The INNs and outs of antibody nonproprietary names.

An important step in drug development is the assignment of an International Nonproprietary Name (INN) by the World Health Organization (WHO) that provides healthcare professionals with a unique and universally available designated name to identify each pharmaceutical substance. Monoclonal antibody INNs comprise a -mab suffix preceded by a substem indicating the antibody type, e.g., chimeric (-xi-), humanized (-zu-), or human (-u-). The WHO publishes INN definitions that specify how new monoclonal antibody therapeutics are categorized and adapts the definitions to new technologies. However, rapid progress in antibody technologies has blurred the boundaries between existing antibody categories and created a burgeoning array of new antibody formats. Thus, revising the INN system for antibodies is akin to aiming for a rapidly moving target. The WHO recently revised INN definitions for antibodies now to be based on amino acid sequence identity. These new definitions, however, are critically flawed as they are ambiguous and go against decades of scientific literature. A key concern is the imposition of an arbitrary threshold for identity against human germline antibody variable region sequences. This leads to inconsistent classification of somatically mutated human antibodies, humanized antibodies as well as antibodies derived from semi-synthetic/synthetic libraries and transgenic animals. Such sequence-based classification implies clear functional distinction between categories (e.g., immunogenicity). However, there is no scientific evidence to support this. Dialog between the WHO INN Expert Group and key stakeholders is needed to develop a new INN system for antibodies and to avoid confusion and miscommunication between researchers and clinicians prescribing antibodies.

A HER2-specific Modified Fc Fragment (Fcab) Induces Antitumor Effects Through Degradation of HER2 and Apoptosis.

FS102 is a HER2-specific Fcab (Fc fragment with antigen binding), which binds HER2 with high affinity and recognizes an epitope that does not overlap with those of trastuzumab or pertuzumab. In tumor cells that express high levels of HER2, FS102 caused profound HER2 internalization and degradation leading to tumor cell apoptosis. The antitumor effect of FS102 in patient-derived xenografts (PDXs) correlated strongly with the HER2 amplification status of the tumors. Superior activity of FS102 over trastuzumab or the combination of trastuzumab and pertuzumab was observed in vitro and in vivo when the gene copy number of HER2 was equal to or exceeded 10 per cell based on quantitative polymerase chain reaction (qPCR). Thus, FS102 induced complete and sustained tumor regression in a significant proportion of HER2-high PDX tumor models. We hypothesize that the unique structure and/or epitope of FS102 enables the Fcab to internalize and degrade cell surface HER2 more efficiently than standard of care antibodies. In turn, increased depletion of HER2 commits the cells to apoptosis as a result of oncogene shock. FS102 has the potential of a biomarker-driven therapeutic that derives superior antitumor effects from a unique mechanism-of-action in tumor cells which are oncogenically addicted to the HER2 pathway due to overexpression.

Limits for antibody affinity maturation and repertoire diversification in hypervaccinated humans.

The immune system is known to generate a diverse panel of high-affinity Abs by adaptively improving the recognition of pathogens during ongoing immune responses. In this study, we report the biological limits for Ag-driven affinity maturation and repertoire diversification by analyzing Ab repertoires in two adult volunteers after each of three consecutive booster vaccinations with tetanus toxoid. Maturation of on-rates and off-rates occurred independently, indicating a kinetically controlled affinity maturation process. The third vaccination induced no significant changes in the distribution of somatic mutations and binding rate constants implying that the limits for affinity maturation and repertoire diversification had been reached. These fully matured Ab repertoires remained similar in size, genetically diverse, and dynamic. Somatic mutations and kinetic rate constants showed normal and log-normal distribution profiles, respectively. Mean values can therefore be considered as biological constants defining the observed boundaries. At physiological temperature, affinity maturation peaked at k(on) = 1.6 × 10(4) M(-1) s(-1) and k(off) = 1.7 × 10(-4) s(-1) leading to a maximum mean affinity of K(D) = 1.0 × 10(-9) M. At ambient temperature, the average affinity increased to K(D) = 3.4 × 10(-10) M mainly due to slower off-rates. This experimentally determined set of constants can be used as a benchmark for analysis of the maturation level of human Abs and Ab responses.

