Association of the internal membrane protein with the lipid bilayer in influenza virus. A study with the fluorescent probe 12-(9-anthroyl)-stearic acid

Influenza virus Matrix Protein M1 preserves its conformation with pH, changing multimerization state at the priming stage due to electrostatics

Influenza A virus matrix protein M1 plays an essential role in the virus lifecycle, but its functional and structural properties are not entirely defined. Here we employed small-angle X-ray scattering, atomic force microscopy and zeta-potential measurements to characterize the overall structure and association behavior of the full-length M1 at different pH conditions. We demonstrate that the protein consists of a globular N-terminal domain and a flexible C-terminal extension. The globular N-terminal domain of M1 monomers appears preserved in the range of pH from 4.0 to 6.8, while the C-terminal domain remains flexible and the tendency to form multimers changes dramatically. We found that the protein multimerization process is reversible, whereby the binding between M1 molecules starts to break around pH 6. A predicted electrostatic model of M1 self-assembly at different pH revealed a good agreement with zeta-potential measurements, allowing one to assess the role of M1 domains in M1-M1 and M1-lipid interactions. Together with the protein sequence analysis, these results provide insights into the mechanism of M1 scaffold formation and the major role of the flexible and disordered C-terminal domain in this process.

pH-Dependent Formation and Disintegration of the Influenza A Virus Protein Scaffold To Provide Tension for Membrane Fusion

Influenza virus is taken up from a pH-neutral extracellular milieu into an endosome, whose contents then acidify, causing changes in the viral matrix protein (M1) that coats the inner monolayer of the viral lipid envelope. At a pH of ~6, M1 interacts with the viral ribonucleoprotein (RNP) in a putative priming stage; at this stage, the interactions of the M1 scaffold coating the lipid envelope are intact. The M1 coat disintegrates as acidification continues to a pH of ~5 to clear a physical path for the viral genome to transit from the viral interior to the cytoplasm. Here we investigated the physicochemical mechanism of M1's pH-dependent disintegration. In neutral media, the adsorption of M1 protein on the lipid bilayer was electrostatic in nature and reversible. The energy of the interaction of M1 molecules with each other in M1 dimers was about 10 times as weak as that of the interaction of M1 molecules with the lipid bilayer. Acidification drives conformational changes in M1 molecules due to changes in the M1 charge, leading to alterations in their electrostatic interactions. Dropping the pH from 7.1 to 6.0 did not disturb the M1 layer; dropping it lower partially desorbed M1 because of increased repulsion between M1 monomers still stuck to the membrane. Lipid vesicles coated with M1 demonstrated pH-dependent rupture of the vesicle membrane, presumably because of the tension generated by this repulsive force. Thus, the disruption of the vesicles coincident with M1 protein scaffold disintegration at pH 5 likely stretches the lipid membrane to the point of rupture, promoting fusion pore widening for RNP release.

IMPORTANCE

Influenza remains a top killer of human beings throughout the world, in part because of the influenza virus's rapid binding to cells and its uptake into compartments hidden from the immune system. To attack the influenza virus during this time of hiding, we need to understand the physical forces that allow the internalized virus to infect the cell. In particular, we need to know how the protective coat of protein inside the viral surface reacts to the changes in acid that come soon after internalization. We found that acid makes the molecules of the protein coat push each other while they are still stuck to the virus, so that they would like to rip the membrane apart. This ripping force is known to promote membrane fusion, the process by which infection actually occurs.

Physicochemical properties of albumin microspheres determined by spectroscopic studies

The interactions of a family of fluorescein dyes of varying hydrophobicities and polarizabilities (as well as those of several model drugs) with native and colloidal denatured albumin systems from various sources were monitored spectroscopically. The use of colloidal denatured albumin systems allowed direct determination of spectral shifts induced by the interactions of the dyes or drugs with the albumins. Large bathochromic shifts were observed upon interaction of hydrophobic dyes or drugs with bovine and human albumin systems. Egg albumin systems, on the other hand, did not induce such shifts. The hydrophobicities of the albumin surfaces estimated using bathochromic shifts were in the order bovine greater than human greater than egg, in agreement with literature values. The changes in absorbances of the dyes or drugs following interaction with the albumins allowed estimation of the polarizabilities of the albumins; these were in the order bovine greater than human greater than egg. The similar interactions of dyes and model drugs with albumin microspheres suggest that fluorescein dyes serve as excellent probes of the physicochemical state of denatured albumin systems and as good models for studying drug interaction with albumin microspheres. These studies also indicate that it may be possible to predict drug uptake by albumin microspheres from physicochemical properties of the drugs and carriers. Such predictions would be of great potential value for screening the suitability of carriers, especially for drugs which are highly sensitive to the preparation conditions of the microspheres, such as heating and cross-linking agents.

