Prediction of methionine oxidation risk in monoclonal antibodies using a machine learning method

Sankar, Kalyanasundaram; Hoi, Kam Hon; Yuan, Yin; Ramachandran, Prasanna; Andersen, Nisana; Hilderbrand, Amy E.; McDonald, Paul C.; Spiess, Christoph; Zhang, Qing

doi:10.1080/19420862.2018.1518887

Cited by 43 publications

(34 citation statements)

References 65 publications

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“…25,[101][102][103][104][105][106][107][108][109][110][111] One of the most common degradation events is the chemical modification of Asn and Asp residues, which share a degradation pathway. 25 Many of the methods to predict such degradation are statisticalbased methods, and experimental data to derive such prediction models are either from in-house experiments 101,103,107,108,110 or from literature. 104,106,111 For example, to understand origins of Asn deamidation and Asp isomerization, Sydow et al 101 used mass spectrometry to experimentally characterize 37 antibodies that were subjected to forced degradation.…”

Section: Prediction Of Chemical Stabilitymentioning

confidence: 99%

Engineering Stability, Viscosity, and Immunogenicity of Antibodies by Computational Design

Kuroda

Tsumoto

2020

Journal of Pharmaceutical Sciences

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In recent years, computational methods have garnered much attention in protein engineering. A large number of computational methods have been developed to analyze the sequences and structures of proteins and have been used to predict the various properties. Antibodies are one of the emergent protein therapeutics, and thus, methods to control their physicochemical properties are highly desirable. However, despite the tremendous efforts of past decades, computational methods to predict the physicochemical properties of antibodies are still in their infancy. Experimental validations are certainly required for real-world applications, and the results should be interpreted with caution. Among the various properties of antibodies, we focus in this review on stability, viscosity, and immunogenicity, and we present the current status of computational methods to engineer such properties.

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Section: Prediction Of Chemical Stabilitymentioning

confidence: 99%

Engineering Stability, Viscosity, and Immunogenicity of Antibodies by Computational Design

Kuroda

Tsumoto

2020

Journal of Pharmaceutical Sciences

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“…It is highly likely that this model can be applied to other display platforms that use bio-panning as the selection process, such as yeast display library for fluorescence-activated cell sorting screening [54]. Recently, artificial intelligence has been applied to predict the physicochemical properties of antibody sequences [55][56][57][58][59] and/or optimize them [60][61][62].…”

Section: Discussionmentioning

confidence: 99%

Machine Learning-Guided Prediction of Antigen-Reactive In Silico Clonotypes Based on Changes in Clonal Abundance through Bio-Panning

Yoo

Lee

Jung³

et al. 2020

Biomolecules

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c-Met is a promising target in cancer therapy for its intrinsic oncogenic properties. However, there are currently no c-Met-specific inhibitors available in the clinic. Antibodies blocking the interaction with its only known ligand, hepatocyte growth factor, and/or inducing receptor internalization have been clinically tested. To explore other therapeutic antibody mechanisms like Fc-mediated effector function, bispecific T cell engagement, and chimeric antigen T cell receptors, a diverse panel of antibodies is essential. We prepared a chicken immune scFv library, performed four rounds of bio-panning, obtained 641 clones using a high-throughput clonal retrieval system (TrueRepertoireTM, TR), and found 149 antigen-reactive scFv clones. We also prepared phagemid DNA before the start of bio-panning (round 0) and, after each round of bio-panning (round 1–4), performed next-generation sequencing of these five sets of phagemid DNA, and identified 860,207 HCDR3 clonotypes and 443,292 LCDR3 clonotypes along with their clonal abundance data. We then established a TR data set consisting of antigen reactivity for scFv clones found in TR analysis and the clonal abundance of their HCDR3 and LCDR3 clonotypes in five sets of phagemid DNA. Using the TR data set, a random forest machine learning algorithm was trained to predict the binding properties of in silico HCDR3 and LCDR3 clonotypes. Subsequently, we synthesized 40 HCDR3 and 40 LCDR3 clonotypes predicted to be antigen reactive (AR) and constructed a phage-displayed scFv library called the AR library. In parallel, we also prepared an antigen non-reactive (NR) library using 10 HCDR3 and 10 LCDR3 clonotypes predicted to be NR. After a single round of bio-panning, we screened 96 randomly-selected phage clones from the AR library and found out 14 AR scFv clones consisting of 5 HCDR3 and 11 LCDR3 AR clonotypes. We also screened 96 randomly-selected phage clones from the NR library, but did not identify any AR clones. In summary, machine learning algorithms can provide a method for identifying AR antibodies, which allows for the characterization of diverse antibody libraries inaccessible by traditional methods.

