The helical structure propensity in the first helix of the histidine phosphocarrier protein of Streptomyces coelicolor.

The bacterial phosphoenolpyruvate (PEP):sugar phosphotransferase system (PTS), formed by a cascade of several proteins, mediates the uptake and phosphorylation of carbohydrates, and it is also involved in signal transduction. Its uniqueness in bacteria makes the PTS a target for new antibacterial drugs. These drugs can be obtained from peptides or proteins fragments able to interfere the first step of the protein cascade: the phosphorylation of the HPr protein by the enzyme EI. We designed a peptide comprising the active site and the first alpha-helix of HPr of S. coelicolor; we also obtained a fragment of HPr by protein engineering methods, comprising the first forty-eight residues and thus, containing the amino acids of the shorter peptide. Both fragments were disordered in aqueous solution, with a similar percentage of helical structure ( approximately 7 %), and an identical free energy of helix formation. In 40 % TFE, both fragments acquired native-like helical structure, stabilized by non-native hydrophobic interactions, as shown by the 2D-NMR assignments of the shorter peptide, and the presence of similar NOE contacts in both fragments. These findings, with the kinetic results in other members of the HPr family, highlight the importance of short- and long-range interactions during the folding reaction of HPr proteins. Based on the residual helical population, hypothesis about the inhibition capacity of the PTS by both fragments are discussed.

Binding of the C-terminal domain of the HIV-1 capsid protein to lipid membranes: a biophysical characterization.

The capsid protein, CA, of HIV-1 forms a capsid that surrounds the viral genome. However, recent studies have shown that an important proportion of the CA molecule does not form part of this capsid, and its location and function are still unknown. In the present work we show, by using fluorescence, differential scanning calorimetry and Fourier-transform infrared spectroscopy, that the C-terminal region of CA, CA-C, is able to bind lipid vesicles in vitro in a peripheral fashion. CA-C had a greater affinity for negatively charged lipids (phosphatidic acid and phosphatidylserine) than for zwitterionic lipids [PC/Cho/SM (equimolar mixture of phosphatidylcholine, cholesterol and sphingomyelin) and phosphatidylcholine]. The interaction of CA-C with lipid membranes was supported by theoretical studies, which predicted that different regions, occurring close in the three-dimensional CA-C structure, were responsible for the binding. These results show the flexibility of CA-C to undergo conformational rearrangements in the presence of different binding partners. We hypothesize that the CA molecules that do not form part of the mature capsid might be involved in lipid-binding interactions in the inner leaflet of the virion envelope.