Targeted tumor therapy with a fusion protein of an antiangiogenic human recombinant scFv and yeast cytosine deaminase.

In adults, endothelial cell division occurs only in wound healing, during menstruation, or in diseases such as wet age-related macular degeneration or development of benign or malignant tissues. Angiogenesis is one of the major requirements to supply the fast developing tumor tissue with oxygen and nutrients, and enables it to spread into other tissues far from its origin. We selected the extradomain B (ED-B), a splice variant of fibronectin, which is exclusively expressed in ovaries, uterus, during wound healing, and in tumor tissues, as a target for the development of an innovative antiangiogenic, prodrug-based targeted tumor therapy approach. We designed a fusion protein termed L19CDy-His, consisting of the antibody single chain fragment L19 for targeting ED-B and yeast cytosine deaminase for the conversion of 5-fluorocytosine into cytotoxic 5-fluorouracil. We purified high amounts of the fusion protein from Pichia pastoris that is stable, enzymatically active, and retains 75% of its activity after incubation with human plasma for up to 72 hours. The binding of L19CDy-His to ED-B was confirmed by an enzyme-linked immunosorbent assay and quantified by surface plasmon resonance spectroscopy determining a KD value of 81±7 nM. L19CDy-His successfully decreased cell survival of the murine ED-B-expressing teratocarcinoma cell line F9 upon addition of the prodrug 5-fluorocytosine. Our data demonstrate the suitability of targeting ED-B by L19CDy-His for effective prodrug-based tumor therapy.

Real time monitoring of the cell viability during treatment with tumor-targeted toxins and saponins using impedance measurement.

This work describes the application of an impedance-based measurement for the real time evaluation of targeted tumor therapies in cell culture (HeLa cells). We used a treatment procedure that is well established in cells and mice. Therein, tumor cells are treated with a combination of an epidermal growth factor-based targeted toxin named SE and particular plant glycosides called saponins. In the present study HeLa cells were seeded in different numbers onto interdigitated electrode structures integrated into the bottom of a 96 well plate. The cells were treated with SE in the presence and absence of the saponin SpnS-1 (isolated from Saponaria officinalis roots). The impedance was directly correlated with the viability of the cells. As expected from known end point measurements, a concentration dependent enhancement of toxicity was observed; however, with the impedance measurement we were for the first time able to trace the temporal changes of cell death during the combination treatment. This substantially added to the understanding of initial cellular mechanisms in the augmentation of the toxicity of targeted toxins by saponins and indicated the superiority of real time monitoring over end point assays. The method is less labor intensive and label-free with ease of monitoring the effects at each time point.

The toxin component of targeted anti-tumor toxins determines their efficacy increase by saponins.

Tumor-targeting protein toxins are composed of a toxic enzyme coupled to a specific cell binding domain that targets cancer-associated antigens. The anti-tumor treatment by targeted toxins is accompanied by dose-limiting side effects. The future prospects of targeted toxins for therapeutic use in humans will be determined by reduce side effects. Certain plant secondary metabolites (saponins) were shown to increase the efficacy of a particular epidermal growth factor receptor (EGFR)-targeted toxin, paralleled by a tremendous decrease of side effects. This study was conducted in order to investigate the effects of substituting different toxin moieties fused to an EGF ligand binding domain on the augmentative ability of saponins for each against therapeutic potential of the saponin-mediated efficacy increase for different anti-tumor toxins targeting the EGFR. We designed several EGFR-targeted toxins varying in the toxic moiety. Each targeted toxin was used in combination with a purified saponin (SA1641), isolated from the ornamental plant Gypsophila paniculata L. SA1641 was characterized and the SA1641-mediated efficacy increase was investigated on EGFR-transfected NIH-3T3 cells. We observed a high dependency of the SA1641-mediated efficacy increase on the nature of toxin used for the construction of the targeted toxin, indicating high specificity. Structural alignments revealed a high homology between saporin and dianthin-30, the two toxic moieties that benefit most from the combination with SA1641. We further demonstrate that SA1641 did not influence the plasma membrane permeability, indicating an intracellular interaction of SA1641 and the toxin components of targeted toxins. Surface plasmon resonance measurements point to a transient binding of SA1641 to the toxin components of targeted toxins.

The endocytic uptake pathways of targeted toxins are influenced by synergistically acting Gypsophila saponins.