Replication of H1N1 influenza viruses in cultured mouse embryo brain cells: virus strain and cell differentiation affect synthesis of proteins encoded in RNA segments 7 and 8 and efficiency of mRNA splicing

The aims of these studies are (1) to determine whether, and by what mechanism(s), underexpression of M1 and/or NS1 protein restricts replication and cytopathogenicity in mouse brain cells of human influenza viruses which are closely related to the neurovirulent WSN variant but not selected for the neurovirulent phenotype; (2) to learn, ultimately, whether similarly restricted replication in natural infections might be enough to cause direct or indirect, immunologically mediated, neuropathology. On the basis of immunostaining, we have suggested that, in "aged" mouse embryo brain (MEB) cell cultures infected with A/PR/8/34 (PR8) or A/WS/33 (WS), M1 protein expression is restricted mainly in mature astrocytes (the dominant cell type in such cultures), but not in mature oligodendrocytes or neurons. Here we show that amounts of radiolabeled M1 protein in lysates of MEB cultures infected with PR8, WS, or WSN differ in proportion to previously reported single-cycle yields of trypsin-activated infectious virions. Low or undetectable cell-associated M1 does not reflect accelerated degradation, but tends to be accompanied by increased M2 protein (a product of spliced mRNA7). Radiolabeled NS1 is reduced, NS2 relatively increased, in "aged" MEB cultures infected at low m.o.i. with PR8, at high m.o.i. with WS as well, but not with WSN. In contrast, actively dividing and differentiating astrocyte-enriched or "young" MEB cultures tend to produce greatly increased amounts of NS2 even though NS1 may be at "normal" levels, both relative to those in similarly infected CEF cultures. We show, in extension of comparative studies by others on permissive and abortive FPV-infected cell systems, that virus strain-, cell type-, and perhaps differentiation-dependent variations in efficiency of mRNA 7 and 8 transcription and/or splicing are primary factors controlling variable expression of M and NS proteins in mouse brain cell cultures.

Determination of fluorescent probes localization in membranes by nonradiative energy transfer

One of the new methods of studying the structure and dimensions of biological membranes is based on the Förster's nonradiative energy transfer between special molecules, the so-called 'membrane fluorescent probes'. Further development of the approach is presented in this article. It consists of the combined use of the time-resolved and steady-state fluorescence data with subsequent computer simulation of the energy transfer in membranes. Anthracene as an energy donor, and 4-p-(dimethylamino)styryl-N-dodecylpyridinium (DSP-12) or 4-dimethylaminochalcone (DMC) as energy acceptors were bound with artificial phospholipid membrane vesicles ('liposomes'). The synchrotron radiation was used as an impulse source for the excitation light. The steady-state fluorescence data permit the area of possible probe localization in membranes to be distinguished, while the kinetic data allow them to be narrowed significantly. There is a good agreement between the obtained localization and our present-day knowledge of lipid bilayer structure. The accuracy of the method is ca. several Angströms.

Ellipticine derivatives interacting with model membranes. Influence of quaternarization of nitrogen-2

Four compounds of the ellipticine family were examined in their interaction with liposomes and with an isolated bacterial membrane. The physicochemical methods used detected only minor differences between the properties of the amphiphilic drugs (ellipticine and 2-methyl-ellipticinium) and the two dipolar drugs (9-hydroxy-ellipticine and 2-methyl 9-hydroxy-ellipticinium). The amphiphilic drugs were able to become associated to anionic liposomes in a 20-30% excess of charge neutralization, and seem to penetrate deeper into the lipid layer than the two dipolar drugs. It was also shown that ellipticine penetrates deeper into liposomes membrane than into natural membrane used. In contrast with what can be postulated from the literature dealing with the behaviour of quaternarized drugs, it seems that ellipticine and its quaternarized analogues present fast diffusion through multilayered vesicles. On the whole, the membrane effects of the ellipticines studied here are not different for quaternarized drugs and for drugs not permanently charged, but are influenced by the existence on the molecules of a second polar function.

