Betacellulin-Pseudomonas toxin fusion proteins bind but are not cytotoxic to cells expressing HER4; correlation of EGFR for cytotoxic activity.

Betacellulin (BTC) is a member of the EGF ligand family that directly binds to both EGFR and HER4 and induces the growth of certain epithelial cell types. Fusion proteins composed of the terminal 48 or 50 amino acids of mature betacellulin and a binding defective form of Pseudomonas exotoxin (BTC-TX48 and BTC-TX50, respectively), have been produced. BTC-TX50 induced tyrosine phosphorylation of both EGFR and HER4, whereas BTC-TX48 induced phosphorylation of HER4 but to a much lesser extent EGFR, indicating that the presence of two additional amino acid residues, Arg62 and Lys63, contribute to full kinase activity. BTC-TX50 was up to 300-fold more active at inhibiting protein synthesis than BTC-TX48 on cell lines expressing EGFR, most likely due to the >tenfold higher affinity of BTC-TX50. MDA-MB-453 breast carcinoma cells which express HER4 but not EGFR, were not sensitive to either BTC-TX form. These data indicate that despite the ability of BTC-TX to bind and phosphorylate HER4, it was only cytotoxic to cells expressing EGFR. The inability of BTC-TX to kill cells was likely due to its failure to internalize through HER4.

Characterization of vascular leak syndrome induced by the toxin component of Pseudomonas exotoxin-based immunotoxins and its potential inhibition with nonsteroidal anti-inflammatory drugs.

Clinical trials of immunotoxins in cancer patients have been limited in many cases by vascular leak syndrome (VLS). Recently, rats were identified as a model for VLS induced by BR96 sFv-PE40, a carcinoma-reactive single-chain immunotoxin. In this study, the toxin component of this immunotoxin, PE40, was found to be responsible for inducing hydrothorax in rats, thereby demonstrating that direct binding to the BR96 antigen was not essential to the onset of VLS. Mutational analysis of PE40 determined that both ADP ribosylation and proteolytic processing functions innate to Pseudomonas exotoxin A (PE) were necessary for PE40 to induce hydrothorax in rats; however, neither function by itself was sufficient for VLS induction. Additionally, nonsteroidal anti-inflammatory agents were found to block VLS in rats receiving BR96 sFv-PE40. These results demonstrate that the toxin component of PE-based immunotoxins induce VLS and suggest agents for clinical management of the toxicity.

Identification and activities of human carboxylesterases for the activation of CPT-11, a clinically approved anticancer drug.

CPT-11 is a clinically approved anticancer drug used for the treatment of advanced colorectal cancer. Upon administration, the carbamate side chain of the drug is hydrolyzed, resulting in the release of SN-38, an agent that has approximately 1000-fold increased cytotoxic activity. Since only a very small percentage of the injected dose of CPT-11 is converted to SN-38, there is a significant opportunity to improve its therapeutic efficacy and to diminish its systemic toxicity by selectively activating the drug within tumor sites. We envisioned that a mAb-human enzyme conjugate for CPT-11 activation would be of interest, particularly since the conjugate would likely be minimally immunogenic, and the prodrug is clinically approved. Toward this end, it was necessary to identify the most active human enzyme that could convert CPT-11 to SN-38. We isolated enzymes from human liver microsomes based on their abilities to effect the conversion and identified human carboxylesterase 2 (hCE-2) as having the greatest specific activity. hCE-2 was 26-fold more active than human carboxylesterase 1 and was 65% as active as rabbit liver carboxylesterase, the most active CPT-11 hydrolyzing enzyme known. The anti-p97 mAb 96.5 was linked to hCE-2, forming a conjugate that could bind to antigen-positive cancer cells and convert CPT-11 to SN-38. Cytotoxicity assays established that the conjugate led to the generation of active drug, but the kinetics of prodrug activation (48 pmol x min(-1) x mg(-1) was insufficient for immunologically specific prodrug activation. These results confirm the importance of hCE-2 for CPT-11 activation and underscore the importance of enzyme kinetics for selective prodrug activation.

Characterization of ribosome-inactivating proteins isolated from Bryonia dioica and their utility as carcinoma-reactive immunoconjugates.

