The dynamic action mechanism of small cationic antimicrobial peptides.

Antimicrobial peptides form part of the immune system as protection against the action of external pathogens. The differences that exist between mammalian and microbial cell membrane architectures are key aspects of the ability of these peptides to discriminate between pathogens and host cells. Given that the pathogen membrane is the non-specific target of these cationic peptides, different molecular mechanisms have been suggested to describe the rules that permit them to distinguish between pathogens and mammalian cells. In this context, and setting aside the old fashion idea that cationic peptides act through one mechanism alone, this work will provide insight into the molecular action mechanism of small antimicrobial peptides, based on molecular dynamics simulations of phospholipid bilayers that mimic different cell membrane architectures. After measuring different properties of these lipid bilayers, in the absence and presence of peptides, a four-step action mechanism was suggested on the basis of the formation of phospholipid rafts induced by the presence of these cationic peptides. Thus, this work shows how differences in the bending modulus (k(b)) of these lipid rafts and differences in the free energy profiles (ΔG(z)) associated with the insertion of these peptides into these lipid rafts are key aspects for explaining the action mechanism of these cationic peptides at the molecular level.

Thermodynamic study of benzocaine insertion into different lipid bilayers.

Despite the general consensus concerning the role played by sodium channels in the molecular mechanism of local anesthetics, the potency of anaesthetic drugs also seems to be related with their solubility in lipid bilayers. In this respect, this work represents a thermodynamic study of benzocaine insertion into lipid bilayers of different compositions by means of molecular dynamics simulation. Thus, the free energy profiles associated with benzocaine insertion into symmetric lipid bilayers composed of different proportions of dipalmitoylphosphatidylcholine and dipalmitoylphosphatidylserine were studied. From the simulation results, a maximum in the free energy (ΔG) profile was measured in the region of the lipid/solution interface. This free energy barrier appears to be very much dependent on the lipid composition of the membrane. On the other hand, the minimum free energy (ΔG) within the bilayer remained almost independent of the lipid composition of the bilayer. By repeating the study at different temperatures, it was seen how the spontaneity of benzocaine insertion into the lipid bilayer is due to an increase in the entropy associated with the process.

Analysis of potentiometric titrations of heterogeneous natural polyelectrolytes in terms of counterion condensation theory: application to humic acid.

A model, developed within the framework of the counterion condensation theory of linear polyelectrolytes, is presented in this paper to describe the acid-base properties of linear polyelectrolytes, consisting of several types of functional ionizable groups. This formalism has been successfully applied to Fluka humic acid under salt-free conditions, as well as in the presence of supporting simple 1:1 salt (KNO3) at three different concentrations. As part of this approach, the charge density of the humic acid is obtained from the activity coefficient measurements of potassium counterions at different humic acid concentrations at a constant degree of dissociation of the polyelectrolyte. The humic acid average charge density was found to be 0.80 +/- 0.05. Using the present model, we are able to satisfactorily describe the experimental data obtained from acid-base potentiometric titrations. Four main functional groups making up the polymer are determined through their fractional abundances (Xi) and intrinsic pK (pK0i) values. The fractional abundances remained constant and independent of the ionic strength, indicating that the humic acid constitution does not depend on the concentration of excess salts. The pK0i values show a small change with ionic strength, which can be explained by the polyelectrolytic behavior of the solution.