GnRH-Bik/Bax/Bak chimeric proteins target and kill adenocarcinoma cells; the general use of pro-apoptotic proteins of the Bcl-2 family as novel killing components of targeting chimeric proteins

Design and characterization of a recombinant immunotoxin for targeted therapy of breast cancer cells: In vitro and in silico analyses

AIMS

GnRH-DFF40 (gonadotropin releasing hormone-DNA fragmentation factor 40) humanized recombinant immunotoxin serves as a prospective candidate for targeted therapy of malignancies with over-expressed gonadotropin releasing hormone receptor (GnRHR). In this study, we attempted to generate a GnRH-based chimeric protein composed of human DFF40 fused with GnRH which encodes an apoptotic nuclease and specifically targets cancer cells displaying GnRH receptor overexpression.

MATERIALS AND METHODS

A codon optimized, synthetic GnRH-DFF40 fusion gene and its single counterpart (DFF40) were constructed in pET28a expression vector. Cytotoxicity of these expressed proteins were evaluated on three breast cancer cell lines (MCF7, MDA-MB231, and SKBR3). The stability and biological activity of the recombinant proteins were investigated in the treated cell line and cell-free system. Also, the ability of this fusion and its single form in inducing apoptosis, and inhibiting metastasis and migration were evaluated by flow cytometry, migration assay and wound healing analysis, respectively. In silico analyses were also done to understand the specific interactions between GnRH and its receptor.

KEY FINDINGS

GnRH-DFF40 fusion protein and DFF40 were successfully expressed. The purified chimeric protein showed dose-dependent cytotoxicity against all three cell lines. The recombinant fusion protein was biologically active with nucleolytic functionality and apoptosis induction ability. Moreover, the fusion could inhibit the invasion property of MDA-MB-231 cells. In silico analysis also showed that four residues from GnRH domain and 11 GnRHR residues had the most interaction sites for specific targeted delivery of the immunotoxin in cancer cells.

SIGNIFICANCE

Fusion construct could be a prospective candidate for targeted therapy of cancers upregulating GnRH receptor.

Protein-Based Therapeutic Killing for Cancer Therapies

The treatment of some high-incidence human diseases is based on therapeutic cell killing. In cancer this is mainly achieved by chemical drugs that are systemically administered to reach effective toxic doses. As an innovative alternative, cytotoxic proteins identified in nature can be adapted as precise therapeutic agents. For example, individual toxins and venom components, proapoptotic factors, and antimicrobial peptides from bacteria, animals, plants, and humans have been engineered as highly potent drugs. In addition to the intrinsic cytotoxic activities of these constructs, their biological fabrication by DNA recombination allows the recruitment, in single pharmacological entities, of diverse functions of clinical interest such as specific cell-surface receptor binding, self-activation, and self-assembling as nanoparticulate materials, with wide applicability in cell-targeted oncotherapy and theragnosis.

Improving the therapeutic potential of endostatin by fusing it with the BAX BH3 death domain

Endostatin (ES) inhibits angiogenesis, reducing tumor growth in animal models. However, it has low therapeutic effect in human clinical trials. BAX is a member of the BCL-2 family of proteins; its proapoptotic (BH3) domain interacts with other members of the family in the cytoplasm, to induce apoptosis. Here, we fused the BAX BH3 domain with murine ES, to enhance ES potency. Endothelial cells specifically internalize the fusion protein ES-BAX. The presence of the BAX domain enhances endothelial cell death by apoptosis by 1.8-fold and diminishes microvessel outgrowth in the rat aortic ring assay by 6.5-fold. Daily injections of 15 μg of ES-BAX/g in tumor-bearing mice reduce tumor weight by 86.9% as compared with ES-treated animals. Co-immunoprecipitation assays confirmed that ES-BAX interacts with members of the BCL-2 family. Also, ES interacts with BCL-2, BCL-X_L, and BAK in endothelial cell lysates, suggesting a potential new mechanism for the apoptosis induction by ES. The superiority of the ES-BAX antiangiogenic effect indicates that this fusion protein could be a promising therapeutic alternative to treat cancer.

