Survivin: a unique target for tumor therapy

Due to important role of Survivin in tumor cell division, apoptosis, chemo resistance and cancer stem cell survival; therapeutic blockade of Survivin in tumor cells may possibly yield cumulative benefits. Various strategies have been envisaged to block the expression or function of Survivin in tumour cells (i) immunotherapeutic approaches to induce immune response against Survivin, (ii) small molecule inhibitors/antagonists to block function of Survivin, (iii) nucleic acid based approaches which interfere with Survivin gene expression or (iv) gene ablation of Survivin to regulate cell cycle and apoptosis.

Manipulation of host immune system to produce an anti-tumour response is known as immunotherapy. This concept was first pioneered by William Coley (1891) who used extracts of S. pyogenes and heat-killed Bacillus prodigious (now reclassified as Serratia marcecsens) bacteria to treat sarcomas [81]. Coley’s experiments established that immune stimulatory components present in “Coley’s toxins” boosted anti-tumor immune response and induced disease remission in cancer. Coley’s experimental results were widely criticized and concept of immunotherapy was totally dismissed as an effective strategy to control cancer. Alternative treatment modalities in cancer like chemotherapy and radiotherapy which had been well developed by that time presented with drawbacks of inducing disease resurgence and toxicity. Simultaneously, with better understanding of principles of immunology, it was apparent that immune system had a crucial role in controlling certain types of cancer. As various principles of immunology were being unravelled, it became clear that immunotherapy is a better therapeutic option as compared to chemotherapy or radiotherapy because it is specific for tumor cells and is devoid of side effects.

Immunotherapy eliminates tumor cells by initiating/boosting anti-tumor immune response or reversing inhibitory immune signalling. Active immunotherapy involves development of a targeted anti-tumor immune response in the host using specific cancer antigens or ex vivo expansion of effector cells and infusion back into the patient. Passive immunotherapy covers transfer of preformed molecules such as therapeutic antibodies or antigen specific T cells which can eliminate or suppress tumor. A number of monoclonal antibodies against growth factor receptors or antigenic determinants on cancer cells have been successfully translated for therapeutic usage in various cancers. Recent success of antibodies targeting inhibitory immune checkpoints such as CTLA-4 and PD-1 has again shifted the focus on inhibitory molecules in immune cell signalling for a beneficial anti-tumor response [82]. Although, diverse approaches for therapeutic cancer vaccines have shown good immunogenicity in clinical trials yet clinical translation of antigen specific cancer vaccines has not been as successful as passive immunotherapy. The rationale for cancer vaccine is to target a specific tumor antigen as vaccine candidate, induce robust antigen presentation mostly through DCs and induction of cytotoxic T cell (CTL) response. Tumor antigens are processed into peptides, loaded onto MHC molecules and MHC-peptide complex is presented by antigen presenting cells (APCs) to T cells for activation. Induction of effector T cell response is sequential; antigen specific T cells are first primed in the secondary lymphoid organs through the interaction with APC. APCs particularly dendritic cells (DC) sample antigens from tumor cells and present antigens to CD4+ T cells via the MHC class-II pathway or to CD8+ T-cells via cross presentation or cross priming [83, 84]. This antigen recognition in association with MHC is insufficient to effectively activate T cells; APC provide additional co-signals that regulate the breadth of T cell activation. These multiple co-signals can be induced by stimulatory (CD80/CD86:CD28) and inhibitory molecules also known as “Immune checkpoints” [85, 86]. Antigen specific T cells once primed by APCs will scan for cognate MHC-peptide on target tumor cells and execute lysis of target cells. Immunotherapy using specific cancer antigens serves to expand the population of antigen specific T cells so that immune escape of tumor is prevented (Fig. 3). The vaccine strategies employ either peptides or whole recombinant protein in adjuvant, recombinant viruses encoding the antigen of interest or other recombinant microorganisms, DNA vaccines, cytokine or co-stimulation enhanced vaccines, killed tumor cells, or DCs pulsed with protein-or peptide. Incorporating a strong adjuvant enhances tumor antigen presentation and activation of immune effector mechanisms leading to induction of a robust CTL response against tumor cells.

An ideal cancer vaccine should use an antigen which is specific and overexpressed on tumor cells. Survivin has emerged as an ideal antigen for cancer immunotherapy because of tumour specific expression and critical role in regulating cell division and apoptosis of tumour cells. [87‐89]. Human transcriptome analysis reveals that Survivin is the fourth most highly expressed transcript in human cancer cells when compared to normal cells [90]. Overexpression of Survivin has been associated with an unfavourable prognosis in colorectal and bladder cancers and neuroblastoma [91, 92], melanoma and non-melanoma skin cancers [93, 94]. Survivin overexpression also induces an increased chemotherapeutic drug resistance as discussed earlier in the review. Survivin expression confers a survival advantage on tumour cells and can be a universal therapeutic and diagnostic target for all tumours.

