Evaluation of the cyclic single-chain Fv antibody derived from nivolumab by biophysical analyses and in vitro cell-based bioassay.

Single-chain Fv (scFv) is a recombinant small antibody in which a polypeptide linker connects the variable regions of the light chain (VL) and the heavy chain (VH). The practical use of scFv, however, has been prevented by its tendency to aggregate due to interchain VL-VH interactions. We recently developed a cyclic scFv whose N-terminus and C-terminus were connected by protein ligation techniques. Biophysical comparisons between cyclic and linear scFv have been conducted, but cell biological evaluations remain unexplored. Here we studied the properties of cyclic and linear scFv derived from nivolumab. Biophysical studies revealed that the thermal stability was not changed but that the antigen-binding activity was approximately 3-fold higher as a result of circularization. A cell-based PD-1/PD-L1 interaction inhibitory assay revealed that the biological activity of scFv was markedly higher in the circularized form. In addition, biophysical analysis of scFv proteins incubated in the presence of serum revealed that circularization suppressed the decrease in antigen-binding activity. It could be assumed that circularization of scFv improved stability in the presence of serum, which in turn would suggest the applicability of cyclic scFv as a biopharmaceutical format.

Structure-based design, biophysical characterization, and biochemical application of the heterodimeric affinity purification tag based on the Schistosoma japonicum glutathione-S-transferase (SjGST) homodimer.

Schistosoma japonicum glutathione-S-transferase (SjGST), the so-called GST-tag, is one of the most widely used protein tags for the purification of recombinant proteins by affinity chromatography. Attachment of SjGST enables the purification of a protein of interest (POI) using commercially available glutathione-immobilizing resins. Here we produced an SjGST mutant pair that forms heterodimers by adjusting the salt bridge pairs in the homodimer interface of SjGST. An MD study confirmed that the SjGST mutant pair did not disrupt the heterodimer formation. The modified SjGST protein pair coexpressed in Escherichia coli was purified by glutathione-immobilized resin. The stability of the heterodimeric form of the SjGST mutant pair was further confirmed by size exclusion chromatography. Surface plasmon resonance measurements unveiled the selective formation of heterodimers within the pair, accompanied by a significant suppression of homodimerization. The heterodimeric SjGST exhibited enzymatic activity in assays employing a commercially available fluorescent substrate. By fusing one member of the heterodimeric SjGST pair with a fluorescent protein and the other with the POI, we were able to conveniently and sensitively detect protein-protein interactions using fluorescence spectroscopy in the pull-down assays. Thus, utilization of the heterodimeric SjGST would be a useful tag for protein science.

Idiotopes of antibodies against HIV-1 CD4-induced epitope shared with those against microorganisms.

Induction of antibodies (Abs) against the conformational CD4-induced (CD4i) epitope is frequent in HIV-1 infection. However, the mechanism of development of anti-CD4i Abs is unclear. We used anti-idiotypic (aID) monoclonal Abs (mAbs) of anti-CD4i mAbs to isolate anti-CD4i mAbs from infected subjects and track the causative antigens. One anti-aID mAb sorted from infected subjects by aID mAbs had the characteristics of anti-CD4i Abs, including IGHV1-69 usage and ability to bind to HIV-1 Env enhanced by sCD4. Critical amino acid sequences for the binding of six anti-aID mAbs, with shared idiotope to anti-CD4i mAbs, were analysed by phage display. The identified amino acid sequences showed similarity to proteins from human microbiota and infectious agents. Peptides synthesized from Caudoviricetes sp and Vibrio vulnificus based on the identified sequences were reactive to most anti-aID and some anti-CD4i mAbs. These results suggest that anti-CD4i Abs may evolve from B cells primed by microorganisms.

Molecular Dynamics-Based Design and Biophysical Evaluation of Thermostable Single-Chain Fv Antibody Mutants Derived from Pharmaceutical Antibodies.

