Your search keyword '"Peter M. Tessier"' showing total 9 results

1. Reduction of monoclonal antibody viscosity using interpretable machine learning

Author

Emily K. Makowski, Hsin-Ting Chen, Tiexin Wang, Lina Wu, Jie Huang, Marissa Mock, Patrick Underhill, Emma Pelegri-O’Day, Erick Maglalang, Dwight Winters, and Peter M. Tessier

Subjects

Antibody engineering, charge, computation, developability, formulation, Fv, Therapeutics. Pharmacology, RM1-950, Immunologic diseases. Allergy, RC581-607

Abstract

ABSTRACTEarly identification of antibody candidates with drug-like properties is essential for simplifying the development of safe and effective antibody therapeutics. For subcutaneous administration, it is important to identify candidates with low self-association to enable their formulation at high concentration while maintaining low viscosity, opalescence, and aggregation. Here, we report an interpretable machine learning model for predicting antibody (IgG1) variants with low viscosity using only the sequences of their variable (Fv) regions. Our model was trained on antibody viscosity data (>100 mg/mL mAb concentration) obtained at a common formulation pH (pH 5.2), and it identifies three key Fv features of antibodies linked to viscosity, namely their isoelectric points, hydrophobic patch sizes, and numbers of negatively charged patches. Of the three features, most predicted antibodies at risk for high viscosity, including antibodies with diverse antibody germlines in our study (79 mAbs) as well as clinical-stage IgG1s (94 mAbs), are those with low Fv isoelectric points (Fv pIs

Published

2024

2. Assessing developability early in the discovery process for novel biologics

Author

Monica L. Fernández-Quintero, Anne Ljungars, Franz Waibl, Victor Greiff, Jan Terje Andersen, Torleif T. Gjølberg, Timothy P. Jenkins, Bjørn Gunnar Voldborg, Lise Marie Grav, Sandeep Kumar, Guy Georges, Hubert Kettenberger, Klaus R. Liedl, Peter M. Tessier, John McCafferty, and Andreas H. Laustsen

Subjects

Biologics, developability, antibodies, drug development, biotherapeutics, drug discovery, Therapeutics. Pharmacology, RM1-950, Immunologic diseases. Allergy, RC581-607

Abstract

ABSTRACTBeyond potency, a good developability profile is a key attribute of a biological drug. Selecting and screening for such attributes early in the drug development process can save resources and avoid costly late-stage failures. Here, we review some of the most important developability properties that can be assessed early on for biologics. These include the influence of the source of the biologic, its biophysical and pharmacokinetic properties, and how well it can be expressed recombinantly. We furthermore present in silico, in vitro, and in vivo methods and techniques that can be exploited at different stages of the discovery process to identify molecules with liabilities and thereby facilitate the selection of the most optimal drug leads. Finally, we reflect on the most relevant developability parameters for injectable versus orally delivered biologics and provide an outlook toward what general trends are expected to rise in the development of biologics.

Published

2023

3. Reduction of therapeutic antibody self-association using yeast-display selections and machine learning

Author

Emily K. Makowski, Hongwei Chen, Matthew Lambert, Eric M. Bennett, Nicole S. Eschmann, Yulei Zhang, Jennifer M. Zupancic, Alec A. Desai, Matthew D. Smith, Wenjia Lou, Amendra Fernando, Timothy Tully, Christopher J. Gallo, Laura Lin, and Peter M. Tessier

Subjects

mAb, antibody, self-interaction, affinity, directed evolution, complementarity-determining regions, Therapeutics. Pharmacology, RM1-950, Immunologic diseases. Allergy, RC581-607

