Highly specific ligand-receptor interactions generally characterize surface recognition reactions. Such processes can be simulated by streptavidin-biotin-specific binding. Biotin lipids have thus been synthesized, and their interaction with streptavidin (or avidin) at the air-water interface was directly shown by measurement of surface pressure isotherms and fluorescence microscopy. These proteins interact with the biotin lipid monolayer via specific binding or nonspecific adsorption. Both phenomena were clearly distinguished by use of the inactivated form of streptavidin. The binding of fluorescein-labeled streptavidin to monolayers was also directly observed by fluorescence microscopy. The fluorescence of the protein domains is directly related to the state of polarization of the exciting light. This anisotropy can only be explained by the formation of oriented two-dimensional biotin lipid-streptavidin domains.
The binding of peripheral proteins to membranes results in different biological effects. The large diversity of membrane lipids is thought to modulate the activity of these proteins. However, information on the selective binding of peripheral proteins to membrane lipids is still largely lacking. Lipid monolayers at the air/water interface are useful model membrane systems for studying the parameters responsible for peripheral protein membrane binding. We have thus measured the maximum insertion pressure (MIP) of two proteins from the photoreceptors, Retinitis pigmentosa 2 (RP2) and recoverin, to estimate their binding to lipid monolayers. Photoreceptor membranes have the unique characteristic that more than 60% of their fatty acids are polyunsaturated, making them the most unsaturated natural membranes known to date. These membranes are also thought to contain significant amounts of saturated phospholipids. MIPs of RP2 and recoverin have thus been measured in the presence of saturated and polyunsaturated phospholipids. MIPs higher than the estimated lateral pressure of biomembranes have been obtained only with a saturated phospholipid for RP2 and with a polyunsaturated phospholipid for recoverin. A new approach was then devised to analyze these data properly. In particular, a parameter called the synergy factor allowed us to highlight the specificity of RP2 for saturated phospholipids and recoverin for polyunsaturated phospholipids as well as to demonstrate clearly the preference of RP2 for saturated phospholipids that are known to be located in microdomains.
Phospholipase 4, a ubiquitous lipolytic enzyme that actively catalyzes hydrolysis of phospholipids, has been studied as a model for enzyme-substrate reactions, as a membrane structural probe, and as a model for lipid-protein interactions. Its mechanism of action remains largely controversial. We report here for the first time direct microscopic observation of the lipolytic action of fluorescently marked phospholipase 4 (No& naju naja) against phosphatidylcholine monolayers in the lipid phase transition region. Under these conditions, phospholipase 4 is shown to target and hydrolyze solidphase lipid domains of L-a-dipalmitoylphosphatidylcholine.In addition, after a critical extent of monolayer hydrolysis, the enzyme itself aggregates into regular, visible proteinaceous domains within the lipid monolayer. Solid-phase lipid hydrolysis indicates a preferential hydrolytic environment for phospholipase 4 while enzyme domain formation points to a possible allosteric inhibition mechanism by hydrolysis products.
The interaction of a nonspecific wheat lipid transfer protein (LTP) with phospholipids has been studied using the monolayer technique as a simplified model of biological membranes. The molecular organization of the LTP-phospholipid monolayer has been determined by using polarized attenuated total internal reflectance infrared spectroscopy, and detailed information on the microstructure of the mixed films has been investigated by using epifluorescence microscopy. The results show that the incorporation of wheat LTP within the lipid monolayers is surface-pressure dependent. When LTP is injected into the subphase under a dipalmytoylphosphatidylglycerol monolayer at low surface pressure (< 20 mN/m), insertion of the protein within the lipid monolayer leads to an expansion of dipalmytoylphosphatidylglycerol surface area. This incorporation leads to a decrease in the conformational order of the lipid acyl chains and results in an increase in the size of the solid lipid domains, suggesting that LTP penetrates both expanded and solid domains. By contrast, when the protein is injected under the lipid at high surface pressure (> or = 20 mN/m) the presence of LTP leads neither to an increase of molecular area nor to a change of the lipid order, even though some protein molecules are bound to the surface of the monolayer, which leads to an increase of the exposure of the lipid ester groups to the aqueous environment. On the other hand, the conformation of LTP, as well as the orientation of alpha-helices, is surface-pressure dependent. At low surface pressure, the alpha-helices inserted into the monolayers are rather parallel to the monolayer plane. In contrast, at high surface pressure, the alpha-helices bound to the surface of the monolayers are neither parallel nor perpendicular to the interface but in an oblique orientation.
The accumulation of fibronectin (FN) in response to corneal epithelium injury has been postulated to turn on expression of the FN-binding integrin ␣ 5  1 . In this work, we determined whether the activity directed by the ␣ 5 gene promoter can be modulated by FN in rabbit corneal epithelial cells (RCEC). The activity driven by chloramphenicol acetyltransferase/␣ 5 promoter-bearing plasmids was drastically increased when transfected into RCEC grown on FN-coated culture dishes. The promoter sequence mediating FN responsiveness was shown to bear a perfect inverted repeat that we designated the fibronectin-responsive element (FRE). Analyses in electrophoretic mobility shift assays provided evidence that Sp1 is the predominant transcription factor binding the FRE. Its DNA binding affinity was found to be increased when RCEC are grown on FN-coated dishes. The addition of the MEK kinase inhibitor PD98059 abolished FN responsiveness suggesting that alteration in the state of phosphorylation of Sp1 likely accounts for its increased binding to the ␣ 5 FRE. The FRE also proved sufficient to confer FN responsiveness to an otherwise unresponsive heterologous promoter. However, site-directed mutagenesis indicated that only the 3 half-site of the FRE was required to direct FN responsiveness. Collectively, binding of FN to its ␣ 5  1 integrin activates a signal transduction pathway that results in the transcriptional activation of the ␣ 5 gene likely through altering the phosphorylation state of Sp1.Corneal wounds account for a substantial proportion of all visual disabilities and medical consultations for ocular problems in North America. They can be superficial with damage limited to the epithelium or associated with a deeper involvement of the epithelial basement membrane and of the stromal lamella. Severe recurrent and persistent corneal wounds are most commonly secondary to ocular diseases and damage such as recurrent erosion, mild chemical burns, superficial herpetic infections, neuroparalytic cornea, autoimmune diseases, and stromal ulcerations due to viral or bacterial infections or to severe burns (1). Despite currently available treatments, many of these corneal wounds persist for weeks and months or else recur frequently and can progress to corneal perforation.Tissue repair requires cell migration, proliferation, and adhesion. Cell adhesion and migration in turn require extracellular matrix (ECM) 1 synthesis and assembly. ECM is a complex, cross-linked structure of proteins and polysaccharides. It organizes the geometry of normal tissues. Fibronectin (FN) is an ECM adhesion protein identified as a potential wound healing agent because of its cell attachment, migration, differentiation, and orientation properties (for a review see Refs. 2-4). In the unwounded rat eye, FN is observed by immunohistological staining at the level of the corneal epithelium basement membrane (5-7). Shortly after corneal injury, the basal cells that border the injured area and stromal keratocytes start producing massive amounts of FN (5,[8]...
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