Multiscale Coarse-Grained Approach to Investigate Self-Association of Antibodies

Overview

Journal Biophys J

Publisher Cell Press

Specialty Biophysics

Date 2020 May 17

PMID 32416079

Citations 18

Authors

Saeed Izadi

Thomas W Patapoff

Benjamin T Walters

Affiliations

Soon will be listed here.

Abstract

Self-association of therapeutic monoclonal antibodies (mabs) are thought to modulate the undesirably high viscosity observed in their concentrated solutions. Computational prediction of such a self-association behavior is advantageous early during mab drug candidate selection when material availability is limited. Here, we present a coarse-grained (CG) simulation method that enables microsecond molecular dynamics simulations of full-length antibodies at high concentrations. The proposed approach differs from others in two ways: first, charges are assigned to CG beads in an effort to reproduce molecular multipole moments and charge asymmetry of full-length antibodies instead of only localized charges. This leads to great improvements in the agreement between CG and all-atom electrostatic fields. Second, the distinctive hydrophobic character of each antibody is incorporated through empirical adjustments to the short-range van der Waals terms dictated by cosolvent all-atom molecular dynamics simulations of antibody variable regions. CG simulations performed on a set of 15 different mabs reveal that diffusion coefficients in crowded environments are markedly impacted by intermolecular interactions. Diffusion coefficients computed from the simulations are in correlation with experimentally measured observables, including viscosities at a high concentration. Further, we show that the evaluation of electrostatic and hydrophobic characters of the mabs is useful in predicting the nonuniform effect of salt on the viscosity of mab solutions. This CG modeling approach is particularly applicable as a material-free screening tool for selecting antibody candidates with desirable viscosity properties.

Citing Articles

Modulation of the high concentration viscosity of IgG antibodies using clinically validated Fc mutations.

Heisler J, Kovner D, Izadi S, Zarzar J, Carter P MAbs. 2024; 16(1):2379560.

PMID: 39028186 PMC: 11262234. DOI: 10.1080/19420862.2024.2379560.

DeepSP: Deep learning-based spatial properties to predict monoclonal antibody stability.

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Antibody association in solution: cluster distributions and mechanisms.

Brudar S, Breydo L, Chung E, Dill K, Ehterami N, Phadnis K MAbs. 2024; 16(1):2339582.

PMID: 38666507 PMC: 11057677. DOI: 10.1080/19420862.2024.2339582.

A multi-scale numerical approach to study monoclonal antibodies in solution.

Polimeni M, Zaccarelli E, Gulotta A, Lund M, Stradner A, Schurtenberger P APL Bioeng. 2024; 8(1):016111.

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Accelerating therapeutic protein design with computational approaches toward the clinical stage.

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