https://www.selleckchem.com/products/CHR-2797(Tosedostat).html Interestingly, we noted a similarity in the dependence of membrane dipole potential and cholesterol with progress of the cell cycle. In addition, we observed an increase in neutral lipid (which contains esterified cholesterol) content as cells progressed from the G1 to G2/M phase via the S phase of the cell cycle. Importantly, we further observed a cell cycle dependent reduction in ligand binding activity of serotonin1A receptors expressed in CHO-K1 cells. To the best of our knowledge, these results constitute the first report of cell cycle dependent modulation of membrane dipole potential and activity of a neurotransmitter receptor belonging to the G protein-coupled receptor family. We envision that understanding the basis of cell cycle events from a biophysical perspective would result in a deeper appreciation of the cell cycle and its regulation in relation to cellular function.The polyglutamine tract length represents a key regulator for the Huntington's disease toxicity level and its aggregation rates, often being related to helical structural conformations. In this study, we performed all-atom MD simulations on mutant Huntingtin-Exon1 protein with additional mutation spots, aiming to observe the corresponding structural and dynamical changes at the level of the helix. The simulated structures consist of three sets of Q residue mutations into P residues (4P, 7P, and 9P), with each set including different spots of mutations random along the mutant sequence (R models), at the edges of the helix (E models), as well as at the edges and in the middle of the helix (EM models). At the helical level, our results predict less compactness profiles for a higher number of P mutations (7P and 9P models) with particular mutation spots at the edges and at the edges-middle of the helix. Moreover, the C-alpha atom distances decreased for 7P and 9P models in comparison to 4P models, and the RMSF values show the highe