Quenching accumulation of toxic galactose-1-phosphate as a system to select disruption of protein-protein interactions in vivo.

The reverse two-hybrid system has been developed to readily identify molecules or mutations that can disrupt protein-protein interactions in vivo. This system is generally based on the interaction-dependent activation of a reporter gene, whose product inhibits the growth of the engineered yeast cell. Thus, disruption of the interaction between the hybrid proteins can be positively selected because, by reducing the expression of the negative marker gene, it allows cell growth. Although several counter-selectable marker genes are currently available, their application in the reverse two-hybrid system is generally confronted with technical and practical problems such as low selectivity and relatively complex experimental procedures. Thus, the characterization of more reliable and simple counter-selection assays for the reverse two-hybrid system continues to be of interest. We have developed a novel counter-selection assay based on the toxicity of intracellular galactose-1-phosphate, which accumulates upon expression of a galactokinase-encoding GAL1 reporter gene in the absence of transferase activity. Decreased GAL1 gene expression upon dissociation of interacting proteins causes reduction of intracellular galactose-1-phosphate concentrations, thus allowing cell growth under selective conditions.

Antigen-independent selection of intracellular stable antibody frameworks.

The intracellular expression of highly specific antibody fragments ("intrabodies") in eukaryotes has a great potential in functional genomics and therapeutics. However, since the intracellular reducing environment prevents formation of the conserved intrachain disulfide bonds, most antibodies do not fold properly and are therefore inactive inside cells. The few antibodies that have been found to function in an intracellular environment and that have been characterized for their biophysical properties have generally shown a high degree of stability and solubility. Thus, for intracellular expression and application, very stable antibody frameworks are needed that can correctly fold even in the absence of disulfide bonds and that do not aggregate. Here, we present and discuss a novel method, named "Quality Control," which allows selection of stable and soluble antibody frameworks in vivo without the requirement or knowledge of antigens. This system is based on the expression of single-chain antibody fragments (scFvs) fused to a selectable marker that can control gene expression and cell growth. The activity of such a selectable marker fused to various scFvs that have been biophysically characterized correlated with the solubility and stability of the scFv moieties. This antigen-independent intrabody selection system was applied to screen scFv libraries for identifying stable and soluble frameworks, which subsequently served as acceptor backbones to construct intrabody libraries by randomization of hypervariable loops.