Development and validation of a novel semi-homogenous clinical assay for quantitation of Ranibizumab in human serum.

Ranibizumab (Lucentis®), a humanized antigen-binding fragment (Fab) monoclonal antibody that blocks VEGF-A activity, is currently approved for the treatment of several retinal degenerative diseases. The assessment of drug pharmacokinetics (PK) is essential for evaluating exposure as it relates to drug safety and efficacy. For drugs administered intravitreally, systemic drug levels during the course of clinical studies are typically 100 to 1000-fold lower than those of similar therapeutics dosed intravenously, posing a significant bioanalytical challenge for PK measurements. Thus, the development of a highly-sensitive assay for measuring pg/mL levels of ranibizumab in patients' sera after intravitreal administration was needed to support clinical studies. In this report, we describe the development of a novel method that utilizes a high-affinity murine monoclonal anti-ranibizumab-VEGF-complexes antibody (MARA) reagent to measure ranibizumab in human serum. The assay format utilizes a semi-homogeneous solution phase step using a monoclonal antibody (the MARA) that binds specifically to the ranibizumab-VEGF complex, but not to either alone. This unique reagent exhibited low non-specific binding and high selectivity, increasing signal-to-noise readouts and maximizing assay sensitivity. The resulting MARA enzyme-linked immunosorbent assay (ELISA) has a lower limit of quantification of 15 pg/mL in human serum. In the assay, serum samples are incubated overnight with a mixture containing biotinylated-VEGF and MARA, which form a three-molecule complex with ranibizumab in the sample. These complexes are then captured onto streptavidin-coated wells, followed by enzymatic detection using a horseradish peroxidase-labeled-anti-murine antibody reagent and a colorimetric reaction. The assay conditions were optimized to allow for quantitative detection of "total" ranibizumab levels in serum. The assay was fully validated, establishing its high tolerance to sample matrix, as well as its suitable specificity, accuracy, dilution linearity, as well as intra- and inter-assay precision. The MARA ELISA's novel and unique approach has resulted in a considerably more sensitive ranibizumab PK assay compared to earlier versions of this assay. The MARA ELISA has been used for PK measurements in multiple ranibizumab studies, supporting this drug's life-cycle management and related preclinical and clinical-development studies.

A novel immunoassay to measure total serum lymphotoxin-α levels in the presence of an anti-LTα therapeutic antibody.

During drug development, measurement of suitable pharmacodynamic biomarkers is key to establishing in vivo drug activity. Binding of monoclonal antibody (mAb) therapeutics to soluble target proteins often results in elevated serum levels of their target antigen, and measuring total (free and bound) concentration of the target antigen can be an important means of demonstrating that the mAb has reached its specific target. However, accurately measuring soluble circulating antigen in preclinical or clinical samples in the presence of a therapeutic mAb presents a bioanalytical challenge. Particularly in the case of low molecular weight and/or multimeric targets, epitopes for capture and detection of the target by reagent antibodies can be obscured by bound therapeutic mAb. Lymphotoxin-alpha (LTα) is a cytokine in the TNF superfamily that has been implicated in the pathophysiology of autoimmune disease, and is a therapeutic target for neutralizing mAb. During preclinical safety studies in cynomolgus macaques, we encountered difficulties in measuring total LTα in serum of dosed animals. When serum LTα trimer was saturated with the anti-LTα mAb, binding of two reagent antibodies, as required for a classic sandwich ELISA, was not feasible, and dissociation methods were also found to be unsuitable. We therefore developed an approach in which excess anti-LTα mAb was added to the in vitro assay system to fully saturate all binding sites, and an anti-idiotypic antibody was used to detect bound therapeutic antibody. Using this method, total LTα could be accurately measured in cynomolgus macaque serum, and was observed to increase with increasing anti-LTα therapeutic mAb dose. Additional in vitro studies demonstrated that the method worked equally well in human serum. This assay strategy will be useful for quantifying total concentrations of other small and/or multimeric target proteins in the presence of a therapeutic antibody.