Targeted cancer therapy with gonadotropin-releasing hormone chimeric proteins

Tumor-associated antigens (TAAs) have been identified mainly to determine cancer prognosis. In the past few years, TAAs have been used in the development of treatment modalities such as tumor vaccination. This review describes an additional application of TAAs: as a target for specific antitumor treatment. Since TAAs are overexpressed on the tumor cell surface, they can be targeted to deliver drugs directly to cancer cells. One such delivery system exploits chimeric proteins. Chimeric proteins are a class of targeted molecules designed to recognize and specifically destroy cells that overexpress specific receptors. These molecules, designed and constructed by gene fusion techniques, comprise both cell-targeting and cell-killing moieties. The authors' laboratory has developed a number of chimeric proteins using gonadotropin-releasing hormone (GnRH) as the targeting moiety. These chimeras recognize a GnRH binding site that is expressed on adenocarcinoma cells. GnRH was fused to a large number of killing moieties, including bacterial and human proapoptotic proteins. All GnRH-based chimeric proteins selectively killed adenocarcinoma cells both in vitro and in vivo. Utilizing chimeric proteins for targeted therapy represents a new and exciting therapeutic modality for the treatment of cancer in humans.

Eliminating the six N-terminal amino acids of the caspase 3 large subunit improved production of a biologically active IL2-Caspase3 chimeric protein

Designing a chimeric protein and developing a procedure for its stable production as a biologically active protein, are key steps in its potential application to clinical trails. IL2-Caspase3 chimeric protein designed to target activated T lymphocytes was found to be a promising molecule for targeted treatment, however was found to be difficult to produce as a biological active molecule. Thus, we designed a new version of the molecule, IL2-Caspase3s, in which six amino acids (aa 29-34) from the N-terminus of the large subunit of caspase 3 were excluded. Repeated expressions, productions, and partial purifications of the IL2-Caspase3s yielded reproducible batches with consistent results. We found that IL2-Caspase3s causes cell death in a specific, dose-, and time-dependent manner. Cell death due to IL2-Caspase3s is caused by apoptosis. This improved and biologically stable IL2-Caspase3s chimeric protein may be developed in the future for clinical trails as a promising therapy for several pathologies involving activated T-cells. Moreover, this truncated caspase 3 sequence, lacking the N-terminal six amino acids of its large subunit, may be used in other caspase 3-based chimeric proteins targeted against various human diseases, using the appropriate targeting moiety.

Human toxin-based recombinant immunotoxins/chimeric proteins as a drug delivery system for targeted treatment of human diseases

INTRODUCTION

The development of specific immunosuppressive reagents remains the major goal in the treatment of human diseases. One such approach is the use of recombinant immunotoxins/chimeric proteins, composed of targeting and killing moieties, fused at the cDNA level. Most of these 'magic bullets' use bacterial or plant toxins to induce cell death. These toxins are extremely potent, but they also cause severe toxicity and systemic side effects that limit the maximal doses given to patients. Moreover, being of non-human origin, they are highly immunogenic, and the resulting neutralizing antibody production impairs their efficacy.

AREAS COVERED

This review describes recombinant immunotoxins/chimeric proteins composed of the classical delivering, cell-targeting molecules, fused to highly cytotoxic human proteins capable of generating an intense apoptotic response within the target cell. This review focuses on the new 'Human Killing Moieties' of these targeted proteins and describes recent progress in the development of these promising molecules.

EXPERT OPINION

Human toxin-based immunotoxins/chimeric proteins for the targeted delivery of drugs are still in their early stages of development. However, they are certain to advance in the very near future to become an extra weapon in the everlasting war against human diseases, mainly cancer.

Humanized immunotoxins: a new generation of immunotoxins for targeted cancer therapy

Chemotherapy, radiation, and surgery are the conventional treatment modalities for cancer. The success achieved with these approaches has been limited due to several factors like chemoresistance to drugs, non-specificity leading to peripheral toxicity, and non-resectable tumors. To combat these problems, the concept of targeted therapy using immunotoxins was developed. Immunotoxins are chimeric proteins with a cell-selective ligand chemically linked or genetically fused to a toxin moiety and can target cancer cells overexpressing tumor-associated antigens, membrane receptors, or carbohydrate antigens. Ligands for these receptors or monoclonal antibodies or single chain variable fragments directed against these antigens are fused with bacterial or plant toxins and are made use of as immunotoxins. Pseudomonas exotoxin, anthrax toxin, and diphtheria toxin are the commonly used bacterial toxins. Ricin, saporin, gelonin, and poke weed antiviral protein are the plant toxins utilized in immunotoxin constructs. Several such fusion proteins are in clinical trials, and denileukin difitox is a FDA-approved fusion protein. In spite of the promise shown by bacterial- and plant toxin-based chimeric proteins, their clinical application is hampered by several factors like immunogenicity of the toxin moiety and non-specific toxicity leading to vascular leak syndrome. In order to overcome these problems, a novel generation of immunotoxins in which the cytotoxic moiety is an endogenous protein of human origin like proapoptotic protein or RNase has been developed. This review summarizes the advances in this new class of fusion protein and the future directions to be explored.

