A scanning force- and fluorescence light microscopy study of the structure and function of a model pulmonary surfactant

The structure of an artificial pulmonary surfactant was studied by scanning force- and fluorescence light microscopy (SFM, and FLM, respectively). The surfactant – a mixture of dipalmitoylphosphatidylcholine (DPPC), dipalmitoylphosphatidylglycerol (DPPG) and recombinant surfactant-associated protein C (SP-C) – was prepared at the air-water interface of a Langmuir film balance and imaged by FLM under various states of compression. In order to visualize their topography by SFM, the films were transferred onto a solid mica support by the Langmuir-Blodgett (LB) technique. We found that a region of high film compressibility of the spread monolayer close to its equilibrium surface pressure (π=50 mN/m) was due to the exclusion of layered protrusions with each layer 5.5 to 6.5 nm thick. They remained associated with the monolayer and readily reinserted upon expansion of the film. Comparison with the FLM showed that the protrusions contained the protein in high concentration. The more the film was compressed, the larger was the number of layers on top of each other. The protrusions arose from regions of the monolayer with a distinct microstructure that may have been responsible for their formation. The molecular architecture of the microstructure remains to be elucidated, although some of it can be inferred from spectroscopic data in combination with the SFM topographical images. We illustrate our current understanding of the film structure with a molecular model. Received: 20 September 1996 / Accepted: 22 May 1997     

The structure of a model pulmonary surfactant as revealed by scanning force microscopy.

The structures formed by a pulmonary surfactant model system of dipalmitoylphosphatidylcholine (DPPC), dipalmitoylphosphatidylglycerol (DPPG), and recombinant surfactant-associated protein C (SP-C) were studied using scanning force microscopy (SFM) on Langmuir-Blodgett films. The films appeared to be phase separated, in agreement with earlier investigations by fluorescence light microscopy. There were smooth polygonal patches of mostly lipid, surrounded by a corrugated rim rich in SP-C. When the films were compressed beyond the equilibrium surface pressure, the protein-rich phase mediated the formation of layered protrusions. The height of these multilamellar structures embodied equidistant steps slightly higher than a DPPC double layer in the gel phase. At the air-water interface too, a high compressibility at low surface tension was indicative of the exclusion of matter. The exclusion process proved to be fully reversible. The present study demonstrates that some of the matter of the model pulmonary surfactant can move in and out of the active monolayer. The SFM images revealed a lipid-protein complex that was responsible for the reversible exclusion of double-layer structures. This mechanism may be important in the natural system too, to keep the surface tension of the alveolar air/water interface constantly low over the range of area encountered upon breathing.     

Structural alterations of phospholipid film domain morphology induced by cholesterol

Structures of the monolayer films of dipalmitoylphosphatidylcholine (DPPC) mixed with different amounts of cholesterol were studied at air-water interface using surface pressure-area measurements, epifluorescence microscopy and atomic force microscopy (AFM). Pure DPPC, cholesterol or DPPC-cholesterol mixtures were dissolved in organic solvents with a small amount of fluorescently labeled phospholipid probe (NBD-PC) and spread onto the air-water interface. Surface pressure-area isotherms and epifluorescence microscopy of such films at the air-water interface suggested that DPPC undergoes a gas to fluid to condensed phase transition, while cholesterol undergoes a gas to solid-like transition. A shift of the surface pressure-area curve to lower area per molecule was observed when cholesterol was mixed with DPPC. Epifluorescence microscopy showed the formation of spiral shaped domains for mixed monolayers. Increase in cholesterol content abolished domain characteristics possibly due to fluidizing property of cholesterol. AFM measurements of monolayers, transferred onto freshly cleaved mica by Langmuir-Blodgett technique, revealed the alterations caused by cholesterol on the gel and fluid domains of such films. AFM measurements re-established similar trend in domain characteristics as evidenced in epifluorescence microscopy.     