Generation and characterization of a unique reagent that recognizes a panel of recombinant human monoclonal antibody therapeutics in the presence of endogenous human IgG.

Pharmacokinetic (PK) and immunohistochemistry (IHC) assays are essential to the evaluation of the safety and efficacy of therapeutic monoclonal antibodies (mAb) during drug development. These methods require reagents with a high degree of specificity because low concentrations of therapeutic antibody need to be detected in samples containing high concentrations of endogenous human immunoglobulins. Current assay reagent generation practices are labor-intensive and time-consuming. Moreover, these practices are molecule-specific and so only support one assay for one program at a time. Here, we describe a strategy to generate a unique assay reagent, 10C4, that preferentially recognizes a panel of recombinant human mAbs over endogenous human immunoglobulins. This "panel-specific" feature enables the reagent to be used in PK and IHC assays for multiple structurally-related therapeutic mAbs. Characterization revealed that the 10C4 epitope is conformational, extensive and mainly composed of non-CDR residues. Most key contact residues were conserved among structurally-related therapeutic mAbs, but the combination of these residues exists at low prevalence in endogenous human immunoglobulins. Interestingly, an indirect contact residue on the heavy chain of the therapeutic appears to play a critical role in determining whether or not it can bind to 10C4, but has no affect on target binding. This may allow us to improve the binding of therapeutic mAbs to 10C4 for assay development in the future. Here, for the first time, we present a strategy to develop a panel-specific reagent that can expedite the development of multiple clinical assays for structurally-related therapeutic mAbs.

Evaluation of heterophilic antibody blocking agents in reducing false positive interference in immunoassays for IL-17AA, IL-17FF, and IL-17AF.

IL-17AA, IL-17FF, and IL-17AF are proinflammatory cytokines that have been implicated in the pathogenesis of autoimmune diseases such as rheumatoid arthritis (RA). In order to measure the levels of these cytokines in synovial fluid and serum samples from RA patients, immunoassays specific for IL-17AA, FF, and AF were developed. Although these assays could tolerate up to 50% pooled normal human serum, false positive reactivity was problematic in patient samples suggesting interference from heterophilic antibodies. We therefore evaluated the ability of several commercially available heterophilic antibody blocking agents to reduce false positive reactivity by testing them against samples that were confirmed as false positives in the IL-17AA, FF, and AF assays. Several of the blockers performed well, including HBR-1, HBR-9, HBR-11, HBR-Plus, Serum Cytokine Assay Diluent, and IIR. We chose to move forward using IIR blocker for sample analysis and verified that IIR had no effect on the assay standard curves and did not affect IL-17 quantitation in plasma from ex vivo stimulated human whole blood. IL-17FF and IL-17AF were below the limits of quantitation of the assays (12.3 and 10.5pg/ml, respectively) in synovial fluid and serum samples from patients with RA and osteoarthritis (OA). For the more sensitive IL-17AA assay (1.6pg/ml limit of quantitation), low levels of IL-17AA were measurable in 48% of RA synovial fluid samples (mean, 7.9pg/ml; median, <1.6pg/ml; range, <1.6-29.7pg/ml; n=23) but not in synovial fluid from patients with OA (n=33). For serum samples, however, IL-17AA was below the limit of detection for both RA and OA patients. When these same serum samples were analyzed in the absence of a heterophilic antibody blocker, false positive reactivity yielded apparent mean IL-17AA levels of 43.3pg/ml (28% positive; n=50) and 14.8pg/ml (12% positive; n=50) for RA and OA patients, respectively, results that could potentially be interpreted as consistent with disease biology. These studies demonstrate the importance of ensuring that HAb interference is well controlled, particularly when measuring low concentrations of cytokines in samples from patients with autoimmune disease.

Antibodies specific for a segment of human membrane IgE deplete IgE-producing B cells in humanized mice.