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“…In recent years, several companies have reported the development of structure-based tools for the prediction of chemical PTMs like deamidation, isomerization, and oxidation hot spots in therapeutic antibodies. [22][23][24] Also, several opensource web-based predictors have been developed to suggest positions of enzyme-catalyzed PTMs based on consensus sequences/logos (e.g., www.expasy.org/proteomics, www.cbs. dtu.dk/databases/PTMpredictions, www.modpred.org/).…”

Section: Discussionmentioning

confidence: 99%

“…20 Recently, matrix-assisted laser desorption ionization (MALDI) was combined with in-source decay (ISD) fragmentation and ultrahigh resolution Fourier-transform ion cyclotron resonance (FT-ICR) mass spectrometry (MS) for fast characterization of mAbs providing complementary sequence information compared to other MS-based techniques. 21 Other approaches have focused on the development of structure-based prediction tools for the identification of, for example, deamidation, isomerization, and oxidation hot spots in mAbs [22][23][24] or other in silico PTM prediction tools. [25][26][27] Herein, we describe the integration of innovative PTM analysis and in silico identification tool for the detection and verification of 4-hydroxyproline (4Hyp) and sulfotyrosine (sTyr) in antibody-based therapeutics.…”

Section: Introductionmentioning

confidence: 99%

Characterization and prediction of positional 4-hydroxyproline and sulfotyrosine, two post-translational modifications that can occur at substantial levels in CHO cells-expressed biotherapeutics

Tyshchuk

Gstöttner

Funk

et al. 2019

mAbs

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Biotherapeutics may contain a multitude of different post-translational modifications (PTMs) that need to be assessed and possibly monitored and controlled to ensure reproducible product quality. During early development of biotherapeutics, unexpected PTMs might be prevented by in silico identification and characterization together with further molecular engineering. Mass determinations of a human IgG1 (mAb1) and a bispecific IgG-ligand fusion protein (BsAbA) demonstrated the presence of unusual PTMs resulting in major +80 Da, and +16/+32 Da chain variants, respectively. For mAb1, analytical cation exchange chromatography demonstrated the presence of an acidic peak accounting for 20%. A + 79.957 Da modification was localized within the light chain complementarity-determining region-2 and identified as a sulfation based on accurate mass, isotopic distribution, and a complete neutral loss reaction upon collision-induced dissociation. Top-down ultrahigh resolution MALDI-ISD FT-ICR MS of modified and unmodified Fabs allowed the allocation of the sulfation to a specific Tyr residue. An aspartate in amino-terminal position-3 relative to the affected Tyr was found to play a key role in determining the sulfation. For BsAbA, a + 15.995 Da modification was observed and localized to three specific Pro residues explaining the +16 Da chain A, and +16 Da and +32 Da chain B variants. The BsAbA modifications were verified as 4-hydroxyproline and not 3-hydroxyproline in a tryptic peptide map via cochromatography with synthetic peptides containing the two isomeric forms. Finally, our approach for an alert system based on in-house in silico predictors is presented. This system is designed to prevent these PTMs by molecular design and engineering during early biotherapeutic development.

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Prediction of methionine oxidation risk in monoclonal antibodies using a machine learning method

Cited by 43 publications

References 65 publications

Engineering Stability, Viscosity, and Immunogenicity of Antibodies by Computational Design

Engineering Stability, Viscosity, and Immunogenicity of Antibodies by Computational Design

Machine Learning-Guided Prediction of Antigen-Reactive In Silico Clonotypes Based on Changes in Clonal Abundance through Bio-Panning

Characterization and prediction of positional 4-hydroxyproline and sulfotyrosine, two post-translational modifications that can occur at substantial levels in CHO cells-expressed biotherapeutics

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