The expression of the epidermal growth factor (EGF) receptor is upregulated in many human tumors. We developed the targeted toxin SE, consisting of the plant toxin saporin-3 and human EGF. The cytotoxic effect of SE drastically increases in a synergistic manner by a combined treatment with Saponinum album (Spn), a saponin composite from Gypsophila paniculata L. Here we analyzed which endocytic pathways are involved in the uptake of SE and which are mandatory for the Spn-mediated enhancement. We treated HER14 cells (NIH-3T3 cells transfected with human EGF receptor) with either chlorpromazine, dynasore, latrunculin A, chloroquine, bafilomycin A1 or filipin and analyzed the effect on the cytotoxicity of SE alone or in combination with Spn. We demonstrated that SE in combination with Spn enters cells via clathrin- and actin-dependent pathways and the acidification of the endosomes after endocytosis is relevant for the cytotoxicity of SE. Notably, our data suggest that SE without Spn follows a different endocytic uptake pathway. SE cytotoxicity is independent of blocking of clathrin or actin, and the decrease in endosomal pH is irrelevant for SE cytotoxicity. Furthermore, Spn has no influence on the retrograde transport. This work is important for the better understanding of the underlying mechanism of Spn-enhanced cytotoxicity and helps to describe the role of Spn better.

Electrophoretic isolation of saponin fractions from Saponinum album and their evaluation in synergistically enhancing the receptor-specific cytotoxicity of targeted toxins.

Saponinum album (SA) is a commercial mixture of saponins isolated from Gypsophila species. In the previously published work, we reported that SA dramatically improves the inhibition of tumor growth by targeted toxins in mice in a synergistic way. Here we report a simplified electrophoretic method for the isolation of a highly effective fraction of SA with a relative electrophoretic mobility to the dye front (R(f) ) of 0.63 from the mixture. In total, four different fractions were separated at a preparative scale, and evaluated by ESI-MS, HPLC and TLC analysis. Electrophoretic mobility and electrochemical properties of the different fractions of saponins from SA were set into relation to their ability to enhance the cytotoxicity of epidermal growth factor (EGF)-based targeted toxins. We here treated HER-14 cells, which are NIH-3T3 Swiss mouse embryo cells transfected with the human EGF receptor. Untransfected NIH-3T3 cells served as control. The major bulk of SA (72.3%) (R(f) =0.78) migrated the farthest and was found to be significantly ineffective (p<0.05) in enhancing the cytotoxicity of the targeted toxin, while the second fraction (R(f) =0.63) showed an enhancement of 9800-fold. The third (R(f) =0.56) had an enhancement factor of 3200, the fourth (R(f) =0.08) was again significantly ineffective (p<0.05) in exhibiting any enhancement of cytotoxicity.

A lysine-free mutant of epidermal growth factor as targeting moiety of a targeted toxin.

AIMS: Elevated levels of epidermal growth factor (EGF) receptor are observed on several human tumors, e.g. cervical carcinoma and mamma carcinomas. The natural ligand EGF is an alternative to established antibodies and tyrosine kinase inhibitors for targeting EGF receptor-overexpressing tumor cells for therapy. Conjugations of compounds to EGF lack the necessary homogeneity for an intended application, since several amino acids may react with the chemical linker. MAIN METHODS: We designed an EGF variant (EGF(RR)) in which the two lysines were substituted with arginine (K28R and K48R). EGF(RR) was fused to the protein toxin saporin to obtain a model protein for detailed analyses on EGF receptor binding and on both the enzymatic activity of saporin and the cytotoxicity of the fusion protein. KEY FINDINGS: The mutation decreased the enzymatic activity of saporin 2.3-fold and the binding of EGF(RR) retained its specificity for EGF receptor while increasing the Kd 5.5-fold. In spite of these differences the cytotoxicity of the fusion protein was unchanged in comparison to a fusion protein with EGF both when applied alone and in combination with cytotoxicity augmenting saponin. SIGNIFICANCE: We conclude that EGF(RR) retained its ability to bind with high specificity to EGF receptor and is thus suitable for a number of chemical linkage applications such as targeting drugs or dyes to EGF receptor-expressing cells.

A convenient method for saponin isolation in tumour therapy.