Abstract

Self-association governs the viscosity and solubility of therapeutic antibodies in high-concentration formulations used for subcutaneous delivery, yet it is difficult to reliably identify candidates with low self-association during antibody discovery and early-stage optimization. Here, we report a high-throughput protein engineering method for rapidly identifying antibody candidates with both low self-association and high affinity. We find that conjugating quantum dots to IgGs that strongly self-associate (pH 7.4, PBS), such as lenzilumab and bococizumab, results in immunoconjugates that are highly sensitive for detecting other high self-association antibodies. Moreover, these conjugates can be used to rapidly enrich yeast-displayed bococizumab sub-libraries for variants with low levels of immunoconjugate binding. Deep sequencing and machine learning analysis of the enriched bococizumab libraries, along with similar library analysis for antibody affinity, enabled identification of extremely rare variants with co-optimized levels of low self-association and high affinity. This analysis revealed that co-optimizing bococizumab is difficult because most high-affinity variants possess positively charged variable domains and most low self-association variants possess negatively charged variable domains. Moreover, negatively charged mutations in the heavy chain CDR2 of bococizumab, adjacent to its paratope, were effective at reducing self-association without reducing affinity. Interestingly, most of the bococizumab variants with reduced self-association also displayed improved folding stability and reduced nonspecific binding, revealing that this approach may be particularly useful for identifying antibody candidates with attractive combinations of drug-like properties.Abbreviations: AC-SINS: affinity-capture self-interaction nanoparticle spectroscopy; CDR: complementarity-determining region; CS-SINS: charge-stabilized self-interaction nanoparticle spectroscopy; FACS: fluorescence-activated cell sorting; Fab: fragment antigen binding; Fv: fragment variable; IgG: immunoglobulin; QD: quantum dot; PBS: phosphate-buffered saline; VH: variable heavy; VL: variable light.

Published

2022

4. Discovery-stage identification of drug-like antibodies using emerging experimental and computational methods

Author

Emily K. Makowski, Lina Wu, Priyanka Gupta, and Peter M. Tessier

Subjects

mAb, monoclonal antibody, therapeutic, developability, viscosity, aggregation, Therapeutics. Pharmacology, RM1-950, Immunologic diseases. Allergy, RC581-607

Abstract

There is intense and widespread interest in developing monoclonal antibodies as therapeutic agents to treat diverse human disorders. During early-stage antibody discovery, hundreds to thousands of lead candidates are identified, and those that lack optimal physical and chemical properties must be deselected as early as possible to avoid problems later in drug development. It is particularly challenging to characterize such properties for large numbers of candidates with the low antibody quantities, concentrations, and purities that are available at the discovery stage, and to predict concentrated antibody properties (e.g., solubility, viscosity) required for efficient formulation, delivery, and efficacy. Here we review key recent advances in developing and implementing high-throughput methods for identifying antibodies with desirable in vitro and in vivo properties, including favorable antibody stability, specificity, solubility, pharmacokinetics, and immunogenicity profiles, that together encompass overall drug developability. In particular, we highlight impressive recent progress in developing computational methods for improving rational antibody design and prediction of drug-like behaviors that hold great promise for reducing the amount of required experimentation. We also discuss outstanding challenges that will need to be addressed in the future to fully realize the great potential of using such analysis for minimizing development times and improving the success rate of antibody candidates in the clinic.

Published

2021

5. Highly sensitive detection of antibody nonspecific interactions using flow cytometry

Author

Emily K. Makowski, Lina Wu, Alec A. Desai, and Peter M. Tessier

Subjects

Developability, nonspecific, non-specific, polyreactivity, off-target binding, specificity, Therapeutics. Pharmacology, RM1-950, Immunologic diseases. Allergy, RC581-607

Abstract

The rapidly evolving nature of antibody drug development has resulted in technologies that generate vast numbers (hundreds to thousands) of lead antibody candidates during early discovery. These candidates must be rapidly pared down to identify the most drug-like candidates for in-depth analysis of their safety and efficacy, which can only be performed on a limited number of antibodies due to time and resource requirements. One key biophysical property of successful antibody therapeutics is high specificity, defined as low levels of nonspecific binding or polyspecificity. Although there has been some progress in developing assays for detecting antibody polyspecificity, most of these assays are limited by poor sensitivity or assay formats that require proprietary antibody surface display methods, and some of these assays use complex and poorly defined polyspecificity reagents. Here we report the PolySpecificity Particle (PSP) assay, a sensitive flow cytometry assay for evaluating antibody nonspecific interactions that overcomes previous limitations and can be used for evaluating diverse types of IgGs, multispecific antibodies and Fc-fusion proteins. Our approach uses micron-sized magnetic beads coated with Protein A to capture antibodies at extremely dilute concentrations (

