Optimization of extracellular truncated staphylococcal protein A expression in Escherichia coli BL21 (DE3).

Staphylococcal protein A (SpA) plays an important role in Staphylococcus aureus pathogenesis. The recombinant SpA is also widely used in biotechnology to purify polyclonal and monoclonal immunoglobulin G antibodies. In this study, expression and secretion of a truncated form of SpA containing five immunoglobulin-binding domains using its own native signal sequence were optimized in Escherichia coli. Optimization was carried out using response surface method (RSM), making use of the interaction between five variables. The initial results revealed that the signal peptide from S. aureus was recognized in E. coli and the resulting SpA was expressed and secreted into the medium. Compounds, such as glycine, affected the secretion of SpA into the culture medium. The central composite design experiment showed that the optimum conditions for the maximum expression of recombinant truncated SpA in E. coli included 10% (w/v) lactose, 1.77% (w/v) glycine, induction time of 11 H, an optical density (600) of 1.1, and a temperature of 33 °C. Optimization using RSM resulted in a fivefold increase in the secretion of SpA. To date, this is the first study of its kind regarding the definite influence of glycine concentration and duration of the cultivation period on the secretion of SpA.

Regulation of GSK-3beta and beta-Catenin by Galphaq in HEK293T cells.

Recent studies have shown that heterotrimeric G proteins are involved in the regulation of the canonical Wnt/beta-Catenin pathway. However, the mechanism(s) behind this involvement is (are) poorly understood. Our previous results have shown that activation of Galphaq in Xenopus oocytes leads to inhibition of GSK-3beta and stabilization of the beta-Catenin protein, suggesting that Galphaq might stabilize beta-Catenin via inhibition of GSK-3beta. In this study, we have observed similar results in HEK293T cells. In these cells optimal activation of endogenous Galphaq by expressing M3-muscarinic acetylcholine receptor (with or without carbachol treatment), or exposing the cells to thrombin led to an increase of 2 to 3-fold in endogenous cytoplasmic beta-Catenin protein levels. In addition, expression of the activated mutant of Galphaq (GalphaqQL) dramatically enhanced accumulation of exogenous beta-Catenin with no effect on beta-catenin (CTNNB1) gene transcription. The Galphaq-mediated cellular accumulation of beta-Catenin was blocked by expression of a minigene encoding a Galphaq specific inhibitory peptide but not by a minigene encoding a Galphas blocking peptide. Also, expression of GalphaqQL led to a significant reduction in GSK-3beta kinase activity, supporting the idea that the positive role of Galphaq signaling in inducing cellular accumulation of beta-Catenin is mediated through inhibition of GSK-3beta.

The importance of the non-active site and non-periodical structure located histidine residue respect to the structure and function of exo-inulinase.

Here, we have studied the role of a histidine residue with the lowest solvent accessibility among other histidine residues at the end of a short connecting structure (189AELH192) of the catalytic domain of the exo-inulinase through creation of H192A mutant. Site-directed mutagenesis method was applied to create the mutant enzyme. Molecular dynamics (MD) simulations, spectroscopic, calorimetric and kinetics analysis were used to study the structural and functional consequences of His192 substitution. Accordingly, the thermo-stabilities and catalytic performance were decreased upon H192A mutation. In silico and experimental approaches evidently confirm that His192 residue of exo-inulinase possesses structural and functional importance regardless of the lack of direct interaction with the substrate or involvement in the catalytic activity of exo-inulinase.

Deletion of loop fragment adjacent to active site diminishes the stability and activity of exo-inulinase.

Inulinases are classified as hydrolases and widely used in the food and medical industries. Here, we report the deletion of a six-membered adjacent active site loop fragment (74YGSDVT79 sequence) from third Ω-loop of the exo-inulinase containing aspartate residue from Aspergillus niger to study its structural and functional importance. Site-directed mutagenesis was used to create the mutant of the exo-inulinase (Δ6SL). To investigate the stability of the region spanning this loop, MD simulations were performed 80ns for 20-85 residues. Molecular docking was performed to compare the interactions in the active sites of enzymes with fructose as a ligand. Accordingly, the functional thermostability of the exo-inulinase was significantly decreased upon loop fragment deletion. Evaluation of the kinetics parameters (Vmax, Km, kcat and, kcat/Km) and activation energy (Ea) of the catalysis of enzymes indicated the importance of the deleted sequence on the catalytic performance of the enzyme. In conclusion, six-membered adjacent active site loop fragment not only plays a crucial role in the stability of the enzyme, but also it involves in the enzyme catalysis through lowering the activation energy of the catalysis and effective improving the catalytic performance.