Efficient growth inhibition of EGFR over-expressing tumor cells by an anti-EGFR nanobody

Epidermal growth factor receptor (EGFR) is deemed to be one of the main molecular targets for diagnosis and treatment of cancer. It has been identified that EGFR involves in pathogenesis of some forms of human cancers. Monoclonal antibodies targeting EGFR could control the tumor cell growth, proliferation, and apoptosis by suppressing the signal transduction pathways. Nanobodies can be regarded as the smallest intact antigen binding fragments, derived from heavy chain-only antibodies existing in camelids. Here, we describe the identification of an EGFR-specific nanobody, referred to as OA-cb6, obtained from immunized camel with a cell line expressing high levels of EGFR. Utilizing flow cytometry (FACS) and blotting methods, we demonstrated that OA-cb6 nanobody binds specifically to EGFR expressing on the surface of A431 cells. In addition, OA-cb6 nanobody potently causes the inhibition of EGFR over expression, cell growth and proliferation. The antibody fragments can probably be regarded as worthwhile binding block for further rational design of anti-cancer therapy.     

The role of therapeutic antibodies in drug discovery

The last 5 years have seen a major upturn in the fortune of therapeutic monoclonal antibodies (mAbs), with nine mAbs approved for clinical use during this period and more than 70 now in clinical trials beyond phase II. Sales are expected to reach $4 billion per annum worldwide in 2002 and $15 billion by 2010. This success can be related to the engineering of mouse mAbs into mouse/human chimaeric antibodies or humanized antibodies, which have had a major effect on immunogenicity, effector function and half-life. The issue of repeated antibody dosing at high levels with limited toxicity was essential for successful clinical applications. Emerging technologies (phage display, human antibody-engineered mice) have created a vast range of novel, antibody-based therapeutics, which specifically target clinical biomarkers of disease. Modified recombinant antibodies have been designed to be more cytotoxic (toxin delivery), to enhance effector functions (bivalent mAbs) and to be fused with enzymes for prodrug therapy and cancer treatment. Antibody fragments have also been engineered to retain specificity and have increased the penetrability of solid tumours (single-chain variable fragments). Radiolabelling of antibodies has now been shown to be effective for cancer imaging and targeting. This article focuses on developments in the design and clinical use of recombinant antibodies for cancer therapy.     

Antitumor activity of combinations of antibodies directed against different epitopes on the extracellular domain of the human EGF receptor

The receptor (EGFR) for epidermal growth factor (EGF) and transforming growth alpha (TGFα) is often overexpressed in certain types of human malignancy and high levels of expression of the receptor and/ or coexpression of growth factors. EGF and TGFα have also been correlated with poor prognosis in many patients. We have produced a number of rat monoclonal antibodies (MAbs) against four distinct epitopes on the external domain of the EGF receptor and are currently evaluating their potential for therapeutic use. Nine of these of MAbs were found to inhibit the binding of TGF and EGF to the receptor on tumor cells and these MAbs were able to inhibit the growth in vitro and in vivo of tumor cells that overexpress the EGF receptor. Here, we describe the results of experiments to determine the antitumor activity of combination treatment with two antibodies directed against separate epitopes on the external domain of human EGFR. Our results showed that treatment of human tumor xenografts with a combination of two anti-EGFR MAbs that bind to two distinct epitopes on the external domain of EGF receptor was not as effective as treatment with ICR62 alone, which binds to epitope C on the EGFR and is of IgG2b isotype. A phase I clinical trial with antibody ICR62 is currently underway in Royal Marseden Hospital (UK) in patients with head and neck and lung carcinomas.     

A bacterial-two-hybrid selection system for one-step isolation of intracellularly functional Nanobodies

Camel single-domain antibody fragments or Nanobodies, are practical in a wide range of applications. Their unique biochemical and biophysical properties permit an intracellular expression and antigen targeting. The availability of an efficient intracellular selection step would immediately identify the best intracellularly performing functional antibody fragments. Therefore, we assessed a bacterial-two-hybrid system to retrieve such Nanobodies. With GFP as an antigen we demonstrate that antigen-specific Nanobodies of sub-micromolar affinity and stability above 30kJ/mol, at a titer of 10(-4) can be retrieved in a single-step selection. This was further proven practically by the successful recovery from an 'immune' library of multiple stable, antigen-specific Nanobodies of good affinity for HIV-1 integrase or nucleoside hydrolase. The sequence diversity, intrinsic domain stability, antigen-specificity and affinity of these binders compare favorably to those that were retrieved in parallel by phage display pannings.     