o-Phthalaldehyde, a fluorescence probe of aldolase active site

Conditions were determined in which approximately one mole of omicron-phthalaldehyde reacts with one mole of aldolase subunit yielding a stable fluorescent isoindole derivative. During this chemical modification, a linear relationship was observed between the enzyme inactivation and absorbance change (337 nm) or fluorescence change (lambda em 420 nm, and lambda ex 338 nm) characteristic for isoindole ring formation. The reaction follows second-order kinetics, k = 1.1 X 10(3) M-1 S-1, in 50 mM borate buffer, pH 8.4 at 25 degrees C. The modification of aldolase results in loss of approximately one -SH group per protein subunit. The enzyme is protected against modification by substrates and competitive inhibitors. Essentially no isoindole derivative is formed when the glycerol-1-phosphate-lysyl derivative of aldolase is used for modification studies. It is concluded that aldolase modification occurs at the active-site region. Isolation of cross-linked peptides suggests that Lys-227 and Cys-336 are involved in formation of the isoindole derivative. This result supports Cys-336 as the active-site cysteine necessary for aldolase catalytic activity. Fluorescence studies have shown that the isoindole group linked to aldolase has its lambda max, em markedly shifted toward shorter wavelength in comparison to the fluorescence of free isoindole derivatives in aqueous solution. In model studies a linear relationship between lambda max, em of 1-(beta-hydroxyethylthio)-2-beta-hydroxyethylisoindole and the solvent polarity or acidity was observed. The results of the studies suggest that the microenvironment of the cleft in aldolase which binds isoindole appears to be of low acidity and low polarity. The apparent low polarity experienced by the isoindole probe may be due to its location in an actual low-polarity portion of the active site, or may be due to non-relaxing surroundings of the probe.

Localization of ellipticine derivatives interacting with membranes. A fluorescence-quenching study

The interaction with membranes of three anti-cancer drugs of the ellipticine family was studied by fluorescence quenching of membrane probes. The fluorescence of three probes, located at different levels in membranes, was quenched by addition of two types of ellipticine derivatives, one amphiphilic drug (9-methoxyellipticine) and two dipolar molecules (9-aminoellipticine and 9-hydroxyellipticine). By comparing the quenching curves obtained, the following can be proposed. a) 9-Methoxyellipticine can penetrate deeper in the lipid layers than 9-aminoellipticine and 9-hydroxyellipticine can. b) The three drugs are able to penetrate at least between the first methylene groups of the acyl chains of lipids in liposomes. c) In an isolated bacterial membrane, only 9-methoxyellipticine can be located in the region of the first methylene groups of lipids, the two dipolar drugs being adsorbed on the membrane surface. It was also shown that cholesterol hindered the penetration of 9-methoxyellipticine in the bilayer of liposomes.

Investigation on the interactions of peptides in the assembly of liposome and peptide by fluorescence

The peptide-lipid and the peptide-peptide interactions of hydrophobic linear dipeptides containing tryptophan in liposome were investigated by fluorescence. The linear dipeptides were buried into the hydrophobic region of liposome to induce blue-shift of the fluorescence. With the addition of various anthracene derivatives to liposome, the energy transfer from tryptophan to anthryl group took place, which increased as the temperature decreased below the phase-transition temperature of the membrane. This phenomenon was explained in terms of the phase separation of the membrane, in which crystalline regions without the probes and the domains containing high concentrations of probes are intermixed. The energy-transfer efficiency was larger in the case of peptide acceptors than lipid acceptors. This suggests the presence of special interactions between donor peptide and acceptor peptide.

Selective dansylation of M protein within intact influenza virions

Exposure of purified influenza virions to [14C]dansyl chloride resulted in the covalent attachment of the dansyl chromophore to the virion. Gel electrophoresis revealed that the dansyl chromophore was specifically coupled to the internal membrane (M) protein. Purification of the M protein by gel filtration followed by cyanogen bromide cleavage and peptide fractionation revealed that four of six peptide peaks contained dansyl label. Acid hydrolysis of the separated peptide peaks followed by thin-layer chromatography revealed that dansyl label was coupled to lysine residues present in these peptides. The results of these investigations have demonstrated that the M protein molecule is the major viral polypeptide labeled when intact virions are exposed to dansyl chloride.

