggest a new direction for the localization mechanism study of Apoptin in cells.     

A tumor-specific kinase activity regulates the viral death protein Apoptin

Apoptin, a chicken anemia virus-encoded protein, is thought to be activated by a general tumor-specific pathway, because it induces apoptosis in a large number of human tumor or transformed cells but not in their normal, healthy counterparts. Here, we show that Apoptin is phosphorylated robustly both in vitro and in vivo in tumor cells but negligibly in normal cells, and we map the site to threonine 108. A gain-of-function point mutation (T108E) conferred upon Apoptin the ability to accumulate in the nucleus and kill normal cells, implying that phosphorylation is a key regulator of the tumor-specific properties of Apoptin. An activity that could phosphorylate Apoptin on threonine 108 was found specifically in tumor and transformed cells from a variety of tissue origins, suggesting that activation of this kinase is generally associated with the cancerous or pre-cancerous state. Moreover, analyses of human tissue samples confirm that Apoptin kinase activity is detectable in primary malignancies but not in tissue derived from healthy individuals. Taken together, our results support a model whereby the dysregulation of the cellular pathway leading to the phosphorylation of Apoptin contributes to human tumorigenesis.     

DNA damage response signaling triggers nuclear localization of the chicken anemia virus protein Apoptin

The chicken anemia virus (CAV) protein Apoptin is a small, 13.6-kDa protein that has the intriguing activity of inducing G(2)/M arrest and apoptosis specifically in cancer cells by a mechanism that is independent of p53. The activity of Apoptin is regulated at the level of localization. Whereas Apoptin is cytoplasmic in primary cells and does not affect cell growth, in transformed cells it localizes to the nucleus, where it induces apoptosis. The properties of cancer cells that are responsible for activating the proapoptotic activities of Apoptin remain unclear. In the current study, we show that DNA damage response (DDR) signaling is required to induce Apoptin nuclear localization in primary cells. Induction of DNA damage in combination with Apoptin expression was able to induce apoptosis in primary cells. Conversely, chemical or RNA interference (RNAi) inhibition of DDR signaling by ATM and DNA-dependent protein kinase (DNA-PK) was sufficient to cause Apoptin to localize in the cytoplasm of transformed cells. Furthermore, the nucleocytoplasmic shuttling activity of Apoptin is required for DDR-induced changes in localization. Interestingly, nuclear localization of Apoptin in primary cells was able to inhibit the formation of DNA damage foci containing 53BP1. Apoptin has been shown to bind and inhibit the anaphase-promoting complex/cyclosome (APC/C). We observe that Apoptin is able to inhibit formation of DNA damage foci by targeting the APC/C-associated factor MDC1 for degradation. We suggest that these results may point to a novel mechanism of DDR inhibition during viral infection.     

A putative NES mediates cytoplasmic localization of Apoptin in normal cells

Chicken anemia virus (CAV) is a small non-envelopedvirus containing a single-stranded circular DNA genome.The virus causes a disease in the newborn chickens, whichis characterized by generalized lymphoid atrophy, increasedmortality and severe anemia. CAV …     

A critical role of heat shock cognate protein 70 in Apoptin-induced phosphorylation of Akt

Apoptin, a protein from chicken anemia virus, selectively induces apoptosis of transformed or tumor cells, but not in normal cells. However, the mechanism of action of Apoptin is still not well understood. Using yeast two-hybrid and immunoprecipitation approaches, we found that Apoptin interacted with Heat shock cognate protein 70 (Hsc70). In vivo, Apoptin induced the translocation of endogenous Hsc70 from the cytoplasm to the nucleus, and both were co-localized in the nucleus. In addition, Apoptin induced Akt phosphorylation, which was markedly inhibited by Hsc70 knockdown, suggesting that Hsc70 may play a critical role in Apoptin-induced Akt phosphorylation. These findings help to further understand the molecular mechanism of Apoptin.     

