Noncovalent scFv multimers of tumor-targeting anti-Lewis(y) hu3S193 humanized antibody.

Single-chain variable fragments (scFvs) of anti-Lewis(y) hu3S193 humanized antibody were constructed by joining the V(H) and V(L) domains with either +2 residues, +1 residue, or by directly linking the domains. In addition two constructs were synthesized in which one or two C-terminal residues of the V(H) domain were removed (-1 residue, -2 residue) and then joined directly to the V(L) domain. An scFv construct in the reverse orientation with the V(L) joined directly to the V(H) domain was also synthesized. Upon transformation into Escherichia coli all scFv constructs expressed active protein. Binding activity, multimeric status, and multivalent properties were assessed by flow cytometry, size exclusion chromatography, and biosensor analysis. The results for hu3S193 scFvs are consistent with the paradigm that scFvs with a linker of +3 residues or more associate to form a non-covalent dimer, and those with a shorter linker or directly linked associate predominantly to form a non-covalent trimer and tetramer that are in equilibrium. While the association of V domains to form either a dimer or trimer/tetramer is governed by the length of the linker, the stability of the trimer/tetramer in the equilibrium mixture is dependent on the affinity of the interaction of the individual V domains to associate to form the larger Fv module.

Cytotoxicity of dihydropteroate in Saccharomyces cerevisiae.

Microbes and plants synthesise folate using a unique biosynthetic pathway that is absent in animals. The end product, tetrahydrofolate, is utilised by all forms of life. In this study, an intermediate in this synthesis, dihydropteroic acid, was found to be toxic to Saccharomyces cerevisiae. Further tests were performed on mutants deficient in folate synthesis. One mutant specifically lacked dihydropteroate synthase and the second lacked dihydrofolate synthase. Dihydropteroic acid itself appeared to be toxic since both of these mutants were also inhibited. These results suggest novel ways in which antifolate therapy may be developed.

Large-scale bacterial fermentation and isolation of scFv multimers using a heat-inducible bacterial expression vector.

This protocol describes optimised large-scale bacterial fermentation conditions for recombinant single-chain Fv molecule (scFv) monomers and multimers (diabodies and triabodies). The heat-inducible bacterial secretion vector, pPOW3, utilising the temperature-regulated tandem lambda promoters is particularly suited to the large-scale fermentation of single-chain antibodies, providing low-cost recombinant protein synthesis. The protein expressed by this vector is secreted into the periplasm where it is found as both the soluble and insoluble protein that is associated with the cell membranes. A protein fractionation method for the rapid extraction and affinity purification of the soluble protein fraction and the urea solubilization and refolding of the insoluble protein fraction expressed from single-chain antibody (Ab) fragment gene constructs is described. This method is simple to perform and utilises inexpensive reagents to provide cost-effective protein synthesis.