Extensive restrictions in the VH sequence usage of the human antibody response against the Rhesus D antigen.

Anti-Rhesus D immunoglobulin purified from human sera is used as a prophylactic reagent in Rhesus D negative women at risk of alloimmunization during pregnancy. We are currently developing a Rhesus D antigen-specific recombinant polyclonal antibody drug lead for replacing the existing blood derived-products. By analyzing the RhD-specific antibody VH repertoires from eight alloimmunized women we found, in agreement with previous studies, a strong preference for the VH 3-33 "superspecies" gene segments which encompasses the IGHV3-30-3*01, IGHV3-30*18, and IGHV3-33*01 VH alleles. Even more extensive genetic restriction was observed among five donors, which produced antibodies of identical V-D-J usage and CDR3 loop length and joining regions of similar amino acid composition. In addition, we find a high degree of sequence relatedness to previously isolated anti-Rhesus D antibodies. Such close homology in VH domains indicates that significant structural restrictions are operating in the selection of antibodies recognizing RhD as seen for T cell receptors. Moreover, some VH domains were isolated in their germline configuration indicating that anti-RhD antibodies of relatively high affinity are present in the naïve antibody repertoire of Rhesus negative individuals which offers an explanation for the strong and clinically significant immunogenicity of the Rhesus D.

Reduced susceptibility of recombinant polyclonal antibodies to inhibitory anti-variable domain antibody responses.

The immunogenicity of therapeutic Abs is a concern as anti-drug Abs may impact negatively on the pharmacodynamics and safety profile of Ab drugs. The factors governing induction of anti-drug Abs are not fully understood. In this study, we describe a model based on mouse-human chimeric Abs for the study of Ab immunogenicity in vivo. Six chimeric Abs containing human V regions and mouse C regions were generated from six human anti-Rhesus D Abs and the Ag-binding characteristics of the parental human Abs were retained. Analysis of the immune response toward the individual chimeric Abs revealed the induction of anti-variable domain Abs including anti-idiotypic Abs against some of these, thereby demonstrating the applicability of the model for studying anti-drug Ab responses in vivo. Immunization of BALB/c, C57, and outbred NMRI mice with a polyclonal composition consisting of all six chimeric Abs demonstrated that the immunogenicity of the individual Abs was haplotype dependent. Chimeric Abs, which were nonimmunogenic when administered individually, did not become immunogenic as part of the polyclonal composition, implying the absence of epitope spreading. Ex vivo Ab-binding studies established a clear correlation between the level of immunogenicity of the Abs comprised in the composition and the impact on the pharmacology of the Abs. These analyses demonstrate that under these conditions this polyclonal Ab composition was generally less susceptible to blocking Abs than the respective mAbs.

Recombinant polyclonal antibodies: the next generation of antibody therapeutics?

Antibodies have been used as therapeutics in various forms for over a century. Traditional immunoglobulin therapy has the advantage of reflecting the diversity of the natural immune response but has very limited clinical applications. However, over the past ten years more than 30 monoclonal antibodies have been successfully introduced on to the drug market. The monoclonal approach provides the advantage of specificity, but lacks efficacy in the treatment of diseases caused by complex antigens. Recombinant polyclonal antibodies, the third generation of antibody therapeutics, have the ability to tackle complex and highly mutagenic targets, and will undoubtedly offer a promising commercial future.

Recombinant human polyclonal antibodies: A new class of therapeutic antibodies against viral infections.