TAT-凋亡素融合蛋白的表达及其抗肿瘤活性

凋亡素(apoptin)由鸡贫血病毒vp3基因编码,能特异地诱导肿瘤细胞凋亡而对正常细胞 没有毒性,为了获得可转导入细胞内部的凋亡素,将人工合成的编码TAT蛋白转导结构域的DNA片段与凋亡素编码基因克隆入质粒pET-28a内,构建出表达融合蛋白TAT-apoptin的原核表达载体pET-28a-TAT-apoptin.在大肠杆菌Rosetta（DE3）中表达融合蛋白,利用IDA -Ni2+ 亲和柱纯化,葡聚糖凝胶G 25除去尿素后得到可溶的变性蛋白.纯化后的TAT apoptin加入体外培养的人脐静脉内皮细胞(HUVECs)和人肺癌Anip973细胞,对照组加入TAT-麦芽糖结合蛋白（TAT-MBP）. 经免疫组化检测,转导1 h后TAT-MBP分布于以上两种细胞的胞浆和胞核,TAT-apoptin则主要分布于2种细胞的胞浆内,转导24 h后TAT-MBP的亚细胞定位没有变化,TAT-apoptin分别定位于HUVECs的胞浆和Anip973的胞核中.脱氧核糖核苷酸末端转移酶介导的缺口末端标记法（TUNEL）显示转导48 h后,TAT-MBP处理过的 HUVECs和Anip973细胞、TAT-apoptin处理过的HUVECs没有明显改变,而TAT-apoptin处理过的Anip973细胞大量凋亡.以上结果表明TAT apoptin融合蛋白在肿瘤治疗上有潜在的应用价值.     

Apoptin nucleocytoplasmic shuttling is required for cell type-specific localization, apoptosis, and recruitment of the anaphase-promoting complex/cyclosome to PML bodies

The chicken anemia virus protein Apoptin selectively induces apoptosis in transformed cells while leaving normal cells intact. This selectivity is thought to be largely due to cell type-specific localization: Apoptin is cytoplasmic in primary cells and nuclear in transformed cells. The basis of Apoptin cell type-specific localization and activity remains to be determined. Here we show that Apoptin is a nucleocytoplasmic shuttling protein whose localization is mediated by an N-terminal nuclear export signal (NES) and a C-terminal nuclear localization signal (NLS). Both signals are required for cell type-specific localization, since Apoptin fragments containing either the NES or the NLS fail to differentially localize in transformed and primary cells. Significantly, cell type-specific localization can be conferred in trans by coexpression of the two separate fragments, which interact through an Apoptin multimerization domain. We have previously shown that Apoptin interacts with the APC1 subunit of the anaphase-promoting complex/cyclosome (APC/C), resulting in G(2)/M cell cycle arrest and apoptosis in transformed cells. We found that the nucleocytoplasmic shuttling activity is critical for efficient APC1 association and induction of apoptosis in transformed cells. Interestingly, both Apoptin multimerization and APC1 interaction are mediated by domains that overlap with the NES and NLS sequences, respectively. Apoptin expression in transformed cells induces the formation of PML nuclear bodies and recruits APC/C to these subnuclear structures. Our results reveal a mechanism for the selective killing of transformed cells by Apoptin.     

Apoptin®-induced apoptosis: a review

Apoptin, a protein encoded by an avian virus, induces apoptosis in various cultured human tumorigenic and/ or transformed cell lines, e.g. derived from breast and lung tumor, leukemia, lymphoma, osteosarcoma melanoma, cholangiocarcinoma, and hepatoma. In such cells, Apoptin induces p53-independent apoptosis, and the proto-oncogene Bcl-2 can accelerate this effect. The latter is surprising for, in general, Bcl-2 is known to inhibit e.g., p53-induced apoptosis. On the other hand, in normal non-transformed human cells, Apoptin is unable to induce apoptosis, even when Bcl-2 is over-expressed. In animal models Apoptin-induced apoptosis appears to be a safe and efficient anti-tumor agent. These data, in continuation with the observations that Apoptin is specifically stimulated by Bcl-2 in tumor cells, does not need p53, and is not inhibited by Bcr-Abl in these cells, imply that Apoptin is a potential anti-tumor therapy.     

