Lipids interactions with signal sequences

Thus, protein secretion in E. coli is dramatically affected by the physical state of the membrane lipids. Both increased and decreased fluidity inhibit secretion. It is possible that this effect arises because the signal sequence and/or the secreted protein interact with the membrane lipids, and these interactions are perturbed when the lipid fluidity is changed. However, changes in lipid fluidity also affect other membrane functions such as active transport (DiRienzo and Inouye, 1979). Thus the effect of membrane fluidity on protein secretion may be due to altered activity of a membrane-bound part of the secretory apparatus, and may not be an indication of signal sequence-membrane interaction. 

The experiments described in Sections VI,A,B show that two physical properties of the synthetic LamB signal peptides correlate with their in vivo export function tendency to adopt an a-helical conformation in hydrophobic environments, and tendency to insert into lipid mono-layers. These properties may be involved in the same step in the secretion process, or in different steps. An a-helical conformation may be required to generate a structure sufficiently hydrophobic to allow mono-layer insertion. Alternatively, these properties may reflect separate roles of the signal sequence in protein secretion. For instance, an a-helical conformation may be necessary for binding to a proteinaceous site, while the ability to interact with lipids may be important for another step in the secretion process. We have studied the conformations of the synthetic LamB signal peptides in phospholipid vesicles and monolayers by CD and IR spectroscopy. 

Proteins have many functions in the body. They serve as transporters of hydrophobic compounds in the blood, as cell adhesion molecules that attach cells to each other and to the extracellular matrix, as hormones that carry signals from one group of cells to another, as ion channels through lipid membranes, and as enzymes that increase the rate of biochemical reactions. The unique characteristics of a protein are dictated by its linear sequence of amino acids, termed its primary structure. The primary structure of a protein determines how it can fold and how it interacts with other molecules in the cell to perform its function. The primary structures of all of the diverse human proteins are synthesized from 20 amino acids arranged in a linear sequence determined by the genetic code. 

As discussed for N-myristoylation and S-prenylation, even S-acylation of proteins with a fatty acid which in the vast majority of cases is the C16 0 palmitic acid, plays a fundamental role in the cellular signal-transduction process (Table l). 2-5 14 While N-myristoylation and S-prenylation are permanent protein modifications due to the amide- and sulfide-type linkage, the thioester bond between palmitic acid and the peptide chain is rather labile and palmi-toylation is referred to as a dynamic modification. 64 This reversibility plays a crucial role in the modulation of protein functions since the presence or absence of a palmitoyl chain can determine the membrane localization of the protein and can also be used to regulate the interactions of these proteins with other proteins. Furthermore, a unique consensus sequence for protein palmitoylation has not been found, in contrast to the strict consensus sequences required for N-myristoylation and S-prenylation. Palmitoylation can occur at N- or C-terminal parts of the polypeptide chain depending on the protein family and often coexists with other types of lipidation (see Section 6.4.1.4). Given the diversity of protein sequences... 

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