Alain Beck

Strategies and challenges for the next generation of therapeutic antibodies

Antibodies and related products are the fastest growing class of therapeutic agents. By analysing the regulatory approvals of IgG-based biotherapeutic agents in the past 10 years, we can gain insights into the successful strategies used by pharmaceutical companies so far to bring innovative drugs to the market. Many challenges will have to be faced in the next decade to bring more efficient and affordable antibody-based drugs to the clinic. Here, we discuss strategies to select the best therapeutic antigen targets, to optimize the structure of IgG antibodies and to design related or new structures with additional functions.

Strategies and challenges for the next generation of antibody–drug conjugates

Antibody–drug conjugates (ADCs) are one of the fastest growing classes of oncology therapeutics. After half a century of research, the approvals of brentuximab vedotin (in 2011) and trastuzumab emtansine (in 2013) have paved the way for ongoing clinical trials that are evaluating more than 60 further ADC candidates. The limited success of first-generation ADCs (developed in the early 2000s) informed strategies to bring second-generation ADCs to the market, which have higher levels of cytotoxic drug conjugation, lower levels of naked antibodies and more-stable linkers between the drug and the antibody. Furthermore, lessons learned during the past decade are now being used in the development of third-generation ADCs. In this Review, we discuss strategies to select the best target antigens as well as suitable cytotoxic drugs; the design of optimized linkers; the discovery of bioorthogonal conjugation chemistries; and toxicity issues. The selection and engineering of antibodies for site-specific drug conjugation, which will result in higher homogeneity and increased stability, as well as the quest for new conjugation chemistries and mechanisms of action, are priorities in ADC research.

A recombinant humanized anti-insulin-like growth factor receptor type I antibody (h7C10) enhances the antitumor activity of vinorelbine and anti-epidermal growth factor receptor therapy against human cancer xenografts.

Interaction of insulin‐like growth factor receptor I (IGF‐IR) with its ligands has been reported to induce cell proliferation, transformation and blockade of cell apoptotic functions. IGF‐IR is overexpressed on numerous tumor cell types and its blockade could be of importance for anti‐cancer therapy. We have generated a humanized anti‐IGF‐IR antibody h7C10 that blocks in vitro IGF‐I and IGF‐II‐induced cell proliferation of MCF‐7 breast cancer cells. Analysis of the IGF‐I transduction cascade demonstrated that the humanized anti‐IGF‐IR antibody and its murine parental form block IGF‐I‐induced tyrosine phosphorylation, both its β‐chain and IRS‐1 tyrosine phosphorylation. This presumably leads to cell cycle arrest and, consequently, growth inhibition. Treatment of nude mice bearing either human breast cancer cells (MCF‐7) or non small lung cancer cells (A549) with h7C10, or its murine parental form 7C10, inhibited significantly tumor growth. An almost complete inhibition of A549 tumor growth was observed when mice were treated with the anti‐IGF‐IR antibody combined with either a chemotherapeutic agent, Vinorelbine or an anti‐epidermal growth factor receptor (EGFR) antibody, 225. Combined therapy prolonged significantly the life span of mice in an orthotopic in vivo model of A549; the combination of the anti‐IGF‐IR antibody with an anti‐EGFR antibody was superior to the Vinorelbine combination. The present results indicate that the humanized anti‐IGF‐IR antibody h7C10 has a great potential for cancer therapy when combined with either a chemotherapeutic agent or an antibody that targets other growth factor receptors, such as the epidermal growth factor receptor.

Trends in Glycosylation, Glycoanalysis and Glycoengineering of Therapeutic Antibodies and Fc-Fusion Proteins

Monoclonal antibodies (MAbs) are the fastest growing class of human pharmaceuticals. More than 20 MAbs have been approved and several hundreds are in clinical trials in various therapeutic indications including oncology, inflammatory diseases, organ transplantation, cardiology, viral infection, allergy, and tissue growth and repair. Most of the current therapeutic antibodies are humanized or human Immunoglobulins (IgGs) and are produced as recombinant glycoproteins in eukaryotic cells. Many alternative production systems and improved constructs are also being actively investigated. IgGs glycans represent only an average of around 3% of the total mass of the molecule. Despite this low percentage, particular glycoforms are involved in essential immune effector functions. On the other hand, glycoforms that are not commonly biosynthesized in human may be allergenic, immunogenic and accelerate the plasmatic clearance of the linked antibody. These glyco-variants have to be identified, controlled and limited for therapeutic uses. Glycosylation depends on multiple factors like production system, selected clonal population, manufacturing process and may be genetically or chemically engineered. The present account reviews the glycosylation patterns observed for the current approved therapeutic antibodies produced in mammalian cell lines, details classical and state-of-the-art analytical methods used for the characterization of glycoforms and discusses the expected benefits of manipulating the carbohydrate components of antibodies by bio- or chemical engineering as well as the expected advantages of alternative biotechnological production systems developed for new generation of therapeutic antibodies and Fc-fusion proteins.

Biosimilar, biobetter, and next generation antibody characterization by mass spectrometry.

This Feature will introduce the strategies of therapeutic antibodies (mAbs) in-depth characterization by mass spectrometry (MS) and discuss analytical comparison of biosimilar to originator mAbs, with the cases of trastuzumab and cetuximab. In addition, the structural and functional insights gained both by state-of-the art and emerging MS methods used for biobetters and next generation antibodies design and optimization will also be highlighted.

