Interactions of the anti-FcRn monoclonal antibody, rozanolixizumab, with Fcγ receptors and functional impact on immune cells in vitro.

Rozanolixizumab is a humanized anti-neonatal Fc receptor (FcRn) monoclonal antibody (mAb) of the immunoglobulin G4 (IgG4) sub-class, currently in clinical development for the treatment of IgG autoantibody-driven diseases. This format is frequently used for therapeutic mAbs due to its intrinsic lower affinity for Fc gamma receptors (FcγR) and lack of C1q engagement. However, with growing evidence suggesting that no Fc-containing agent is truly "silent" in this respect, we explored the engagement of FcγRs and potential functional consequences with rozanolixizumab. In the study presented here, rozanolixizumab was shown to bind to FcγRs in both protein-protein and cell-based assays, and the kinetic data were broadly as expected based on published data for an IgG4 mAb. Rozanolixizumab was also able to mediate antibody bipolar bridging (ABB), a phenomenon that led to a reduction of labeled FcγRI from the surface of human macrophages in an FcRn-dependent manner. However, the presence of exogenous human IgG, even at low concentrations, was able to prevent both binding and ABB events. Furthermore, data from in vitro experiments using relevant human cell types that express both FcRn and FcγRI indicated no evidence for functional sequelae in relation to cellular activation events (e.g., intracellular signaling, cytokine production) upon either FcRn or FcγR binding of rozanolixizumab. These data raise important questions about whether therapeutic antagonistic mAbs like rozanolixizumab would necessarily engage FcγRs at doses typically administered to patients in the clinic, and hence challenge the relevance and interpretation of in vitro assays performed in the absence of competing IgG.

Development of recombinant hemoglobin-based oxygen carriers.

SIGNIFICANCE: The worldwide blood shortage has generated a significant demand for alternatives to whole blood and packed red blood cells for use in transfusion therapy. One such alternative involves the use of acellular recombinant hemoglobin (Hb) as an oxygen carrier. RECENT ADVANCES: Large amounts of recombinant human Hb can be expressed and purified from transgenic Escherichia coli. The physiological suitability of this material can be enhanced using protein-engineering strategies to address specific efficacy and toxicity issues. Mutagenesis of Hb can (i) adjust dioxygen affinity over a 100-fold range, (ii) reduce nitric oxide (NO) scavenging over 30-fold without compromising dioxygen binding, (iii) slow the rate of autooxidation, (iv) slow the rate of hemin loss, (v) impede subunit dissociation, and (vi) diminish irreversible subunit denaturation. Recombinant Hb production is potentially unlimited and readily subjected to current good manufacturing practices, but may be restricted by cost. Acellular Hb-based O(2) carriers have superior shelf-life compared to red blood cells, are universally compatible, and provide an alternative for patients for whom no other alternative blood products are available or acceptable. CRITICAL ISSUES: Remaining objectives include increasing Hb stability, mitigating iron-catalyzed and iron-centered oxidative reactivity, lowering the rate of hemin loss, and lowering the costs of expression and purification. Although many mutations and chemical modifications have been proposed to address these issues, the precise ensemble of mutations has not yet been identified. FUTURE DIRECTIONS: Future studies are aimed at selecting various combinations of mutations that can reduce NO scavenging, autooxidation, oxidative degradation, and denaturation without compromising O(2) delivery, and then investigating their suitability and safety in vivo.

Xenobiotic geometry and media pH determine cytotoxicity through solubility.

Polychlorinated biphenyls (PCBs), a class of 209 individual congeners, have become persistent and ubiquitous environmental contaminants. The health impacts of PCBs, such as cancer, cardiovascular disease, developmental toxicity, and neurotoxicity, have been widely reported, but for many of these, the mechanisms of toxicity are still poorly understood. Many mechanistic studies involve cultured cells where the biological activity is dependent upon the solubility of the xenobiotic. In the present study, we investigated the factors that determine solubility as measured by diffraction spectroscopy and have modeled, with semiempirical and ab initio molecular orbital methods, the dihedral angle and calculated the dipole moment of a series of monofluorinated analogues (F-PCBs 3) of 4-chlorobiphenyl (PCB 3) as model compounds in vacuum and in water. We found a strong positive correlation between the dihedral angle, the rotation energy, the cavitation energy, the solubility, and the cytotoxicity in three human cell lines. The dipole moment was of minor influence. We also determined the influence of pH changes in a medium containing 10% fetal bovine serum (FBS), changes that could be expected when cells in culture are removed from a CO 2 incubator even for a short time. We found that the solubility is strongly affected by the pH and that this effect is not reversed by subsequent pH readjustment. In a study examining cytotoxicity, we showed that the actual pH and the pH history of a medium containing FBS were of major influence. We suggest that pH-driven changes in the tertiary and quaternary structure of albumin are responsible. These observations have implications for studies of the biological activity of semisoluble compounds, like PCBs and related compounds.

A plasmid system for optimization of Fab' production in Escherichia coli: importance of balance of heavy chain and light chain synthesis.

We demonstrate the importance of optimizing the balance of light chain (LC) and heavy chain (HC) expression to achieve high level production of Fab' fragments in the Escherichia coli periplasm. The LC:HC balance has been controlled by varying the codon usage of the signal peptide (SP) and 5' mature domain coding regions. Different SP coding regions have been identified from a codon wobble-based library using alkaline phosphatase (AP) as a reporter gene. A plasmid system that enables random combination of these variant SP coding regions is used to construct optimized Fab' expression plasmids. These small plasmid libraries facilitated selection of optimal Fab' expression plasmids and resulted in increases of periplasmic yield, up to 580 mgL(-1) from E. coli fermentations and will enable rapid variable region subcloning and selection of future Fab(') expression plasmids.