Berend Tolner

A phase I study of single administration of antibody-directed enzyme prodrug therapy with the recombinant anti-carcinoembryonic antigen antibody-enzyme fusion protein MFECP1 and a bis-iodo phenol mustard prodrug

Purpose: Antibody-directed enzyme prodrug therapy is a two-stage treatment whereby a tumor-targeted antibody-enzyme complex localizes in tumor for selective conversion of prodrug. The purpose of this study was to establish optimal variables for single administration of MFECP1, a recombinant antibody-enzyme fusion protein of an anti–carcinoembryonic antigen single-chain Fv antibody and the bacterial enzyme carboxypeptidase G2 followed by a bis-iodo phenol mustard prodrug. MFECP1 is manufactured in mannosylated form to facilitate normal tissue elimination. Experimental Design: Pharmacokinetic, biodistribution, and tumor localization studies were used to test the hypothesis that MFECP1 localizes in tumor and clears from normal tissue via the liver. Firstly, safety of MFECP1 and a blood concentration of MFECP1 that would avoid systemic prodrug activation were tested. Secondly, dose escalation of prodrug was done. Thirdly, the dose of MFECP1 and timing of prodrug administration were optimized. Results: MFECP1 was safe and well tolerated, cleared rapidly via the liver, and was less immunogenic than previously used products. Eighty-fold dose escalation from the starting dose of prodrug was carried out before dose-limiting toxicity occurred. Confirmation of the presence of enzyme in tumor and DNA interstrand cross-links indicating prodrug activation were obtained for the optimal dose and time point. A total of 28 of 31 patients was evaluable for response, the best response being a 10% reduction of tumor diameter, and 11 of 28 patients had stable disease. Conclusions: Optimal conditions for effective therapy were established. A study testing repeat treatment is currently being undertaken.

Production of recombinant protein in Pichia pastoris by fermentation

This protocol is applicable to recombinant protein expression by small-scale fermentation using the Pichia pastoris expression system. P. pastoris has the capacity to produce large quantities of protein with eukaryotic processing. Expression is controlled by a methanol-inducible promoter, which allows a biomass-generation phase before protein production is initiated. The target protein is secreted directly into a protein-free mineral salt medium, and is relatively easy to purify. The protocol is readily interfaced with expanded bed adsorption for immediate capture and purification of recombinant protein. The setting up of the bioreactor plus the fermentation itself takes 1 wk. Making the master and user seed lots takes ∼2 wk for each individual clone.

Nanoparticles functionalised with recombinant single chain Fv antibody fragments (scFv) for the magnetic resonance imaging of cancer cells

Superparamagnetic iron oxide nanoparticles (SPIONs) can substantially improve the sensitivity of magnetic resonance imaging (MRI). We propose that SPIONs could be used to target and image cancer cells if functionalized with recombinant single chain Fv antibody fragments (scFv). We tested our hypothesis by generating antibody-functionalized (abf) SPIONs using a scFv specific for carcinoembryonic antigen (CEA), an oncofoetal cell surface protein. SPIONs of different hydrodynamic diameter and surface chemistry were investigated and targeting was confirmed by ELISA, cellular iron uptake, confocal laser scanning microscopy (CLSM) and MRI. Results demonstrated that abf-SPIONs bound specifically to CEA-expressing human tumour cells, generating selective image contrast on MRI. In addition, we observed that the cellular interaction of the abf-SPIONs was influenced by hydrodynamic size and surface coating. The results indicate that abf-SPIONs have potential for cancer-specific MRI.