Saponinum album (Merck), which is a crude mixture of saponins from Gypsophila paniculata L., was shown to improve the anti cancer therapy when used in vivo in combination with saporin-based targeted toxins. Unfortunately saponinum album cannot be used for further development since Merck has ceased its production in the 1990s. As pure saponins are mandatory for use in medical purposes we developed a convenient method for saponin isolation directly from the roots of Gypsophila paniculata L. The developed method is rapid, cheap and scaling up is also possible. By combining dialysis and HPLC three saponins were isolated in a one-step procedure. Chemical structures of the purified saponins were characterized by extensive one and two-dimensional NMR-spectroscopy and by using ESI-TOF-MS. The biological activities of the purified saponins were also investigated. The method presented herein enabled a rapid and cheap isolation of saponins for tumour therapy.

Epidermal growth factor receptor expression affects the efficacy of the combined application of saponin and a targeted toxin on human cervical carcinoma cells.

Cervical cancer is the second most common cancer in women worldwide. Targeting the epidermal growth factor receptor (EGFR) is a very promising approach since it is overexpressed in about 90% of cervical tumors. Here, we quantified the toxic effect of SE, a targeted toxin consisting of epidermal growth factor (EGF) as targeting moiety and the plant toxin saporin-3, on 3 common human cervical carcinoma cell lines (HeLa, CaSki and SiHa) and recently established lines (PHCC1 and PHCC2) from 2 different individuals. A human melanocytic and a mouse cell line served as negative control. Additionally, we combined SE with saponinum album, a saponin composite from Gypsophila paniculata, which exhibited synergistic properties in previous studies. The cell lines, except for SiHa cells, revealed high sensitivity to SE with 50% cell survival in the range of 5-24.5 nM. The combination with saponin resulted in a remarkable enhancement of cytotoxicity with enhancement factors ranging from 9,000-fold to 2,500,000-fold. The cytotoxicity of SE was clearly target receptor specific since free EGF blocks the effect and saporin-3 alone was considerably less toxic. For all cervical carcinoma cell lines, we evinced a clear correlation between EGFR expression and SE sensitivity. Our data indicate a potential use of targeted toxins for the treatment of cervical cancer. In particular, the combination with saponins is a promising approach since efficacy is drastically improved.

Inhibition of tumor growth by targeted toxins in mice is dramatically improved by saponinum album in a synergistic way.

The application of targeted toxins in cancer therapy remains a challenge due to the severe side effects as a consequence of the high systemic doses required. Here, we describe the combined application of a glycosylated triterpenoid (Spn) and epidermal growth factor receptor (EGFR)-targeted chimeric toxins (SA2E). The cytotoxicity of SA2E on murine TSA tumor cells transfected with human EGFR was enhanced 20,000-fold by low nonpermeabilizing Spn concentrations in a synergistic manner. Subcutaneous application of Spn and SA2E in BALB/c mice bearing a solid TSA cells transfected with epidermal growth factor receptor tumor resulted in 94% tumor volume reduction with a 50-fold lower chimeric toxin concentration compared with pure SA2E treatment. Side effects as monitored by observable complications, body weight, blood parameters; histologic analyses and antibody responses were only moderate and usually reversible.

A simple method for isolation of Gypsophila saponins for the combined application of targeted toxins and saponins in tumor therapy.

Saponinum album (SAP) is a complex mixture of triterpene saponins from Gypsophila paniculata L. Although most of the saponins from SAP are characterized, the separation of pure saponins remains time consuming and costly, involving different chromatographic techniques. Recently it was shown that SAP drastically enhanced the cytotoxicity of a chimeric toxin consisting of the N-glycosidase saporin and human epidermal growth factor (Sap-EGF) in cell culture experiments. In view of a potential therapeutic use of the coadministration of SAP and Sap-EGF in tumor therapy, an economic and time-saving method for the isolation of pure saponins from the crude SAP mixture in high amounts is required. In this study we isolated a single saponin by a simple chromatographic method. The isolated saponin was characterized by mass spectrometry and was shown to enhance the cytotoxicity of Sap-EGF on HER14 cells.

Saponins in tumor therapy.

Saponins are plant glycosides with favorable anti-tumorigenic properties. Several saponins inhibit tumor cell growth by cell cycle arrest and apoptosis with IC50 values of up to 0.2 microM. We discuss diverse groups of saponins (dioscins, saikosaponins, julibrosides, soy saponins, ginseng saponins and avicins) investigated in relation to tumor therapy and focus on cellular and systemic mechanisms of tumor cell growth inhibition both in vitro and in vivo. The review also describes saponins in combination with conventional tumor treatment strategies, which result in improved therapeutic success. Some combinations of saponins and anti-tumorigenic drugs induce synergistic effects with potentiated growth inhibition.

