Fast-tracking antibody maturation using a B cell-based display system.

Affinity maturation, an essential component of antibody engineering, is crucial for developing therapeutic antibodies. Cell display system coupled with somatic hypermutation (SHM) initiated by activation-induced cytidine deaminase (AID) is a commonly used technique for affinity maturation. AID introduces targeted DNA lesions into hotspots of immunoglobulin (Ig) gene loci followed by erroneous DNA repair, leading to biased mutations in the complementary determining regions. However, systems that use an in vivo mimicking mechanism often require several rounds of selection to enrich clones possessing accumulated mutations. We previously described the human ADLib® system, which features autonomous, AID-mediated diversification in Ig gene loci of a chicken B cell line DT40 and streamlines human antibody generation and optimization in one integrated platform. In this study, we further engineered DT40 capable of receiving exogenous antibody genes and examined whether the antibody could be affinity matured. The Ig genes of three representative anti-hVEGF-A antibodies originating from the human ADLib® were introduced; the resulting human IgG1 antibodies had up to 76.4-fold improvement in binding affinities (sub-picomolar KD) within just one round of optimization, owing to efficient accumulation of functional mutations. Moreover, we successfully improved the affinity of a mouse hybridoma-derived anti-hCDCP1 antibody using the engineered DT40, and the observed mutations remained effective in the post-humanized antibody as exhibited by an 8.2-fold increase of in vitro cytotoxicity without compromised physical stability. These results demonstrated the versatility of the novel B cell-based affinity maturation system as an easy-to-use antibody optimization tool regardless of the species of origin.Abbreviations: ADLib®: Autonomously diversifying library, ADLib® KI-AMP: ADLib® knock-in affinity maturation platform, AID: activation-induced cytidine deaminase, CDRs: complementary-determining regions, DIVAC: diversification activator, ECD: extracellular domain, FACS: fluorescence-activated cell sorting, FCM: flow cytometry, HC: heavy chainIg: immunoglobulin, LC: light chain, NGS: next-generation sequencing, PBD: pyrrolobenzodiazepine, SHM: somatic hypermutation, SPR: surface plasmon resonance.

TET3 dioxygenase modulates gene conversion at the avian immunoglobulin variable region via demethylation of non-CpG sites in pseudogene templates.

Diversification of the avian primary immunoglobulin (Ig) repertoire is achieved in developing B cells by somatic hypermutation (SHM) and gene conversion (GCV). GCV is a type of homologous recombination that unidirectionally transfers segments of Ig pseudogenes to Ig variable domains. It is regulated by epigenetic mechanisms like histone modifications, but the role of DNA methylation remains unclear. Here, we demonstrate that the chicken B-cell line DT40 lacking TET3, a member of the TET (Ten-eleven translocation) family dioxygenases that facilitate DNA demethylation, exhibited a marked reduction in GCV activity in Ig variable regions. This was accompanied by a drop in the bulk levels of 5-hydroxymethylcytosine, an oxidized derivative of 5-methylcytosine, whereas TET1-deficient or TET2-deficient DT40 strains did not exhibit such effects. Deletion of TET3 caused little effects on the expression of proteins required for SHM and GCV, but induced hypermethylation in some Ig pseudogene templates. Notably, the enhanced methylation occurred preferably on non-CpG cytosines. Disruption of both TET1 and TET3 significantly inhibited the expression of activation-induced cytidine deaminase (AID), an essential player in Ig diversification. These results uncover unique roles of TET proteins in avian Ig diversification, highlighting the potential importance of TET3 in maintaining hypomethylation In Ig pseudogenes.

Streamlined human antibody generation and optimization by exploiting designed immunoglobulin loci in a B cell line.