Published

2021

6. Highly sensitive detection of antibody nonspecific interactions using flow cytometry

Author

Lina Wu, Peter M. Tessier, Alec A. Desai, and Emily K. Makowski

Subjects

medicine.drug_class, Immunology, specificity, CHO Cells, bispecific, Monoclonal antibody, multispecific, mAb, IgG, Fc, Fab, Flow cytometry, nonspecific, off-target binding, Cricetulus, Antibody Specificity, Report, Antibodies, Bispecific, medicine, Immunology and Allergy, Animals, Humans, medicine.diagnostic_test, biology, polyreactivity, Chemistry, Assay sensitivity, Flow Cytometry, Highly sensitive, Ovalbumin, Developability, HEK293 Cells, Drug development, Biochemistry, Immunoglobulin G, biology.protein, affinity, Antibody, Protein A, non-specific

Abstract

The rapidly evolving nature of antibody drug development has resulted in technologies that generate vast numbers (hundreds to thousands) of lead antibody candidates during early discovery. These candidates must be rapidly pared down to identify the most drug-like candidates for in-depth analysis of their safety and efficacy, which can only be performed on a limited number of antibodies due to time and resource requirements. One key biophysical property of successful antibody therapeutics is high specificity, defined as low levels of nonspecific binding or polyspecificity. Although there has been some progress in developing assays for detecting antibody polyspecificity, most of these assays are limited by poor sensitivity or assay formats that require proprietary antibody surface display methods, and some of these assays use complex and poorly defined polyspecificity reagents. Here we report the PolySpecificity Particle (PSP) assay, a sensitive flow cytometry assay for evaluating antibody nonspecific interactions that overcomes previous limitations and can be used for evaluating diverse types of IgGs, multispecific antibodies and Fc-fusion proteins. Our approach uses micron-sized magnetic beads coated with Protein A to capture antibodies at extremely dilute concentrations (

Published

2021

7. Discovery-stage identification of drug-like antibodies using emerging experimental and computational methods

Author

Priyanka Gupta, Lina Wu, Emily K. Makowski, and Peter M. Tessier

Subjects

Models, Molecular, computational modeling, Drug, humanization, Computer science, medicine.drug_class, media_common.quotation_subject, design, Immunology, specificity, Review, high throughput, Computational biology, immunogenicity, Monoclonal antibody, Drug Development, developability, medicine, Animals, Humans, Immunology and Allergy, Computer Simulation, media_common, mAb, biology, solubility, aggregation, Antibodies, Monoclonal, prediction, therapeutic, Identification (information), Drug development, monoclonal antibody, viscosity, biology.protein, affinity, Antibody, polyspecificity, pharmacokinetics

Abstract

There is intense and widespread interest in developing monoclonal antibodies as therapeutic agents to treat diverse human disorders. During early-stage antibody discovery, hundreds to thousands of lead candidates are identified, and those that lack optimal physical and chemical properties must be deselected as early as possible to avoid problems later in drug development. It is particularly challenging to characterize such properties for large numbers of candidates with the low antibody quantities, concentrations, and purities that are available at the discovery stage, and to predict concentrated antibody properties (e.g., solubility, viscosity) required for efficient formulation, delivery, and efficacy. Here we review key recent advances in developing and implementing high-throughput methods for identifying antibodies with desirable in vitro and in vivo properties, including favorable antibody stability, specificity, solubility, pharmacokinetics, and immunogenicity profiles, that together encompass overall drug developability. In particular, we highlight impressive recent progress in developing computational methods for improving rational antibody design and prediction of drug-like behaviors that hold great promise for reducing the amount of required experimentation. We also discuss outstanding challenges that will need to be addressed in the future to fully realize the great potential of using such analysis for minimizing development times and improving the success rate of antibody candidates in the clinic.

Published

2021

8. An alternative assay to hydrophobic interaction chromatography for high-throughput characterization of monoclonal antibodies

Author

Peter M. Tessier, Tingwan Sun, Yao Yu, Tushar Jain, Heather Lynaugh, Yuan Cao, Isabelle Caffry, Patricia Estep, Yingda Xu, and Maximiliano Vásquez

Subjects

Ammonium sulfate, medicine.drug_class, High-throughput screening, Immunology, Metal Nanoparticles, Monoclonal antibody, high-throughput screening, Hydrophobic effect, chemistry.chemical_compound, developability, medicine, Immunology and Allergy, Humans, Solubility, HIC, Chromatography, biology, Hydrophilic interaction chromatography, solubility, Spectrum Analysis, aggregation, Antibodies, Monoclonal, hydrophobic interaction chromatography, HEK293 Cells, chemistry, Polyclonal antibodies, Colloidal gold, viscosity, biology.protein, manufacturability, Gold, Hydrophobic and Hydrophilic Interactions, Reports, self-interaction nanoparticle spectroscopy, self-association, Chromatography, Liquid