In vitro characterisation of a monovalent and bivalent form of a fully human anti Ep-CAM phage antibody

 Antibodies to tumour-associated antigens are increasingly being used as targeting vehicles for the visualisation and for therapy of human solid tumours. The epithelial cell adhesion molecule (Ep-CAM) is an antigen that is overexpressed on a variety of human solid tumours and constitutes an attractive target for immunotargeting. We set out to obtain fully human antibodies to this antigen by selecting from a large antibody repertoire displayed on bacteriophages. Two single-chain variable antibody fragments (scFv) were identified that specifically bound recombinant antigen in vitro. One of the selected antibodies (VEL-1) cross-reacted with extracellular matrix components in immunohistochemistry of colon carcinoma, whereas the other scFv (VEL-2) specifically recognised colon cancer cells. The latter antibody was further characterised with respect to epitope specificity and kinetics of antigen-binding. It showed no competition with the well-characterised anti Ep-CAM MOC-31 monoclonal antibody and had an off-rate of 5 × 10⁻² s⁻¹. To obtain an antibody format more suitable for in vivo tumour targeting and to increase the apparent affinity through avidity, the genes of scFv VEL-2 were re-formatted by fusion to a human (γ1) hinge region and CH3 domain. This “minibody” was expressed in Escherichia coli, specifically bound the Ep-CAM antigen and showed a 20-fold reduced off-rate in surface plasmon resonance analysis. These results show that phage antibody selection, combined with antibody engineering, may result in fully human antibody molecules with promising characteristics for in vivo use in tumour targeting. Received: 13 July 2000 / Accepted: 12 October 2000     

Properties,production, and applications of camelid single-domain antibody fragments

Camelids produce functional antibodies devoid of light chains of which the single N-terminal domain is fully capable of antigen binding. These single-domain antibody fragments (VHHs or Nanobodies) have several advantages for biotechnological applications. They are well expressed in microorganisms and have a high stability and solubility. Furthermore, they are well suited for construction of larger molecules and selection systems such as phage, yeast, or ribosome display. This minireview offers an overview of (1) their properties as compared to conventional antibodies, (2) their production in microorganisms, with a focus on yeasts, and (3) their therapeutic applications.     

Conversion of murine antibodies to human antibodies and their optimization for ovarian cancer therapy targeted to the folate receptor

We previously developed murine and chimeric antibodies against a specific epithelial ovarian carcinoma (EOC) marker, named folate receptor (FR), and promising results were obtained in phase II trials. More recently, we successfully generated a completely human Fab fragment, C4, by conversion of one of the murine anti-FR antibodies to human antibody using phage display and guided selection. However, subsequent efforts to obtain C4 in a dimer format, which seems especially desirable for EOC locoregional treatment, resulted in a highly heterogeneous product upon natural dimerization and in a very poor production yield upon chemical dimerization by a non-hydrolyzable linker to a di-Fab-maleimide (DFM). We therefore designed, constructed and characterized a large Fab dual combinatorial human antibody phage display library obtained from EOC patients and potentially biased toward an anti-tumor response in an effort to obtain new anti-FR human antibodies suitable for therapy. Using this library and guiding the selection on FR-expressing cells with murine/human antibody chains, we generated four new human anti-FR antibody (AFRA) Fab fragments, one of which was genetically and chemically manipulated to obtain a chemical dimer, designated AFRA-DFM5.3, with high yield production and the capability for purification scaled-up to clinical grade. Overall affinity of AFRA-DFM5.3 was in the 2-digit nanomolar range, and immunohistochemistry indicated that the reagent recognized the FR expressed on EOC samples. ¹³¹I-AFRA-DFM5.3 showed high immunoreactivity, in vitro stability and integrity, and specifically accumulated only in FR-expressing tumors in subcutaneous preclinical in vivo models. Overall, our studies demonstrate the successful conversion of murine to completely human anti-FR antibodies through the combined use of antibody phage display libraries biased toward an anti-tumor response, guided selection and chain shuffling, and point to the suitability of AFRA5.3 for future clinical application in ovarian cancer.     

