From rodent reagents to human therapeutics using antibody guided selection

Guided selection is a method of producing a human version of a rodent or any other non-human antibody. The process is a serial transition from rodent to human via rodent-human chimaerics, through to a panel of human antibodies with similar characteristics to those of the starting rodent antibody. The guided selection process can be undertaken using either phage display or ribosome display, and chimaeric antibodies can be made either in series or parallel, with or without the retention of the original rodent CDR3s. Guided selection has successfully been used for the generation of a number of human versions of rodent antibodies, including HUMIRA, an inhibitor of tumour necrosis factor-alpha which is approved for the treatment of moderate to severe rheumatoid arthritis in over 40 countries.     

Metrics for antibody therapeutics development

A wide variety of full-size monoclonal antibodies (mAbs) and therapeutics derived from alternative antibody formats can be produced through genetic and biological engineering techniques. These molecules are now filling the preclinical and clinical pipelines of every major pharmaceutical company and many biotechnology firms. Metrics for the development of antibody therapeutics, including averages for the number of candidates entering clinical study and development phase lengths for mAbs approved in the United States, were derived from analysis of a dataset of over 600 therapeutic mAbs that entered clinical study sponsored, at least in part, by commercial firms. The results presented provide an overview of the field and context for the evaluation of on-going and prospective mAb development programs. The expansion of therapeutic antibody use through supplemental marketing approvals and the increase in the study of therapeutics derived from alternative antibody formats are discussed.     

Tailor-made antibody therapeutics

Therapeutic antibodies represent one of the fastest growing areas of the pharmaceutical industry. There are currently 18 monoclonal antibodies in the market that have been approved by the FDA and over 150 in clinical developments. Driven by innovation and technological developments, scientists have gone beyond the traditional antibody molecules. Antibodies have been engineered in a variety of ways to meet the challenges posed by different biological settings. Described in this review is an abridged account of the different ways antibodies have been tailored to make them efficient drug molecules.     

Probabilities of success for antibody therapeutics

Probabilities of success (POS) play a key role in determining the distribution of resources by both investors and the pharmaceutical industry. Resources such as time, money and personnel are more likely to be directed toward programs in categories with acceptable rates of success. What is considered acceptable may, of course, vary between companies and other decision-makers. With the increased focus on development of antibody therapeutics, it is important for stakeholders to understand the utility, and limitations, of POS values such as cumulative approval success rates and clinical phase transition probabilities. A key point is that cumulative approval success rates are derived from data for only those candidates with known fates (either approved or terminated), but clinical phase transition probability calculations include data on the status of all candidates.     

Glycosylation of recombinant antibody therapeutics

The adaptive immune system has the capacity to produce antibodies with a virtually infinite repertoire of specificities. Recombinant antibodies specific for human targets are established in the clinic as therapeutics and represent a major new class of drug. Therapeutic efficacy depends on the formation of complexes with target molecules and subsequent activation of downstream biologic effector mechanisms that result in elimination of the target. The activation of effector mechanisms is dependent on structural characteristics of the antibody molecule that result from posttranslational modifications, in particular, glycosylation. The production of therapeutic antibody with a consistent human glycoform profile has been and remains a considerable challenge to the biopharmaceutical industry. Recent research has shown that individual glycoforms of antibody may provide optimal efficacy for selected outcomes. Thus a further challenge will be the production of a second generation of antibody therapeutics customized for their clinical indication.     

Potent antibody therapeutics by design

Antibodies constitute the most rapidly growing class of human therapeutics and the second largest class of drugs after vaccines. The generation of potent antibody therapeutics, which I review here, is an iterative design process that involves the generation and optimization of antibodies to improve their clinical potential.     

Isotype can affect the fine specificity of an antibody for a polysaccharide antigen

Ab specificity is determined by V region sequence. The murine Mab 18B7 (IgG1) binds to the Cryptococcus neoformans capsular polysaccharide glucuronoxylomannan and produces annular immunofluorescence (IF) on yeast cells. The heavy and light V regions of 18B7 were expressed with the human C regions micro, gamma 1, gamma 2, gamma 3, gamma 4, and alpha1, and the specificity and binding properties of these mouse-human chimeric (ch) Abs was determined. The chIgG1, chIgG2, chIgG4, and the chIgA produced annular IF, whereas the IgM and IgG3 produced punctate IF, despite identical V region sequences. Competition experiments with murine Abs that competed with mAb 18B7 and binding assays to peptide mimetics of glucuronoxylomannan provided additional evidence for altered specificity in some of the ch Abs. Expression of 18B7 heavy V region with murine micro C region produced IgM with a punctate IF, indicating that a change in fine specificity also accompanied the change from murine IgG1 to IgM. Our results show that Ab fine specificity can be a function of isotype. This phenomenon may be most apparent for Abs that bind to Ag with repeating epitopes, such as polysaccharides, where the quarternary structure of the Ag-Ab complex may be influenced by such constraints as Fab-Fab angles, Fc-Fc interactions, Ab size, and solvent accessibility to exposed surfaces. Alterations in Ab fine specificity following isotype change could have important implications for current concepts on the generation of secondary Ab responses to certain Ags and for the isotype preference observed in Abs to polysaccharides.     

