Stabilizing osmolytes' effects on the structure, stability and function of tc-tenecteplase: A one peptide bond digested form of tenecteplase.

Organic osmolytes, as major cellular compounds, cause protein stabilization in the native form. In the present study, the possible chaperone effects of the three naturally occurring osmolytes on the two-chain form of tenecteplase (tc-TNK), a recombinant, genetically engineered mutant tissue plasminogen activator, have been explored by using circular dichroism, steady-state fluorescence, UV-Visible spectroscopy, and in silico experiments. The tc-TNK is derived from the one-chain protein upon disruption of one peptide bond.

A comparative study of structure, stability and function of sc-tenecteplase in the presence of stabilizing osmolytes.

The aim of the present study was to investigate the effect of three routine drug excipients, as osmolytes, in three different concentrations, on structure, thermal stability and the activity of single-chain (sc-) tenecteplase. To see the influence of trehalose, mannitol, and sucrose on the structure, stability and function of sc-tenecteplase, thermal stability, fluorescence, circular dichroism (CD) and enzyme kinetic measurements and molecular docking studies were carried out. To measure the effect of osmolytes on stability of sc-tenecteplase, thermodynamic parameters (transition temperature (T), standard enthalpy change (ΔH°), standard entropy change (ΔS°) and ΔG°, the standard Gibbs free energy change, were determined from heat-induced transition curves of the protein in absence and presence of each osmolyte.

Display of B. pumilus chitinase on the surface of B. subtilis spore as a potential biopesticide.

Background: Chitinases can inhibit the growth of many fungal diseases which are a great threat for global agricultural production. Biological control of pathogens like fungi, is believed to be one of the best ways to eliminate the adverse effects of plant pathogens. To this end, we expressed and displayed a chitinase from Bacillus pumilus (ChiS) on the surface of Bacillus subtilis spores, as a biocontrol agent.

Evaluation of Iron Oxide Nanoparticles Toxicity on Liver Cells of BALB/c Rats.

Background: Because of their unique magnetic properties, Fe3O4 nanoparticles (Fe3O4-NPs) have extensive applications in various biomedical aspects. Investigation of the possible adverse aspects of these particles has lagged far behind their fast growing application.

Objectives: The current study aimed to evaluate the toxicity of Fe3O4-NPs in the liver of mice.