The surface activity of vasopressin and its interaction with artificial and biological membranes]

It was determined that vasopressin has surface active properties and in nanomolic concentrations is capable to incorporate in lipoprotein monolayers which are formed from myocytes plasma membranes. By means of pH-metric and fluorescent analysis it was shown that vasopressin interacts with other membrane structures which have no specific receptors--phosphatidylcholinic liposomes and vesicles of sarcoplasmic reticulum of skeletal muscles causing increasing permeability of phospholipid bilayer for Ca2+ ions.     

Simultaneous measurements of optical and electrical properties of artificial membranes composed of mitochondrial lipids and their interaction with cytochromec

Summary A newly constructed cell, which allows simultaneous measurements of optical and electrical properties, was used to study bimolecular black membranes composed of beef heart mitochondrial lipids and their interaction with cytochromec.The results show that these highly charged membranes are stable only in relatively limited ranges of boundary conditions. In 0.1n KCl their maximum direct current (dc) resistance is 7×10⁸ Ohm cm²±10%; the series capacity at 1kHz is 0.43 F/cm²±3%; the entire thickness, determined by optical reflectivity, is 5.8±0.2 nm.The interaction between oxidized cytochromec and these lipid membranes is primarily of electrostatic nature, and dependent on the presence of highly charged phospholipids, such as diphosphatidyl glycerol (cardiolipin) and phosphatidyl ethanolamine. The attachment of cytochromec maximally causes a 2.5-fold increase in reflectivity, without any noticeable change in the capacity. This leads to a subsequent instability of the membrane (i.e., rupture) preceded by a rapid increase of the dc conductivity. This behavior is far less pronounced with reduced cytochromec.     

Cryo-electron microscopy of artificial biological membranes

Vitrified synthetic phosphatidycholine liposome suspensions were studied by cryo-electron microscopy. The bilayer structure is resolved on vitrified liposome images. The packing of the aliphatic chains of the lipid within vitrified liposomes can be determined by the analysis of electron diffraction patterns. Images and electron diffraction patterns show that the structure of vitrified liposomes is related to the structure that liposomes have before vitrification. In fact, vitrified liposomes have a different structure, depending whether they are maintained before cooling at a temperature higher or lower than that corresponding to the ‘melting’ of the hydrocarbon chain of the lipids. Below the melting temperature, liposomes are formed by small domains.     

The interaction of thylakoid lipids with everted photosystem II membranes

Spinach ( Spinacia oleracea L. cv. Viking II) thylakoid membranes enriched in photosystem II were disrupted by incubation at 35°C for 5 min followed by sonication. This treatment caused the loss of manganese and the release of extrinsic photosystem II proteins of 16, 23 and 33 kdaltons, resulting in retention of only 12–18% of the oxygen-evolving activity. Prior addition of exogenous digalactosyldiacylglycerol to the membranes afforded protection against the release of manganese and extrinsic proteins and enabled the retention of up to 47% of the activity. Monogalactosyldiacylglycerol was less effective in both respects and enabled retention of only 30% of the activity. Addition of charged thylakoid lipids had a severely damaging effect on photosystem II.     

Simultaneous measurements of optical and electrical properties of artificial membranes composed of mitochondrial lipids and their interaction with cytochrome c.

A newly constructed cell, which allows simultaneous measurements of optical and electrical properties, was used to study bimolecular black membranes composed of beef heart mitochondrial lipids and their interaction with cytochrome c. The results show that these highly charged membranes are stable only in relatively limited ranges of boundary conditions. In 0.1 n KCl their maximum direct current (dc) resistance is 7 X 10(8) Ohm cm2 +/- 10%; the series capacity at 1 kHz is 0.43 muF/cm2 +/- 3%; the entire thickness, determined by optical reflectivity, is 5.8 +/- 0.2 nm. The interaction between oxidized cytochrome c and these lipid membranes is primarily of electrostatic nature, and dependent on the presence of highly charged phospholipids, such as diphosphatidyl glycerol (cardiolipin) and phosphatidyl ethanolamine. The attachment of cytochrome c maximally causes a 2.5-fold increase in reflectivity, without any noticeable change in the capacity. This leads to a subsequent instability of the membrane (i.e., rupture) preceded by a rapid increase of the dc conductivity. This behavior is far less pronounced with reduced cytochrome c.     