Gi protein-mediated translocation of serine/threonine phosphatase to the plasma membrane and apoptosis of ovarian cancer cell in response to gonadotropin-releasing hormone antagonist cetrorelix

Serine/threonine protein phosphatase 2A (PP2A), a crucial enzyme in apoptosis control, has been demonstrated within the plasma membrane as well as in the soluble fraction. This study aimed to examine hormonal translocation of PP2A to the plasma membrane in gonadotropin-releasing hormone (GnRH)-responsive ovarian cancer cells. Apoptosis of ovarian cancer cell lines Caov-3 and SK-Ov-3 was quantified by nuclear morphology after staining with Hoechst 33342 dye. PP2A protein and activity in plasma membrane were assessed by immunohistochemical staining with PP2A-specific antibodies and by the measurement of the dephosphorylation of phosphopeptide highly selective for the PP2A, respectively. Incubation for 48 h with a GnRH antagonist cetrorelix caused parallel increases in the percentage of cells undergoing apoptosis and the membrane-associated PP2A activity; half-maximal effects occurred with 5 nmol/l cetrorelix. PP2A protein was also localised to the plasma membrane when the cell lines were exposed to cetrorelix. Pretreatment of the cells with pertussis toxin, but not cholera toxin, completely inhibited cetrorelix-stimulated apoptotic cell death and PP2A redistribution. These findings demonstrate that translocation of PP2A to plasma membrane is closely coupled to the onset of apoptosis in ovarian cancer cells exposed to GnRH antagonist. These GnRH-induced cellular events may be mediated through pertussis toxin-sensitive Gi protein-linked GnRH receptor.

The Bik BH3-only protein is induced in estrogen-starved and antiestrogen-exposed breast cancer cells and provokes apoptosis

Evidence has been accumulating that some estrogen-dependent human breast cancers require estrogen for not only proliferation but also survival. To obtain insights into the molecular mechanisms of apoptosis of breast cancer cells subjected to estrogen starvation or exposed to antiestrogens, we characterized changes in the gene expression profile of MCF-7/BUS human breast cancer cells and revealed a strong induction of Bik, a member of the BH3-only proapoptotic proteins. The Bik mRNA transcript and protein were strongly induced by estrogen starvation or exposure to fulvestrant, a pure antiestrogen that competes with the natural estrogens for binding to the estrogen receptors. This Bik induction preceded apoptotic cell death, which was blocked by zVAD-fmk, a pancaspase inhibitor. Amounts of the Bcl-2-related proteins, such as Bcl-2, Bcl-XL, or Bax, showed only marginal changes in the presence or absence of estrogens or antiestrogens. Suppression of Bik expression by using the small interfering RNA effectively blocked the fulvestrant-induced breast cancer cell apoptosis. These results indicate that Bik is induced in MCF-7/BUS cells in the absence of estrogen signaling and plays a critical role in the antiestrogen-provoked breast cancer cell apoptosis.

Utilizing Fcε-Bak chimeric protein for studying IgE–FcεRI interactions

We previously constructed a pro-apoptotic Fcepsilon-Bak chimeric protein, targeted against cells expressing the IgE high affinity receptor (FcepsilonRI). We demonstrated that the chimeric protein is internalized by target mast cells and kills them. These results, which constitute a promising basis for applying this approach to antiallergic therapy, raise some theoretical questions with respect to two major issues: (a) is the monomeric Fcepsilon-Bak-FcepsilonRI complex able to undergo endocytosis, and (b) does the receptor binding domain of human IgE (Fcepsilon) react with rodent FcepsilonRI? In an attempt to answer these questions, we have now thoroughly investigate the interaction of human (h) and mouse (m) Fcepsilon-Bak with FcepsilonRI-positive cells. Using established cultures of rodent and human origin, as well as a primary mouse mast cell culture, we demonstrate that binding of the chimeric protein to the membrane is followed by quick endocytosis, leading to the apoptosis of specific cells. We also confirm that this interaction depends on FcepsilonRI and not on other IgE receptors. We found that the effect of Fcepsilon-Bak on the cells depends on the level of surface FcepsilonRI expression, but not on the origin of the target cells or of the Fcepsilon moiety. We suggest that endocytosis of the monomeric Fcepsilon-Bak-FcepsilonRI complex results from the inability of Fcepsilon-Bak to transduce signals, characteristic of the monomeric IgE-FcepsilonRI complex due to the absence of the variable portion of the IgE molecule. Our results also indicate that at least the Fc fragment of human IgE is able to interact with both human and rodent FcRI.

