Single domain antibodies: a new concept for epidermal growth factor receptor and EGFRvIII targeting

Epidermal growth factor receptor (EGFR) is one of the major molecular targets for cancer diagnosis and therapy. EGFR and EGFRvIII, mutated form of EGFR, have been identified as participating in pathogenesis of some forms of human cancers. Monoclonal antibodies (mAbs) targeting EGFR/EGFRvIII have been shown to suppress the signal transduction pathways controlling tumor cell growth, proliferation, and apoptosis. Until now, different types of mAbs or antibody fragments against EGFR family have been established. Some of these antibodies have been used clinically for treating various forms of human malignancies. More recently, a single domain antibody (sdAb) targeting this family of receptors has been introduced. The heavy chain antibodies (HCAbs) that made up variable regions of heavy chain, CH2, and CH3 domains are shown in camelids. SdAbs derived from camel HCAbs are the smallest known natural building parts for binding to antigen. They also possess a longer antigen recognizing region, which increases their capability for being more specific in target antigen enhancement. Camelid antibodies are highly valuable for their special characteristics, including heat resistance, small size, high solubility in an aqueous environment, and non-immunogenicity in a human environment. Due to these abilities, research on biotechnological production and treatment applications of recombinant smaller fragments of these only HCAbs is widely in progress. In this article, we will discuss the challenges and successes of different types of mAbs targeting EGFR/EGFRvIII in human cancer.     

Generation of functional scFv intrabodies for triggering anti-tumor immunity

Intracellular expression of recombinant antibodies (intrabodies) allows to interfere with the functions of oncogenic or viral molecules expressed in different cell compartments and has therefore a vast clinical potential in therapy. Although the use of phage-display libraries has made it possible to select Fab or single chain Fv (scFv) antibody fragments usable for intracellular targeting, a major source of recombinant antibodies for therapeutic use still remains hybridoma B cells producing well-characterized monoclonal antibodies (mAbs). However, the cloning and the intracellular expression of antibody fragments derived from mAbs can be markedly hampered by a number of technical difficulties that include failure of cloning functional variable regions as well as lack of binding of the antibody fragments to the targeted molecule in an intracellular environment. We discuss herein various molecular methods that have been developed to generate functional recombinant antibody fragments usable as anti-tumor triggering agents when expressed in tumor cells. Such antibodies can neutralize or modify the activity of oncogenic molecules when addressed in specific subcellular compartments and/or they can be used to trigger anti-tumor immunity when expressed on tumor cell surface.     

Multivalency: the hallmark of antibodies used for optimization of tumor targeting by design

High-precision tumor targeting with conventional therapeutics is based on the concept of the ideal drug as a "magic bullet"; this became possible after techniques were developed for production of monoclonal antibodies (mAbs). Innovative DNA technologies have revolutionized this area and enhanced clinical efficiency of mAbs. The experience of applying small-size recombinant antibodies (monovalent binding fragments and their derivatives) to cancer targeting showed that even high-affinity monovalent interactions provide fast blood clearance but only modest retention time on the target antigen. Conversion of recombinant antibodies into multivalent format increases their functional affinity, decreases dissociation rates for cell-surface and optimizes biodistribution. In addition, it allows the creation of bispecific antibody molecules that can target two different antigens simultaneously and do not exist in nature. Different multimerization strategies used now in antibody engineering make it possible to optimize biodistribution and tumor targeting of recombinant antibody constructs for cancer diagnostics and therapy.     

Selecting and screening recombinant antibody libraries

During the past decade several display methods and other library screening techniques have been developed for isolating monoclonal antibodies (mAbs) from large collections of recombinant antibody fragments. These technologies are now widely exploited to build human antibodies with high affinity and specificity. Clever antibody library designs and selection concepts are now able to identify mAb leads with virtually any specificity. Innovative strategies enable directed evolution of binding sites with ultra-high affinity, high stability and increased potency, sometimes to a level that cannot be achieved by immunization. Automation of the technology is making it possible to identify hundreds of different antibody leads to a single therapeutic target. With the first antibody of this new generation, adalimumab (Humira, a human IgG1 specific for human tumor necrosis factor (TNF)), already approved for therapy and with many more in clinical trials, these recombinant antibody technologies will provide a solid basis for the discovery of antibody-based biopharmaceuticals, diagnostics and research reagents for decades to come.     

