The regulated expression of an intrabody produces a mutant phenotype in Drosophila

Strategies for successful recombinant expression of disulfide bond-dependent proteins in Escherichia coli

Bacteria are simple and cost effective hosts for producing recombinant proteins. However, their physiological features may limit their use for obtaining in native form proteins of some specific structural classes, such as for instance polypeptides that undergo extensive post-translational modifications. To some extent, also the production of proteins that depending on disulfide bridges for their stability has been considered difficult in E. coli.

Both eukaryotic and prokaryotic organisms keep their cytoplasm reduced and, consequently, disulfide bond formation is impaired in this subcellular compartment. Disulfide bridges can stabilize protein structure and are often present in high abundance in secreted proteins. In eukaryotic cells such bonds are formed in the oxidizing environment of endoplasmic reticulum during the export process. Bacteria do not possess a similar specialized subcellular compartment, but they have both export systems and enzymatic activities aimed at the formation and at the quality control of disulfide bonds in the oxidizing periplasm.

This article reviews the available strategies for exploiting the physiological mechanisms of bactera to produce properly folded disulfide-bonded proteins.

Recombinant Antibodies Against Subcellular Fractions Used to Track Endogenous Golgi Protein Dynamicsin Vivo

Generation of specific antibodies against enriched subcellular fractions is a powerful strategy to identify and characterize cellular components. We show that recombinant antibodies can be selected in vitro by phage display against complex subcellular fractions, namely microtubule-binding proteins and Golgi stacks. This technique has allowed us to overcome many limitations of the classical animal-based approach and generate cell biology-compliant antibodies. In addition, we show that intracellular expression of GFP-tagged recombinant antibodies can reveal the dynamics of endogenous proteins in vivo. Endogenous Giantin is very static and outlines the Golgi in living cells. It accumulates neither onto Golgi-derived tubules upon Brefeldin A treatment before Golgi disappearance, nor onto de novo formed Golgi mini-stacks upon microtubule depolymerization, and remains instead on the 'old' pericentriolar Golgi. This suggests that, in contrast to other Golgi matrix proteins, endogenous Giantin is very stably associated with the Golgi and does not efficiently recycle to the ER. Altogether, we show that the antibody phage display technique represents an efficient alternative to rapidly generate versatile antibodies that represent new tools to study protein function.

Nucleocytoplasmic shuttling of antigen in mammalian cells conferred by a soluble versus insoluble single-chain antibody fragment equipped with import/export signals

The ectopic expression of antibody fragments within mammalian cells is a challenging approach for interfering with or even blocking the biological function of the intracellular target. For this purpose, single-chain Fv (scFv) fragments are generally preferred. Here, by transfecting several mammalian cell lines, we compared the intracellular behavior of two scFvs (13R4 and 1F4) that strongly differ in their requirement of disulphide bonding for the formation of active molecules in bacteria. The scFv 13R4, which is correctly folded in the bacterial cytoplasm, was solubly expressed in all cell lines tested and was distributed in their cytoplasm and nucleus, as well. In addition, by appending to the 13R4 molecules the SV40 T-antigen nuclear localisation signal (NLS) tag, cytoplasmic-coexpressed antigen was efficiently retargeted to the nucleus. Compared to the scFv 13R4, the scFv 1F4, which needs to be secreted in bacteria for activity, accumulated, even with the NLS tag, as insoluble aggregates within the cytoplasm of the transfected cells, thereby severely disturbing fundamental functions of cell physiology. Furthermore, by replacing the NLS tag with a leucine-rich nuclear export signal (NES), the scFv 13R4 was exclusively located in the cytoplasm, whereas the similarly modified scFv 1F4 still promoted cell death. Coexpression of NES-tagged 13R4 fragments with nuclear antigen promoted its efficient retargeting to the cytoplasm. This dominant effect of the NES tag was also observed after exchange of the nuclear signals between the scFv 13R4 and its antigen. Taken together, the results indicate that scFvs that are active in the cytoplasm of bacteria may behave similarly in mammalian cells and that the requirement of their conserved disulphide bridges for activity is a limiting factor for mediating the nuclear import/export of target in a mammalian cell context. The described shuttling effect of antigen conferred by a soluble scFv may represent the basis of a reliable in vivo assay of effective protein- protein interactions.

Intracellular stability of anti-caspase-3 intrabodies determines efficacy in retargeting the antigen

Although intracellular antibodies (intrabodies) are being explored as putative therapeutic and research reagents, little is known about the principles that dictate the efficacy of these molecules. In our efforts to address this issue, we generated a panel of five intrabodies, directed against catalytically inactive murine caspase-3, by screening single-chain antibody (Fv) phage display libraries. Here we determined criteria that single-chain Fv fragments must fulfill to act as efficient intrabodies. The affinities of these intrabodies, as measured by surface plasmon resonance, varied approximately 5-fold (50-250 nm). Despite their substantial sequence similarity, only two of the five intrabodies were able to significantly accumulate intracellularly. These disparities in intracellular expression levels were reflected by differences in the stability of the purified protein species when analyzed by urea denaturation studies. We observed varied efficiencies in retargeting the antigen murine caspase-3, from the cytosol to the nucleus, mediated by intrabodies tagged with an SV40 nuclear localization signal. Our results demonstrate that the intrinsic stability of the intrabody, rather than its affinity for the antigen, dictates its intracellular efficacy.

Isolation and characterization of single-chain Fv genes encoding antibodies specific for Drosophila Poxn protein

The usefulness of intrabodies as specific inhibitors of gene function has been extensively demonstrated in cell culture assays. However, very few experiments have been conducted with intrabodies expressed in whole organisms. To evaluate the intrabody technology in Drosophila, we focused on poxn protein, since its effects can be easily studied. We purified the recombinant poxn protein. We next isolated three single-chain variable fragments (scFv) which specifically recognize poxn protein. Two scFvs, designated alpha-Poxn2 and alpha-Poxn4, react with both denatured and native Poxn with half maximal inhibition values of 100 nM and 40 nM, respectively. The alpha-Poxn5 scFv also recognizes denatured Poxn but either does not recognize native Poxn or its half maximal inhibition value for native Poxn is high.