The demand for highly efficient macromolecular drugs, used in the treatment of many severe diseases, is continuously increasing. However, the hydrophilic character and large molecular size of these drugs significantly limit their ability to permeate across cellular membranes and thus impede the drugs in reaching their target sites in the body. Cell-penetrating peptides (CPP) have gained attention as promising drug excipients, since they can facilitate drug permeation across cell membranes constituting a major biological barrier. Fluorophores are frequently covalently conjugated to CPPs to improve detection, however, the ensuing change in physico-chemical properties of the CPPs may alter their biological properties. With complementary biophysical techniques, we show that the mode of biomembrane interaction may change considerably upon labeling of the CPP penetratin (PEN) with a fluorophore. Fluorophore-PEN conjugates display altered modes of membrane interaction with increased insertion into the core of model cell membranes thereby exerting membrane-thinning effects. This is in contrast to PEN, which localizes along the head groups of the lipid bilayer, without affecting the thickness of the lipid tails. Particularly high membrane disturbance is observed for the two most hydrophobic PEN conjugates; rhodamine B or 1-pyrene butyric acid, as compared to the four other tested fluorophore-PEN conjugates.
A prerequisite for the use of dendrimers as drug delivery vehicles is the detailed molecular understanding of the drug interaction. The purpose of this study was to characterize the self-assembly process between siRNA and generation 7 poly(amidoamine) dendrimers and the resulting dendriplexes in aqueous solution using structural and calorimetric methods combined with molecular dynamics simulations. Complexes with a length scale of 150 nm showed a decreasing size with increasing amine-to-phosphate ratio by dynamic light scattering. At the molecular level, individual dendrimers studied by small-angle X-ray scattering (SAXS) showed no change in size upon siRNA binding, suggesting a rigid sphere behavior. Isothermal titration calorimetry (ITC) demonstrated exothermic binding with a concentration-dependent collapse of complexes. Both the experimentally determined ΔH(bind) and size were in close accordance with molecular dynamics simulations. This study demonstrates the unique complementarity of SAXS, ITC, and modeling for the detailed description of the molecular interactions between dendrimers and siRNA during dendriplex formation.
The reduced coenzyme NADH plays a central role in mitochondrial respiratory metabolism. However, reports on the amount of free NADH in mitochondria are sparse and contradictory. We first determined the emission spectrum of NADH bound to proteins using isothermal titration calorimetry combined with fluorescence spectroscopy. The NADH content of actively respiring mitochondria (from potato tubers [Solanum tuberosum cv Bintje]) in different metabolic states was then measured by spectral decomposition analysis of fluorescence emission spectra. Most of the mitochondrial NADH is bound to proteins, and the amount is low in state 3 (substrate þ ADP present) and high in state 2 (only substrate present) and state 4 (substrate þ ATP). By contrast, the amount of free NADH is low but relatively constant, even increasing a little in state 3. Using modeling, we show that these results can be explained by a 2.5-to 3-fold weaker average binding of NADH to mitochondrial protein in state 3 compared with state 4. This indicates that there is a specific mechanism for free NADH homeostasis and that the concentration of free NADH in the mitochondrial matrix per se does not play a regulatory role in mitochondrial metabolism. These findings have far-reaching consequences for the interpretation of cellular metabolism.
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