Abstract

The effectiveness of therapeutic monoclonal antibodies (mAbs) is governed not only by their bioactivity, but also by their biophysical properties. Assays for rapidly evaluating the biophysical properties of mAbs are valuable for identifying those most likely to exhibit superior properties such as high solubility, low viscosity and slow serum clearance. Analytical hydrophobic interaction chromatography (HIC), which is performed at high salt concentrations to enhance hydrophobic interactions, is an attractive assay for identifying mAbs with low hydrophobicity. However, this assay is low throughput and thus not amenable to processing the large numbers of mAbs that are commonly generated during antibody discovery. Therefore, we investigated whether an alternative, higher throughput, assay could be developed that is based on evaluating antibody self-association at high salt concentrations using affinity-capture self-interaction nanoparticle spectroscopy (AC-SINS). Our approach is to coat gold nanoparticles with polyclonal anti-human antibodies, use these conjugates to immobilize human mAbs, and evaluate mAb self-interactions by measuring the plasmon wavelengths of the antibody conjugates as a function of ammonium sulfate concentration. We find that hydrophobic mAbs, as identified by HIC, generally show significant self-association at low to moderate ammonium sulfate concentrations, while hydrophilic mAbs typically show self-association only at high ammonium sulfate concentrations. The correlation between AC-SINS and HIC measurements suggests that our assay, which can evaluate tens to hundreds of mAbs in a parallel manner and requires only small (microgram) amounts of antibody, will enable early identification of mAb candidates with low hydrophobicity and improved biophysical properties.

Published

2015

9. High-throughput screening for developability during early-stage antibody discovery using self-interaction nanoparticle spectroscopy

Author

Tingwan Sun, Jiemin Wu, Steven B. Geng, Felicia Reid, Yuan Cao, Peter M. Tessier, Yingda Xu, Maximiliano Vásquez, Tushar Jain, Isabelle Caffry, Yuqi Liu, Patricia Estep, and Yao Yu

Subjects

medicine.drug_class, High-throughput screening, Immunology, Antibody Affinity, Nanoparticle, Metal Nanoparticles, Monoclonal antibody, Report, High-Throughput Screening Assays, Drug Discovery, medicine, Immunology and Allergy, Humans, Throughput (business), Cells, Cultured, biology, Chemistry, Spectrum Analysis, Antibodies, Monoclonal, Reproducibility of Results, Surface Plasmon Resonance, Combinatorial chemistry, Biochemistry, Polyclonal antibodies, Colloidal gold, biology.protein, Gold, Immunotherapy, Antibody, Protein Multimerization, Antibodies, Immobilized

Abstract

The discovery of monoclonal antibodies (mAbs) that bind to a particular molecular target is now regarded a routine exercise. However, the successful development of mAbs that (1) express well, (2) elicit a desirable biological effect upon binding, and (3) remain soluble and display low viscosity at high concentrations is often far more challenging. Therefore, high throughput screening assays that assess self-association and aggregation early in the selection process are likely to yield mAbs with superior biophysical properties. Here, we report an improved version of affinity-capture self-interaction nanoparticle spectroscopy (AC-SINS) that is capable of screening large panels of antibodies for their propensity to self-associate. AC-SINS is based on concentrating mAbs from dilute solutions around gold nanoparticles pre-coated with polyclonal capture (e.g., anti-Fc) antibodies. Interactions between immobilized mAbs lead to reduced inter-particle distances and increased plasmon wavelengths (wavelengths of maximum absorbance), which can be readily measured by optical means. This method is attractive because it is compatible with dilute and unpurified mAb solutions that are typical during early antibody discovery. In addition, we have improved multiple aspects of this assay for increased throughput and reproducibility. A data set comprising over 400 mAbs suggests that our modified assay yields self-interaction measurements that are well-correlated with other lower throughput assays such as cross-interaction chromatography. We expect that the simplicity and throughput of our improved AC-SINS method will lead to improved selection of mAbs with excellent biophysical properties during early antibody discovery.

Published

2014