Development of ADA against recombinant human interferon beta in immune tolerant mice requires rapid recruitment of CD4⁺ T cells, induces formation of germinal centers but lacks susceptibility for (most) adjuvants.

Immunological processes leading to formation of antidrug antibodies (Abs) against recombinant human proteins remain poorly understood. Animal and clinical studies revealed that immunogenicity shares both T-cell-dependent (requirement of CD4(+) T cells, isotype switching) and T-cell-independent (involvement of Marginal Zone B cells, apparent lack of memory) characteristics. We used immune tolerant mice to study the mechanism underlying immunogenicity in more detail.

Practical considerations for the pharmacokinetic and immunogenic assessment of antibody-drug conjugates.

Currently, the most bioanalytically challenging drugs are antibody-drug conjugates (ADCs), constructs comprising a monoclonal antibody and a cytotoxic drug connected by a linker. The bioanalytical challenges arise from the heterogeneous nature of ADCs and their complex in vivo behavior, resulting in a high number of analytes to be measured. Measuring the concentration of biologics in blood/plasma/serum is a necessity to properly assess their pharmacokinetic (PK)/pharmacodynamic behaviors in vivo.

Development of a transgenic mouse model to study the immunogenicity of recombinant human insulin.

Mouse models are commonly used to assess the immunogenicity of therapeutic proteins and to investigate the immunological processes leading to antidrug antibodies. The aim of this work was to develop a transgenic (TG) Balb/c mouse model for evaluating the immunogenicity of recombinant human insulin (insulin) formulations. Validation of the model was performed by measuring the antibody response against plain and particulate insulin in TG and nontransgenic (NTG) mice.

Antibody response against Betaferon® in immune tolerant mice: involvement of marginal zone B-cells and CD4+ T-cells and apparent lack of immunological memory.

Purpose: The immunological processes underlying immunogenicity of recombinant human therapeutics are poorly understood. Using an immune tolerant mouse model we previously demonstrated that aggregates are a major trigger of the antidrug antibody (ADA) response against recombinant human interferon beta (rhIFNβ) products including Betaferon®, and that immunological memory seems to be lacking after a rechallenge with non-aggregated rhIFNβ. The apparent absence of immunological memory indicates a CD4+ T-cell independent (Tind) immune response underlying ADA formation against Betaferon®.

Natural antibodies against bone morphogenic proteins and interferons in healthy donors and in patients with infections linked to type-1 cytokine responses.

In patients receiving recombinant therapeutic proteins, the production of antibodies against the therapeutics is a rising problem. The antibodies can neutralize and interfere with the efficacy and safety of drugs and even cause severe side effects if they cross-react against the natural, endogenous protein. Various factors have been identified to influence the immunogenic potential of recombinant human therapeutics, including several patients' characteristics.

Oxidized and aggregated recombinant human interferon beta is immunogenic in human interferon beta transgenic mice.

Purpose: To study the effect of oxidation on the structure of recombinant human interferon beta-1a (rhIFNβ-1a) and its immunogenicity in wild-type and immune-tolerant transgenic mice.

Methods: Untreated rhIFNβ-1a was degraded by metal-catalyzed oxidation, H(2)O(2)-mediated oxidation, and guanidine-mediated unfolding/refolding. Four rhIFNβ-1a preparations with different levels of oxidation and aggregation were injected intraperitoneally in mice 15× during 3 weeks.

Aggregated recombinant human interferon Beta induces antibodies but no memory in immune-tolerant transgenic mice.

Purpose: To study the influence of protein aggregation on the immunogenicity of recombinant human interferon beta (rhIFNbeta) in wild-type mice and transgenic, immune-tolerant mice, and to evaluate the induction of immunological memory.

Methods: RhIFNbeta-1b and three rhIFNbeta-1a preparations with different aggregate levels were injected intraperitoneally in mice 15x during 3 weeks, and the mice were rechallenged with rhIFNbeta-1a. The formation of binding (BABs) and neutralizing antibodies (NABs) was monitored.

Immunological mechanism underlying the immune response to recombinant human protein therapeutics.

Recombinant human (rhu) protein therapeutics are powerful tools to treat several severe diseases such as multiple sclerosis and diabetes mellitus, among others. A major drawback of these proteins is the production of anti-drug antibodies (ADAs). In some cases, these ADAs have neutralizing capacity and can interfere with the efficacy and safety of the drug.

B-1 cells and naturally occurring antibodies: influencing the immunogenicity of recombinant human therapeutic proteins?

Recombinant human therapeutic proteins are increasingly being used to treat serious and life-threatening diseases like multiple sclerosis, diabetes mellitus, and cancer. An important side effect of these proteins is the development of antidrug antibodies, which can be neutralizing and thus interfere with the efficacy and safety of the drug. Some biophysical properties, for example, aggregation, also can initiate the immunogenic response to human therapeutics.

Hybrid transgenic immune tolerant mouse model for assessing the breaking of B cell tolerance by human interferon beta.

To date, the therapeutic efficacy of recombinant human proteins is limited by their potential to break B cell tolerance in patients. The formation of neutralising antibodies (NABs) directed against recombinant human interferon beta (rhIFNbeta) is associated with a decrease in the therapeutic effect of the protein. For this reason, there is a need to study factors that can cause the immunogenicity of rhIFNbeta.