Authors
Brakti, I., Henriksen, A., Tomczak, M. L., Godsk, S. L., Lenton, S., Fodera, V., Groenning, M.
Abstract
In a pharmaceutical setting, understanding the factors governing monoclonal antibody (mAb) attractive interactions in formulations is highly warranted as many solution phenomena such as liquid-liquid phase separation (LLPS) result from their preferential self-interaction. While the effect of locally accumulated charge in the variable region has been recognized as an important factor in mediating non-specific mAb self-assembly, the effect of charge asymmetry, i.e. the distribution of oppositely charges residues, has been much less studied experimentally. Moreover, most studies restrict such analyses to the variable region of mAbs, leaving out possible contributions from the constant region of the molecule to the observed sticky behavior. Hence, the aim of this work is to correlate the charge asymmetry over the entire mAb surface to the extent of attractive self-interaction. To do so, we selected three mAbs with distinct solvent exposed surface distribution of charged residues, for which we computationally assessed the charge asymmetry and defined an apparent molecular stickiness ranking. We then tested this ranking experimentally by evaluating their ability to engage in attractive self-interaction as a function of mAb concentration and ionic strength. Experimental data included a combination of small-angle X-ray scattering, dynamic light scattering and micro-flow imaging. We show that the mAbs with oppositely charged Fab and Fc domains are characterized by overall attractive protein-protein interactions in solution amounting to diverse sub-visible morphologies, which vary non-linearly with mAb concentration and ionic strength. As a proof of concept, we also report the absence of any of such assemblies for the mAb with like-charged Fab and Fc domains, resulting in an overall repulsive behavior in solution. Altogether, we show how to utilize charge distribution analyses of full-length mAbs to rationally develop formulations that pre-vent problematic self-assembly.
Preprint server:
bioRxiv
The authors list and abstract were imported from bioRxiv on 05 Nov 2025.
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