Matthias Thorolfsson

Aggregation of a multidomain protein: a coagulation mechanism governs aggregation of a model IgG1 antibody under weak thermal stress.

Using an IgG1 antibody as a model system, we have studied the mechanisms by which multidomain proteins aggregate at physiological pH when incubated at temperatures just below their lowest thermal transition. In this temperature interval, only minor changes to the protein conformation are observed. Light scattering consistently showed two coupled phases: an initial fast phase followed by several hours of exponential growth of the scattered intensity. This is the exact opposite of the lag‐time behavior typically observed in protein fibrillation. Dynamic light scattering showed the rapid formation of an aggregate species with a hydrodynamic radius of about 25 nm, which then increased in size throughout the experiment. Theoretical analysis of our light scattering data showed that the aggregate number density goes through a maximum in time providing compelling evidence for a coagulation mechanism in which aggregates fuse together. Both the analysis as well as size‐exclusion chromatography of incubated samples showed the actual increase in aggregate mass to be linear and reach saturation long before all molecules had been converted to aggregates. The CH2 domain is the only domain partly unfolded in the temperature interval studied, suggesting a pivotal role of this least stable domain in the aggregation process. Our results show that for multidomain proteins at temperatures below their thermal denaturation, transient unfolding of a single domain can prime the molecule for aggregation, and that the formation of large aggregates is driven by coagulation.

Small‐Angle X‐ray Scattering Screening Complements Conventional Biophysical Analysis: Comparative Structural and Biophysical Analysis of Monoclonal Antibodies IgG1, IgG2, and IgG4

A crucial step in the development of therapeutic monoclonal antibodies is the selection of robust pharmaceutical candidates and screening of efficacious protein formulations to increase the resistance toward physicochemical degradation and aggregation during processing and storage. Here, we introduce small-angle X-ray scattering (SAXS) to characterize antibody solution behavior, which strongly complements conventional biophysical analysis. First, we apply a variety of conventional biophysical techniques for the evaluation of structural, conformational, and colloidal stability and report a systematic comparison between designed humanized IgG1, IgG2, and IgG4 with identical variable regions. Then, the high information content of SAXS data enables sensitive detection of structural differences between three IgG subclasses at neutral pH and rapid formation of dimers of IgG2 and IgG4 at low pH. We reveal subclass-specific variation in intermolecular repulsion already at low and medium protein concentrations, which explains the observed improved stability of IgG1 with respect to aggregation. We show how excipients dramatically influence such repulsive effects, hence demonstrating the potential application of extensive SAXS screening in antibody selection, eventual engineering, and formulation development.

In-depth analysis of subclass-specific conformational preferences of IgG antibodies

An extended analysis of structural ensembles obtained from small-angle X-ray scattering data reveals subclass-specific conformational preferences of IgG antibodies, which are largely determined by the hinge-region structure.

Monoclonal Antibodies Follow Distinct Aggregation Pathways During Production-Relevant Acidic Incubation and Neutralization

PurposeAggregation aspects of therapeutic monoclonal antibodies (mAbs) are of common concern to the pharmaceutical industry. Low pH treatment is applied during affinity purification and to inactivate endogenous retroviruses, directing interest to the mechanisms of acid-induced antibody aggregation.MethodsWe characterized the oligomerization kinetics at pH 3.3, as well as the reversibility upon neutralization, of three model mAbs with identical variable regions, representative of IgG1, IgG2 and IgG4 respectively. We applied size-exclusion high performance liquid chromatography and orthogonal analytical methods, including small-angle X-ray scattering and dynamic light scattering and supplemented the experimental data with crystal structure-based spatial aggregation propensity (SAP) calculations.ResultsWe revealed distinct solution behaviors between the three mAb models: At acidic pH IgG1 retained monomeric, whereas IgG2 and IgG4 exhibited two-phase oligomerization processes. After neutralization, IgG2 oligomers partially reverted to the monomeric state, while on the contrary, IgG4 oligomers tended to aggregate. Subclass-specific aggregation-prone motifs on the Fc fragments were identified, which may lead to two distinct pathways of reversible and irreversible aggregation, respectively.ConclusionsWe conclude that subtle variations in mAb sequence greatly affect responses towards low-pH incubation and subsequent neutralization, and demonstrate how orthogonal biophysical methods distinguish between reversible and irreversible mAb aggregation pathways at early stages of acidic treatment.

High level expression, purification and activation of human dipeptidyl peptidase I from mammalian cells

Dipeptidyl peptidase I (DPPI) plays a crucial role in maturation of many regulatory peptides and has been suggested as a pharmaceutical target in several inflammatory diseases. It is also a useful processing enzyme for the generation of authentic protein products by catalyzing the removal of N-terminal fusion peptides. We used a robust transient transfection system in human embryonic kidney 293 cells to exploit expression and activation of DPPI from chicken, rat and man for the development of an industrial production process. The expression of human and rat DPPI was significantly higher in the human HEK293 cell line than that obtained with avian DPPI. A CHO K1SV stable cell line was selected as the optimal stable host system for production of human DPPI yielding expression levels higher than 1.5 g/L. The secreted pro-DPPI underwent auto-maturation during defined buffer conditions during the purification steps. Active human DPPI was purified with a three-step purification strategy employing: Butyl Sepharose 4 Fast Flow, Sephadex G-25 Medium and Q Sepharose Fast Flow chromatography. The final yield of active enzyme was approximately 1 g/L cell culture. The enzyme exhibited exopeptidase activity against both a dipeptide-p-nitroanilide substrate and N-terminally extended MEAE-hGH (Met-Glu-Ala-Glu-human growth hormone). In conclusion, an efficient production process for recombinant human DPPI has been developed including a highly efficient and stable CHO cell system and an efficient purification procedure, which is simple and easy to scale for industrial purposes. The present data facilitates not only industrial applications of DPPI as a processing enzyme, but also provides active enzyme useful in the identification of small molecule inhibitors.