重组抗体工程及其在肿瘤靶向及癌症治疗中的应用

在过去的十几年中,重组抗体工程在基础研究、医学和药物生产上已经成为最有希望的领域之一。重组抗体及其片段在正在进行诊断和治疗的临床试验中占所有生物蛋白的30％以上。研究集中在抗体作为理想的癌症靶向试剂方面,最近由于FDA批准使用第一个工程化治疗抗体而使热度达到极点。过去的几年中,在设计、筛选及生产新型工程化抗体方面已经取得了重大进展。改革的筛选方法已经能够分离出高亲和力的癌－靶向及抗病毒的抗体,后能够抑制病毒用于基因治疗。癌症诊断和治疗的另一个策略是将重组抗体片段与放射性同位素、药物、毒素、酶以及生物传感器表面进行融合。双特异性抗体及相关融合蛋白也已经生产出来用于癌症的免疫治疗,在抗癌疫苗以及T细胞补充策略上有效地增强了人免疫应答。     

Optimization of humanized IgGs in glycoengineered Pichia pastoris

As the fastest growing class of therapeutic proteins, monoclonal antibodies (mAbs) represent a major potential drug class. Human antibodies are glycosylated in their native state and all clinically approved mAbs are produced by mammalian cell lines, which secrete mAbs with glycosylation structures that are similar, but not identical, to their human counterparts. Glycosylation of mAbs influences their interaction with immune effector cells that kill antibody-targeted cells. Here we demonstrate that human antibodies with specific human N-glycan structures can be produced in glycoengineered lines of the yeast Pichia pastoris and that antibody-mediated effector functions can be optimized by generating specific glycoforms. Glycoengineered P. pastoris provides a general platform for producing recombinant antibodies with human N-glycosylation.     

Advances in the production and downstream processing of antibodies

Sales of monoclonal antibody (mAbs) therapies exceeded $ 40 billion in 2010 and are expected to reach $ 70 billion by 2015. The majority of the approved antibodies are targeting cancer and autoimmune diseases with the top 5 grossing antibodies populating these two areas. In addition over 100 monoclonal antibodies are in Phase II and III of clinical development and numerous others are in various pre-clinical and safety studies. Commercial production of monoclonal antibodies is one of the few biotechnology manufacturing areas that has undergone significant improvements and standardization over the last ten years. Platform technologies have been established based on the structural similarities of these molecules and the regulatory requirements. These improvements include better cell lines, advent of high-performing media free of animal-derived components, and advances in bioreactor and purification processes. In this chapter we will examine the progress made in antibody production as well as discuss the future of manufacturing for these molecules, including the emergence of single use technologies.     

A simplified techno-economic model for the molecular pharming of antibodies

By the end of 2017, the Food and Drug Administration had approved a total of 77 therapeutic monoclonal antibodies (mAbs), most of which are still manufactured today. Furthermore, global sales of mAbs topped $90 billion in 2017 and are projected to reach $125 billion by 2020. The mAbs approved for human therapy are mostly produced using Chinese hamster ovary (CHO) cells, which require expensive infrastructure for production and purification. Molecular pharming in plants is an alternative approach with the benefits of lower costs, greater scalability, and intrinsic safety. For some platforms, the production cycle is also much quicker. But do these advantages really stack up in economic terms? Earlier techno-economic evaluations have focused on specific platforms or processes and have used different methods, making direct comparisons challenging and the overall benefits of molecular pharming difficult to gauge. Here, we present a simplified techno-economic model for the manufacturing of mAbs, which can be applied to any production platform by focusing on the most important factors that determine the efficiency and cost of bulk drug manufacturing. This model develops economic concepts to identify variables that can be used to achieve cost savings by simultaneously modeling the dynamic costs of upstream production at different scales and the corresponding downstream processing costs for different manufacturing modes (sequential, serial, and continuous). The use of simplified models will help to achieve meaningful comparisons between diverse manufacturing technologies.     