Non-viral adeno-associated virus-based platform for stable expression of antibody combination therapeutics: Non-viral adeno-associated virus-based platform for stable expression of antibody combination therapeutics

Antibody combination therapeutics (ACTs) are polyvalent biopharmaceuticals that are uniquely suited for the control of complex diseases, including antibiotic resistant infectious diseases, autoimmune disorders and cancers. However, ACTs also represent a distinct manufacturing challenge because the independent manufacture and subsequent mixing of monoclonal antibodies quickly becomes cost prohibitive as more complex mixtures are envisioned. We have developed a virus-free recombinant protein expression platform based on adeno-associated viral (AAV) elements that is capable of rapid and consistent production of complex antibody mixtures in a single batch format. Using both multiplexed immunoassays and cation exchange (CIEX) chromatography, cell culture supernatants generated using our system were assessed for stability of expression and ratios of the component antibodies over time. Cultures expressing combinations of three to ten antibodies maintained consistent expression levels and stable ratios of component antibodies for at least 60 days. Cultures showed remarkable reproducibility following cell banking, and AAV-based cultures showed higher stability and productivity than non-AAV based cultures. Therefore, this non-viral AAV-based expression platform represents a predictable, reproducible, quick and cost effective method to manufacture or quickly produce for preclinical testing recombinant antibody combination therapies and other recombinant protein mixtures.     

Isotype determination of anti-Trypanosoma cruzi antibody in murine Chagas' disease.

Isotypic analysis of anti-parasite humoral responses of C57B1/6 and C3H (He) mice surviving acute Trypanosoma cruzi infection showed that both mouse strains demonstrate IgG1, IgG2a, IgG2b, and IgM enzyme-linked immunosorbent assay titers from days 21 to 300 of infection. Using the western blot technique to determine the antigen specificity of the isotypic responses, 100-day infected C3H mice showed strong IgG1, IgG2a, and IgG2b responses to many antigens, whereas C57B1/6 mice showed weak responses to fewer antigens. Isotype western blots showed that reactivity to the T. cruzi antigen of 75-77 kDa is present in the humoral response of day 21-infected mice that will survive and missing in those that will not survive. In general, surviving immunized C3H mice respond with IgG1, IgG2a, and IgG2b reactions to the 75-77-kDa and other antigens, whereas resistant B6 mice concentrate their anti-T. cruzi response in the IgG2b isotype to the 75-77-kDa antigen. Perhaps induction of ineffective antibody responses to nonprotective antigens is beneficial to the parasite and detrimental to the host.     

The promise and pitfalls of monoclonal antibody therapeutics

Recent experience has helped to clarify the best ways to use monoclonal antibodies to solve clinical problems. For example, imaging based on tumor antigens, rather than tumor size, will permit early detection of cancer and accurate staging. Blocking receptor—ligand interactions may permit therapeutic intervention in cell growth or function but activity may depend on the choice of an antiligand or antireceptor strategy. Humanized antibodies will achieve greater intensity and duration of therapy, while allowing repeat administration in chronic diseases.     

The birth pangs of monoclonal antibody therapeutics

This paper examines the development and termination of nebacumab (Centoxin®), a human IgM monoclonal antibody (mAb) drug frequently cited as one of the notable failures of the early biopharmaceutical industry. The non-approval of Centoxin in the United States in 1992 generated major concerns at the time about the future viability of any mAb therapeutics. For Centocor, the biotechnology company that developed Centoxin, the drug posed formidable challenges in terms of safety, clinical efficacy, patient selection, the overall economic costs of health care, as well as financial backing. Indeed, Centocor's development of the drug brought it to the brink of bankruptcy. This article shows how many of the experiences learned with Centoxin paved the way for the current successes in therapeutic mAb development.     

Non-viral adeno-associated virus-based platform for stable expression of antibody combination therapeutics

Antibody combination therapeutics (ACTs) are polyvalent biopharmaceuticals that are uniquely suited for the control of complex diseases, including antibiotic resistant infectious diseases, autoimmune disorders and cancers. However, ACTs also represent a distinct manufacturing challenge because the independent manufacture and subsequent mixing of monoclonal antibodies quickly becomes cost prohibitive as more complex mixtures are envisioned. We have developed a virus-free recombinant protein expression platform based on adeno-associated viral (AAV) elements that is capable of rapid and consistent production of complex antibody mixtures in a single batch format. Using both multiplexed immunoassays and cation exchange (CIEX) chromatography, cell culture supernatants generated using our system were assessed for stability of expression and ratios of the component antibodies over time. Cultures expressing combinations of three to ten antibodies maintained consistent expression levels and stable ratios of component antibodies for at least 60 days. Cultures showed remarkable reproducibility following cell banking, and AAV-based cultures showed higher stability and productivity than non-AAV based cultures. Therefore, this non-viral AAV-based expression platform represents a predictable, reproducible, quick and cost effective method to manufacture or quickly produce for preclinical testing recombinant antibody combination therapies and other recombinant protein mixtures.     

Analytical comparability study of recombinant monoclonal antibody therapeutics

Process changes are inevitable in the life cycle of recombinant monoclonal antibody therapeutics. Products made using pre- and post-change processes are required to be comparable as demonstrated by comparability studies to qualify for continuous development and commercial supply. Establishment of comparability is a systematic process of gathering and evaluating data based on scientific understanding and clinical experience of the relationship between product quality attributes and their impact on safety and efficacy. This review summarizes the current understanding of various modifications of recombinant monoclonal antibodies. It further outlines the critical steps in designing and executing successful comparability studies to support process changes at different stages of a product's lifecycle.