Modifying an immunogenic epitope on a therapeutic protein: a step towards an improved system for antibody-directed enzyme prodrug therapy (ADEPT)

Carboxypeptidase G2 (CP) is a bacterial enzyme, which is targeted to tumours by an antitumour antibody for local prodrug activation in antibody-directed enzyme prodrug therapy (ADEPT). Repeated cycles of ADEPT are desirable but are hampered by human antibody response to CP (HACA). To address this, we aimed to identify and modify clinically important immunogenic sites on MFECP, a recombinant fusion protein of CP with MFE-23, a single chain Fv (scFv) antibody. A discontinuous conformational epitope at the C-terminus of the CP previously identified by the CM79 scFv antibody (CM79-identified epitope) was chosen for study. Modification of MFECP was achieved by mutations of the CM79-identified epitope or by addition of a hexahistidine tag (His-tag) to the C-terminus of MFECP, which forms part of the epitope. Murine immunisation experiments with modified MFECP showed no significant antibody response to the CM79-identified epitope compared to A5CP, an unmodified version of CP chemically conjugated to an F(ab)2 antibody. Success of modification was also demonstrated in humans because patients treated with His-tagged MFECP had a significantly reduced antibody response to the CM79-identified epitope, compared to patients given A5CP. Moreover, the polyclonal antibody response to CP was delayed in both mice and patients given modified MFECP. This increases the prospect of repeated treatment with ADEPT for effective cancer treatment.

Engineering Antibodies for Clinical Applications in Cancer

The ‘magic bullet’ concept predicted over a century ago that antibodies would be used to target cancer therapy. Since then initial problems that were related to specificity, purity and immungenicity of antibody-based reagents have slowly been overcome due to developments in technology and increased knowledge. As a result, antibodies are in use for many clinical applications and now comprise the second largest category of medicines in clinical development after vaccines. For antibody-based cancer therapeutics the last 20 years have met with an explosion of knowledge about the biology of the disease and potential targets as well as new technology which allows cloning and manipulation of multifunctional antibody-based molecules. However, the focus still remains on developing therapeutics that will have potential for treating cancer in people and this is efficiently assessed in mechanistic clinical trials that feed back to the laboratory for further development. This review illustrates the mechanistic approach to making new molecules for antibody imaging and therapy of cancer. It is illustrated by examples of radioimmunotherapy and antibody-directed enzyme prodrug therapy developed by the authors.

Engineering a Single Chain Fv Antibody to αvβ6 Integrin using the Specificity-Determining Loop of a Foot-and-Mouth Disease Virus

The alpha v beta 6 integrin is a promising target for cancer therapy. Its expression is up-regulated de novo on many types of carcinoma where it may activate transforming growth factor-beta1 and transforming growth factor-beta 3, interact with the specific extracellular matrix proteins and promote migration and invasion of tumor cells. The viral protein 1 (VP1) coat protein of the O(1) British field strain serotype of foot-and-mouth disease virus is a high-affinity ligand for alpha v beta 6, and we recently reported that a peptide derived from VP1 exhibited alpha v beta 6-specific binding in vitro and in vivo. We hypothesized that this peptide could confer binding specificity of an antibody to alpha v beta 6. A 17-mer peptide of VP1 was inserted into the complementarity-determining region H3 loop of MFE-23, a murine single-chain Fv (scFv) antibody reactive with carcinoembryonic antigen (CEA). The resultant scFv (B6-1) bound to alpha v beta 6 but retained residual reactivity with CEA. This was eliminated by point mutation (Y100bP) in the variable heavy-chain domain to create an scFv (B6-2) that was as structurally stable as MFE-23 and reacted specifically with alpha v beta 6 but not with alpha 5 beta 1, alpha v beta 3, alpha v beta 5, alpha v beta 8 or CEA. B6-2 was internalized into alpha v beta 6-expressing cells and inhibited alpha v beta 6-dependent migration of carcinoma cells. B6-2 was subsequently humanized. The humanized form (B6-3) was obtained as a non-covalent dimer from secretion in Pichia pastoris (115 mg/l) and was a potent inhibitor of alpha v beta 6-mediated cell adhesion. Thus, we have used a rational stepwise approach to create a humanized scFv with therapeutic potential to block alpha v beta 6-mediated cancer cell invasion or to deliver and internalize toxins specifically to alpha v beta 6-expressing tumors.