Activation of the tumor-specific death effector apoptin and its kinase by an N-terminal determinant of simian virus 40 large T antigen

Apoptin, a viral death protein derived from chicken anemia virus, displays a number of tumor-specific behaviors. In particular, apoptin is phosphorylated, translocates to the nucleus, and induces apoptosis specifically in tumor or transformed cells, whereas it is nonphosphorylated and remains primarily inactive in the cytoplasm of nontransformed normal cells. Here, we show that in normal cells apoptin can also be activated by the transient transforming signals conferred by ectopically expressed simian virus 40 (SV40) large T antigen (LT), which rapidly induces apoptin's phosphorylation, nuclear accumulation, and the ability to induce apoptosis. Further analyses with mutants of LT showed that the minimum domain capable of inducing all three of apoptin's tumor-specific properties resided in the N-terminal J domain, a sequence which is largely shared by SV40 small t antigen (st). Interestingly, the J domain in st, which lacks its own nuclear localization signal (NLS), required nuclear localization to activate apoptin. These results reveal the existence of a cellular pathway shared by conditions of transient transformation and the stable cancerous or precancerous state, and they support a model whereby a transient transforming signal confers on apoptin both the upstream activity of phosphorylation and the downstream activity of nuclear accumulation and apoptosis induction. Such a pathway may reflect a general lesion contributing to human cancers.     

The chicken anemia virus-derived protein apoptin requires activation of caspases for induction of apoptosis in human tumor cells

The chicken anemia virus protein Apoptin has been shown to induce apoptosis in a large number of transformed and tumor cell lines, but not in primary cells. Whereas many other apoptotic stimuli (e.g., many chemotherapeutic agents and radiation) require functional p53 and are inhibited by Bcl-2, Apoptin acts independently of p53, and its activity is enhanced by Bcl-2. Here we study the involvement of caspases, an important component of the apoptotic machinery present in mammalian cells. Using a specific antibody, active caspase-3 was detected in cells expressing Apoptin and undergoing apoptosis. Although Apoptin activity was not affected by CrmA, p35 did inhibit Apoptin-induced apoptosis, as determined by nuclear morphology. Cells expressing both Apoptin and p35 showed only a slight change in nuclear morphology. However, in most of these cells, cytochrome c is still released and the mitochondria are not stained by CMX-Ros, indicating a drop in mitochondrial membrane potential. These results imply that although the final apoptotic events are blocked by p35, parts of the upstream apoptotic pathway that affect mitochondria are already activated by Apoptin. Taken together, these data show that the viral protein Apoptin employs cellular apoptotic factors for induction of apoptosis. Although activation of upstream caspases is not required, activation of caspase-3 and possibly also other downstream caspases is essential for rapid Apoptin-induced apoptosis.     

Comparison of Enterococcus quantitative polymerase chain reaction analysis results from fresh and marine waters on two real-time instruments

Apoptin, a protein derived from chicken anemia virus (CAV), induces apoptosis selectively in human tumor cells as compared with normal cells. This activity depends on phosphorylation and relocation of apoptin to the nucleus of cancer cells. Here, we describe an in vitro kinase assay that allows the biochemical characterization of apoptin kinase activity in tumor cells. The kinase phosphorylates apoptin in a strictly ATP-dependent fashion and in a broad salt range. The kinase activity is present constitutively in both cytoplasm and nucleus of various human tumor cells. Q-column chromatography showed that both cytoplasmic and nuclear fractions have identical fractionation characteristics, suggesting that the same kinase is present in both cellular compartments. Kinase activity derived from positive Q-column fractions bound to amylose-maltose-binding protein (MBP)-apoptin and could be eluted with ATP only in the presence of the cofactor Mg(2+). Apparently, unphosphorylated apoptin interacts with the kinase and is released only after phosphorylation has occurred, proving that our assay recognizes the genuine apoptin kinase. This is further corroborated by the finding that apoptin is phosphorylated in vitro at positions Thr108 and Thr107, in concert with earlier in vivo observations. Our assay excludes cyclin-dependent kinase 2 (CDK2) and protein kinase C beta (PKC-β), previously nominated by two separate studies as being the genuine apoptin kinase.     

