The Escherichia coli low molecular mass penicillin-binding proteins PBP4, PBP5 and PBP6 are DD-peptidases involved in murein biosynthesis. It has been suggested that these proteins may be anchored to the periplasmic face of the inner membrane via their C termini. Here, peptide homologues (P4, P5 and P6) of the PBP4, PBP5 and PBP5 C-terminal regions have been used to investigate potential protein-lipid interactions involved in this anchoring mechanism. Surface pressure changes observed for the interactions of P5 and P6 with a range of monolayers indicated that the peptides are membrane interactive and that the interactions proceeded via predominantly hydrophobic forces with only minor requirements for anionic lipid. In contrast, P4 interactions with monolayers appeared to proceed via predominantly electrostatic forces with a major requirement for anionic lipid. The lipid interactions of all three peptides were generally enhanced by low pH and for P5 and P6 were in the range of 10-15 mN m-1 whereas for P4 interactions they were in the range of 3-7 mN m-1. CD analysis implied the presence of alpha-helical structure in P5 and P6 and molecular area determinations implied that P4 may also possess helical architecture in the presence of dioleoylphosphatidylglycerol monolayers. Overall, our results support the view that C-terminal amphiphilic alpha-helices are involved in the membrane anchoring of PBP5 and PBP6 and suggest that a similar mechanism could contribute to PBP4-membrane anchoring. Furthermore, we have speculated that the presence of cationic residues in the hydrophilic face of these alpha-helices may help facilitate membrane interaction.
The interactions between beta-lactoglobulin and 1-monostearoyl-glycerol were studied in order to gain insight into protein-gel-phase monoglyceride interactions. Using a monomolecular layer at the air-water interface, we determined the insertion of beta-lactoglobulin into the monoglycerides under different conditions of protein and surface charge by varying the pH and/or incorporating charged amphiphiles into the monolayer, respectively, and using subphases with either a low or high ionic strength. The interactions were quantified by determining the binding of 14C-labeled beta-lactoglobulin to the monolayer. Our results show the importance of electrostatics for binding of beta-lactoglobulin to condensed monoglycerides. Moreover, electrostatic interactions were found to be important for specific insertion of beta-lactoglobulin into the monolayer. A negatively charged surface in particular allowed positively charged beta-lactoglobulin to insert in a surface charge density-dependent manner, even at surface pressures as high as 36 mN/m, whereas under other conditions, the limiting insertion pressure was 32 mN/m. The rheological properties of the monolayer were not affected by the interactions with beta-lactoglobulin.
2H and 31P NMR techniques were used to study the effects on acyl chain order and lipid organization of the well-characterized pore-forming domain of colicin A (20-kDa thermolytic fragment of colicin A) upon insertion in model membrane systems derived from the Escherichia coli fatty acid auxotrophic strain K 1059, which was grown in the presence of [11,11-2H2]-labeled oleic acid. Addition of the protein to dispersions of the E. coli total lipid extract, in a 1/70 molar ratio of peptide to lipids, resulted in a large pH-dependent decrease in quadrupolar splitting of the 2H NMR spectra. The decrease of the quadrupolar splitting obtained at the various pH values was correlated with the pH dependence of the insertion of the protein in monolayer films using the same E. coli lipid extracts. The pK governing the perturbing effects on the order of the fatty acyl chains was around 5, in agreement with the values of the pH-dependent conformational changes of the pore-forming domain of colicin A required for membrane insertion as reported by van der Goot et al. [(1991) Nature 354, 408-410]. 31P NMR measurements show that the bilayer organization remains intact upon addition of the protein to dispersions of lipid extract. Surprisingly, 31P NMR measurements as a function of temperature indicate that the pore-forming domain of colicin A even stabilizes bilayer lipid structure at pH 4. Both the large effect of the protein on acyl chain order and its bilayer-stabilizing activity are indicative of a surface localization of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)
This study aims at gaining insight into the specificity and molecular mechanism of monoglyceride-protein interactions. We used beta-lactoglobulin (beta-LG) and lysozyme as model proteins and both monostearoylglycerol and monopalmitoylglycerol as defined gel phase monoglycerides. The monoglycerides were used in different combinations with the two negatively charged amphiphiles dicetylphosphate and distearylphosphate. The interactions were characterized using the monolayer technique, isothermal titration calorimetry, (2)H-nuclear magnetic resonance (NMR) using deuterium labelled monoglycerides and freeze fracture electron microscopy (EM). Our results show that lysozyme inserts efficiently into all monolayers tested, including pure monoglyceride layers. The insertion of beta-LG depends on the lipid composition of the monolayer and is promoted when the acylchains of the negatively charged amphiphile are shorter than that of the monoglyceride. The binding parameters found for the interaction of beta-LG and lysozyme with monoglyceride bilayers were generally similar. Moreover, in all cases a large exothermic binding enthalpy was observed which was found to depend on the nature of the monoglycerides but not of the proteins. (2)H-NMR and freeze fracture EM showed that this large enthalpy results from a protein mediated catalysis of the monoglyceride L(beta) to coagel phase transition. The mechanism of this phase transition consists of two steps, an initial protein mediated vesicle aggregation step which is followed by stacking and probably fusion of the bilayers.
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