Abstract
Cell membranes are commonly considered fundamental structures having multiple roles such as confinement, storage of lipids, sustain and control of membrane proteins. In spite of their importance, many aspects remain unclear. The number of lipid types is orders of magnitude larger than the number of amino acids, and this compositional complexity is not clearly embedded in any membrane model. A diffused hypothesis is that the large lipid palette permits to recruit and organize specific proteins controlling the formation of specialized lipid domains and the lateral pressure profile of the bilayer. Unfortunately, a satisfactory knowledge of lipid abundance remains utopian because of the technical difficulties in isolating definite membrane regions. More importantly, a theoretical framework where to fit the lipidomic data is still missing. In this work, we wish to utilize the amino acid sequence and frequency of the membrane proteins as bioinformatics sensors of cell bilayers. The use of an alignment-free method to find a correlation between the sequences of transmembrane portion of membrane proteins with the membrane physical state suggested a new approach for the discovery of antimicrobial peptides.
Highlights
Cell membranes are complex structures made of hundreds of different types of molecules [1, 2]
In the Results and discussion section, we validate the approach on known systems and we demonstrate how lipid composition and membrane evolution is, in some ways, encoded in the transmembrane proteome composition
The present work is based on the hypothesis that the activity of any peptide acting in or on membranes depends on the peptide sequence and the membrane physical state (MPS)
Summary
Cell membranes are complex structures made of hundreds of different types of molecules [1, 2]. The formation of lateral segregation is the result of chemical-physical differences in lipids and, in some cases, the effect of cytoskeletal structures supporting the membrane that restrict the movement of both lipids and proteins. Lipids influence the activity of membrane proteins by means of their chemical nature and the physical properties of lipid mixtures in function of their composition [3,4,5]. During pathological conditions such as cancer [7] or Alzheimer’s disease [8] and ageing processes [9, 10] membrane lipid composition can change significantly. Each of these changes causes a membrane remodeling, with consequent
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