Evaluation of solute binding to proteins and intra-protein distances from steady state fluorescence measurements.

Steady state fluorescence measurements, due to their relative simplicity and fast and easy implementation, are one of the most employed techniques for evaluating the non-covalent binding of small molecules to proteins. In the present review we discuss the main characteristics of solute binding and the experimental procedures that can be employed for evaluating both, the efficiency of the process and the number of binding sites. It is also discussed the possibility of determining the distance between endogenous fluorophores and non-covalently bound solutes. Albumins (human serum albumin and bovine serum albumin) are considered as model proteins due to their relevance as solute carriers, the extensive available data comprising binding of a large number of solutes, and the reduced number of intrinsic fluorophores which simplifies the data treatment. It is shown that, in spite of the apparent simplicity of the systems, extreme care must be exercised in data treatment and interpretation to avoid misleading results. This applies to the evaluation of binding constants, number of binding sites, and average distance between intrinsic fluorophores and non-covalently bound solutes associated to the proteins.

Kinetics of peroxidation of linoleic acid incorporated into DPPC vesicles initiated by the thermal decomposition of 2,2'-azobis(2-amidinopropane) dihydrochloride.

In a previous work [Chem. Phys. Lipids 2000 104, 49], we have derived the following rate law for the oxidation of lipids in compartmentalized systems: R(T)=(k(1)/k(t))(0.5) k(p) [In](0.5) c(0.5) [LH], where, R(T) is the total rate of oxidation, k(1) is the rate constant for the production of free radicals, k(t) and k(p) are the intra-particle rate constants for the termination and propagation sets, respectively, [In] is the concentration of a water-soluble initiator, c is the concentration of particles, and [LH] is the intra-particle concentration of oxidable lipid. In the present work, we have investigated on the applicability of the proposed kinetic rate law for a system where it takes place the oxidation of a reactive lipid incorporated into an inert matrix. With this purpose, we have measured the rate of oxidation of linoleic acid incorporated into dipalmitoylphosphatidylcholine vesicles initiated by the thermal decomposition of 2,2'-azobis(2-amidinopropane) dihydrochloride as a function of the initiator, particles, and intra-particle LH concentrations. The experimentally determined kinetic orders obtained were 0.54+/-0.02, 0.48+/-0.05 and 0.83+/-0.04 for the dependence of the oxidation rate with initiator, particles, and LH intra-particle concentrations, respectively, in agreement with those theoretically predicted. The lower value obtained for the kinetic order in LH is attributed to a change in k(t) with the increase in oxidable lipid intra-particle concentration. The main point to be emphazised from the results here obtained is that the kinetic rate law for the oxidation of lipids in compartmentalized systems can be significantly different than that observed when to the oxidation takes place in homogeneous solution.

Kinetics of lipid peroxidation in compartmentalized systems initiated by a water-soluble free radical source.

Kinetic rate laws arising from theoretical expectations for the oxidation of lipids initiated by water-soluble free radicals in compartmentalized systems under different experimental conditions are deduced. In particular, the predictions for the kinetic reaction orders in: (a) intra-particle oxidizable compound concentration (at fixed number of particles and particle size), alpha; (b) number of particles or analytical lipid concentration (at fixed intra-particle concentration and particle size), beta and (c) initiator, gamma, are obtained. The reaction orders beta and gamma are determined by the fraction of initiator derived radicals captured by the particles (f) and the mean number of chain carrying radicals per particle () when the system reaches the steady state condition. Predicted orders in initiator range from 0 ( = 0.5) to 0.5 (f-->1; > > 1), while the order in number of particles ranges between 0.5 (f-->1; > > 1) and 1. These predictions are tested by measuring the kinetic law for the oxidation of SUV's egg yolk phosphatidylcholine vesicles initiated by the thermal decomposition of ABAP. The results indicate that, under the conditions employed, beta = 0.68 +/- 0.05 and gamma = 0.46 +/- 0.04. These values are close to those expected for a system in which > > 1 and the efficiency of capture is relatively high. This last condition is confirmed by estimating the efficiency of capture from a comparison of induction times elicited by similar concentrations of Trolox and alpha-tocopherol.

Synthesis of a new neoglycolipid (AgH-1) and its effect upon the properties of dipalmitoylphosphatidylcholine: cholesterol liposomes.

A new neoglycolipid (AgH-1) bearing carbohydrate units that mimics the antigenic determinant of the O-blood group was synthesized and the effect of its incorporation in dipalmitoylphosphatidylcholine (DPPC): cholesterol liposomes was evaluated. The results obtained show that AgH-1 is readily incorporated into DPPC:cholesterol liposomes. The conditions leading to the optimal incorporation are the result of a compromise between incorporation efficiency and incorporation extent. The presence of AgH-1 produces liposomes of smaller size, with only small changes in the properties of the bilayer. However, the data obtained employing diphenylhexatriene and laurodan as fluorescence probes and merocyanine 540 as optical probe suggest that AgH-1 incorporation leads to a small rigidization of the liposomes at temperatures lower than ca. 42 degrees C.