Identification and characterization of asparagine deamidation in the light chain CDR1 of a humanized IgG1 antibody

Despite technological advances, detection of deamidation in large proteins remains a challenge and the use of orthogonal methods is needed for unequivocal assignment. By a combination of cation-exchange separation, papain digestion, and a panel of mass spectrometry techniques we identified asparagine deamidation in light chain complementarity determining region 1 (CDR1) of a humanized IgG1 monoclonal antibody. The reaction yields both Asp and isoAsp, which were assigned by Edman degradation and by isoAsp detection using protein isoaspartate methyltransferase. The deamidated antibody variants were less potent in antigen binding compared to the nondegraded antibody. Changes in near-UV CD spectra, susceptibility to papain cleavage in an adjacent CDR2 loop, and the tendency of the newly formed isoAsp to undergo isomerization suggest local perturbations in the structure of the isoAsp-containing antibody.

Marketing approval of mogamulizumab: A triumph for glyco-engineering

Therapeutic properties of antibodies strongly depend on the composition of their glycans. Most of the currently approved antibodies are produced in mammalian cell lines, which yield mixtures of different glycoforms that are close to those of humans, but not fully identical. Glyco-engineering is being developed as a method to control the composition of carbohydrates and to enhance the pharmacological properties of mAbs. The recent approval in Japan of mogamulizumab (POTELIGEO®), the first glyco-engineered antibody to reach the market, is a landmark in the field of therapeutic antibodies. Mogamulizumab is a humanized mAb derived from Kyowa Hakko Kirin’s POTELLIGENT® technology, which produces antibodies with enhanced antibody-dependent cell-mediated cytotoxicity (ADCC) activity. The approval was granted April 30, 2012 by the Japanese Ministry of Health, Labour and Welfare for patients with relapsed or refractory CCR4-positive adult T-cell leukemia-lymphoma.

Therapeutic Fc-fusion proteins and peptides as successful alternatives to antibodies

Therapeutic antibodies have captured substantial attention due to the relatively high rate at which these products reach marketing approval, and the subsequent commercial success they frequently achieve. In the 2000s, a total of 20 antibodies (18 full-length IgG and 2 Fab) were approved by the Food and Drug Administration (FDA) or European Medicines Agency (EMA). In the 2010s to date, an additional 3 antibodies (denosumab, belimumab, ipilimumab) have been approved and one antibody-drug conjugate (brentuximab vedotin) is undergoing regulatory review and may be approved in the US by August 30, 2011. However, a less heralded group of antibody-based therapeutics comprising proteins or peptides fused with an Fc is following the success of classical antibodies.

The immunodominant influenza matrix T cell epitope recognized in human induces influenza protection in HLA-A2/Kb transgenic mice

The protective efficacy of the influenza matrix protein epitope 58-66 (called M1), recognized in the context of human HLA-A2 molecules, was evaluated in a HLA-A2/K(b) transgenic mouse model of lethal influenza infection. Repeated subcutaneous immunizations with M1 increased the percentage of survival. This effect was mediated by T cells since protection was abolished following in vivo depletion of all T lymphocytes, CD8(+), or CD4(+) T cells. The survival correlated with the detection of memory CD8(+) splenocytes able to proliferate in vitro upon stimulation with M1 and to bind M1-loaded HLA-A2 dimers, as well as with M1-specific T cells in the lungs, which were directly cytotoxic to influenza-infected cells following influenza challenge. These results demonstrated for the first time that HLA-A2-restricted cytotoxic T cells specific for the major immunodominant influenza matrix epitope are protective against the infection. They encourage further in vivo evaluation of T cell epitopes recognized in the context of human MHC molecules.

Correct primary structure assessment and extensive glyco-profiling of cetuximab by a combination of intact, middle-up, middle-down and bottom-up ESI and MALDI mass spectrometry techniques

The European Medicines Agency received recently the first marketing authorization application for a biosimilar monoclonal antibody (mAb) and adopted the final guidelines on biosimilar mAbs and Fc-fusion proteins. The agency requires high similarity between biosimilar and reference products for approval. Specifically, the amino acid sequences must be identical. The glycosylation pattern of the antibody is also often considered to be a very important quality attribute due to its strong effect on quality, safety, immunogenicity, pharmacokinetics and potency. Here, we describe a case study of cetuximab, which has been marketed since 2004. Biosimilar versions of the product are now in the pipelines of numerous therapeutic antibody biosimilar developers. We applied a combination of intact, middle-down, middle-up and bottom-up electrospray ionization and matrix assisted laser desorption ionization mass spectrometry techniques to characterize the amino acid sequence and major post-translational modifications of the marketed cetuximab product, with special emphasis on glycosylation. Our results revealed a sequence error in the reported sequence of the light chain in databases and in publications, thus highlighting the potency of mass spectrometry to establish correct antibody sequences. We were also able to achieve a comprehensive identification of cetuximab’s glycoforms and glycosylation profile assessment on both Fab and Fc domains. Taken together, the reported approaches and data form a solid framework for the comparability of antibodies and their biosimilar candidates that could be further applied to routine structural assessments of these and other antibody-based products.