Rational design of viscosity reducing mutants of a monoclonal antibody: Hydrophobic <i>versus</i> electrostatic inter-molecular interactions

Nichols, Pilarin; Li, Li; Kumar, Sandeep; Buck, Patrick M.; Singh, Satish K.; Goswami, Sumit; Balthazor, Bryan; Conley, Tami R; Sek, David; Allen, Martin

doi:10.4161/19420862.2014.985504

Cited by 92 publications

(92 citation statements)

References 48 publications

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“…This option requires an advanced understanding of sequencestructure properties of the drug candidates and access to protein engineering and molecular biology facilities. 75 …”

Section: Strategy II (Optimization Of Antibody Lead Candidate(s) For mentioning

confidence: 99%

“…Use of full-length antibody models may further improve accuracy of the viscosity prediction methods due to improved descriptions of electrostatic multipole effects that arise from the differences in charges on individual antibody domains. In three closely related studies, Kumar and coworkers 42,71,75 identified the molecular attributes that correlate with viscosity in highly concentrated antibody solutions, rationalized their observations using a putative mechanism involving antibody network formation gleaned from coarse-grained simulations, and then used this knowledge to rationally design viscosity reducing mutants of an antibody. They obtained concentration-dependent viscosity curves of eleven different antibodies under standardized formulation conditions, 71 and interpreted this experimental data in terms of sequence and structural attributes of the mAbs and their components.…”

Section: Strategies I and Ii: Effects Of Sequence And Structure Attrimentioning

confidence: 99%

“…Initial attempts to rationally design such antibody variants have been successful. 73,75,77 Further delineating such rational strategies will be very useful toward suitably improving solution behaviors of highly valuable lead candidates. As discussed earlier, a large and positive osmotic second virial coefficient is a good indicator of lower viscosity of antibody solutions at 150 mg per mL concentration.…”

Section: Future Directionsmentioning

confidence: 99%

“…The findings from this data analysis 71 and coarse grained simulations 42 were combined to rationally design viscosity lowering variants of an antibody that demonstrated high viscosities at concentrations above 100 mg per mL. 75 A negatively charged patch and an aggregation-prone region (APR) on the Fv portion of the viscosity-challenged antibody were disrupted via single point mutations. The APR was disrupted via two different single-point mutations, V44K and L45K.…”

Section: Strategies I and Ii: Effects Of Sequence And Structure Attrimentioning

confidence: 99%

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Molecular basis of high viscosity in concentrated antibody solutions: Strategies for high concentration drug product development

Tomar

Kumar

Singh

et al. 2016

mAbs

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162

145

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Effective translation of breakthrough discoveries into innovative products in the clinic requires proactive mitigation or elimination of several drug development challenges. These challenges can vary depending upon the type of drug molecule. In the case of therapeutic antibody candidates, a commonly encountered challenge is high viscosity of the concentrated antibody solutions. Concentration-dependent viscosity behaviors of mAbs and other biologic entities may depend on pairwise and higher-order intermolecular interactions, non-native aggregation, and concentration-dependent fluctuations of various antibody regions. This article reviews our current understanding of molecular origins of viscosity behaviors of antibody solutions. We discuss general strategies and guidelines to select low viscosity candidates or optimize lead candidates for lower viscosity at early drug discovery stages. Moreover, strategies for formulation optimization and excipient design are also presented for candidates already in advanced product development stages. Potential future directions for research in this field are also explored.

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“…This option requires an advanced understanding of sequencestructure properties of the drug candidates and access to protein engineering and molecular biology facilities. 75 …”

Section: Strategy II (Optimization Of Antibody Lead Candidate(s) For mentioning

confidence: 99%

Section: Strategies I and Ii: Effects Of Sequence And Structure Attrimentioning

confidence: 99%

Section: Future Directionsmentioning

confidence: 99%

Section: Strategies I and Ii: Effects Of Sequence And Structure Attrimentioning

confidence: 99%

See 2 more Smart Citations

Molecular basis of high viscosity in concentrated antibody solutions: Strategies for high concentration drug product development

