Breaks in arrhenius plots of reactions involving membrane-bound and solubilized sialyltransferases, due to temperature dependence of kinetic parameters

The Stability of lyophilized lipid/DNA complexes during prolonged storage

It is well known that excipients are required to protect nonviral vectors during the lyophilization process. The goal of this study is to describe the stability of lyophilized nonviral vector preparations on pharmaceutically relevant timescales and provide insight into the factors that govern long-term stability of vectors in the dried state. Lipid/DNA complexes were lyophilized in glucose, sucrose, or trehalose and stored for a period of up to 2 years at five different temperatures (-20, 4, 22, 40, 60 degrees C). We evaluated simultaneously the physico-chemical characteristics (size, zeta potential, ethidium bromide (EtBr) accessibility, supercoiled DNA content) and the ability of vector formulations to transfect COS-7 cells at different time intervals. In addition, a fluorescence assay was utilized to assess levels of ROS in the dried cake after storage. The physical state of each formulation was evaluated by determination of the glass transition temperature and residual moisture content, before and after storage. Results from our stability study show that a progressive degradation of lipid/DNA complexes occurs in terms of transfection rates, particle size, dye accessibility, and supercoil content, even when samples are stored at low temperatures (e.g., -20 degrees C). Furthermore, our preliminary results on the quantification of free radicals in rehydrated formulations emphasize the importance of developing strategies to prevent the formation of reactive oxygen species (ROS) during prolonged storage in the dried state.

Comparative thermodynamics of opioid receptor ligand interaction in the bovine adrenal medulla membranes--evidence of opioid site heterogeneity

1. A marked dependence on temperature of agonist binding delta, mu and kappa 1-3 opioid sites in the bovine adrenal medulla was observed, at the range of 0 to 37 degrees C. These changes concern kinetic (k1) and equilibrium constants (Kd), but not binding capacities (Bmax). 2. These dependences are different for each ligand and each opioid receptor, suggesting their molecular heterogeneity. 3. The comparative thermodynamics indicates that the interaction of opioid agonists with their receptor is exergonic (delta G degree < 0) and entropy driven (delta S degree > 0). 4. The comparison of Van't Hoff and Arrhenius plots indicates a discrete mechanism in the binding of each opioid receptor.