Randall A. Hughes scite author profile

Isolation of antigen-specific monoclonal antibodies (mAbs) and antibody fragments relies on high-throughput screening of immortalized B cells or recombinant antibody libraries. We bypassed the screening step by using high-throughput DNA sequencing and bioinformatic analysis to mine antibody variable region (V)-gene repertoires from bone marrow plasma cells (BMPC) of immunized mice. BMPCs, which cannot be immortalized, produce the vast majority of circulating antibodies. We found that the V-gene repertoire of BMPCs becomes highly polarized after immunization, with the most abundant sequences represented at frequencies between approximately 1% and >10% of the total repertoire. We paired the most abundant variable heavy (V(H)) and variable light (V(L)) genes based on their relative frequencies, reconstructed them using automated gene synthesis, and expressed recombinant antibodies in bacteria or mammalian cells. Antibodies generated in this manner from six mice, each immunized with one of three antigens were overwhelmingly antigen specific (21/27 or 78%). Those generated from a mouse with high serum titers had nanomolar binding affinities.

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Synthetic DNA Synthesis and Assembly: Putting the Synthetic in Synthetic Biology

Hughes

Ellington

2017

Cold Spring Harb Perspect Biol

322

235

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The chemical synthesis of DNA oligonucleotides and their assembly into synthons, genes, circuits, and even entire genomes by gene synthesis methods has become an enabling technology for modern molecular biology and enables the design, build, test, learn, and repeat cycle underpinning innovations in synthetic biology. In this perspective, we briefly review the techniques and technologies that enable the synthesis of DNA oligonucleotides and their assembly into larger DNA constructs with a focus on recent advancements that have sought to reduce synthesis cost and increase sequence fidelity. The development of lower-cost methods to produce high-quality synthetic DNA will allow for the exploration of larger biological hypotheses by lowering the cost of use and help to close the DNA read -write cost gap.DNA neither cares nor knows. DNA just is. And we dance to its music.-Richard Dawkins River Out of Eden: A Darwinian Life

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Directed evolution of genetic parts and circuits by compartmentalized partnered replication

et al. 2013

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Most existing directed evolution methods, both in vivo and in vitro, suffer from inadvertent selective pressures (i.e., altering organism fitness), resulting in the evolution of products with unintended or suboptimal function. To overcome these barriers, here we present compartmentalized partnered replication (CPR). In this approach, synthetic circuits are linked to the production of Taq DNA polymerase so that evolved circuits that most efficiently drive Taq DNA polymerase production are enriched by exponential amplification during a subsequent emulsion PCR step. We apply CPR to evolve a T7 RNA polymerase variant that recognizes an orthogonal promoter and to reengineer the tryptophanyl tRNA-synthetase:suppressor tRNA pair from Saccharomyces cerevisiae to efficiently and site-specifically incorporate an unnatural amino acid into proteins. In both cases, the CPR-evolved parts were more orthogonal and/or more active than variants evolved using other methods. CPR should be useful for evolving any genetic part or circuit that can be linked to Taq DNA polymerase expression.

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Molecular deconvolution of the monoclonal antibodies that comprise the polyclonal serum response

Wine

Boutz

Lavinder

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

129

156

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We have developed and validated a methodology for determining the antibody composition of the polyclonal serum response after immunization. Pepsin-digested serum IgGs were subjected to standard antigen-affinity chromatography, and resulting elution, wash, and flow-through fractions were analyzed by bottom-up, liquid chromatography-high-resolution tandem mass spectrometry. Identification of individual monoclonal antibodies required the generation of a database of IgG variable gene (V-gene) sequences constructed by NextGen sequencing of mature B cells. Antibody V-gene sequences are characterized by short complementarity determining regions (CDRs) of high diversity adjacent to framework regions shared across thousands of IgGs, greatly complicating the identification of antigen-specific IgGs from proteomically observed peptides. By mapping peptides marking unique V H CDRH3 sequences, we identified a set of V-genes heavily enriched in the affinity chromatography elution, constituting the serum polyclonal response. After booster immunization in a rabbit, we find that the antigenspecific serum immune response is oligoclonal, comprising antibodies encoding 34 different CDRH3s that group into 30 distinct antibody V H clonotypes. Of these 34 CDRH3s, 12 account for ∼60% of the antigen-specific CDRH3 peptide mass spectral counts. For comparison, antibodies with 18 different CDRH3s (12 clonotypes) were represented in the antigen-specific IgG fraction from an unimmunized rabbit that fortuitously displayed a moderate titer for BSA. Proteomically identified antibodies were synthesized and shown to display subnanomolar affinities. The ability to deconvolute the polyclonal serum response is likely to be of key importance for analyzing antibody responses after vaccination and for more completely understanding adaptive immune responses in health and disease.antibody proteomics | antibody repertoire | serum immunoprofiling | B-cell response | humoral response T he first Nobel Prize in Medicine was awarded to Emil von Behring, who in collaboration with Kitasato Shibasaburo and Paul Ehrlich discovered serum antitoxins (1, 2). Remarkably, after more than 100 y of intense research in immunology, little is known about the clonality, relative concentrations, and binding properties of the monoclonal antibodies that constitute the antigen-specific Ig pool in serum.At steady state, circulating antibodies are produced by terminally differentiated B lymphocytes (plasma cells) within the bone marrow, and thus cannot be accessed in living individuals (3). Although recent single B-cell cloning methods (4, 5) have led to the identification of peripheral antigen-specific B memory and/or antibody-secreting cells (plasmablasts), it is generally unknown whether the Igs encoded by peripheral blood B cells correspond to the antibodies present in circulation and especially whether they are present at physiologically relevant levels (i.e., at serum concentrations above K D corresponding to >1 μg/mL for an average affinity of individual antibodies of 5 nM)...

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Structure-Based Design of Supercharged, Highly Thermoresistant Antibodies

Miklos

Kluwe

Der

et al. 2012

Chemistry & Biology

131

133

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SUMMARY Mutation of surface residues to charged amino acids increases resistance to aggregation and can enable reversible unfolding. We have developed a protocol using the Rosetta computational design package that “supercharges” proteins while considering the energetic implications of each mutation. Using a homology model, a single-chain variable fragment antibody was designed that has a markedly enhanced resistance to thermal inactivation and displays an unanticipated ≈30-fold improvement in affinity. Such supercharged antibodies should prove useful for assays in resource-limited settings and for developing reagents with improved shelf lives.

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Randall A. Hughes

Monoclonal antibodies isolated without screening by analyzing the variable-gene repertoire of plasma cells

Synthetic DNA Synthesis and Assembly: Putting the Synthetic in Synthetic Biology

Directed evolution of genetic parts and circuits by compartmentalized partnered replication

Molecular deconvolution of the monoclonal antibodies that comprise the polyclonal serum response

Structure-Based Design of Supercharged, Highly Thermoresistant Antibodies

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