The mammalian immune system eliminates pathogens by generating a specific antibody response. Polyclonality is a key feature of this immune response: the immune system produces antibodies which bind to different structures on a given pathogen thereby increasing the likelihood of its elimination. The vast majority of current recombinant antibody drugs rely on monospecific monoclonal antibodies. Inherently, such antibodies do not represent the benefits of polyclonality utilized by a natural immune system and this has impeded the identification of efficacious antibody drugs against infectious agents, including viruses. The development of novel technologies has allowed the identification and manufacturing of antigen-specific recombinant polyclonal human antibodies, so-called symphobodies. This review describes the rationale for designing drugs based on symphobodies against pathogenic viruses, including HIV, vaccinia and smallpox virus, and respiratory syncytial virus.

Allergen-specific polyclonal antibodies reduce allergic disease in a mouse model of allergic asthma.

BACKGROUND: Recombinant allergen-specific immunoglobulin G (IgG) antibody therapy can reduce allergic asthma symptoms by inhibiting the immunoglobulin E (IgE)-mediated allergic response. This study investigated the effect of intranasally administered allergen-specific monoclonal (mAb) and polyclonal (pAb) antibody on airway inflammation and hyperresponsiveness (AHR) in a mouse model of human asthma. METHODS: Ovalbumin (OVA)-specific IgG2b antibodies were generated by phage display using spleens from OVA-immunized mice, and screening against OVA and finally expressed in CHO cells. Sensitized mice were treated intranasally with either a recombinant anti-OVA mAb (gc32) or a polyclonal preparation comprising seven selected antibodies (including gc32). Control mice received diluent only, OVA only, a control polymeric IgG or dexamethasone. Following challenge with nebulized OVA, investigators assessed airway inflammation by histology and cellular composition of the bronchoalveolar fluid, and methacholine-induced airway hyperresponsiveness (AHR). Serum levels of total and OVA-specific IgE were measured by ELISA. RESULTS: Sensitized mice developed airway inflammation and AHR in response to OVA challenge. Intranasally administered OVA-specific murine polyclonal or monoclonal IgG2b antibodies both reduced OVA-induced lung inflammation. Polyclonal, but not anti-OVA mAb, also reduced AHR and eosinophil influx into the airway lumen. Both anti-OVA antibody preparations reduced levels of specific IgE with no effect on total IgE levels. CONCLUSIONS: Intranasal treatment with allergen-specific pAb reduces pulmonary inflammation and AHR in a mouse model of allergic asthma, but allergen-specific mAb reduces inflammation only. Allergen-specific recombinant pAb offers a potentially valuable therapeutic approach to the management of allergic asthma.

Production of target-specific recombinant human polyclonal antibodies in mammalian cells.

We describe the expression and consistent production of a first target-specific recombinant human polyclonal antibody. An anti-Rhesus D recombinant polyclonal antibody, Sym001, comprised of 25 unique human IgG1 antibodies, was produced by the novel Sympress expression technology. This strategy is based on site-specific integration of antibody genes in CHO cells, using the FRT/Flp-In recombinase system. This allows integration of the expression construct at the same genomic site in the host cells, thereby reducing genomic position effects. Different bioreactor batches of Sym001 displayed highly consistent manufacturing yield, antibody composition, binding potency, and functional activity. The results demonstrate that diverse recombinant human polyclonal antibody compositions can be reproducibly generated under conditions directly applicable to industrial manufacturing settings and present a first recombinant polyclonal antibody which could be used for treatment of hemolytic disease of the newborn and/or idiopathic thrombocytopenic purpura.

Isolation of human antibody repertoires with preservation of the natural heavy and light chain pairing.

The humoral immune system in higher vertebrates is unique in its ability to generate highly diverse antibody responses against most pathogens as well as against certain malignancies. Several technologies have been developed to exploit this vast source of potentially therapeutic antibodies, including hybridoma technology, phage display and yeast display. Here, we present a novel, high-throughput technology (the Symplex Technology) for rapid direct cloning and identification of human antigen-specific high-affinity antibodies from single antibody-producing cells of immune individuals. The utility of the technology was demonstrated by isolation of diverse sets of unique high-affinity antibodies against tetanus toxoid and influenza virus from immunized volunteers. Hence, the Symplex Technology is a new method for the rapid isolation of high-affinity antibodies directly from humans.