Monoclonal antibodies (mAbs) are widely utilized as therapeutic drugs for various diseases, such as cancer, autoimmune diseases, and infectious diseases. Using the avian-derived B cell line DT40, we previously developed an antibody display technology, namely, the ADLib system, which rapidly generates antigen-specific mAbs. Here, we report the development of a human version of the ADLib system and showcase the streamlined generation and optimization of functional human mAbs. Tailored libraries were first constructed by replacing endogenous immunoglobulin genes with designed human counterparts. From these libraries, clones producing full-length human IgGs against distinct antigens can be isolated, as exemplified by the selection of antagonistic mAbs. Taking advantage of avian biology, effective affinity maturation was achieved in a straightforward manner by seamless diversification of the parental clones into secondary libraries followed by single-cell sorting, quickly affording mAbs with improved affinities and functionalities. Collectively, we demonstrate that the human ADLib system could serve as an integrative platform with unique diversity for rapid de novo generation and optimization of therapeutic or diagnostic antibody leads. Furthermore, our results suggest that libraries can be constructed by introducing exogenous genes into DT40 cells, indicating that the ADLib system has the potential to be applied for the rapid and effective directed evolution and optimization of proteins in various fields beyond biomedicine.

Rapid Chimerization of Antibodies.

We previously developed the in vitro method to generate monoclonal antibodies (mAbs) from libraries constructed with chicken B-cell line DT40 (referred to as the "ADLib system"). As the wild-type DT40 cells express immunoglobulin M (IgM), the original ADLib system provides monoclonal antibodies in chicken IgM format. For the therapeutic, diagnostic, and research purposes, the Fc regions of IgMs should be exchanged to other classes and species, for example human or murine IgG. However, the Fc engineering by conventional bioengineering process is laborious and takes plenty of time. Here, we developed a method to enable the seamless replacement of the Fc regions of antibodies generated by the ADLib system, using recombination-mediated cassette exchange (RMCE). In this system, two Cre recombinase recognition sites were inserted into the IgM's Fc region of the DT40 genome, allowing the exchange of the Fc region to the sequences of interest by co-transfection of a donor sequence and a Cre recombinase expression vector. We describe the detailed protocol of the technology: how to construct the RMCE host strains, select mAbs by the ADLib system, and exchange their Fc regions to generate chimeric mAbs.

B Cell-Based Seamless Engineering of Antibody Fc Domains.

Engineering of monoclonal antibodies (mAbs) enables us to obtain mAbs with additional functions. In particular, modifications in antibody's Fc (fragment, crystallizable) region can provide multiple benefits such as added toxicity by drug conjugation, higher affinity to Fc receptors on immunocytes, or the addition of functional modules. However, the generation of recombinant antibodies requires multiple laborious bioengineering steps. We previously developed a technology that enables rapid in vitro screening and isolation of specific mAb-expressing cells from the libraries constructed with chicken B-cell line DT40 (referred to as the 'ADLib system'). To upgrade this ADLib system with the ability to generate customized mAbs, we developed a novel and rapid engineering technology that enables seamless exchanges of mAbs' Fc domains after initial selections of mAb-producing clones by the ADLib system, using a gene-replacement unit for recombinase-mediated cassette exchange (RMCE). In this system, Cre-recombinase recognition sites were inserted into the Fc region of the active DT40 IgM allele, allowing the replacement of the Fc domain by the sequences of interest upon co-transfection of a Cre recombinase and a donor DNA, enabling the rapid exchange of Fc regions. Combining this method with the ADLib system, we demonstrate rapid Fc engineering to generate fluorescent antibodies and to enhance affinity to Fc receptors.

Modulation of immunoglobulin gene conversion frequency and distribution by the histone deacetylase HDAC2 in chicken DT40.

Modifications of histones are reportedly associated with the regulation of immunoglobulin (Ig) gene diversification mechanisms, but the extent of their involvement in promoting sequence alterations at the Ig variable (V) regions still remains to be elucidated. We have previously demonstrated that Ig gene conversion in the B cell line DT40 is accompanied by the local hyperacetylation of histones, and that its frequency is highly increased in cells treated with the histone deacetylase (HDAC) inhibitor trichostatin A (TSA). In this report, we describe the enhancing effects of the homozygous deletion of HDAC2 (HDAC2-/-) on Ig gene conversion. Remarkably, sequence analysis revealed that the distribution of the gene conversion tracts induced throughout the Ig V regions in HDAC2-/- was significantly different from the diversification patterns in TSA-treated wild-type cultures. Furthermore, we found that the effects of HDAC2-/- and of the treatment with TSA were additive as regards histone acetylation, Ig gene transcription, gene conversion frequency and distribution of gene conversion tracts. These results underscore the potential participation of HDAC-mediated histone acetylation in Ig diversification, but also suggest a specific role of HDAC2 to control the spatial targeting of Ig gene conversion.