Two ribosome-inactivating proteins (RIPs) were isolated and characterized from the roots of Bryonia dioica. One of these was a novel 27-kDa protein termed bryodin 2 (BD2), while the second was a previously reported RIP, referred to here as bryodin 1 (BD1). The amino-terminal sequence obtained for BD2 was similar, but distinct from BD1, ricin A chain, trichosanthin, and momorcharin. BD2-specific monoclonal antibodies were generated and found not to react with BD1 or ricin A chain. Purified BD1 and BD2 RIP inhibited protein synthesis in a cell-free in vitro translation assay at EC50 values of 7 and 9 pM, respectively. Intravenous administration of BD1 was less toxic to mice than BD2, with LD50 values of > 40 for BD1 and 10-12 mg/kg for BD2. Primary human endothelial cells were 5-8-fold less sensitive to BD1 and BD2 than compared to ricin A chain. BD1 and BD2 were constructed as immunoconjugates with the chimeric form of BR96 (chiBR96), a carcinoma-reactive, internalizing antibody. ChiBR96-BD1 and chiBR96-BD2 were found to bind to and kill BR96 antigen-positive carcinoma cells while not killing antigen-negative carcinoma cells. Bryodins represent RIPs that may be useful in constructing immunotoxin conjugates with reduced toxicity and vascular sensitivity, as compared to ricin A chain immunotoxins.

Selective tumor sensitization to taxanes with the mAb-drug conjugate cBR96-doxorubicin.

The chimeric monoclonal antibody cBR96 conjugated to doxorubicin (cBR96-Dox) is selectively internalized by a wide variety of human carcinomas expressing an extended form of Lewis Y antigen (Le(y)). Endocytosis is followed by cleavage and release of free doxorubicin from the endocytic vesicles and subsequent cytotoxicity. Combination studies with standard anti-cancer agents, undertaken to further increase the potency of this targeted therapy, identified significant synergistic anti-tumor activity of cBR96-Dox and either of the taxanes paclitaxel or docetaxel. Treatment with cBR96-Dox 24 hr prior to paclitaxel resulted in a steady increase in the percentage of G(2) tumor cells and corresponding increase in sensitivity to taxanes. Cell cycle analysis indicated the cBR96-delivered doxorubicin was most effective against S-phase cells, yet cells exposed to even subtoxic levels progressed to and arrested in G(2), at a point of high sensitivity to the anti-tubulin agent paclitaxel. The synergy obtained by staged combination of cBR96-Dox and paclitaxel in vitro was reflected in significant anti-tumor efficacy in vivo against xenograft models of human lung and breast tumors that could not be achieved by either agent alone. The staged combination elicited significant or complete regressions of established human Le(y)-positive tumor xenografts using significantly reduced drug levels. Taken together, these data demonstrate a mechanistic approach to the selective elimination of Le(y)-positive tumors by using targeted doxorubicin followed by taxane treatment.

Prevention of immunotoxin-induced immunogenicity by coadministration with CTLA4Ig enhances antitumor efficacy.

Immunotoxins have shown promise as antitumor agents in clinical trials. However, they have not become part of standard cancer therapy because of factors that include their inherent immunogenicity, which limits the duration of therapy. To address this issue, we evaluated in preclinical models the concomitant use of the immunosuppressive agent CTLA4Ig and BR96 sFv-PE40, a single-chain immunotoxin that binds to carcinoma cells expressing Le(y). Cotreatment with CTLA4Ig, an inhibitor of the CD28/CTLA4-CD80/CD86 costimulation pathway, blocked the production of Abs against BR96 sFv-PE40 in immunocompetent rodents and dogs. It also blocked hypersensitivity reactions in rats carrying colon carcinoma allografts during a second course of BR96 sFv-PE40 therapy, and the cotreatment with CTLA4Ig resulted in enhanced antitumor activity. Cotreatment with CTLA4Ig also prevented hypersensitivity reactions induced by repeat dosing of BR96 sFv-PE40 (q3dx5) in dogs. The production of anti-BR96-sFv-PE40 Abs was decreased in CTLA4Ig-cotreated rodents and dogs resulting in increased plasma levels of BR96 sFv-PE40 relative to non-CTLA4Ig-cotreated animals. These data show that cotreatment of immunotoxins with CTLA4Ig, by inhibiting the production of anti-immunotoxin Abs, can extend the duration of BR96 sFv-PE40 therapy to give greater exposure, reduced toxicities, and increased efficacy.

