T-cell-dependent antibody responses in the rat: forms and sources of keyhole limpet hemocyanin matter.

The T-cell-dependent antibody response (TDAR) is a functional assay used in immunopharmacology and immunotoxicology to assess ability to mount an antibody response to immunization. Keyhole limpet hemocyanin (KLH) is extensively used as the immunogen of choice in non-clinical and clinical settings. Native KLH is comprised of high molecular weight (HMW; 4-8 MDa) assemblies of KLH subunit dimers (> 600-800 kDa). It is not known how the different forms (HMW vs subunit) and manufacturing processes (commercial sources) may impact the nature of anti-KLH immune responses (e.g. magnitude and inter-animal variability). Anti-KLH IgM and IgG responses were studied in Sprague-Dawley rats immunized with different forms and commercial sources of KLH: 100 µg of HMW KLH from two different sources or subunit KLH from three different sources. Biophysical and biochemical analyses were conducted to characterize the KLH formulations. Anti-KLH IgM and IgG responses were measured using a proprietary indirect quantitative electrochemiluminescence immunoassay. The HMW KLH preparations showed a greater number of sub-visible particles (2-150 µm size range) than the subunit KLH preparations. All HMW KLH and all subunit KLH were equivalent on SEC (hydrodynamic volume), PAGE (size and charge), and SDS-PAGE (molecular radius). Robust primary and secondary anti-KLH responses were detected for both sources of HMW KLH. The subunit KLH immunizations resulted in lower IgG and IgM responses compared to the HMW KLH, with the exception of Stellar Biotechnologies subunit KLH that produced both robust primary and secondary responses, which approached the HMW KLH responses. Inter-animal variability for IgM and IgG responses was lower with HMW KLH than with subunit KLH. In conclusion, different forms and commercial sources of KLH were associated with different magnitudes and inter-animal variability in IgM and IgG responses, a critical finding to take into consideration when designing TDAR studies for robust immunotoxicology or immunopharmacology testing.

Statistical and bioanalytical considerations for establishing a depletion criterion for specificity testing during immunogenicity assessment of a biotherapeutic.

Immunogenicity assessment of fully human monoclonal antibody-based biotherapeutics requires sensitive and specific ligand binding assays. One of the components of specificity is the depletion of signal by a relevant biotherapeutic that is commonly based on an arbitrary depletion criterion of inhibition of the original response or reduction of the signal below the screening assay cut point (ACP). Hence, there is a need to develop a statistically derived physiologically relevant specificity criterion. We illustrate an optimization approach to determine the concentration of biotherapeutic required for the specificity evaluation. Naïve donor sample sets with and without circulating drug and antitherapeutic/drug antibody (ADA) were prepared. Next, a depletion cut point (DCP) using naïve and ADA-containing donor sets with the optimized biotherapeutic concentration was evaluated. A statistically derived design of experiment was used to establish a validated DCP. A reliable DCP requires naïve (no ADA) donors treated only with an optimized concentration of biotherapeutic. The additional DCPs generated using two distinct concentrations of ADA-spiked sample sets led to a physiologically irrelevant criterion that was not necessarily representative of real-time samples. This increased the risk of false positives or negatives. In this study, well-defined bioanalytical and statistical methods were employed to validate a DCP to confirm the presence of biotherapeutic specific ADA in human serum samples. A physiologically relevant and effective strategy to confirm specificity in immune reactive samples, especially those that are close to the ACP, is proposed through this study.

Clinical validation of the "in silico" prediction of immunogenicity of a human recombinant therapeutic protein.