Regulation of histone H4 acetylation by transcription factor E2A in Ig gene conversion.

Recent studies implicate the transcription factor E2A in Ig diversification such as somatic hypermutation or gene conversion (GCV). GCV also requires active Ig transcription, expression of the activation-induced deaminase (AID) and a set of homologous recombination factors. We have disrupted the E2A gene in the chicken B-cell line DT40 and found greatly diminished rate of GCV without changes in the levels of transcripts from AID and Ig heavy chain or Ig light chain (IgL) genes. However, chromatin immunoprecipitation analysis revealed that the loss of E2A accompanies drastically reduced acetylation levels of the histone H4 in rearranged IgL locus. Furthermore, the defects in GCV were restored by trichostatin A treatment, which raised H4 acetylation to the normal levels. Thus, E2A may contribute to GCV by maintaining histone acetylation, which could be a prerequisite for targeting or full deaminase function of AID.

[ADLib system for rapid and flexible design of monoclonal antibodies].

Monoclonal antibodies (MAbs) have been utilized as research tools, as diagnostic reagents, and for antibody medicine. The preparation of MAbs involves laborious processes and normally takes months. Here we describe an ex vivo B cell-based antibody display system called the ADLib (Autonomously Diversifying Library) system, which enables us to select chicken B cell clones producing antibody against antigens of interest in a couple of weeks. The ADLib system is applicable to self- or highly conserved antigens, polysaccharide chains, peptides, and haptens.

An ex vivo method for rapid generation of monoclonal antibodies (ADLib system).

Here, we describe a protocol for using the ADLib (Autonomously Diversifying Library) system to rapidly generate specific monoclonal antibodies using DT40, a chicken B-cell line that undergoes constitutive gene conversion at both light- and heavy-chain immunoglobulin loci. We previously developed the ADLib system on the basis of our finding that gene conversion in DT40 cells was enhanced by treatment of the cells with a histone deacetylase inhibitor, trichostatin A (TSA). TSA treatment evolves a diversified library of DT40 cells (ADLib), in which each cell has different surface IgM specificity. Antigen-specific DT40 cells are selected from ADLib using antigen-conjugated magnetic beads, and their specificity can be examined by various immunological assays, using culture supernatant containing secreted IgM. The whole process from selection to screening can be completed in about 1 week. Thus, the ADLib system will accelerate biological studies, including drug discovery and design.

Rapid generation of specific antibodies by enhanced homologous recombination.

In the chicken immune system, gene conversion, a type of homologous recombination, primarily contributes to diversification of the immunoglobulin gene. Here, we report on the rapid generation of specific monoclonal antibodies using the chicken DT40 B-cell line undergoing gene conversion. We discovered that the gene conversion frequency at the immunoglobulin locus is increased by treating DT40 cells with a histone deacetylase inhibitor, trichostatin A (TSA), thereby generating diversity at the immunoglobulin locus in the majority of treated cells. This indicates that TSA treatment accelerates the autonomous diversification of surface IgMs on DT40 cells. We took advantage of this effect to select DT40 cells producing specific antibodies with antigen-conjugated magnetic beads. This autonomously diversifying library (ADLib) selection system enables the quick establishment (approximately 1 week from a diversifying library) of various clones producing monoclonal IgMs with enough specificity and affinity for immunological assays, and is applicable to various biotechnologies including rational protein design.

Incorporation of DUF/FACT into chromatin enhances the accessibility of nucleosomal DNA.

DNA unwinding factor (DUF) was discovered as an essential DNA replication factor in Xenopus egg extracts. DUF consists of an HMG protein and a homolog of Cdc68p/Spt16p, and has the capability of unwinding dsDNA. Here we have examined the interaction of DUF with chromatin. DUF was incorporated into chromatin assembled from sperm heads and from plasmid DNA in egg extracts. It was revealed that the chromatin assembled in egg extracts immunodepleted of DUF is less sensitive to micrococcal nuclease (NNase) digestion than that assembled in control extracts, indicating that chromatin containing DUF has more decompact structure than that without DUF. Also we found that DUF has a high affinity for core histones in vitro. We suggest that the function of DUF may be to make the chromatin structure accessible to replication factors.