Construction of humanized anti-ganglioside monoclonal antibodies with potent immune effector functions

 Gangliosides GD3, GD2 and GM2, which are the major gangliosides expressed on most human cancers of neuroectodermal and epithelial origin, have been focused on as effective targets for passive immunotherapy with monoclonal antibodies. We previously developed a chimeric anti-GD3 mAb, KM871, and a humanized anti-GM2 mAb, KM8969, which specifically bound to the respective antigen with high affinity and showed potent immune effector functions. Humanization of anti-ganglioside antibody is expected to enhance its use for human cancer therapy. In the present study, we generated a chimeric anti-GD2 mAb, KM1138, and further developed the humanized form of anti-GD2 and anti-GD3 mAbs by the complementarity-determining regions grafting method. The resultant humanized anti-GD2 mAb, KM8138, and anti-GD3 mAb, KM8871, showed binding affinity and specificity similar to those of their chimeric counterparts. In addition, both humanized mAbs had functional potency comparable to the chimeric mAbs in mediating the immune effector functions, consisting of antibody-dependent cellular cytotoxicity and complement-dependent cytotoxicity. The production of these humanized anti-ganglioside mAbs, with potent effector functions and low immunogenicity, precedes the evaluation of the therapeutic value of anti-ganglioside mAbs in passive immunotherapy and the target validation for ganglioside-based vaccine therapy. Received: 30 November 2000 / Accepted: 30 January 2001     

Recombinant Monoclonal Antibodies,from Tumor Targeting to Cancer Immunotherapy: A Critical Overview

In view of the explosion of the present clinical use of monoclonal antibodies (mAbs), not only in the treatment of cancer, but also of autoimmune diseases, I was asked to review the development of mAbs in tumor diagnosis and therapy, with some illustrations of our own contribution in the field. The initial use of radiolabeled mAbs for tumor targeting and radioimmunotherapy led to the extensive clinical application of unlabeled, “humanized” mAbs for cancer therapy, which I describe with a critical perspective. The introduction of recombinant bispecific antibodies, capable of bridging T lymphocytes with tumor cells and inducing killing of the cancer cells, was found to be mostly active in the treatment of hematological malignancies. Most interestingly, the use of mAbs not directed to the tumor cells, but to inhibitory receptors expressed by cytotoxic T lymphocytes, which trigger them to kill the cancer cells, represents a new form of active cancer immunotherapy. My motivation in writing this review was related to my long-term interactions with several Russian scientists, mentioned at the end of this article.     

Engineered Fc based antibody domains and fragments as novel scaffolds

Therapeutic monoclonal antibodies (mAbs) have been successful for the therapy of a number of diseases mostly cancer and immune disorders. However, the vast majority of mAbs approved for clinical use are full size, typically in IgG1 format. These mAbs may exhibit relatively poor tissue penetration and restricted epitope access due to their large size. A promising solution to this fundamental limitation is the engineering of smaller scaffolds based on the IgG1 Fc region. These scaffolds can be used for the generation of libraries of mutants from which high-affinity binders can be selected. Comprised of the CH2 and CH3 domains, the Fc region is important not only for the antibody effector function but also for its long half-life. This review focuses on engineered Fc based antibody fragments and domains including native (dimeric) Fc and monomeric Fc as well as CH2 and monomeric CH3, and their use as novel scaffolds and binders. The Fc based binders are promising candidate therapeutics with optimized half-life, enhanced tissue penetration and access to sterically restricted binding sites resulting in an increased therapeutic efficacy. This article is part of a Special Issue entitled: Recent advances in molecular engineering of antibody.     

