Martha Hokom

Megakaryocyte growth and development factor. Analyses of in vitro effects on human megakaryopoiesis and endogenous serum levels during chemotherapy-induced thrombocytopenia.

The present study shows that recombinant human megakaryocyte growth and development factor (r-HuMGDF) behaves both as a megakaryocyte colony stimulating factor and as a differentiation factor in human progenitor cell cultures. Megakaryocyte colony formation induced with r-HuMGDF is synergistically affected by stem cell factor but not by interleukin 3. Megakaryocytes stimulated with r-HuMGDF demonstrate progressive cytoplasmic and nuclear maturation. Measurable levels of megakaryocyte growth and development factor in serum from patients undergoing myeloablative therapy and transplantation are shown to be elaborated in response to thrombocytopenic stress. These data support the concept that megakaryocyte growth and development factor is a physiologically regulated cytokine that is capable of supporting several aspects of megakaryopoiesis.

Highly aggregated antibody therapeutics can enhance the in vitro innate and late-stage T-cell immune responses

Background: Aggregated biotherapeutics have the potential to induce an immune response. Results: Aggregates can enhance innate and adaptive immune responses of PBMC. Conclusion: The response depends on aggregate type, immunogenicity of the monomer, donor immune status, and high particle numbers in the in vitro assay. Significance: This is the first study showing the impact of aggregate characteristics on the potential immune response of PBMC. Aggregation of biotherapeutics has the potential to induce an immunogenic response. Here, we show that aggregated therapeutic antibodies, previously generated and determined to contain a variety of attributes (Joubert, M. K., Luo, Q., Nashed-Samuel, Y., Wypych, J., and Narhi, L. O. (2011) J. Biol. Chem. 286, 25118–25133), can enhance the in vitro innate immune response of a population of naive human peripheral blood mononuclear cells. This response depended on the aggregate type, inherent immunogenicity of the monomer, and donor responsiveness, and required a high number of particles, well above that detected in marketed drug products, at least in this in vitro system. We propose a cytokine signature as a potential biomarker of the in vitro peripheral blood mononuclear cell response to aggregates. The cytokines include IL-1β, IL-6, IL-10, MCP-1, MIP-1α, MIP-1β, MMP-2, and TNF-α. IL-6 and IL-10 might have an immunosuppressive effect on the long term immune response. Aggregates made by stirring induced the highest response compared with aggregates made by other methods. Particle size in the 2–10 μm range and the retention of some folded structure were associated with an increased response. The mechanism of aggregate activation at the innate phase was found to occur through specific cell surface receptors (the toll-like receptors TLR-2 and TLR-4, FcγRs, and the complement system). The innate signal was shown to progress to an adaptive T-cell response characterized by T-cell proliferation and secretion of T-cell cytokines. Investigating the ability of aggregates to induce cytokine signatures as biomarkers of immune responses is essential for determining their risk of immunogenicity.

The role of megakaryocyte growth and development factor in terminal stages of thrombopoiesis.

Thrombopoietin (TPO), the ligand for the c‐Mpl cytokine receptor, is a recently identified cytokine with potent effects on platelet production. The receptor‐binding portion of c‐Mpl ligand is encompassed in another molecule known as megakaryocyte growth and development factor, or MGDF. Although it is clear that the administration of TPO or MGDF to animals dramatically increases the platelet count, the specific stage(s) of thrombopoiesis during which these molecules are principally active have not been unambiguously determined. Pharmacology studies administering MGDF at doses ranging from 0.1 to 630 μg/kg/d to mice revealed a biphasic response in platelet production. Administration of the drug at concentrations from 6 to 60 μg/kg/d resulted in platelet counts 5‐fold above normal. However, doses >60 μg/kg/d resulted in less‐than‐optimal platelet production. This phenomenon was investigated in vitro. Using an established culture system for the generation of human megakaryocytes and platelets, MGDF was shown to be optimally and equivalently active in the generation of mature megakaryocytes at concentrations from 10 to 1000 ng/ml. However, the cytokine was not required for proplatelet formation and in fact was inhibitory to that process in a dose‐dependent manner. When MGDF was added to human megakaryocytes at concentrations of 200 ng/ml or greater, proplatelet formation was inhibited to 30% of control values. MGDF‐mediated inhibition was specific, since the addition of the truncated form of the c‐Mpl receptor reversed the inhibition in a dose‐dependent manner. Other recombinant factors, interleukin‐6, interleukin‐11 and erythropoietin had no significant positive or negative effects in this human proplatelet assay. Together, these data suggest that although TPO and MGDF promote the full spectrum of megakaryocyte growth and development, they are not necessary for proplatelet formation, and may in part regulate platelet shedding by their absence.

Identification and inhibition of drug target interference in immunogenicity assays

A well-designed anti-drug antibody (ADA) immunoassay is critical for appropriately monitoring the immunogenicity profile of a therapeutic protein during its development. AMG 386 is a peptide-Fc fusion protein that inhibits angiogenesis by preventing the interaction of angiopoietins with the Tie2 receptor. In bridging immunoassays for ADA, interference by the drug target, present in the assay sample, can result in false positive antibody detection. We used a statistical design-of-experiments approach to identify angiopoietin interference in bridging immunoassays of anti-AMG 386 antibodies. We also demonstrated that a high-affinity monoclonal antibody, directed against an epitope on angiopoietin that competes with AMG 386 binding, could inhibit the angiopoietin interference while preserving the detection of ADA. This report describes the development and validation of methodologies for evaluating and addressing drug target interference in bioanalytical assays that involve interactions between drug, ADA, immune complexes, and drug target.

Development of a Human Antibody Tolerant Mouse Model to Assess the Immunogenicity Risk Due to Aggregated Biotherapeutics

We describe a novel human immunoglobulin G2 (IgG2 )-tolerant and immune-competent heterozygous mouse model (Xeno-het) developed by crossbreeding a human Ig-tolerized XenoMouse® with a C57BL/6J wild-type mouse. The Xeno-het mouse expresses both mouse and human immunoglobulin G (IgG) genes, resulting in B-cells expressing human and mouse IgG, and secretion of human and mouse Ig into serum. This model was utilized to evaluate the immunogenicity risk of aggregated and chemically modified human antibodies. The mice were tested for their ability to break tolerance to self-tolerant monomeric antibodies. Aggregates made by mechanical stirring elicited an anti-drug antibody (ADA) response, but did not induce a robust and long-term memory B and T-cell response. Chemically modified antibodies made by oxidation were only weak and transient inducers of an immune response, as measured by a lack of both an ADA response and a B-cell antigen-specific response. Aggregate size was an important characteristic, as specific-sized protein-coated beads were able to elicit an immune response. We propose the use of this model to identify risk factors such as aggregation during manufacturing at early development for an increased potential immunogenicity risk.