Interaction of Trastuzumab with biomembrane models at air-water interfaces mimicking cancer cell surfaces

Trastuzumab (Tmab) is a monoclonal antibody administered as targeted therapy for HER2-positive breast cancer whose molecular interactions at the HER2 receptor microenvironment are not completely clarified yet. This paper describes the influence of Tmab in the molecular organization of films of biological-relevant molecules at the air water interface. For that, we spread components of tumorigenic and non-tumorigenic cells directly on the air-water interface. The physicochemical properties of the films were investigated with surface pressure-area isotherms and Brewster angle microscopy, and distinction between the cellular lines with higher or lower amount of HER2 could be detected based on the physicochemical properties of the interfacial films. The systems organized at the air-water interface were transferred to solid supports as Langmuir-Blodgett films and the nano-scale morphology investigated with atomic force microscopy. The overall results related to Tmab interacting with the films lead to the conclusion that Tmab tends to condense rich-HER2 films, causing irregular dimerization of the receptor protein, changing the membrane topography of the films, with formation of phases with different levels of reflectivity and aggregation morphology, and finally revealing that the interaction of the antibody with proteo-lipidic biointerfaces is modulated by the film composition. We believe that novel perspectives concerning the molecular interactions in the plasma membrane microenvironment through Langmuir monolayers can be obtained from this work in order to enhance the Tmab-based cancer therapy.     

Mixed monolayers of amphiphile-modified nucleic bases and diynoic acids. I. Phase states at air-water interface and in Langmuir-Blodgett films

Monolayers of amphiphile-modified nucleic bases with diynoic acid were obtained and characterized. The synthesized nucleic bases contained in the monolayer complementarily bind the nucleotide molecules contained in the aqueous subphase, and the structure of the resulting monolayers can be fixed by the photopolymerization of diynoic acid. The resulting monolayer exemplifies a novel type of model systems for investigating molecular recognition at the surface of biological membranes. Procedures for the transfer of the monolayers onto solid substrates and photopolymerization of the diynoic acid in mixtures with the derivatives of nucleic bases were developed. The films obtained were structurally characterized using atomic force microscopy. Compression isotherms of the mixed monolayers as well as individual components of monolayers at the air-water interface allowed one to determine the concentration range at which the diynoic acid form true mixtures or domain structures with the derivatives of nucleic base. A study of the films transferred to the solid substrate by atomic force microscopy indicated that this concentration dependence of miscibility behavior was conserved in the transferred films.     

Langmuir and Langmuir-Blodgett films of organophosphorus acid anhydrolase

In this paper, we describe the preparation and characterization of Langmuir and Langmuir-Blodgett (LB) monolayers of the enzyme organophosphorus acid anhydrolase (OPAA). Langmuir films of OPAA were characterized on different subphases, such as phosphate, ammonium carbonate, and bis-tris-propane buffers. Monolayers at the air-water interface were characterized by measuring the surface pressure and surface potential-area isotherms. In situ UV-vis absorption spectra were also recorded from the Langmuir monolayers. The enzyme activity at the air-water interface was tested by the addition of diisopropylfluorophosphate (DFP) to the subphase. LB films of OPAA were transferred to mica substrates to be studied by atomic force microscopy. Finally, a one-layer LB film of OPAA labeled with a fluorescent probe, fluorescein isothiocyanate (FITC), was deposited onto a quartz slide to be tested as sensor for DFP. The clear, pronounced response and the stability of the LB film as a DFP sensor show the potential of this system as a biosensor.     

Fluorescence light microscopy of pulmonary surfactant at the air-water interface of an air bubble of adjustable size

The structural dynamics of pulmonary surfactant was studied by epifluorescence light microscopy at the air-water interface of a bubble as a model close to nature for an alveolus. Small unilamellar vesicles of dipalmitoylphosphatidylcholine, dipalmitoylphosphatidylglycerol, a small amount of a fluorescent dipalmitoylphosphatidylcholine-analog, and surfactant-associated protein C were injected into the buffer solution. They aggregated to large clusters in the presence of Ca(2+) and adsorbed from these units to the interface. This gave rise to an interfacial film that eventually became fully condensed with dark, polygonal domains in a fluorescent matrix. When now the bubble size was increased or decreased, respectively, the film expanded or contracted. Upon expansion of the bubble, the dark areas became larger to the debit of the bright matrix and reversed upon contraction. We were able to observe single domains during the whole process. The film remained condensed, even when the interface was increased to twice its original size. From comparison with scanning force microscopy directly at the air-water interface, the fluorescent areas proved to be lipid bilayers associated with the (dark) monolayer. In the lung, such multilayer phase acts as a reservoir that guarantees a full molecular coverage of the alveolar interface during the breathing cycle and provides mechanical stability to the film.     