Role of lipids in the interaction of antimicrobial peptides with membranes

Antimicrobial peptides (AMPs) take part in the immune system by mounting a first line of defense against pathogens. Recurrent structural and functional aspects are observed among peptides from different sources, particularly the net cationicity and amphipathicity. However, the membrane seems to be the key determinant of their action, either as the main target of the peptide action or by forming a barrier that must be crossed by peptides to target core metabolic pathways. More importantly, the specificity exhibited by antimicrobial peptides relies on the different lipid composition between pathogen and host cells, likely contributing to their spectrum of activity. Several mechanisms of action have been reported, which may involve membrane permeabilization through the formation of pores, membrane thinning or micellization in a detergent-like way. AMPs may also target intracellular components, such as DNA, enzymes and even organelles. More recently, these peptides have been shown to produce membrane perturbation by formation of specific lipid-peptide domains, lateral phase segregation of zwitterionic from anionic phospholipids and even the formation of non-lamellar lipid phases. To countermeasure their activity, some pathogens were successful in developing effective mechanisms of resistance to decrease their susceptibility to AMPs. The functional and integral knowledge of such interactions and the clarification of the complex interplay between molecular determinants of peptides, the pathogen versus host cells dichotomy and the specific microenvironment in which all these elements convene will contribute to an understanding of some elusive aspects of their action and to rationally design novel therapeutic agents to overcome the current antibiotic resistance issue.     

Fission of biological membranes: interplay between dynamin and lipids

Membrane budding and fission are the key stages of ubiquitous processes of formation of intracellular transport vesicles. We present a theoretical consideration of one of the most important types of fission machinery, which is mediated by GTPase dynamin and controlled by lipid composition of the membrane. We suggest a mechanism for collapse of a membrane neck driven by interplay between the dynamin collar and the bending elastic energy of the neck membrane. The collar plays a role of a rigid external skeleton, which imposes mechanical constraints on the neck. We show that in certain conditions the membrane of the neck loses its stability and collapses. Collapse can result from: (i) shifting of the spontaneous curvature of the neck membrane towards negative values, (ii) stretching of the dynamin collar, (iii) tightening of the dynamin collar. The three factors can act separately or concertedly. The suggested model accounts for the major experimental knowledge on membrane fission mediated by dynamin. It includes the elements of all previous models of dynamin action based on different sets of experimental results [Sever et al., Traffic 2000; 1: 385-392]. It reconciles, at least partially, the apparent contradictions between the existing alternative views on biomembrane fission machinery.     

Effects of lipids on the interaction of SecA with model membranes.

The effects of nonlamellar-prone lipids, diacylglycerol and phosphatidylethanolamine (PE), on the kinetic association of SecA with model membranes were examined by measuring changes in the intrinsic emission fluorescence with a stopped-flow apparatus. Upon interaction with standard liposomes composed of 50 mol% dioleolyphosphatidylcholine (DOPC) and 50 mol% of dioleoylphosphatidylglycerol (DOPG), the intrinsic fluorescence intensity of SecA was decreased after a lapse of time with a rate constant of 0.0049 s(-1). When the DOPC of the standard vesicles was gradually replaced with either dioeloyl PE (DOPE) or Escherichia coli (E. coli) PE, the rate constant increased appreciably as a function of PE concentration, in the order DOPE > E. coli PE. In addition, when the PE of E. coli PE/DOPG (50/50) vesicles was replaced with more than 5 mol% dioleoylglycerol (DOG), the rate constant further increased by 40%. The incorporation of nonlamellar-prone lipids in the vesicles also enhanced the binding of SecA to model membranes in the order DOPE > or = E. coli PE/DOG > E. coli PE > DOPC. These results provide the first kinetic evidence for the importance of nonlamellar-prone phospholipids for the association rate of SecA with membranes.     

Biphasic nature of the binding of cationic amphipaths with artificial and biological membranes

We have studied the interaction with liposomes and red cell membrane of various cationic amphipaths, chlorpromazine, methochlorpromazine, imipramine and propranolol. At low concentrations the interaction is a partition of the molecule between the lipid hydrophobic phase and the aqueous medium. The extent of the partition is dependent on the membrane composition or physical properties, on the incubation conditions (pH, ions) and on the amphipath used. After a given amount of amphipath has entered in the membrane, a new type of interaction appears which leads to an apparent saturable association. This association, which probably involves the anionic groups of the membrane components, might result from structural or/and electrical membrane perturbations induced by the presence of drug molecules between the phospholipids. Thus the interaction of a molecule of cationic amphipath with a membrane varies according to the amount of drug present.     

Role of lipids in the structure and function of biological membranes

The concept of biological membranes as vesicular or tubular continua built up of nesting repeating units has been systematically explored and some of the relevant experimental work has been assembled. The bulk of the data have been drawn from studies on the mitochondrion, which is assumed to be a model for membranes generally. The repeating units of membranes are composite macromolecules containing both protein and lipid. The unit of the mitochondrial inner membrane is tripartite; the basepiece is the membrane-forming element. The four complexes of the electron transfer chain represent the different species of basepieces in the inner membrane. The repeating units of the outer mitochondrial membrane have a different form and size and a completely different set of enzymes (the enzymes of the citric and fatty acid oxidation cycles). The repeating units of the inner mitochondrial membrane are capable of forming membranes spontaneously. This membrane-forming capability is absolutely dependent on the presence of lipid. Evidence is presented for the view that lipid restricts the number of binding modalities and thus compels a two-dimensional alignment of repeating units. In absence of lipid three-dimensional stacking takes place, and the aggregates thus formed are, in effect, bulk phases. The membrane may be looked upon as a device for molecularizing repeating units, and it is this molecularization which underlies the essentiality of lipid for electron transfer. The theory of lipid requirement for enzymic activity is developed. The reconstitution of the electron transfer chain is shown to be essentially a membrane phenomenon rather than an expression of direct chemical interaction between the different parts of the electron transfer chain.     

