Interaction of type I collagen with phosphatidylcholine vesicles

Interaction of type-I collagen with phospholipid monolayer

The effects of type-I collagen on dipalmitoyl phosphatidylcholine (DPPC) and dimyristoyl phosphatidylcholine (DMPC) monolayer films with different compositions were studied using monolayer technique. The addition of collagen in the subphase of different monolayer films induced a considerable shift towards larger area/molecule in the compression-isotherm curves. This is either referred to the insertion of collagen into the monolayer by its hydrophobic residues or to an adsorption process causing a protein layer to be located parallel to the lipid monolayer [1]. The variation of collagen interaction with different lipid compositions was also verified through the penetration-kinetics experiment. Comparing our results to the results of Pajean et al. [2] and Pajean and Herbage [3] on the effect of collagen on the stability of lipid vesicles implies that the collagen induced stability could be explained on the basis of collagen-lipid monolayer interaction.

Triple helix formation of procollagen type I can occur at the rough endoplasmic reticulum membrane

One key problem in understanding the biosynthesis of collagens remains the assembly of the three alpha-chains. How and when are the different gene products selected, aligned, and folded into a triple helix? As the spatial arrangement during biosynthesis might be important, we concentrated on whether the rough endoplasmic reticular membrane is involved in this process. Microsomes were prepared from biosynthetically labeled chick tendon fibroblasts. Vesicles were spread as a monomolecular film which was then transferred over several compartments of a filmbalance containing fresh subphase. Fluorograms of the surface film showed that the monolayer contains procollagen chains. When the monolayer was transferred onto a chymotrypsin/trypsin-containing subphase, the gel bands of the proalpha-chains were shifted into the position of mature alpha-chains, indicating that only the propeptides were digested and the collagenous regions were protected due to triple helix formation. Our results suggest that newly synthesized proalpha-chains can associate as trimers and fold into a triple helical conformation while they are still associated with the membranes of the rough endoplasmic reticulum. These processes also occur when interchain disulfide linkage is inhibited, indicating that chain selection and registration is not dependent on formation of covalent bonds among the carboxyl propeptides.

Lipids in predentine and dentine

Using two histochemical methods, malachite green-aldehyde and iodoplatinate, phospholipids were visualized in the predentine of rat incisors in the spaces located between collagen fibers and in dentine as needle-like structures located along individual or groups of mineralizing collagen fibers. The same staining pattern was seen with phospholipase A2-gold. Autoradiographic investigation using 3H choline as labelled precursor, visualized the incorporation of membrane-associated and extracellular choline-containing phosphatidyl choline and sphingomyelin. The cell and membrane-associated labelling decreased gradually between 24 and 4 days, whereas incorporation of the labelled precursor as stable extracellular matrix component was seen in dentine. In addition to these investigations, pharmacologically induced (suramine) and genetically (Krabbe's disease) lysosomal storage pathology was investigated. Defects due to lipid metabolism alterations were seen in predentine and/or in dentine. The major differences visualized here between the non-mineralized and mineralized compartments and interactions between phospholipids and proteoglycans, support the view that phospholipids as matrix components play an important role in the mechanisms of dentine formation and mineralization.

Acid phospholipid vesicles produce conformational changes on the antitumour protein alpha-sarcin

The antitumour protein alpha-sarcin interacts at neutral pH with acid phospholipid vesicles promoting their aggregation and fusion. This interaction produces conformational changes on the protein molecule. Circular dichroism and infrared spectroscopy have been used to analyze the secondary structure of the protein molecule. The obtained results show an increased alpha-helix content upon interaction with the lipid vesicles. Detergents and halogenated alcohols have also been considered as an approach to the study of the conformational changes produced upon alpha-sarcin-phospholipid vesicles interaction. SDS treatment as well as trifluoroethanol also increase the helical content of alpha-sarcin. Intrinsic fluorescence of the protein has also been measured for the analysis of the conformational changes produced. The above helicogenic treatments produce a decrease on the structural quenching in alpha-sarcin which is consistent with the existence of hydrophobic protein-lipid interactions. The observed conformational changes are interpreted in terms of a shielding from polar groups caused by the lipids, which promotes intrachain hydrogen bonding and decreased static quenching. The reported conformational changes are discussed in terms of electrostatic and hydrophobic interactions involved in the fusion of lipid vesicles promoted by alpha-sarcin, and potentially in the passage of the protein across membrane cells.

