Begoña Garcia-Alvarez

Structure–function correlations of pulmonary surfactant protein SP-B and the saposin-like family of proteins

Pulmonary surfactant is a lipid-protein complex secreted by the respiratory epithelium of mammalian lungs, which plays an essential role in stabilising the alveolar surface and so reducing the work of breathing. The surfactant protein SP-B is part of this complex, and is strictly required for the assembly of pulmonary surfactant and its extracellular development to form stable surface-active films at the air–liquid alveolar interface, making the lack of SP-B incompatible with life. In spite of its physiological importance, a model for the structure and the mechanism of action of SP-B is still needed. The sequence of SP-B is homologous to that of the saposin-like family of proteins, which are membrane-interacting polypeptides with apparently diverging activities, from the co-lipase action of saposins to facilitate the degradation of sphingolipids in the lysosomes to the cytolytic actions of some antibiotic proteins, such as NK-lysin and granulysin or the amoebapore of Entamoeba histolytica. Numerous studies on the interactions of these proteins with membranes have still not explained how a similar sequence and a potentially related fold can sustain such apparently different activities. In the present review, we have summarised the most relevant features of the structure, lipid-protein and protein–protein interactions of SP-B and the saposin-like family of proteins, as a basis to propose an integrated model and a common mechanistic framework of the apparent functional versatility of the saposin fold.

A model for the structure and mechanism of action of pulmonary surfactant protein B

Surfactant protein B (SP‐B), from the saposin‐like family of proteins, is essential to facilitate the formation and proper performance of surface active films at the air‐liquid interface of mammalian lungs, and lack of or deficiency in this protein is associated with lethal respiratory failure. Despite its importance, neither a structural model nor a molecular mechanism of SP‐B is available. The purpose of the present work was to purify and characterize native SP‐B supramolecular assemblies to provide a model supporting structure‐function features described for SP‐B. Purification of porcine SP‐B using detergent‐solubilized surfactant reveals the presence of 10 nm ring‐shaped particles. These rings, observed by atomic force and electron microscopy, would be assembled by oligomerization of SP‐B as a multimer of dimers forming a hydrophobically coated ring at the surface of phospholipid membranes or monolayers. Docking of rings from neighboring membranes would lead to formation of SP‐B‐based hydrophobic tubes, competent to facilitate the rapid flow of surface active lipids both between membranes and between surfactant membranes and the interface. A similar sequential assembly of dimers, supradimeric oligomers and phospholipid‐loaded tubes could explain the activity of other saposins with colipase, cytolysin, or antibiotic activities, offering a common framework to understand the range of functions carried out by saposins.—Olmeda, B., García‐Álvarez, B., Gómez, M. J., Martínez‐Calle, M., Cruz, A., Pérez‐Gil, J. Amodel for the structure and mechanism of action of pulmonary surfactant protein B. FASEB J. 29, 4236‐4247 (2015). www.fasebj.org

Palmitoylation as a key factor to modulate SP-C-lipid interactions in lung surfactant membrane multilayers

Surfactant protein C (SP-C) has been regarded as the most specific protein linked to development of mammalian lungs, and great efforts have been done to understand its structure-function relationships. Previous evidence has outlined the importance of SP-C palmitoylation to sustain the proper dynamics of lung surfactant, but the mechanism by which this posttranslational modification aids SP-C to stabilize the interfacial surfactant film along the compression-expansion breathing cycles, is still unrevealed. In this work we have compared the structure, orientation and lipid-protein interactions of a native palmitoylated SP-C with those of a non-palmitoylated recombinant SP-C (rSP-C) form in air-exposed multilayer membrane environments, by means of ATR-FTIR spectroscopy. Palmitoylation does not affect the secondary structure of the protein, which exhibits a full α-helical conformation in partly dehydrated phospholipid multilayer films. However, differences between the Amide I band of the IR spectrum of palmitoylated and non-palmitoylated proteins suggest subtle differences affecting the environment of their helical component. These differences are accompanied by differential effects on the IR bands from phospholipid phosphates, indicating that palmitoylation modulates lipid-protein interactions at the headgroup region of phospholipid layers. On the other hand, the relative dichroic absorption of polarized IR has allowed calculating that the palmitoylated protein adopts a more tilted transmembrane orientation than the non-palmitoylated SP-C, likely contributing to more compact, dehydrated and possibly stable multilayer lipid-protein films. As a whole, the behavior of multilayer films containing palmitoylated SP-C may reflect favorable structural properties for surfactant reservoirs at the air-liquid respiratory interface.

Divide & Conquer: surfactant protein SP-C and cholesterol modulate phase segregation in lung surfactant

Lung surfactant (LS) is an essential system supporting the respiratory function. Cholesterol can be deleterious for LS function, a condition that is reversed by the presence of the lipopeptide SP-C. In this work, the structure of LS-mimicking membranes has been analyzed under the combined effect of SP-C and cholesterol by deuterium NMR and phosphorus NMR and by electron spin resonance. Our results show that SP-C induces phase segregation at 37°C, resulting in an ordered phase with spectral features resembling an interdigitated state enriched in dipalmitoylphosphatidylcholine, a liquid-crystalline bilayer phase, and an extremely mobile phase consistent with small vesicles or micelles. In the presence of cholesterol, POPC and POPG motion seem to be more hindered by SP-C than dipalmitoylphosphatidylcholine. The use of deuterated cholesterol did not show signs of specific interactions that could be attributed to SP-C or to the other hydrophobic surfactant protein SP-B. Palmitoylation of SP-C had an indirect effect on the extent of protein-lipid perturbations by stabilizing SP-C structure, and seemed to be important to maximize differences among the lipids participating in each phase. These results shed some light on how SP-C-induced lipid perturbations can alter membrane structure to sustain LS functionality at the air-liquid interface.