Two-dimensional recognition pattern of lipid-anchored Fab'' fragments.

A two-dimensional pattern of oriented antibody fragments was formed at the air-water interface and transferred onto a solid support. The Fab'-fragments of a monoclonal antibody against the hapten dinitrophenyl (DNP) were covalently linked via a hydrophilic spacer to phospholipid vesicles. A monomolecular lipid-protein layer at equilibrium with these vesicles was allowed to form at the air-water interface. The monolayer was separated from the vesicle phase and transferred to a Langmuir-Blodgett trough. By cooling and compressing, the previously homogeneous lipid-protein film was driven into a two-dimensional phase separation resulting in protein-rich domains and a second phase consisting mainly of lipid. This film was transferred onto a solid support in a way that preserved the protein-lipid pattern. The specificity as well as the contrast in the binding activity of the two different separated phases were then quantified using microfluorometry. DNP conjugated to fluorescein-labeled bovine serum albumin (BSA) showed virtually no binding to the lipid regions, but gave a ratio of bound DNP-BSA to Fab'-lipid of greater than 50% in the protein-rich domains proving that the Fab'-moiety retained its biological activity. This demonstrates that the technique presented here is well suited to modify different solid surfaces with a pattern of a given biological function. The optional control of lateral packing and orientation of the components in the monolayer makes it a general tool for the reconstitution of supported lipid-protein membranes and might also open new ways for the two-dimensional crystallization of proteins at membranes.     

Self-assembled hydrophobin protein films at the air-water interface: structural analysis and molecular engineering

Hydrophobins are amphiphilic proteins produced by filamentous fungi. They function in a variety of roles that involve interfacial interactions, as in growth through the air-water interface, adhesion to surfaces, and formation of coatings on various fungal structures. In this work, we have studied the formation of films of the class II hydrophobin HFBI from Trichoderma reesei at the air-water interface. Analysis of hydrophobin aqueous solution drops showed that a protein film is formed at the air-water interface. This elastic film was clearly visible, and it appeared to cause the drops to take unusual shapes. Because adhesion and formation of coatings are important biological functions for hydrophobins, a closer structural analysis of the film was made. The method involved picking up the surface film onto a solid substrate and imaging the surface by atomic force microscopy. High-resolution images were obtained showing both the hydrophilic and hydrophobic sides of the film at nanometer resolution. It was found that the hydrophobin film had a highly ordered structure. To study the orientation of molecules and to obtain further insight in film formation, we made variants of HFBI that could be site specifically conjugated. We then used the avidin-biotin interaction as a probe. On the basis of this work, we suggest that the unusual interfacial properties of this type of hydrophobins are due to specific molecular interactions which lead to an ordered network of proteins in the surface films that have a thickness of only one molecule. The interactions between the proteins in the network are likely to be responsible for the unusual surface elasticity of the hydrophobin film.     

Langmuir-Blodgett based lipase nanofilms of unique structure-function relationship

Proteins represent versatile building blocks for realization of nanostructured materials of unique structure-function relationship to be applied in nanobiotechnology. Following a recent work [Bruzzese, D., Pastorino, L., Pechkova, E., Sivozhelezov, Nicolini, C., Increase of catalytic activity of lipase towards olive oil by Langmuir-Film Immobilization of Lipase, Enzyme and Microbial Technology, submitted for publication.], the Langmuir-Blodgett technique was utilized to develop nanostructured crystal materials based on enzymes interfacially activated with olive oil as substrate. Particularly, thin films of lipase from both Mucor miehei and Candida rugosa were fabricated and characterized by UV-vis spectroscopy, Atomic force microscopy and biochemical assays. As the first step the M. miehei protein films were studied at the air-water interface and then transferred onto a solid support for further characterization of the enzymatic activity also versus surface pressure, proving that Langmuir-Blodgett film provides a better catalytic effect in lipase than a mere oil-water boundary. Moreover, improvement of lipase catalytic performance was achieved for the M. miehei versus the C. rugosa, despite its almost random distribution of hydrophobic patches and the low purity of its preparation.     

