Measuring the sequence-affinity landscape of antibodies with massively parallel titration curves

Despite the central role that antibodies play in the adaptive immune system and in biotechnology, much remains unknown about the quantitative relationship between an antibody’s amino acid sequence and its antigen binding affinity. Here we describe a new experimental approach, called Tite-Seq, that i...

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Vydané v:eLife Ročník 5
Hlavní autori: Adams, Rhys M, Mora, Thierry, Walczak, Aleksandra M, Kinney, Justin B
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: England eLife Sciences Publications Ltd 30.12.2016
eLife Sciences Publications, Ltd
Predmet:
Affinity
Amino Acid Sequence
Antibodies
antibody
Antibody Affinity
Antibody Specificity
Antigen-Antibody Complex - analysis
Antigens
Binding Sites, Antibody
Biophysics and Structural Biology
Biotechnology
deep mutational scan
dissociation constant
Experiments
Flow cytometry
High-Throughput Screening Assays
Humans
Immune system
Immunoglobulins
Kinetics
Ligands
Models, Molecular
Mutation
Oligonucleotides - chemistry
Oligonucleotides - genetics
Oligonucleotides - metabolism
Peptide Library
Protein Binding
Protein expression
Proteins
Saccharomyces cerevisiae - genetics
Saccharomyces cerevisiae - metabolism
Single-Chain Antibodies - chemistry
Single-Chain Antibodies - genetics
Single-Chain Antibodies - immunology
Structure-Activity Relationship
Titration
titration curve
Yeast
titration curve
antibody
deep mutational scan
dissociation constant
structural biology
biophysics
S. cerevisiae
affinity
ISSN:2050-084X, 2050-084X
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Shrnutí:Despite the central role that antibodies play in the adaptive immune system and in biotechnology, much remains unknown about the quantitative relationship between an antibody’s amino acid sequence and its antigen binding affinity. Here we describe a new experimental approach, called Tite-Seq, that is capable of measuring binding titration curves and corresponding affinities for thousands of variant antibodies in parallel. The measurement of titration curves eliminates the confounding effects of antibody expression and stability that arise in standard deep mutational scanning assays. We demonstrate Tite-Seq on the CDR1H and CDR3H regions of a well-studied scFv antibody. Our data shed light on the structural basis for antigen binding affinity and suggests a role for secondary CDR loops in establishing antibody stability. Tite-Seq fills a large gap in the ability to measure critical aspects of the adaptive immune system, and can be readily used for studying sequence-affinity landscapes in other protein systems. Antibodies are proteins produced by cells of the immune system to tag or neutralize potential threats to the body, such as foreign substances and disease-causing microbes. Antibodies do this by binding to target molecules called antigens. An antibody’s ability to bind to an antigen depends on the sequence of amino acids – the building blocks of proteins – that make up the antibody. Through a process that randomizes this sequence of amino acids, the immune system generates a vast pool of antibodies that are able to target almost any foreign antigen that exists in nature. Currently, little is understood about how the sequence of amino acids in an antibody determines how strongly that antibody binds to its antigen target – a property referred to as the antibody’s binding affinity. Answering this fundamental question requires techniques that can measure the affinities of many different antibodies at the same time. However, previous high-throughput methods have been unable to provide quantitative measurements of binding affinities. These kinds of measurements are difficult because an antibody’s amino acid sequence governs more than just binding affinity: it also affects how easy it is to produce that antibody, and what fraction of antibody molecules work properly. Adams et al. now describe a new method, named “Tite-Seq”, that overcomes these issues. First, thousands of different antibodies are displayed on the surface of yeast cells, with each cell carrying a single kind of antibody. These cells are then incubated with fluorescently labeled antigen at a wide range of different concentrations. Next, the yeast cells are sorted based on how brightly they glow; brighter cells have more antigen bound to them, and so it is possible to calculate how much of the antigen is bound to each kind of antibody at each concentration. Plotting these data provides a “binding curve” for each antibody, which is then used to read off the antibody’s binding affinity in a way that is not affected by the factors that have plagued other high-throughput methods. Tite-Seq is thus able to measure the binding affinities for thousands of different antibodies at the same time. This will potentially allow researchers to address many fundamental and yet unanswered questions about how the immune system works. Tite-Seq can also be used to measure how amino acid sequence affects the binding affinity of proteins other than antibodies.
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Francis Crick Institute, London, United Kingdom.
These authors contributed equally to this work.
ISSN:2050-084X
2050-084X
DOI:10.7554/eLife.23156