Survivin protein has been shown to induce CTL response in vitro when processed and presented by dendritic cells [95] and Survivin derived peptides prime CTLs in vivo in murine model of melanoma [96]. Generation of Survivin specific CTLs that can lyse HLA matched tumour target cells has been demonstrated in cancer patients [97]. Presence of spontaneous CTL response against MHC-I restricted peptide antigens derived from Survivin in patients suffering from melanoma, breast cancer and leukemia strongly indicates that CD8 T cell restricted epitopes from Survivin are of substantial immunotherapeutic value [98‐100]. Induction of effective CTL response was also coupled with homing of Survivin specific CTLs to the site of tumour in situ in melanoma and breast cancer [101] representing a complete synchronization of both local and systemic immune response when using Survivin as a vaccine candidate.

Vaccine approaches such as dendritic cell based (DC) vaccines, DNA vaccines [102], peptide vaccines or VLP based vaccine for Survivin have also been evaluated in preclinical or clinical studies. A DC vaccine trial conducted on non-small cell lung carcinoma (NSCLC) patients who received autologous DCs pulsed with apoptotic bodies of NSCLC showed immunological responses in 4/7 stage III unresectable, and 6/7 stage I/II surgically resected patients [103]. Another vaccine for HLA-A24 positive patients was developed by immunizing HLA-A24 restricted Survivin peptide 2B80–88 which induced peptide specific CTL response in urothelial [104], oral [105], colorectal [106] and breast cancer [107] patients with no adverse effects. In another study, same peptide was combined with IFN alpha and immunised in urothelial cancer patients but had no better results as compared to peptide alone [108]. The peptide alone had low immunogenicity and the investigators concluded that combining the peptide with adjuvants such as heat shock proteins, cytokines etc. may boost immune response to the peptide [107]. A combination of HLA restricted Survivin peptides has also been tested in a phase II trial on metastatic melanoma patients who showed prolonged survival post treatment [109]. A multi-epitope vaccine approach using cocktail of five Survivin peptides: EMD640744 and Montanide(^®) ISA 51 VG as an adjuvant resulted in anti-Survivin specific T cell responses in patients with solid cancers [110]. A liposome based formulation of Survivin known as DPX-Survivac has also shown to induce Survivin specific immune response in patients with ovarian cancer [111].

Although CTL responses are critical for elimination of tumour cells, role of CD4 T cells and antibodies is also important in modulating anti-tumour immune responses [112]. A number of studies have also shown the important role of CD4 T cells acting as crucial helper cells to boost CTL function and enhance anti-Survivin immune response [113, 114]. Presence of HLA-class II epitopes to stimulate T helper cell response has been demonstrated in Survivin peptides [115, 116]. Sharma et al. have demonstrated an indispensable role of CD4 T cells in sustaining primary and memory anti-tumour immune response in a vaccine formulation containing Survivin evaluated in a transplantable murine model [117]. Importantly, CD4 T cells were crucial in the priming phase of CTLs but not during the effector phase of CTL response. In another important study by Hoffmann et al. recombinant fowl pox virus encoding Survivin derived class I (H1vax1) and class II (H1vax2) derived peptides were designed and evaluated for preclinical efficacy in co-culture experiments using dendritic cells and T cells isolated from healthy donors. These vaccine constructs showed activation of both antigen specific CD4 and CD8 T cells and cytotoxic activity against Survivin-overexpressing mesothelioma cancer cells [118]. Table 1 summarizes the key conclusions obtained from various Survivin vaccines evaluated in preclinical studies or clinical trials. Preclinical studies with Survivin as vaccine candidate indicate induction of an effective anti-tumor response in animal models of solid or haematological malignancies and support the notion that Survivin is immunogenic in humans. However, the immunogenicity may be low enough to provide protection against tumor cells, therefore antigen delivery and role of adjuvants is important to enhance immunogenicity of this protein Furthermore, both CD4 and CD8 restricted epitopes from Survivin protein are important for induction of effective anti-tumour immune response.

We have also evaluated full length recombinant Survivin protein as a vaccine candidate with Mycobacterium indicus pranii (MIP) as an adjuvant in 4T-1 mouse model of breast cancer. MIP has been shown to act as an excellent immune-modulator in animal models for psoriasis, lung cancer and exercises anti-tumor action against Sp2/0 (myeloma) and EL4 (thymoma) in mice models [119]. Subcutaneous administration of MIP-Survivin generated a tumour protective response and tumour regression in 4T-1 model of breast cancer in a dose dependent manner. MIP as an adjuvant was able to induce a good anti-Survivin antibody titre after immunization with recombinant murine Survivin protein. MIP also has been shown to induce DC activation and enhance antigen presentation [120]. Therefore, we propose that combining full length recombinant Survivin with MIP may generate epitopes which can activate both Survivin specific CD8 and CD4 T cells and induce an effective cell mediated immune response. In addition to mediating a direct cell mediated attack of tumour cells, immunization with recombinant Survivin in mice also elicited production of anti-Survivin antibodies. Pre-existing titre of anti Survivin antibodies in Balb/c mice immunized with recombinant Survivin may also have a role in mediating tumour regression in these mice when transplanted with syngeneic 4T-1 cells. Our data suggests that a combination of Survivin and MIP may potentiate anti-tumour immune response (Garg et al. Manuscript under preparation).