Antibody drugs are denatured under physical stress, e.g., friction, heat, and freezing, which triggers formation of aggregates and resultant allergic reactions. Design of a stable antibody is thus critical for the development of antibody drugs. Here, we obtained a thermostable single-chain Fv (scFv) antibody clone by rigidifying the flexible region. We first conducted a short molecular dynamics (MD) simulation (3 runs of 50 ns) to search for weak spots in the scFv antibody, i.e., flexible regions located outside the CDR (complementarity determining region) and the interface between the heavy-chain and light-chain variable regions. We then designed a thermostable mutant and evaluated it by means of a short MD simulation (3 runs of 50 ns) based on reductions in the root-mean-square fluctuation (RMSF) values and formation of new hydrophilic interactions around the weak spot. Finally, we designed the VL-R66G mutant by applying our strategy to scFv derived from trastuzumab. Trastuzumab scFv variants were prepared by using an Escherichia coli expression system, and the melting temperature-measured as a thermostability index-was 5 °C higher than that of the wild-type trastuzumab scFv, while the antigen-binding affinity was unchanged. Our strategy required few computational resources, and would be applicable to antibody drug discovery.

Hydrogen bonds connecting the N-terminal region and the DE loop stabilize the monomeric structure of transthyretin.

Transthyretin (TTR) is a homo-tetrameric serum protein associated with sporadic and hereditary systemic amyloidosis. TTR amyloid formation proceeds by the dissociation of the TTR tetramer and the subsequent partial unfolding of the TTR monomer into an aggregation-prone conformation. Although TTR kinetic stabilizers suppress tetramer dissociation, a strategy for stabilizing monomers has not yet been developed. Here, we show that an N-terminal C10S mutation increases the thermodynamic stability of the TTR monomer by forming new hydrogen bond networks through the side chain hydroxyl group of Ser10. Nuclear magnetic resonance spectrometry and molecular dynamics simulation revealed that the Ser10 hydroxyl group forms hydrogen bonds with the main chain amide group of either Gly57 or Thr59 on the DE loop. These hydrogen bonds prevent the dissociation of edge strands in the DAGH and CBEF ß-sheets during the unfolding of the TTR monomer by stabilizing the interaction between ß-strands A and D and the quasi-helical structure in the DE loop. We propose that introducing hydrogen bonds to connect the N-terminal region to the DE loop reduces the amyloidogenic potential of TTR by stabilizing the monomer.

Expression, Purification and Characterization of CAR/NCOA-1 Tethered Protein in E. coli Using Maltose-Binding Protein Fusion Tag and Gelatinized Corn Starch.

The constitutive active/androstane receptor (CAR) is a nuclear receptor that functions as a xenobiotic sensor, which regulates the expression of enzymes involved in drug metabolism and of efflux transporters. Evaluation of the binding properties between CAR and a drug was assumed to facilitate the prediction of drug-drug interaction, thereby contributing to drug discovery. The purpose of this study is to construct a system for the rapid evaluation of interactions between CAR and drugs. We prepared recombinant CAR protein using the Escherichia coli expression system. Since isolated CAR protein is known to be unstable, we designed a fusion protein with the CAR binding sequence of the nuclear receptor coactivator 1 (NCOA1), which was expressed as a fusion protein with maltose binding protein (MBP), and purified it by several chromatography steps. The thus-obtained CAR/NCOA1 tethered protein (CAR-NCOA1) was used to evaluate the interactions of CAR with agonists and inverse agonists by a thermal denaturation experiment using differential scanning fluorometry (DSF) in the presence and absence of drugs. An increase in the melting temperature was observed with the addition of the drugs, confirming the direct interaction between them and CAR. DSF is easy to set up and compatible with multiwell plate devices (such as 96-well plates). The use of DSF and the CAR-NCOA1 fusion protein together allows for the rapid evaluation of the interaction between a drug and CAR, and is thereby considered to be useful in drug discovery.