Regulation of Ras p21 and RalA GTPases activity by quinine in mammary epithelial cells.

Quinine, a bitter compound, can act as an agonist to activate the family of bitter taste G protein-coupled receptor family of proteins. Previous work from our laboratory has demonstrated that quinine causes activation of RalA, a Ras p21-related small G protein. Ral proteins can be activated directly or indirectly through an alternative pathway that requires Ras p21 activation resulting in the recruitment of RalGDS, a guanine nucleotide exchange factor for Ral. Using normal mammary epithelial (MCF-10A) and non-invasive mammary epithelial (MCF-7) cell lines, we investigated the effect of quinine in regulating Ras p21 and RalA activity. Results showed that in the presence of quinine, Ras p21 is activated in both MCF-10A and MCF-7 cells; however, RalA was inhibited in MCF-10A cells, and no effect was observed in the case of MCF-7 cells. MAP kinase, a downstream effector for Ras p21, was activated in both MCF-10A and MCF-7 cells. Western blot analysis confirmed the expression of RalGDS in MCF-10A cells and MCF-7 cells. The expression of RalGDS was higher in MCF-10A cells in comparison to the MCF-7 cells. Although RalGDS was detected in MCF-10A and MCF-7 cells, it did not result in RalA activation upon Ras p21 activation with quinine suggesting that the Ras p21-RalGDS-RalA pathway is not active in the MCF-10A cells. The inhibition of RalA activity in MCF-10A cells due to quinine could be as a result of a direct effect of this bitter compound on RalA. Protein modeling and ligand docking analysis demonstrated that quinine can interact with RalA through the R79 amino acid, which is located in the switch II region loop of the RalA protein. It is possible that quinine causes a conformational change that results in the inhibition of RalA activation even though RalGDS is present in the cell. More studies are needed to elucidate the mechanism(s) that regulate Ral activity in mammary epithelial cells.

Construction of human anti-tetanus single-chain variable fragment applying SYMPLEX technology.

BACKGROUND: Human monoclonal antibodies are important molecules in clinical research. Current Limitations of mAb technologies namely instability of immortalized B-cell line and probability of forming unusual VH-VL pairs in phage-display method led to mAbs technology based on single plasma cell called ``SYMPLEX''. OBJECTIVE: In this method, cognate VH and VL fragments generated from individual antibody genes exactly the same as natural ones. METHODS: PBMCs of whole blood of an immunized candidate was used as a resource of rearranged Ab genes. Then flow-cytometric screening was performed to isolate VH and VL from PBMCs. Various VH and VLκ were amplified by six pairs of primers. Overlap Extension PCR was accomplished to link VH and Vκ regions. ScFv inserted into T-vector and its sequence was determined and eventually analyzed by using blast analysis tools. RESULTS: Electrophoresis results indicated that VH and VL fragments were separately amplified by PCR with a length of about 400bp and linked through OE-PCR. Hence, ScFv, which was approximately 800bp in size, was constructed then sequencing and BLASTn results of the ScFv fragment consequently proved the accuracy. CONCLUSION: Results showed 88% similarity to available sequences in mentioned databank. ScFv was ultimately inserted into expression vector for producing recombinant human anti-tetanus mAb.