Analysis of lung surfactant model systems with time-of-flight secondary ion mass spectrometry

An often-used model lung surfactant containing dipalmitoylphosphatidylcholine (DPPC), dipalmitoylphosphatidylglycerol (DPPG), and the surfactant protein C (SP-C) was analyzed as Langmuir-Blodgett film by spatially resolved time-of-flight secondary ion mass spectrometry (TOF-SIMS) to directly visualize the formation and composition of domains. Binary lipid and lipid/SP-C systems were probed for comparison. TOF-SIMS spectra revealed positive secondary ions (SI) characteristic for DPPC and SP-C, but not for DPPG. SI mapping results in images with domain structures in DPPC/DPPG and DPPG/SP-C, but not in DPPC/SP-C films. We are able to distinguish between the fluid and condensed areas probably due to a matrix effect. These findings correspond with other imaging techniques, fluorescence light microscopy (FLM), scanning force microscopy (SFM), and silver decoration. The ternary mixture DPPC/DPPG/SP-C transferred from the collapse region exhibited SP-C-rich domains surrounding pure lipid areas. The results obtained are in full accordance with our earlier SFM picture of layered protrusions that serve as a compressed reservoir for surfactant material during expansion. Our study demonstrates once more that SP-C plays a unique role in the respiration process.     

Langmuir–Blodgett based lipase nanofilms of unique structure–function relationship

Proteins represent versatile building blocks for realization of nanostructured materials of unique structure–function relationship to be applied in nanobiotechnology. Following a recent work [Bruzzese, D., Pastorino, L., Pechkova, E., Sivozhelezov, Nicolini, C., Increase of catalytic activity of lipase towards olive oil by Langmuir-Film Immobilization of Lipase, Enzyme and Microbial Technology, submitted for publication.], the Langmuir–Blodgett technique was utilized to develop nanostructured crystal materials based on enzymes interfacially activated with olive oil as substrate. Particularly, thin films of lipase from both Mucor miehei and Candida rugosa were fabricated and characterized by UV–vis spectroscopy, Atomic force microscopy and biochemical assays. As the first step the M. miehei protein films were studied at the air–water interface and then transferred onto a solid support for further characterization of the enzymatic activity also versus surface pressure, proving that Langmuir–Blodgett film provides a better catalytic effect in lipase than a mere oil–water boundary. Moreover, improvement of lipase catalytic performance was achieved for the M. miehei versus the C. rugosa, despite its almost random distribution of hydrophobic patches and the low purity of its preparation.     

Preparation of Carbon Nanosheets at Room Temperature

Amphiphilic molecules equipped with a reactive, carbon-rich "oligoyne" segment consisting of conjugated carbon-carbon triple bonds self-assemble into defined aggregates in aqueous media and at the air-water interface. In the aggregated state, the oligoynes can then be carbonized under mild conditions while preserving the morphology and the embedded chemical functionalization. This novel approach provides direct access to functionalized carbon nanomaterials. In this article, we present a synthetic approach that allows us to prepare hexayne carboxylate amphiphiles as carbon-rich siblings of typical fatty acid esters through a series of repeated bromination and Negishi-type cross-coupling reactions. The obtained compounds are designed to self-assemble into monolayers at the air-water interface, and we show how this can be achieved in a Langmuir trough. Thus, compression of the molecules at the air-water interface triggers the film formation and leads to a densely packed layer of the molecules. The complete carbonization of the films at the air-water interface is then accomplished by cross-linking of the hexayne layer at room temperature, using UV irradiation as a mild external stimulus. The changes in the layer during this process can be monitored with the help of infrared reflection-absorption spectroscopy and Brewster angle microscopy. Moreover, a transfer of the carbonized films onto solid substrates by the Langmuir-Blodgett technique has enabled us to prove that they were carbon nanosheets with lateral dimensions on the order of centimeters.     