Chimeric toxins inhibit growth of primary oral squamous cell carcinoma cells.

Treatment of oral squamous cell carcinoma (OSCC) is currently based on surgery and radiotherapy. Prolongation of the survival time of patients with progressing tumors is infrequently achieved. To improve the therapeutic options, targeted therapies are a favorable alternative. Therefore, we analyzed the effect of a chimeric toxin (CT) named SE consisting of the epidermal growth factor and the plant protein toxin saporin from Saponaria officinalis. A second construct (SA2E) additionally contains a peptidic adapter designed to enhance efficacy of the CT in vivo and to reduce side effects. The IC(50) values for an OSCC cell line (BHY) were 0.27 nM and 0.73 nM for SE and SA2E, respectively, while fibroblasts remained unaffected. To investigate primary tumor cells, we developed a technique to analyze freshly prepared OSCC cells of 28 patients in a stem cell assay directly after surgery. Cells were treated for 1 h with the CTs, subsequently seeded into soft agar and colony growth determined after 1-2 weeks In spite of the short time of CT incubation, the amount of colonies was reduced to about 78% by 10 nM and to 69% by 100 nM of either toxin. A combined application of 10 nM SA2E with a saponin from Gypsophila paniculata reduced the amount of surviving cells to 68%. The results demonstrate the impact of the CTs on OSCC cells and depict that the stem cell assay is suitable to determine the potential of anti-tumor drugs before studies in vivo will be initiated.

Quantification of diphtheria toxin mediated ADP-ribosylation in a solid-phase assay.

BACKGROUND: Because of reduced vaccination programs, the number of diphtheria infections has increased in the last decade. Diphtheria toxin (DT) is expressed by Corynebacterium diphtheriae and is responsible for the lethality of diphtheria. DT inhibits cellular protein synthesis by ADP-ribosylation of the eukaryotic elongation factor 2 (eEF2). No in vitro system for the quantification of DT enzymatic activity exists. We developed a solid-phase assay for the specific detection of ADP-ribosylation by DT. METHODS: Solid phase-bound his-tag eEF2 is ADP-ribosylated by toxins using biotinylated NAD(+) as substrate, and the transferred biotinylated ADP-ribose is detected by streptavidin-peroxidase. DT enzymatic activity correlated with absorbance. We measured the amount of ADP-ribosylated eEF2 after precipitation with streptavidin-Sepharose. Quantification was done after Western blotting and detection with anti-his-tag antibody using an LAS-1000 System. RESULTS: The assay detected enzymatically active DT at 30 ng/L, equivalent to 5 mU/L ADP-ribosylating activity. Pseudomonas exotoxin A (PE) activity was also detected at 100 ng/L. We verified the assay with chimeric toxins composed of the catalytic domain of DT or PE and a tumor-specific ligand. These chimeric toxins revealed increased signals at 1000 ng/L. Heat-inactivated DT and cholera toxin that ADP-ribosylates G-proteins did not show any signal increase. CONCLUSIONS: The assay may be the basis for the development of a routine diagnostic assay for the detection of DT activity and highly specific inhibitors of DT.

Patents on immunotoxins and chimeric toxins for the treatment of cancer.

Immunotoxins and chimeric toxins are highly potent drugs designed for the treatment of cancer. Immunotoxins are composed of antibodies linked to a toxic substance. The antibodies enable the drug to bind specifically to distinct antigens on the tumor cell while the toxic moiety mediates cell death. Chimeric toxins are based on the same principle but contain other components for specific tumor cell targeting, e.g. cytokines or growth factors. The approval of the chimeric toxin denileukin diftitox (DAB389IL-2; Ontak) for the treatment of cutaneous T-cell lymphoma demonstrates the potential of immunotoxins and chimeric toxins for the treatment of cancer. New immunotoxins and possible treatment regimes are patented for commercial reasons before being published. Patents have become an indispensable requirement for pharmaceutical companies due to the high costs of drug development and clinical trials, allowing the protection of intellectual property and recovery of investments. This article reviews recent patents of immunotoxins and chimeric toxins. New agents are described and differences between certain patents are outlined to give an overview of the current situation of immunotoxins and chimeric toxins for the treatment of cancer.