Carolina R. Jost

Correct disulfide pairing and efficient refolding of detergent-solubilized single-chain Fv proteins from bacterial inclusion bodies

In vitro folding of denatured proteins has remained an inefficient and empirical process that has limited the use of bacterially expressed recombinant proteins. In this paper we show that in vitro folding of recombinant single-chain Fv (sFv) proteins is markedly facilitated when disulfide bonds are formed in detergent solution. sFv proteins from three different antibodies were expressed as bacterial cytoplasmic inclusion bodies and solubilized in the weak ionic detergent, sodium lauroylsarcosine (SLS). Upon oxidation in air in the presence of metal ion catalysts, all three sFvs quantitatively formed intrachain disulfide bonds which ran as a single band in SDS-polyacrylamide gel electrophoresis under non-reducing conditions. By contrast, oxidation from 6 M urea gave large amounts of disulfide linked aggregates, and three closely spaced bands of monomeric protein. Detergent was removed from the oxidized sFvs by addition of 6 M urea and absorption with an ion exchange resin. After dialysis and gel filtration in non-denaturing solution, moderate to high yields of monomeric sFv were obtained, depending upon the sFv. All three sFvs gave single bands on isoelectric focussing and SDS-PAGE gels and had similar or identical binding specificities and affinities as the parental Fabs, implying that the final products contained correctly paired disulfide bonds. The correct disulfide pairing suggests that the disulfide loops within the detergent-solubilized sFvs adopt a native-like structure.

A single-chain bispecific Fv2 molecule produced in mammalian cells redirects lysis by activated CTL

Single-chain Fv (sFv) molecules consist of the two variable domains of an antibody (Ab) connected by a polypeptide spacer and contain the binding activities of their parental antibodies (Abs). In this paper we have attached the C-terminus of 2C11-sFv (anti-mouse CD3 epsilon-chain) to the N-terminus of OKT9-sFv (anti-human transferrin receptor [TfR]) through a 23 amino acid inter-sFv linker consisting primarily of CH1 region residues from 2C11, to form a single-chain bispecific Fv2 [bs(sFv)2] molecule. The bs(sFv)2 was expressed in COS-7 cells, and was secreted at the same rate as the two parental sFvs. The secreted protein had both anti-CD3 and anti-TfR binding activities. Essentially all of the secreted bs(sFv)2 molecules bound TfR and the binding affinity of the bs(sFv)2 was comparable to that of OKT9 sFv and Fab. Thus, the attachment of the inter-sFv linker to the N-terminus of OKT9-sFv did not impair its binding function. The bs(sFv)2 retained both binding specificities after long-term storage at 4 degrees C or overnight incubation at 37 degrees C. It redirected activated mouse CTL to specifically lyse human TfR+ target cells at low (ng/ml) concentrations and was much more active than a chemically cross-linked heteroconjugate prepared from the same parental mAbs. Because bs(sFv)2 molecules secreted by mammalian cells are homogeneous proteins containing two binding sites in a single polypeptide chain, they hold great promise as an easily obtainable, economic source of a bispecific molecule suitable for in vivo use.

Targeted Cellular Cytotoxicity

Cell-mediated cytolysis occurs when a cytotoxic cell binds and delivers a “lethal hit” to a target cell. Several types of cells commonly found in blood are capable of performing cytolysis, including monocytes, neutrophils, eosinophils, natural killer (NK) cells, platelets, and T lymphocytes. The T-cell receptors (TCR) on T cells and the Fc γ receptors (Fc γ R) on myeloid cells, NK cells, and platelets are two well-characterized families of cell surface glycoproteins that are involved in binding target cells and triggering lysis.

Redirection of cellular cytotoxicity: a two step approach using recombinant single-chain Fv molecules.

In this article the authors discuss an indirect system for redirecting cellular cytotoxicity, which utilizes a “universal” bispecific antibody to redirect T-cells to kill cells targeted with single-chain Fv (sFv) fusion proteins that carry a peptide tag recognized by the bispecific antibody. This approach has a number of theoretical advantages in the immunotherapy of cancer.