气/液界面及固体表面硬脂酸LB膜结构性质研究

对气液/和固/液界面上硬脂酸LB膜的结构性质的研究表明,二价离子能够使气/液界面上LB膜表面压力降低,并出现一个固-固转变的过程.对此可以解释为是由二价离子富集在亚相表面,减弱了膜分子之间的库仑作用,使表面电势降低引起的.同时由于二价离子与硬脂酸分子形成复合物,单层膜的结构发生改变,导致固-固转变点的产生.对固体基质上多层LB膜的椭圆偏振研究表明,有序排列的硬脂酸LB膜具有明显的双折射性质.电镜观察发现两个固相垂直提位获得的多层膜在形貌上存在差异,低压固相膜较之高压固相膜存在明显的不均匀性.分析认为这是在膜从气/液界面向固体表面转移过程中发生重结晶引起的.     

A monolayer study on cytochrome b5-phospholipid interactions

Cytochrome b₅ has been incorporated into phospholipid monolayers at the air/water interface (Langmuir films). Protein incorporation was followed by monitoring changes in surface pressure at constant film area or by measuring film area changes at constant surface pressure. It was possible to deposit proteolipid films on solid substrates using the Langmuir-Blodgett technique. Using the homologous series of phosphatidylcholines, C_10:0–C_22:0, it was found that increasing chain-length led to increased cytochrome penetration into the surface film. ¹²⁵I-labelled cytochrome b₅ was used to quantify the degree of protein uptake into the film. Phospholipid/protein ratios of 32 and 60 were determined for dipalmitoylphosphatidylcholine and dipalmitoylphosphatidylethanolamine, respectively. A molecular area of 790 Ų was calculated for the hydrophobic segment of cytochrome b₅. The results are discussed with reference to other work on protein-phospholipid interactions, in particular to studies on cytochrome b₅-liposome systems.     

The interaction of meso-tetraphenylporphyrin with phospholipid monolayers

In this article, we investigate the interaction of meso-tetraphenylporphyrin (TPP) with phospholipid monolayers. Pure TPP molecules form films at the air-water interface with large extension of aggregation, which is confirmed by UV-vis spectra of transferred monolayers. For mixed films of TPP with dipalmitoyl phosphatidyl choline (DPPC) or dipalmitoyl phosphatidyl glycerol (DPPG), on the other hand, aggregation is only significant at high surface pressures or high concentrations of TPP (above 0.1 molar ratio). This was observed via Brewster angle microscopy (BAM) for the Langmuir films and UV-vis spectroscopy for transferred layers onto solid substrates. TPP indeed causes the DPPC and DPPG monolayers to expand, especially at the liquid-expanded to liquid-condensed phase transition for DPPC. The effects from TPP cannot be explained using purely geometrical considerations, as the area per TPP molecule obtained from the isotherms is at least twice the expected value from the literature. Therefore, interaction between TPP and DPPC or DPPG should be cooperative, so that more phospholipid molecules are affected than just the first neighbors to a TPP molecule.     

Synthetic lipid-anchored receptors based on the binding site of a monoclonal antibody.

Highly specific ligand receptor interactions generally characterize molecular recognition at cell surfaces and other biological systems. In this study we simulate a membrane receptor by fusing a monoclonal antibody fragment to a phospholipid. A sulfhydryl group in the hinge region of a monoclonal antibody fragment, was covalently linked to derivatives of phosphatidylethanolamines and phosphatidylserine via three different hydrophilic spacer arms. We investigated and characterized these lipid-anchored Fab-fragments which we have named 'Fab-lipids' in liposomal and monolayer systems. Methods for the monomolecular assembling of such films at the air/water interface and techniques used for their manipulation are outlined. We describe two possibilities for building a monomolecular receptor layer, consisting of two-dimensional pattern of oriented Fab-fragments with their artificial hydrophobic anchor embedded in a lipid matrix. In the first method a monomolecular film at the air/water interface was allowed to form from a vesicular suspension and driven into a phase separation, resulting in protein rich domains embedded in a protein depleted phase. This film was transferred onto a solid support in such a way that the established pattern was preserved. Alternatively, a recognition pattern was formed by directly cross-linking the Fab-fragments to preformed planar membranes composed of the reactive spacer-lipids and an inert matrix lipid. Specificity as well as contrast of the binding activity of the receptor layers were qualified using micro-fluorimetry.     

