Retargeting of CTL by an efficiently refolded bispecific single-chain Fv dimer produced in bacteria.

A single-chain bispecific Fv dimer (bs(sFv)2) having specificity for mouse CD3 epsilon chain and human transferrin receptor was produced in bacterial inclusion bodies. To overcome difficulties associated with in vitro protein folding, we used a novel renaturation approach to obtain active bs(sFv)2. The protein was dissolved in the weak ionic detergent sodium lauroylsarcosine, and disulfides were formed by oxidation in air. After oxidation, the bs(sFv)2 exhibited very little covalent aggregation and migrated as a single species in nonreducing SDS-PAGE, suggesting that disulfides were correctly paired. The detergent was removed using an ion exchange resin and the protein fractionated by size exclusion chromatography. The recovered 65-kDa protein was monomeric in non-denaturing solvent, homogeneous by SDS-PAGE, and comprised 15 to 20% of material applied to the gel filtration column. This protein bound specifically to both mouse CD3 epsilon chain and human transferrin receptor with affinities indistinguishable from those of the parental Fabs or single-chain Fvs. The bs(sFv)2 specifically redirected mouse cytotoxic T cells to lyse target cells expressing human transferrin receptor at picomolar concentrations. Bacterially produced and detergent oxidized bs(sFv)2 molecules may therefore provide the abundant amounts of homogeneous active material required to redirect cytotoxic cells against tumors and other unwanted cells in animal models and in patients.

Mammalian expression and secretion of functional single-chain Fv molecules.

Single-chain Fv (sFv) proteins are genetically engineered molecules that consist of the two variable domains of an antibody connected by a polypeptide linker; they contain the antigen binding function of the parental protein in a single 30-kDa polypeptide chain. sFvs are usually produced in bacteria where they are insoluble and therefore require extensive refolding in vitro. In this report we followed the processing of three antibody sFvs (145-2C11 directed against murine CD3 epsilon chain, OKT9 against the human transferrin receptor, and U7.6 against dinitrophenyl groups) by transfected mammalian (COS-7) cells to determine whether the mammalian protein folding machinery can produce and secrete active sFv with high efficiency. The sFvs contained an immunoglobulin light chain leader sequence, which directed them to the endoplasmic reticulum and allowed secretion into the medium. We found that the sFvs were secreted at different rates, with the rate-limiting step of secretion being their exit from the endoplasmic reticulum. We increased the secretion rate of one of the sFvs by introducing an asparagine-linked glycosylation site in FR1 of the heavy chain, and by using tunicamycin (an inhibitor of glycosylation) we found that glycosylated antibody sFvs were secreted faster than their nonglycosylated counterparts. All secreted sFvs specifically bound their antigens; where tested, at least 90% of the secreted sFv was functional. Therefore, mammalian cells can effectively fold and secrete sFv antibody and can provide a convenient system for testing and producing sFv proteins.