Tomar

Kumar

Singh

et al. 2016

mAbs

Self Cite

162

145

View full text Add to dashboard Cite

show abstract

“…9,15,[18][19][20] In addition to the multitude of distinct domain surfaces that can compose the binding interfaces, the nature of the driving forces behind antibody selfassociation can also be diverse, with both electrostatic and hydrophobic interactions playing key roles. 6,7,18,21,23 Potential strategies to mitigate self-association and other undesired high concentration solution properties may include protein engineering approaches, 20,[24][25][26] as well as formulation development and optimization efforts. [5][6][7]9,18,19,21,23,27 While the former can be limited due to the degree of knowledge of sites of interactions, the latter can be time and resource intensive and may not always be fully successful to a desired degree for all antibodies.…”

Section: Introductionmentioning

confidence: 99%

Mitigation of reversible self-association and viscosity in a human IgG1 monoclonal antibody by rational, structure-guided Fv engineering

Geoghegan¹,

Fleming²,

Damschroder³

et al. 2016

mAbs

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Undesired solution behaviors such as reversible self-association (RSA), high viscosity, and liquid-liquid phase separation can introduce substantial challenges during development of monoclonal antibody formulations. Although a global mechanistic understanding of RSA (i.e., native and reversible proteinprotein interactions) is sufficient to develop robust formulation controls, its mitigation via protein engineering requires knowledge of the sites of protein-protein interactions. In the study reported here, we coupled our previous hydrogen-deuterium exchange mass spectrometry findings with structural modeling and in vitro screening to identify the residues responsible for RSA of a model IgG1 monoclonal antibody (mAb-C), and rationally engineered variants with improved solution properties (i.e., reduced RSA and viscosity). Our data show that mutation of either solvent-exposed aromatic residues within the heavy and light chain variable regions or buried residues within the heavy chain/light chain interface can significantly mitigate RSA and viscosity by reducing the IgG's surface hydrophobicity. The engineering strategy described here highlights the utility of integrating complementary experimental and in silico methods to identify mutations that can improve developability, in particular, high concentration solution properties, of candidate therapeutic antibodies.

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The polypeptide biophysics of proline/alanine‐rich sequences (PAS): Recombinant biopolymers with PEG‐like properties

Breibeck

Skerra

2017

Biopolymers

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PAS polypeptides comprise long repetitive sequences of the small L‐amino acids proline, alanine and/or serine that were developed to expand the hydrodynamic volume of conjugated pharmaceuticals and prolong their plasma half‐life by retarding kidney filtration. Here, we have characterized the polymer properties both of the free polypeptides and in fusion with the biopharmaceutical IL‐1Ra. Data from size exclusion chromatography, dynamic light scattering, circular dichroism spectroscopy and quantification of hydrodynamic and polar properties demonstrate that the biosynthetic PAS polypeptides exhibit random coil behavior in aqueous solution astonishingly similar to the chemical polymer poly‐ethylene glycol (PEG). The solvent‐exposed PAS peptide groups, in the absence of secondary structure, account for strong hydrophilicity, with negligible contribution by the Ser side chains. Notably, PAS polypeptides exceed PEG of comparable molecular mass in hydrophilicity and hydrodynamic volume while exhibiting lower viscosity. Their uniform monodisperse composition as genetically encoded polymers and their biological nature, offering biodegradability, render PAS polypeptides a promising PEG mimetic for biopharmaceutical applications.

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Rational design of viscosity reducing mutants of a monoclonal antibody: Hydrophobic versus electrostatic inter-molecular interactions

Cited by 92 publications

References 48 publications

Molecular basis of high viscosity in concentrated antibody solutions: Strategies for high concentration drug product development

Molecular basis of high viscosity in concentrated antibody solutions: Strategies for high concentration drug product development

Mitigation of reversible self-association and viscosity in a human IgG1 monoclonal antibody by rational, structure-guided Fv engineering

The polypeptide biophysics of proline/alanine‐rich sequences (PAS): Recombinant biopolymers with PEG‐like properties

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