IgE-mediated hypersensitivity is central to the pathogenesis of asthma and other allergic diseases. Although neutralization of serum IgE with IgE-specific antibodies is in general an efficacious treatment for allergic asthma, one limitation of this approach is its lack of effect on IgE production. Here, we have developed a strategy to disrupt IgE production by generating monoclonal antibodies that target a segment of membrane IgE on human IgE-switched B cells that is not present in serum IgE. This segment is known as the M1' domain, and using genetically modified mice that contain the human M1' domain inserted into the mouse IgE locus, we demonstrated that M1'-specific antibodies reduced serum IgE and IgE-producing plasma cells in vivo, without affecting other immunoglobulin isotypes. M1'-specific antibodies were effective when delivered prophylactically and therapeutically in mouse models of immunization, allergic asthma, and Nippostrongylus brasiliensis infection, likely by inducing apoptosis of IgE-producing B cells. In addition, we generated a humanized M1'-specific antibody that was active on primary human cells in vivo, as determined by its reduction of serum IgE levels and IgE plasma cell numbers in a human PBMC-SCID mouse model. Thus, targeting of human IgE-producing B cells with apoptosis-inducing M1'-specific antibodies may be a novel treatment for asthma and allergy.

Species-dependent serum interference in a sandwich ELISA for Apo2L/TRAIL.

To support pre-clinical studies of Apo2L/TRAIL in rodents and non-human primates, a sandwich ELISA was developed using two mouse monoclonal anti-Apo2L/TRAIL antibodies. Mouse, rat, cynomolgus monkey, and chimpanzee serum at concentrations of > or =1% were found to interfere with accurate quantitation of Apo2L/TRAIL. Moreover, the characteristics of the serum interference for each species were different. In order to resolve the observed serum effect, studies were performed in which salts, detergents, and blocking proteins were added to the sample diluent, and optimized sample diluents that eliminated serum interference were developed for mouse, cynomolgus monkey, and chimpanzee serum. These buffers consisted of a base assay diluent (PBS/0.5% BSA/0.05% Tween-20/10 ppm ProClin 300) supplemented with: NaCl (mouse serum); NaCl, EDTA, CHAPS, bovine gamma globulin (BGG), and human IgG (cynomolgus monkey serum); and NaCl and EDTA (chimpanzee serum). Full characterization studies were performed for the "buffer" ELISA run in base assay diluent (intended for non-serum samples) as well as the assays optimized for mouse serum and cynomolgus monkey serum. Precision, accuracy, linearity, and specificity were found to be satisfactory. With the availability of a rabbit polyclonal antibody against Apo2L/TRAIL, a new pAb/mAb ELISA was developed. This assay was not only more sensitive by > or =6-fold, but it was also much less subject to serum interference.

Simple quantitative live cell and anti-idiotypic antibody based ELISA for humanized antibody directed to cell surface protein CD20.

Rituxan, a chimeric anti-CD20 antibody, has been used for treating non-Hodgkin's lymphoma and some autoimmune diseases. However, a humanized anti-CD20 antibody is desirable for long-term treatment of autoimmune diseases. CD20 is an integral membrane protein with a small intervening extracellular loop. Lacking a native soluble CD20 protein, we developed a simple cell-based enzyme-linked immunosorbent assay (ELISA) using live WIL2 cells in a 96-well format to measure relative binding affinity to support the humanization process. Although WIL2 cells grow in suspension and require centrifugation during the wash steps, the assay was quantitative and reproducible. We also demonstrated that cloned adherent transfected Chinese hamster ovary (CHO) cells could be used to improve assay throughput. For clinical studies requiring quantification of the humanized antibody in serum, we used an alternate approach and developed a high throughput ELISA using an anti-idiotypic antibody as a surrogate antigen for capture and an anti-idiotypic antibody for detection to overcome serum effects. These assay strategies may be applied for characterization of other antibodies directed to multitransmembrane proteins.