双组分核定位信号介导Apoptin定位于肿瘤细胞核

Apoptin是一种来源于鸡贫血病毒的小蛋白,在肿瘤细胞中定位于细胞核,而在正常细胞中主要分布于细胞质。根据预测,Apoptin分子中有2段序列(NLS1和NLS2)可能是单组分核定位信号。通过基因突变和缺失构建了Apoptin各种不同的核定位信号突变体和磷酸化突变体,利用增强型绿色荧光蛋白(EGFP)作标签,观察了其在肿瘤细胞中亚细胞定位的变化。结果表明,NLS1和NLS2单独均不是有效的单组分核定位信号。Apoptin的核定位信号是由NLS1和NLS2这2段序列共同组成的双组分核定位信号,缺少任何一段序列都会严重影响Apoptin在肿瘤细胞中的核定位。其中,NLS2对于Apoptin的核定位起主要作用。Apoptin的获得型磷酸化突变体并不能转位到正常细胞的细胞核中,而其磷酸化负突变体仍定位于肿瘤细胞的细胞核。另外,丝氨酸／苏氨酸蛋白激酶抑制剂H7也不影响Apoptin在肿瘤细胞中的核定位。很可能,Apoptin的磷酸化并不参与调控其核定位信号的功能。     

Apoptin induces tumor-specific apoptosis as a globular multimer

The chicken anemia virus-derived Apoptin protein induces tumor-specific apoptosis. Here, we show that recombinant Apoptin protein spontaneously forms non-covalent globular aggregates comprising 30 to 40 subunits in vitro. This multimerization is robust and virtually irreversible, and the globular aggregates are also stable in cell extracts, suggesting that they remain intact within the cell. Furthermore, studies of Apoptin expressed in living cells confirm that Apoptin indeed exists in large complexes in vivo. We map the structural motifs responsible for multimerization in vitro and aggregation in vivo to the N-terminal half of the protein. Moreover, we show that covalently fixing the Apoptin monomers within the recombinant protein multimer by internal cross-linking does not affect the biological activity of Apoptin, as these fixed aggregates exhibit similar tumor-specific localization and apoptosis-inducing properties as non-cross-linked Apoptin. Taken together, our results imply that recombinant Apoptin protein is a multimer when inducing apoptosis, and we propose that this multimeric state is an essential feature of its ability to do so. Finally, we determine that Apoptin adopts little, if any, regular secondary structure within the aggregates. This surprising result would classify Apoptin as the first protein for which, rather than the formation of a well defined tertiary and quaternary structure, semi-random aggregation is sufficient for activity.     

Apoptin® specifically causes apoptosis in tumor cells and after UV-treatment in untransformed cells from cancer-prone individuals: A review

Tumor formation is caused by an imbalance between cell replication and apoptosis, which is a physiological form of cell death. For instance, UV damage can result in tumor formation due to mutations of the tumor-suppressor gene p53, a major apoptosis-inducing protein. Over-expression of the proto-oncogene Bcl-2, due to chromosomal translocation, can also inhibit apoptosis resulting in, e.g., lymphomas and leukemias. Anti-tumor therapies are often based on induction of apoptosis mediated via p53 and/or inhibited by Bcl-2, which explains the frequently poor results of anti-tumor treatment. The avian-virus-derived protein ‘Apoptin’, induces apoptosis in a p53-independent way, is stimulated by Bcl-2 and is insensitive to BCR-ABL, another inhibitor of chemotherapeutic agents. Apoptin induces apoptosis in human transformed/tumorigenic cells but not in normal diploid cells. Co-synthesis of SV40 large T antigen and Apoptin results in induction of apoptosis, illustrating that the establishment of a stable transformed state is not required. UV-irradiation causes an aberrant SOS-response in primary diploid cells from cancer-prone individuals and renders such cells susceptible to Apoptin-induced apoptosis. All these features make Apoptin a potential candidate as a therapeutic and diagnostic tool in cancer treatment.