Distribution of GD3 in DPPC Monolayers: A Thermodynamic and Atomic Force Microscopy Combined Study

Gangliosides are the main component of lipid rafts. These microdomains, floating in the outer leaflet of cellular membrane, play a key role in fundamental cellular functions. Little is still known about ganglioside and phospholipid interaction. We studied mixtures of dipalmitoylphosphatidylcholine and GD3 (molar fraction of 0.2, 0.4, 0.6, 0.8) using complementary techniques: 1), thermodynamic properties of the Langmuir-Blodgett films were assessed at the air-water interface (surface tension, surface potential); and 2), three-dimensional morphology of deposited films on mica substrates were imaged by atomic force microscopy. Mixture thermodynamics were consistent with data in the literature. In particular, excess free energy was negative at each molar fraction, thus ruling out GD3 segregation. Atomic force microscopy showed that the height of liquid-condensed domains in deposited films varied with GD3 molar fraction, as compatible with a lipid aggregation model proposed by Maggio. No distinct GD3-rich domain was observed inside the films, suggesting that GD3 molecules gradually mix with dipalmitoylphosphatidylcholine molecules, confirming ΔG data. Morphological analysis revealed that the shape of liquid-condensed domains is strongly influenced by the amount of GD3, and an interesting stripe-formation phenomenon was observed. These data were combined with the thermodynamic results and interpreted in the light of McConnell's model.     

Increase of catalytic activity of lipase towards olive oil by Langmuir-film immobilization of lipase

Proteins represent versatile building blocks for realization of nanostructured materials to be applied in nanobiotechnology. In the present work, the Langmuir–Blodgett technique was utilized to develop nanobiodevices based on protein molecules. Particularly, lipase thin films were fabricated and characterized, with characterization performed in order to optimize the working parameters. As the first step the protein films were studied at the air–water interface and then transferred onto a solid support for further characterization. The films were characterized by different techniques such as UV–Vis spectroscopy, nanogravimetry, atomic force microscopy, and biochemical assays. Catalytic activity of lipase characterized by the maximal reaction rate found to increase over 10 times as a result of inclusion into LB films, while the substrate binding characterized by the Michaelis constant remain unchanged. Catalytic activity per mole of enzyme was found to increase with the increased number of LB layers up to five, and then decrease at 10, while the surface coverage ranged from 70% to 100% from 1 to 10 layers of lipase. This study exploits the possibility to employ LB based protein structures to use in biocatalysis, exemplified by lipase, which is known as an interfacially-activated enzyme, with olive oil as substrate, when lipase should already be in the maximally active state even without a film. We show, however, that it was possible to form even more active lipase nanostructures by the Langmuir–Blodgett technique at the air–water interface, proving that Langmuir-film provides a better catalytic effect in lipase than a mere oil–water boundary.     

Shear characteristics, miscibility, and topography of sodium caseinate-monoglyceride mixed films at the air-water interface

In this contribution, we are concerned with the study of structure, topography, and surface rheological characteristics (under shear conditions) of mixed sodium caseinate and monoglycerides (monopalmitin and monoolein) at the air/water interface. Combined surface chemistry (surface film balance and surface shear rheometry) and microscopy (Brewster angle microscopy, BAM) techniques have been applied in this study to mixtures of insoluble lipids and sodium caseinate spread at the air-water interface. At a macroscopic level, sodium caseinate and monoglycerides form an heterogeneous and practically immiscible monolayer at the air-water interface. The images from BAM show segregated protein and monoglyceride domains that have different topography. At surface pressures higher than that for the sodium caseinate collapse, this protein is displaced from the interface by monoglycerides. These results and those derived from interfacial shear rheology (at a macroscopic level) appear to support the idea that immiscibility and heterogeneity of these emulsifiers at the interface have important repercussions on the shear characteristics of the mixed films, with the alternating flow of segregated monoglyceride domains (of low surface shear viscosity, etas) and protein domains (of high etas) across the canal.