Heparin adsorbing capacities at physiological pH of three poly(amido-amine) resins, and of poly(amido-amine)-surface-grafted glass microspheres.

Three poly(amido-amine)s of similar structure in the form of highly hydrophilic crosslinked resins, have been prepared, and tested for their heparin-adsorbing capacity at physiological pH. They showed different capacities, and their capacities were related to their basicities. One of the same polymers was grafted on the surface of glass microspheres. After treatment, it was shown that the microspheres could adsorb significant amounts of heparin. In all cases most of the adsorbed heparin was hardly eluted with saline, plasma, or blood, but could be recovered by eluting with 0.1 M NaOH. The resins were found to have some haemolytic properties, but no haemolysis was observed with the grafted microspheres.

Transverse dipoles added to DNA chains by drug binding can induce inversion of the long-range chirality of DNA condensates.

The addition of poly(ethylene glycol) (PEG) to a DNA solution induces phase separation of droplets of condensed DNA. These droplets possess liquid crystalline properties and their ordering is cholesteric. It was recently proved that daunomycin, by binding to DNA chains, inverts the long-range chirality of their tertiary packing into aggregates. The present paper suggests one possible mechanism by which this inversion can take place. Daunomycin bears a cationic group in its sugar residue. Its intercalation adds a helicoidal distribution of transverse dipoles to DNA chains. By this mechanism, in favourable cases, ionic or strongly polar groups in drugs which bind DNA can induce handedness inversion of the cholesteric ordering of its condensates. This inversion mechanism was tested experimentally using several, charged and uncharged, homologues of daunomycin. All those bearing the cationic ammonium group inverted the long-range chirality of the PEG-induced DNA mesomorphic state. The effects of the uncharged desamino homologues could not be evaluated because of their lower solubility and binding affinity for DNA.

Localization and preferred orientations of ubiquinone homologs in model bilayers.

The localization of ubiquinone has been investigated in phospholipid bilayer vesicles in studies of fluorescence quenching of membrane-bound probes by ubiquinone homologs (Qn, where n is the number of the isoprenoid units of the chain). Fluorescence-quenching data obtained by using a set of anthroylstearate probes, having the fluorophore located at different depths, revealed that ubiquinone-3 is located throughout the whole bilayer thickness. From the bimolecular quenching constants in the membrane, lateral diffusion coefficients in two dimensions were calculated to span values of 10(-7)-10(-6) cm2.s-1. This suggests that ubiquinones laterally diffuse in a very fluid environment. On this basis, it is proposed that their translational diffusion in the bilayer takes place in two dimensions, with the quinone ring oscillating between the two bilayer surfaces within a hydrophobic environment not extending beyond the glycerol region. This model implies that the quinonic head is both settled near the polar surface of the bilayer and buried into the host hydrocarbon interior. This two-site distribution was confirmed for all Qn, except Q0, by their linear dichroism spectra in the bilayers provided by disc-like lyotropic nematic liquid crystals. These spectra also provided detailed information on the preferential orientations of the quinonic head of the different derivatives within the two sites. The mechanism by which the localization and orientation of Qn guest molecules inside the host bilayer is modulated by the isoprenoid chain length is discussed on a thermodynamical basis. Being that Qn is expected to be also widely contained in the highly curved cristae of the mitochondrial inner membrane, by using rod-like lyotropic nematic liquid crystals we searched out effects of the curvature of the host bilayer on those Qn distributions. The linear dichroism measurements reveal that Qn guest molecules are no longer obliged to find a partition between two different types of localizations when the host bilayer is highly curved. In this case all Qn, even the longest Q10, were found to stay parallel to the amphiphilic chains with a single site localization of the head near the polar interface. By the same linear dichroism technique, the local ordering of all Qn derivatives was also evaluated. The order parameters were found to be basically the same for all derivatives. This result is justified on the basis of the relaxation, caused by the surface curvature, of the lateral compression of the host chains.

On coenzyme Q orientation in membranes: a linear dichroism study of ubiquinones in a model bilayer.

A general approach is developed to interpret linear dichroism (LD) spectra of ubiquinones (Qn) in host bilayers. Information is reported in terms of guest-host mutual orientation and localization. The overall orientational anisotropy of guest ubiquinone molecules is described by a basic set of limiting orientation/localization modes. Assignments of the UV transitions of the ubiquinone chromophore were obtained by the liquid crystal-linear dichroism technique and molecular orbital (CNDO/S) calculations. The LD spectra of Qn in the bilayers provided by the lyotropic nematic mesophase exhibited by water solutions of potassium laurate and decanol were interpreted on the basis of the above assignments. The resulting experimental evidence showed a multisite distribution in the host bilayer for the aromatic heads of all the investigated Qn derivatives except Q0. The orientational distribution suggested by the LD spectra fits the solubilization model recently proposed by G. Lenaz [J. Membrane Biol. (1988) 104:193-209] for ubiquinone in lipid membranes. Within this model Qn molecules are located in the midplane and their headgroups oscillate transversally across the membrane. Q0 instead has a single site location, close to the polar bilayer interface. Experimental evidence that the headgroup carbonyls tend to grasp the polar interface of the host bilayer was also obtained. Orientation and location distributions of Qn guest molecules are therefore likely to result from the tendency of their aromatic heads to grasp the polar heads of the host bilayer and from the concurrent tendency of their chains to settle into the hydrocarbon host interior.