Mechanism of action of interleukin-2 (IL-2)-Bax, an apoptosis-inducing chimaeric protein targeted against cells expressing the IL-2 receptor

The chimaeric protein interleukin-2 (IL-2)-Bax was designed to target and kill specific cell populations expressing the IL-2 receptor. However, it is not well understood how IL-2-Bax causes target cells to die. In the present study, we investigated the pathway of apoptosis evoked by IL-2-Bax and the possible involvement of endogenous Bax in this process. We report here that, upon internalization of IL-2-Bax into target cells, it is localized first mainly in the nucleus, and only later is it translocated to the mitochondria. Similarly, endogenous Bax is also partially localized in the nucleus, and accumulates mainly in this compartment soon after physiological triggering of apoptosis. Despite the fact that Bax has no nuclear localization sequence, our data suggest that Bax has one or more physiological roles and/or substrates within the nucleus. Indeed, a dramatic repression of nuclear Tax protein expression was induced following treatment of HUT-102 cells with IL-2-Bax, similar to what occurs following serum deprivation of these cells. Unexpectedly, induction of apoptosis using IL-2-Bax was preceded by enhanced expression of newly synthesized Bax protein and suppression of Bcl-2. This imbalance between the pro- and anti-apoptotic genes was associated with p53 induction, although IL-2-Bax activity was also evident in cells lacking p53 expression. By studying the mechanism of action of IL-2-Bax, we were able to follow the intrinsic events and their cascade that culminates in cell death. We have shown that the ability of IL-2-Bax to affect the intracellular apoptotic machinery within the target cells, and to cause the cells to die, uses a mechanism similar to that induced following a normal apoptotic signal.

Utilizing chimeric proteins for exploring the cellular fate of endogenous proteins

We recently designed and constructed chimeric proteins for the elimination of specific cell populations. These chimeric proteins are composed of a targeting component fused to an apoptotic protein as the killing moiety. However, chimeric proteins can serve not only to eliminate cell populations, but also as "biological tools" for studying the fate of endogenous proteins. We show here that upon entering their target cell, a variety of chimeric proteins composed of an endogenous protein as their killing moiety reach the subcellular location of their endogenous counterpart. In contrast, bacterial-based killing domains head for the subcellular site of their substrate. Moreover, the chimeric protein acts similarly to the endogenous protein, while causing the cell to die. Therefore, chimeric proteins may serve as a unique tool for investigating cellular proteins and their intracellular localization, without the need to overexpress them.

Apoptosis-inducing human-origin Fcepsilon-Bak chimeric proteins for targeted elimination of mast cells and basophils: a new approach for allergy treatment

During the past few years, many chimeric proteins have been developed to specifically target and kill cells expressing specific surface molecules. Generally these molecules carry a bacterial or plant toxin to destroy the unwanted cells. The major obstacle regarding these molecules in their clinical application is the immunogenicity and nonspecific toxicity associated with bacterial or plant toxins. We lately reported a new approach for construction of chimeric proteins: we successfully replaced bacterial or plant toxins with human apoptosis-inducing proteins. The resulting chimeras were shown to specifically induce apoptosis in the target cells. Taking advantage of the human apoptosis inducing proteins Bak and Bax as novel killing components, we have now constructed new chimeric proteins targeted against the human FcepsilonRI, expressed mainly on mast cells and basophils. These cells are the main effectors of the allergic response. Treatment of the target cells with the new chimeric proteins, termed Fcepsilon-Bak/Bax, had a dramatic effect on cell survival, causing apoptosis. The effect was specific to cells expressing the FcepsilonRI of both human and, very unexpectedly, also of mouse origin. Moreover, interaction of the chimeric proteins with the mast cells did not cause degranulation. Fcepsilon-Bak/Bax are new chimeric proteins of human origin and, as such, are expected to be both less immunogenic and less toxic and, thus, may be specific and efficient reagents for the treatment of allergic diseases.