Expression and characterization of bryodin 1 and a bryodin 1-based single-chain immunotoxin from tobacco cell culture.

Bryodin 1 (BD1) is a potent ribosome-inactivating protein (RIP) isolated from the plant Bryonia dioica. It is relatively nontoxic in rodents (LD50 > 40 mg/kg) and represents a potential improvement over other RIPs and bacterial toxins that have been used in immunotoxins. Recombinant BD1, expressed in Escherichia coli, localizes to insoluble inclusion bodies necessitating denaturation and refolding steps to generate active protein. In this report, BD1 was expressed as a soluble recombinant protein in tobacco cell culture (ntBD1) and purified to near homogeneity with yields of up to 30 mg/(L of culture). The protein synthesis inhibition activity of ntBD1 was identical to that of both native BD1 isolated from the roots of B. dioica and recombinant BD1 expressed in E. coli. Toxicology analysis showed that ntBD1 was well tolerated in rats at doses that cannot be achieved with most other toxin components of immunotoxins. Additionally, a single-chain immunotoxin composed of BD1 fused to the single-chain Fv region of the anti-CD40 antibody G28-5 (ntBD1-G28-5 sFv) was expressed in tobacco tissue culture as a soluble protein and was specifically cytotoxic toward CD40 expressing non-Hodgkin's lymphoma cells in vitro. These data indicate that tobacco tissue culture is a viable system for soluble expression of BD1 and BD1-containing immunotoxins.

In vitro and in vivo characterization of BR96 sFv-PE40. A single-chain immunotoxin fusion protein that cures human breast carcinoma xenografts in athymic mice and rats.

BR96 sFv-PE40 is a single-chain immunotoxin fusion protein targeted to the Ley Ag, which is expressed in many different human carcinomas as well as in normal gastrointestinal epithelium of humans and certain animals, including athymic rats but not mice. In vitro binding analysis determined that BR96 sFv-PE40 was similar in affinity to BR96 Fab. BR96 sFv-PE40 internalizes rapidly, similar to BR96 IgG. H3396 cells, derived from metastatic human breast carcinoma, have been established as tumor xenografts in estradiol-supplemented athymic mice and rats. H3396 tumor xenografts established in athymic mice (up to 350 mm3) and rats (up to 100 mm3) completely regressed after i.v. administration of BR96 sFv-PE40, given as 0.625 mg/kg (1.975 mg/m2) every 4th day for a total of five doses (mice) or 0.25 mg/kg (1.475 mg/m2) every 4th day for a total of four doses (rats). The tumors remained regressed for the duration of the study (> 85 days post-implant), which represents > 10 doubling times, indicating that the animals were cured. There was no toxicity in rats receiving a curative dose of 0.25 mg/kg, although liver and lung toxicity could be detected at a 16 times higher dose, 4 mg/kg or 23.6 mg/m2. We conclude, therefore, that BR96 sFv-PE40 can cure tumor xenografts at well tolerated doses and also in the presence of Ley expression in normal tissues.

HER4 expression correlates with cytotoxicity directed by a heregulin-toxin fusion protein.

We have constructed, expressed, and purified a fusion protein, HAR-TX beta 2, consisting of heregulin-beta 2 fused to a binding-defective form of Pseudomonas exotoxin A, PE40. The fusion protein was found to induce receptor tyrosine phosphorylation in CEM cells transfected with HER4 alone or in combination with HER2 but not in cells transfected with HER2 or HER1 alone. The phosphorylation of receptor tyrosines was both dose-dependent and saturable in amounts similar to those shown to be active for native heregulin. HAR-TX beta 2 was specifically cytotoxic toward a variety of carcinoma cell lines in the ng/ml range. However, some tumor cell lines were found to be insensitive to the cytotoxic action of the fusion protein even at > 2 micrograms/ml. Relative amounts of HER4, HER3, and HER2 were determined on seven cell lines sensitive and four cell lines insensitive to HAR-TX beta 2. All lines that express HER4 were killed by HAR-TX beta 2, while none lacking HER4 were affected. HAR-TX beta 2 was able to bind to and signal via tyrosine phosphorylation in cell lines that co-express HER2 and HER3 in the absence of HER4 without inducing cytotoxicity. Thus HAR-TX beta 2 may prove to be a useful reagent for the targeting and elimination of HER4-positive tumor cells.