Expanded-bed adsorption immobilized-metal affinity chromatography

The protocol describes a method for capture of secreted hexahistidine-tagged proteins using expanded-bed adsorption immobilized-metal affinity chromatography. The starting material for the procedure is any crude feedstock that contains a histidine (His)-tagged target protein. The protocol is exemplified using unclarified broth from Pichia pastoris fermentation as feedstock. The protocol can be used for laboratory studies or as part of a process for production of recombinant biotherapeutics to standards of good manufacturing practice. It takes approximately 5 h to purify proteins from 10 liters of feedstock and a further 5–6 h to sterilize and regenerate the column.

Preclinical evaluation of a novel CEA-targeting near-infrared fluorescent tracer delineating colorectal and pancreatic tumors

Surgery is the cornerstone of oncologic therapy with curative intent. However, identification of tumor cells in the resection margins is difficult, resulting in nonradical resections, increased cancer recurrence and subsequent decreased patient survival. Novel imaging techniques that aid in demarcating tumor margins during surgery are needed. Overexpression of carcinoembryonic antigen (CEA) is found in the majority of gastrointestinal carcinomas, including colorectal and pancreas. We developed ssSM3E/800CW, a novel CEA‐targeted near‐infrared fluorescent (NIRF) tracer, based on a disulfide‐stabilized single‐chain antibody fragment (ssScFv), to visualize colorectal and pancreatic tumors in a clinically translatable setting. The applicability of the tracer was tested for cell and tissue binding characteristics and dosing using immunohistochemistry, flow cytometry, cell‐based plate assays and orthotopic colorectal (HT‐29, well differentiated) and pancreatic (BXPC‐3, poorly differentiated) xenogeneic human–mouse models. NIRF signals were visualized using the clinically compatible FLARE™ imaging system. Calculated clinically relevant doses of ssSM3E/800CW selectively accumulated in colorectal and pancreatic tumors/cells, with highest tumor‐to‐background ratios of 5.1 ± 0.6 at 72 hr postinjection, which proved suitable for intraoperative detection and delineation of tumor boarders and small (residual) tumor nodules in mice, between 8 and 96 hr postinjection. Ex vivo fluorescence imaging and pathologic examination confirmed tumor specificity and the distribution of the tracer. Our results indicate that ssSM3E/800CW shows promise as a diagnostic tool to recognize colorectal and pancreatic cancers for fluorescent‐guided surgery applications. If successfully translated clinically, this tracer could help improve the completeness of surgery and thus survival.

Generation and Characterization of a Diabody Targeting the αvβ6 Integrin

The αvβ6 integrin is up-regulated in cancer and wound healing but it is not generally expressed in healthy adult tissue. There is increasing evidence that it has a role in cancer progression and will be a useful target for antibody-directed cancer therapies. We report a novel recombinant diabody antibody fragment that targets specifically αvβ6 and blocks its function. The diabody was engineered with a C-terminal hexahistidine tag (His tag), expressed in Pichia pastoris and purified by IMAC. Surface plasmon resonance (SPR) analysis of the purified diabody showed affinity in the nanomolar range. Pre-treatment of αvβ6-expressing cells with the diabody resulted in a reduction of cell migration and adhesion to LAP, demonstrating biological function-blocking activity. After radio-labeling, using the His-tag for site-specific attachment of 99mTc, the diabody retained affinity and targeted specifically to αvβ6-expressing tumors in mice bearing isogenic αvβ6 +/− xenografts. Furthermore, the diabody was specifically internalized into αvβ6-expressing cells, indicating warhead targeting potential. Our results indicate that the new αvβ6 diabody has a range of potential applications in imaging, function blocking or targeted delivery/internalization of therapeutic agents.

Data standards for minimum information collection for antibody therapy experiments.

Research groups developing antibody therapies generate diverse data sets; the value of these sets would be compounded when shared or amalgamated. A complete amalgamation of diverse data sets requires data standards for information collection during experiments. We propose to define elements of the data standards in the form of common data elements (CDEs) in order to clarify each experiments targets and data values. We have created a set of core information elements which we suggest should be collected from antibody therapy experiments. We propose these as a basis for community consultation with a view to defining a set of data standards which can be developed under the auspices of the Antibody Society.