Recent advances in the generation of human monoclonal antibody

The use of monoclonal antibodies (mAbs) has now gained a niche as an epochal breakthrough in medicine. Engineered antibodies (Abs) currently account for over 30% of biopharmaceuticals in clinical trials. Several methods to generate human mAbs have evolved, such as (1) immortalization of antigen-specific human B cell hybridoma technology, (2) generation of chimeric and humanized antibody (Ab) from mouse Ab by genetic engineering, (3) acquisition of antigen-specific human B cells by the phage display method, and (4) development of transgenic mice for producing human mAbs. Besides these technologies, we have independently developed a method to generate human mAbs by combining the method of in vitro immunization using peripheral blood mononuclear cells and the phage display method. In this paper, we review the developments in these technologies for generating human mAbs.     

Antibodies in oncology

Monoclonal antibodies (mAbs) have become one of the largest classes of new therapeutic agents approved for use in oncology, and have revolutionised the treatment of many human malignancies. Clinically useful mAbs can function through several different mechanisms, including inhibition of tumour-related signalling, induction of apoptosis, inhibition of angiogenesis, enhancing host immune response against cancer and targeted delivery of payloads (such as toxins, cytotoxic agents or radioisotopes) to the tumour site. The increasing knowledge of key molecules and cellular pathways involved in tumour induction and progression has led to a rise in the proportion of therapeutic mAbs entering clinical trials. These mAbs consist of various conventional or recombinant, murine, humanised, chimeric or fully human and fusion constructs. In this review, we provide an overview of mAbs approved for use in clinical oncology and those currently in clinical development. We also discuss the mechanisms of action of anti-cancer mAbs, as well as the antigen targets recognised by these antibodies.     

Molecular engineering of antibodies for therapeutic and diagnostic purposes

During the past ten years, monoclonal antibodies (mAbs) have taken center stage in the field of targeted therapy and diagnosis. This increased interest in mAbs is due to their binding accuracy (affinity and specificity) together with the original molecular and structural rules that govern interactions with their cognate antigen. In addition, the effector properties of antibodies constitute a second major advantage associated with their clinical use. The development of molecular and structural engineering and more recently of in vitro evolution of antibodies has opened up new perspectives in the de novo design of antibodies more adapted to clinical and diagnostic use. Thus, efforts are regularly made by researchers to improve or modulate antibody recognition properties, to adapt their pharmacokinetics, engineer their stability, and control their immunogenicity. This review presents the latest molecular engineering results on mAbs with therapeutic and diagnostic applications.     

Molecular engineering of antibodies for therapeutic and diagnostic purposes

During the past ten years, monoclonal antibodies (mAbs) have taken center stage in the field of targeted therapy and diagnosis. This increased interest in mAbs is due to their binding accuracy (affinity and specificity) together with the original molecular and structural rules that govern interactions with their cognate antigen. In addition, the effector properties of antibodies constitute a second major advantage associated with their clinical use. The development of molecular and structural engineering and more recently of in vitro evolution of antibodies has opened up new perspectives in the de novo design of antibodies more adapted to clinical and diagnostic use. Thus, efforts are regularly made by researchers to improve or modulate antibody recognition properties, to adapt their pharmacokinetics, engineer their stability, and control their immunogenicity. This review presents the latest molecular engineering results on mAbs with therapeutic and diagnostic applications.     

Development of new versions of anti-human CD34 monoclonal antibodies with potentially reduced immunogenicity

Despite the widespread clinical use of CD34 antibodies for the purification of human hematopoietic stem/progenitor cells, all the current anti-human CD34 monoclonal antibodies (mAbs) are murine, which have the potential to elicit human antimouse antibody (HAMA) immune response. In the present study, we developed three new mouse anti-human CD34 mAbs which, respectively, belonged to class I, class II and class III CD34 epitope antibodies. In an attempt to reduce the immunogenicity of these three murine mAbs, their chimeric antibodies, which consisted of mouse antibody variable regions fused genetically to human antibody constant regions, were constructed and characterized. The anti-CD34 chimeric antibodies were shown to possess affinity and specificity similar to that of their respective parental murine antibodies. Due to the potentially better safety profiles, these chimeric antibodies might become alternatives to mouse anti-CD34 antibodies routinely used for clinical application.     

