Personal history of dieting and family history of obesity are unrelated: implications for understanding weight gain proneness.

Identifying predictors of future weight gain is important in obesity prevention efforts. Both family history of obesity and personal dieting history have been established as predictors of future weight gain; however, it is unknown if they are independent or overlapping predictors. The purpose of this study was to examine the degree of overlap between these two predictors using cross-sectional data. Baseline data from four studies were examined separately and in combination for a total of 561 female participants, and analyses were conducted to examine parent anthropometric variables by dieting status within and across studies. All participants were female university students between the ages of 17 and 30. For each study, as well as for the entire sample combined, parent anthropometric variables were examined by dieting status using factorial ANOVAs. No meaningful pattern was found when examining parent anthropometric variables by dieting status, which suggests that the two risk factors are largely independent. This suggests that the processes associated with the development of future weight gain by each variable are different; therefore, future research should use a longitudinal study to test the hypothesis that using both variables to predict future weight gain would account for more variance than using either variable alone.

Structural and biophysical properties of a synthetic channel-forming peptide: designing a clinically relevant anion selective pore.

The design, synthesis, modeling and in vitro testing of channel-forming peptides derived from the cys-loop superfamily of ligand-gated ion channels are part of an ongoing research focus. Over 300 different sequences have been prepared based on the M2 transmembrane segment of the spinal cord glycine receptor α-subunit. A number of these sequences are water-soluble monomers that readily insert into biological membranes where they undergo supramolecular assembly, yielding channels with a range of selectivities and conductances. Selection of a sequence for further modifications to yield an optimal lead compound came down to a few key biophysical properties: low solution concentrations that yield channel activity, greater ensemble conductance, and enhanced ion selectivity. The sequence NK(4)-M2GlyR T19R, S22W (KKKKPARVGLGITTVLTMRTQW) addressed these criteria. The structure of this peptide has been analyzed by solution NMR as a monomer in detergent micelles, simulated as five-helix bundles in a membrane environment, modified by cysteine-scanning and studied for insertion efficiency in liposomes of selected lipid compositions. Taken together, these results define the structural and key biophysical properties of this sequence in a membrane. This model provides an initial scaffold from which rational substitutions can be proposed and tested to modulate anion selectivity. This article is part of a Special Issue entitled: Protein Folding in Membranes.

Structural implications of placing cationic residues at either the NH2- or COOH-terminus in a pore-forming synthetic peptide.

Restoration of chloride conductance via introduction of an anion-selective pore, formed by a channel-forming peptide, has been hypothesized as a novel treatment modality for patients with cystic fibrosis. Delivery of these peptides from an aqueous environment in the absence of organic solvents is paramount. M2GlyR peptides, designed based on the glycine receptor, insert into lipid bilayers and polarized epithelial cells and assemble spontaneously into chloride-conducting pores. Addition of 4 lysine residues to either terminus increases the solubility of M2GlyR peptides. Both orientations of the helix within the membrane form an anion-selective pore, however, differences in solubility, associations and channel-forming activity are observed. To determine how the positioning of the lysine residues affects these properties, structural characteristics of the lysyl-modified peptides were explored utilizing chemical cross-linking, NMR and molecular modeling. Initial model structures of the a-helical peptides predict that lysine residues at the COOH-terminus form a capping structure by folding back to form hydrogen bonds with backbone carbonyl groups and hydroxyl side chains of residues in the helical segment of the peptide. In contrast, lysine residues at the NH2-terminus form fewer H-bonds and extend away from the helical backbone. Results from NMR and chemical cross-linking support the model structures. The C-cap formed by H-bonding of lysine residues is likely to account for the different biophysical properties observed between NH2- and COOH-terminal-modified M2GlyR peptides.