There is limited data on therapeutic efficacy of antibodies against intracellular antigens; however a study from Guo et al. indicates that intracellular antigens can also be targeted by antibodies, thereby widening the scope of targeting both extracellular and intracellular tumour antigens by antibody immunotherapy [121‐123]. While direct evidence for role of anti-Survivin antibodies in inducing therapeutic response is lacking, it is possible that induction of anti-Survivin antibodies after antigen immunization may block the overexpression of Survivin on cancer cells or inhibit Survivin expressed on exosomes. Antibodies against Survivin may also promote NK cell lysis of tumor cells. Spontaneous humoral response against Survivin has also been observed in sera of patients of lung, gastrointestinal and colorectal cancer [124]. Importantly, immune response against Survivin (T cell specific or antibodies) was absent in healthy individuals [97, 124] implying that immune response elicited after Survivin vaccination is tumour specific and devoid of autoimmune manifestations. Detailed studies will be required to investigate the effect of Survivin immunization on function of immune effector cells as Survivin has important regulatory role in T cell and B cell effector responses.

Several small molecule inhibitors targeting Survivin have also been evaluated in various in vitro and in vivo studies. Despite the challenges associated with small molecule drug development, these inhibitors are important for understanding Survivin biology and anti-cancer drug development [134, 135]. YM-155 is a novel small molecule which suppresses transactivation of Survivin through direct binding to its promoter [136]. It selectively suppresses expression of Survivin and induces apoptosis in p53-deficient cancer cells in vitro [136].YM155 has also shown to be effective in in vivo models of prostate, pancreatic, and lung cancer [136‐138]. Terameprocol (EM-1421), a plant derived small molecule is a novel transcription inhibitor which suppresses Survivin gene expression and induces apoptosis of cancer cells [139]. It is in Phase II safety studies as a vaginal ointment in HPV-linked cervical intraepithelial neoplasia [140]. GDP366 is a novel small molecule compound which potently and selectively inhibited the expression of both Survivin and Op18; an onco-protein [141]. Another small molecule Survivin inhibitor FL118 exhibited superior antitumor efficacy in human tumor xenograft models in comparison to standard anti-cancer drugs [142]. Anti-sense approaches to block Survivin have also been tested. LY2181308, a novel 2′-O-methoxymethyl modified anti-sense oligonucleotide (2-MOE-ASO), is a specific inhibitor of Survivin mRNA and being investigated for efficacy in clinical trials in various groups of cancer patients [143]. Ribozyme mediated approaches have also been evaluated for inhibition of Survivin expression. Down-regulation of human Survivin gene expression and increased apoptosis was achieved by using two hammerhead ribozymes (RZ-1, RZ-2) targeting human Survivin mRNA [144]. Specific Survivin small interfering RNA (siRNA) also inhibited Survivin expression in HL-60 cells and augmented ability of HL-60 cells to overcome drug resistance [145]. siRNA aimed at blocking Survivin-hsp90 connection have also shown anti-cancer effects in androgen independent prostate cancer models [146]. Adenovirus delivered Survivin dominant negative mutants (double point mutant (TC34, 84AA) mediated hepatocellular carcinoma suppression [147]. Another dominant negative mutant (GST-tagged dominant-negative Survivin protein (dNSurR9-C84A) constructed by mutation of Cys84 to Ala in the extreme C-terminal region of the BIR domain of Survivin completely abrogated Survivin’s ability to inhibit apoptosis in cancer cell lines [148]. Almost all small molecule inhibitors of Survivin have been designed based on protein- protein interactions between Survivin and other partner proteins. Since Survivin functions through multiple mechanisms using a variety of partner proteins, blocking one pathway may not entirely lead to reduction of Survivin signalling. Substantial evidence exists in cancer cells for compensatory proliferative mechanisms to override when one signalling pathway is inhibited.

Small molecules are cost effective and have short development time as compared to immunotherapeutic approaches. Therefore, there is enough reasoning to discover and improve existing small molecule inhibitors of Survivin. Immunotherapy approaches, although complex in terms of translational development, are specific and have long lasting effects. However, tumor adaption and immune evasion is one bottleneck to success of immunotherapy strategies. Moreover, either small molecule or immunotherapy targeting Survivin alone has not demonstrated a completely curative response therefore a synergistic combination of small molecules with immunotherapy may be explored to induce and sustain tumor elimination over a course of time.