Non-agonistic bivalent antibodies that promote c-MET degradation and inhibit tumor growth and others specific for tumor related c-MET

The c-MET receptor has a function in many human cancers and is a proven therapeutic target. Generating antagonistic or therapeutic monoclonal antibodies (mAbs) targeting c-MET has been difficult because bivalent, intact anti-Met antibodies frequently display agonistic activity, necessitating the use of monovalent antibody fragments for therapy. By using a novel strategy that included immunizing with cells expressing c-MET, we obtained a range of mAbs. These c-MET mAbs were tested for binding specificity and anti-tumor activity using a range of cell-based techniques and in silico modeling. The LMH 80 antibody bound an epitope, contained in the small cysteine-rich domain of c-MET (amino acids 519-561), that was preferentially exposed on the c-MET precursor. Since the c-MET precursor is only expressed on the surface of cancer cells and not normal cells, this antibody is potentially tumor specific. An interesting subset of our antibodies displayed profound activities on c-MET internalization and degradation. LMH 87, an antibody binding the loop connecting strands 3d and 4a of the 7-bladed β-propeller domain of c-MET, displayed no intrinsic agonistic activity but promoted receptor internalization and degradation. LMH 87 inhibited HGF/SF-induced migration of SK-OV-3 ovarian carcinoma cells, the proliferation of A549 lung cancer cells and the growth of human U87MG glioma cells in a mouse xenograft model. These results indicate that c-MET antibodies targeting epitopes controlling receptor internalization and degradation provide new ways of controlling c-MET expression and activity and may enable the therapeutic targeting of c-MET by intact, bivalent antibodies.     

Human antibodies from transgenic animals

Laboratory mice provide a ready source of diverse, high-affinity and high-specificity monoclonal antibodies (mAbs). However, development of rodent antibodies as therapeutic agents has been impaired by the inherent immunogenicity of these molecules. One technology that has been explored to generate low immunogenicity mAbs for in vivo therapy involves the use of transgenic mice expressing repertoires of human antibody gene sequences. This technology has now been exploited by over a dozen different pharmaceutical and biotechnology companies toward developing new therapeutic mAbs, and currently at least 33 different drugs in clinical testing--including several in pivotal trials--contain variable regions encoded by human sequences from transgenic mice. The emerging data from these trials provide an early glimpse of the safety and efficacy issues for these molecules. Nevertheless, actual product approval, the biggest challenge so far, is required to fully validate this technology as a drug discovery tool. In the future, it may be possible to extend this technology beyond rodents and use transgenic farm animals to directly generate and produce human sequence polyclonal sera.     

Recombinant polyclonal antibodies for cancer therapy

Although monoclonal antibodies are increasingly used for cancer therapy, remissions are only temporary due to emergence of tumor cell escape variants that are no longer affected by the antibody. The emergence of escape variants could be minimized by multi-targeting of tumor cells with polyclonal antibodies, which would also be more efficient than monoclonal antibodies at mediating effector functions for target destruction. A technology for generating recombinant polyclonal antibodies for cancer therapy has been developed based on the construction and selection of tumor-reactive Fab phage display libraries. The selected Fabs are mass-converted to full-length polyclonal antibody libraries (PCALs) of any isotype and any species. Prototypic PCALs generated against human colorectal cancer cell lines showed that libraries of diverse recombinant antibodies, enriched for reactivity to the cancer cells compared to normal human cells, can be obtained. The success of recombinant polyclonal antibodies as cancer therapeutics will depend on the ability to generate, characterize, and mass-produce PCALs with high ratios of cancer-to-normal reactivities that cross-react with many cancers of the same type.     

抗-D抗体及其应用

Rh血型是仅次于ABO血型系统的人类红细胞抗原系统,至今已发现40多种抗原,但与临床密切相关的是D,C、c、E、e等5种抗原,其中最主要的是D抗原。相应的抗-D抗体无论是在临床输血检测,还是在Rh(D)新生儿溶血病、溶血性输血反应等的防治方面均具有非常重要的意义。传统的抗-D抗体的制备需用人的血清,来源受限。各种抗-D人源性单克隆抗体和基因工程抗体已经成为发展方向。