Comparative in vitro and experimental in vivo studies of the anti–epidermal growth factor receptor antibody nimotuzumab and its aglycosylated form produced in transgenic tobacco plants

A broad variety of foreign genes can be expressed in transgenic plants, which offer the opportunity for large‐scale production of pharmaceutical proteins, such as therapeutic antibodies. Nimotuzumab is a humanized anti–epidermal growth factor receptor (EGFR) recombinant IgG1 antibody approved in different countries for the treatment of head and neck squamous cell carcinoma, paediatric and adult glioma, and nasopharyngeal and oesophageal cancers. Because the antitumour mechanism of nimotuzumab is mainly attributed to its ability to interrupt the signal transduction cascade triggered by EGF/EGFR interaction, we have hypothesized that an aglycosylated form of this antibody, produced by mutating the N₂₉₇ position in the IgG₁ Fc region gene, would have similar biochemical and biological properties as the mammalian‐cell‐produced glycosylated counterpart. In this paper, we report the production and characterization of an aglycosylated form of nimotuzumab in transgenic tobacco plants. The comparison of the plantibody and nimotuzumab in terms of recognition of human EGFR, effect on tyrosine phosphorylation and proliferation in cells in response to EGF, competition with radiolabelled EGF for EGFR, affinity measurements of Fab fragments, pharmacokinetic and biodistribution behaviours in rats and antitumour effects in nude mice bearing human A431 tumours showed that both antibody forms have very similar in vitro and in vivo properties. Our results support the idea that the production of aglycosylated forms of some therapeutic antibodies in transgenic plants is a feasible approach when facing scaling strategies for anticancer immunoglobulins.     

纳米抗体及其在诊断检测中的研究进展

骆驼血液中存在天然缺失轻链的重链抗体,克隆该重链抗体的可变区得到最小的抗原结合片段,即纳米抗体(Nanobody,Nb)。Nb的单域性质使其较普通抗体具有一些独特性能,比如高度水溶性和构象稳定性,较强的抗原亲合力和优良的组织穿透能力,容易体外表达和人源化改造修饰等,Nb的以上持性使其在诊断检测领域展现出广阔的应用前景。尽管Nb的应用开发已经取得前所未有的成功,技术上仍然有待进一步优化,其中包括噬菌体纳米抗体库构建以及Nb的胶体金标记分析等技术。文中简单介绍Nb的研究进展,并从Nb制备、在疾病的体外检测以及体内肿瘤无创伤影像诊断领域的应用3个方面,讨论进一步提高Nb亲合力和人源化改造等优化Nb分子特征的策略,分析Nb在疾病检测诊断应用中存在的问题,并提出一些积极的应对方案。     

Genetic selection of phage engineered for receptor-mediated gene transfer to mammalian cells.

Although phage display is a powerful way of selecting ligands against purified target proteins, it is less effective for selecting functional ligands for complex targets like living cells. Accordingly, phage display has had limited utility in the development of targeting agents for gene therapy vectors. By adapting a filamentous bacteriophage for gene delivery to mammalian cells, however, we show here that it is possible to screen phage libraries for functional ligands capable of delivering DNA to cells. For example, when targeted with epidermal growth factor (EGF), M13 bacteriophage were capable of delivering a green fluorescent protein (GFP) gene to EGF receptor bearing cells in a ligand-, time-, and phage concentration-dependent manner. The EGF-targeted phage transduced COS-1 cells in a highly specific manner as demonstrated by competition with excess free EGF or alternatively with anti-EGF receptor antibodies. We further demonstrate that EGF-phage can be selected, by their ability to transduce EGF receptor bearing cells from libraries of peptide display phage. When phage were incubated with COS-1 cells, EGF ligand-encoding sequences were recovered by PCR from FACsorted, GFP-positive cells and the EGF-displaying phage were enriched 1 million-fold by four rounds of selection. These data suggest the feasibility of applying molecular evolution to phage gene delivery to select novel cell-specific DNA-targeting ligands. The same approach could be used to select genetically altered phage that are specifically designed and evolved as gene therapy vectors.