Characteristics of prostaglandin E1 interaction with components of biological membranes

To estimate the connection between physico-chemical characteristics and biological activity of prostaglandins the interaction of prostaglandin E1 with biological membrane lipids was studied. It is shown that as a result of prostaglandin interaction with phosphatidylcholine a complex is formed that behaves as an individual component and occupies in the surface layer twice as large area than the complex with prostaglandin F2 alpha. The prostaglandin E1 film collapses earlier than F2 alpha. Both facts indicate that the first is more friable. A difference in morphology of prostaglandin monolayers was revealed by electron microscopy. When studying the catalytic activity of peroxidase incorporated in prostaglandin E1 and F2 alpha monolayers some differences were also revealed. In the second case oxidation with methylblue located under the monolayer proceeds more actively. The results obtained point to the connection between the regulatory function of prostaglandins and their chemical structure. Molecular rearrangements of the monolayer caused by prostaglandin incorporation were recorded.     

Study of interaction of polystirolsulphonate with polymerization degree of 8 and polyallylamin with bilayer lipids membranes

Interaction of polystirolsulphonate with polymerization degree of 8 (PSS-8) and polyallylamin PAA (molecular mass 60 kilodaltons) with viruses from bloodline of paramixo- and orthomixoviruses by the example of measles virus, parotitis and flu leads to the decreasing of infective activity. The possible mechanism of viral inhibitive action of these chemical compounds is damaging of interfacial antigenic proteins of paramixo- and orthomixoviruses. In this study it was detected the change of surface tension of bilayer lipid membrane in the presence of PSS-8 and PAA. The change of surface tension leads to disorder in viral proteins adsorption in bilayer lipid membrane. This process could lead to disorder of juncture and self-assembly of virions.     

Cytochrome c interaction with membranes. I. Use of a fluorescent chromophore in the study of cytochrome c interaction with artificial and mitochondrial membranes

Quenching of 12-(9-anthroyl) stearic acid (AS) fluorescence by cytochrome c occurs through an energy-transfer mechanism and can be used to measure the binding of the cytochrome to artificial and mitochondrial membranes. The quenching of AS³ fluorescence is biphasic ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ below 25 msec and above 500 msec) and its extent diminishes at high salt concentration or at high pH and increases in the presence of negatively charged lipids.Addition of cytochrome c to cytochrome c-depleted mitochondria results in binding of the cytochrome to the membrane and quenching of AS fluorescence. The affinity of oxidized cytochrome c for cytochrome c-depleted mitochondria is 1.8 × 10⁶m, while the affinity constant for reduced cytochrome c is 0.5 × 10⁶m. The lower affinity of the reduced cytochrome c for mitochondrial membranes is in accordance with midpoint potential differences between the bound and free forms.     

A novel mechanism of interaction between alpha-synuclein and biological membranes

Conformational abnormalities and aggregation of alpha-synuclein (alpha-syn) have been linked to the pathogenesis of Parkinson's (PD) and related diseases. It has been shown that alpha-syn can stably bind artificial phospholipid vesicles through alpha-helix formation in its N-terminal repeat region. However, little is known about the membrane interaction in cells. In the current study, we determined the membrane-binding properties of alpha-syn to biological membranes by using bi-functional chemical crosslinkers, which allow the detection of transient, but specific, interactions. By utilizing various point mutations and deletions within alpha-syn, we demonstrated that the membrane interaction of alpha-syn in cells is also mediated by alpha-helix formation in the N-terminal repeat region. Moreover, the PD-linked A30P mutation causes reduced membrane binding, which is concordant with the artificial membrane studies. However, contrary to the interaction with artificial membranes, the interaction with biological membranes is rapidly reversible and is not driven by electrostatic attraction. Furthermore, the interaction of alpha-syn with cellular membranes occurs only in the presence of non-protein and non-lipid cytosolic components, which distinguishes it from the spontaneity of the interaction with artificial membranes. More interestingly, addition of the cytosolic preparation to artificial membranes resulted in the transient, charge-independent binding of alpha-syn similar to the interaction with biological membranes. These results suggest that in cells, alpha-syn is engaged in a fundamentally different mode of membrane interaction than the charge-dependent artificial membrane binding, and the mode of interaction is determined by the intrinsic properties of alpha-syn itself and by the cytoplasmic context.