Antibodies elicited by protein therapeutics can cause serious side effects in humans. We studied immunogenicity of a recombinant fusion protein (FPX) consisting of two identical, biologically active, peptides attached to human Fc fragment. EpiMatrix, an in silico epitope-mapping tool, predicted promiscuous T-cell epitope(s) within the 14-amino-acid carboxy-terminal region of the peptide portion of FPX. On administration of FPX in 76 healthy human subjects, 37% developed antibodies after a single injection. A memory T-cell response against the above carboxy-terminus of the peptide was observed in antibody-positive but not in antibody-negative subjects. Promiscuity of the predicted T-cell epitope(s) was confirmed by representation of all common HLA alleles in antibody-positive subjects. As predicted by EpiMatrix, HLA haplotype DRB1*0701/1501 was associated with the highest T-cell and antibody response. In conclusion, in silico prediction can be successfully used to identify Class II restricted T-cell epitopes within therapeutic proteins and predict immunogenicity thereof in humans.

Use of biosensors to monitor the immune response.

Biosensor instruments, such as the BIACORE, are gaining popularity for analysing serum samples for the presence of antibodies. These instruments offer several advantages in the detection and subsequent characterization of clinically relevant antibodies generated in response to administration of therapeutic proteins. Much like other common immunoassay platforms, immobilized ligand is used to capture antibodies. Unlike conventional approaches, the ligand is immobilized to the surface of a biosensor chip, with detection based upon surface plasmon resonance. This assay platform, therefore, does not require reporter molecules such as enzymes, fluorochromes or radioisotopes that are common to conventional immunoassay methodologies. Additional desirable features of the biosensor platform include real-time detection of the binding of antibody to ligand (for kinetic measurements) as well as straightforward characterization of antibody isotype, specificity and relative concentration. This is all performed with minimum serum requirements (typically 10 microlitres per sample analysed) in a fully automated environment. The unique features of the biosensor instrument warrant that these assays are referred to as biosensor immunoassays to clearly distinguish them from more conventional immunoassay methodologies, such as ELISA.

Applications for the new electrochemiluminescent (ECL) and biosensor technologies.

Biosensor and electrochemiluminescent (ECL) assays are replacing enzyme-linked immunosorbent assays (ELISAs) at Schering-Plough as immunoassays of choice to monitor cytokine levels and detect anti-cytokine antibody responses during cytokine therapy. These new assays provide increased sensitivity and a better correlation with biological assays. Biosensor assays using the BIACORE 2000 (BIACORE, Uppsala, Sweden) are being adopted to support preclinical and clinical trials for the detection of antibodies capable of binding to IL-10 and IL-4. Significant advantages when using a biosensor assay are that real-time and label-free detection permit increased throughput and direct detection of binding interactions which enables detection of low affinity antibodies that are not detected by ELISA. The ECL assays using the ORIGEN Analyser (IGEN, Gaithersburg, MD) that we have implemented to replace existing ELISAs for quantification of serum IL-10 and serum interferon alfa levels are more sensitive and less subject to matrix effects. Data obtained during the validation of these assays are described.

Validation parameters for a novel biosensor assay which simultaneously measures serum concentrations of a humanized monoclonal antibody and detects induced antibodies.

This report documents the validation of an assay using BIAcore 2000 that, with a single injection of mouse serum, allows the quantitation of a humanized monoclonal antibody and can also detect the presence of antibodies directed against this humanized antibody. The important components required for the validation of biosensor assays including precision, accuracy, linearity, stability of the immobilized ligand, specificity and sensitivity are addressed. The tandem assay that is used as a model for biosensor validations is accomplished by flowing each sample across the surface of two flowcells in sequence. The first flowcell has the antigen that the humanized mAb was generated against immobilized while the humanized mAb itself is immobilized on the second flowcell. The quantitation component of this assay is precise and accurate with a limit of quantitation of 1 microg/ml in mouse serum samples. Any antibodies directed against the humanized mAb can be detected and also characterized as to isotype. This unique assay can be performed with as little as 10 microl of serum which is then diluted ten-fold prior to analysis. The small sample requirement allows analysis of individual mouse serum samples rather than requiring the use of pooled samples from multiple mice. A further advantage of this assay is the automation capability which allows unattended operation.