Effect of the antitumour protein alpha-sarcin on the thermotropic behaviour of acid phospholipid vesicles

The antitumour protein alpha-sarcin modifies the thermotropic behaviour of phospholipid vesicles. This has been studied by fluorescence depolarization measurements and differential scanning calorimetry. A surface protein-phospholipid interaction is detected by measuring the polarization degree of TMA-DPH-labelled vesicles. At the higher protein/lipid molar ratios studied, the alpha-sarcin-vesicles complexes exhibit different thermotropic behaviour depending on whether they are prepared above or below the Tm of the corresponding phospholipid. Labelling of the protein with photoactive phospholipids has also been considered. alpha-Sarcin penetrates the bilayer deep enough to be labelled with the photoactive group located at the C-12 of the fatty acid acyl chain of phospholipids forming vesicles.

Fusion of phospholipid vesicles produced by the anti-tumour protein alpha-sarcin

The anti-tumour protein alpha-sarcin causes fusion of bilayers of phospholipid vesicles at neutral pH. This is demonstrated by measuring the decrease in the efficiency of the fluorescence energy transfer between N-(7-nitro-2-1,3-benzoxadiazol-4-yl)-dimyristoylphosphatidylethano lamine (NDB-PE) (donor) and N-(lissamine rhodamine B sulphonyl)-diacylphosphatidylethanolamine (Rh-PE) (acceptor) incorporated in dimyristoylphosphatidylcholine (DMPG) vesicles. The effect of alpha-sarcin is a maximum at 0.15 M ionic strength and is abolished at basic pH. alpha-Sarcin promotes fusion between 1,6-diphenylhexa-1,3,5-triene (DPH)-labelled DMPG and dipalmitoyl-PG (DPPG) vesicles, resulting in a single thermotropic transition for the population of fused phospholipid vesicles. Bilayers composed of DMPC and DMPG, at different molar ratios in the range 1:1 to 1:10 PC/PG, are also fused by alpha-sarcin. Freeze-fracture electron micrographs corroborate the occurrence of fusion induced by the protein. alpha-Sarcin also modifies the permeability of the bilayers, causing the leakage of calcein in dye-trapped PG vesicles. All of the observed effects reach saturation at a 50:1 phospholipid/protein molar ratio, which is coincident with the binding stoichiometry previously described.

Interaction of type I collagen fibrils with phospholipid vesicles

Type I collagen fibrils interact with phosphatidylcholine and phosphatidylglycerol vesicles. Fluorescence polarization of (1,6-diphenyl-1,3,5-hexatriene) DPH-labeled vesicles, circular dichroism and differential scanning calorimetry studies have been performed. The protein-lipid interaction produces a decrease of the enthalpy of the phospholipid phase transition. Positive charges of lysine residues of the protein are involved in the interaction as experiments with succinylated collagen show. The kinetic parameters and the extent of the fibrillogenesis of collagen are modified by the phospholipid vesicles.

Study of the interaction between the antitumour protein alpha-sarcin and phospholipid vesicles

alpha-Sarcin is a single polypeptide chain protein which exhibits antitumour activity by degrading the larger ribosomal RNA of tumour cells. We describe the interaction of a alpha-sarcin with lipid model systems. The protein specifically interacts with negatively-charged phospholipid vesicles, resulting in protein-lipid complexes which can be isolated by ultracentrifugation in a sucrose gradient. alpha-Sarcin causes aggregation of such vesicles. The extent of this interaction progressively decreases when the molar ratio of phosphatidylcholine increases in acidic vesicles. The kinetics of the vesicle aggregation induced by the protein have been measured. This process is dependent on the ratio of alpha-sarcin present in the protein-lipid system. A saturation plot is observed from phospholipid vesicles-protein titrations. The saturating protein/lipid molar ratio is 1:50. The effect produced by the antitumour protein on the lipid vesicles is dependent on neither the length nor the degree of unsaturation of the phospholipid acyl chain. However, the aggregation is dependent on temperature, being many times higher above the phase transition temperature of the corresponding phospholipid than below it. The effects of pH and ionic strength have also been considered. An increase in the ionic strength does not abolish the protein-lipid interaction. The effect of pH may be related to conformational changes of the protein. Binding experiments reveal a strong interaction between alpha-sarcin and acidic vesicles, with Kd = 0.06 microM. The peptide bonds of the protein are protected against trypsin hydrolysis upon binding to acidic vesicles. The interaction of the protein with phosphatidylglycerol vesicles does not modify the phase transition temperature of the lipid, although it decreases the amplitude of the change of fluorescence anisotropy associated to the co-operative melting of 1,6-diphenyl-1,3,5-hexatriene (DPH)-labelled vesicles. The results are interpreted in terms of the existence of both electrostatic and hydrophobic components for the interaction between phospholipid vesicles and the antitumour protein.