Evidence for penetration in liposomes and in mitochondrial membranes of a fluorescent analogue of cord factor

A fluorescent analogue of cord factor, a glycolipid toxin of mycobacteria, has been synthesized and its interactions with liposomes and isolated mitochondria have been studied. This compound, methyl alpha-D-6[12-(9-anthroyl)stearoyl]glucoside, is shown to be active against oxidative phosphorylation. When spread as a monolayer at the air-water interface, it forms a well organized phase and it strongly interacts with phosphatidylcholine. Addition of phosphatidylcholine liposomes or of isolated mitochondria to a water disperson of this fluorescent cord factor analogue results in a large increase of the fluorescence intensity. Moreover, the glycolipid probes for the temperature-dependent phase transition of the added suspensions. It is thus suggested that this cord factor analogue penetrates within mitochondrial membranes, a result which is discussed with respect to our previous conclusions concerning the way natural cord factors can interact with these organelles.

Hydrophobicity determined by a fluorescence probe method and its correlation with surface properties of proteins

The fluorescence method of Sklar et al. (Sklar, L.A., Hudson, B.S. and Simoni, R.D. (1977) Biochemistry 16, 5100-5108) using cis-parinaric acid as a probe was applied to determine the effective hydrophobicity of proteins. The initial slope (S0) of fluorescence intensity vs. protein concentration plot was used as an index of the protein hydrophobicity. A good correlation was observed for S0 of native proteins, denatured proteins and surfactant-bound proteins with an effective hydrophobicity determined by the hydrophobic partition method. The effective hydrophobicity determined fluorometrically showed significant correlations with interfacial tension and emulsifying activity of the proteins studied. The fluorescence technique using cis-parinaric acid is useful for determination of the effective hydrophobicity, as the procedure is much simpler and quicker than hydrophobic chromatography and hydrophobic partition.

Properties and the locations of a set of fluorescent probes sensitive to the fluidity gradient of the lipid bilayer

The synthesis and properties of a set of four fluorescent probes (n-(9-anthroyloxy) fatty acids, n = 2, 6, 9, 12) sensitive to the fluidity gradient of the lipid bilayer are described. Fluorescent quenching experiments show that the probes locate at a graded series of depths in the bilayer. A fifth probe, methyl-9-anthroate, locates near the bilayer centre. As an example of their application, the probes are used to study the phase transitions of dipalmitoyl phosphatidyl-choline. Changes in the rotational relaxation times of the probes across the transitions are more pronounced at the centre of the bilayer than at the surface.

Anthroyl stearate as a fluorescent probe of chloroplast membranes

1. A reversible light-induced enhancement of the fluorescence of a "hydrophobic fluorophore", 12-(9-anthroyl)-stearic acid (anthroyl stearate), is observed with chloroplasts supporting phenazine methosulfate, cyclic or 1,1'-ethylene-2,2'-dipyridylium dibromide (Diquat) pseudo-cyclic electron flow; no fluorescence change is observed when methyl viologen or ferricyanide are used as electron acceptors. The stearic acid moiety of anthroyl stearate is important for its localization and fluorescence response in the thylakoid membrane, since structural analogs of anthroyl stearate lacking this group do not show the same response. 2. This effect is decreased under phosphorylating conditions (presence of ADP, Pi, Mg2+), and completely inhibited by the uncoupler of phosphorylation NH4Cl(5-10mM), as well as the ionophores nigericin and gramicidin-D (both at 5 - 10(-8)M). The MgCl2 concentration dependence of the anthroyl stearate enhancement effect is identical to that previously observed for cyclic photophosphorylation, as well as for the formation of a "high energy intermediate". The anthroyl stearate fluorescence enhancement is inhibited by increasing concentrations of ionophores in parallel with the decrease in ATP synthesis, but is essentially unaffected by specific inhibitors (Dio-9 and phlorizin) of photophosphorylation; thus, it appears that anthroyl stearate monitors a component of the "high energy state" of the thylakoid membrane rather than a terminal phosphorylation step. 3. The light-induced anthroyl stearate fluorescence enhancement is suggested to monitor a proton gradient in the energized chloroplast because (a) similar enhancement can be produced by sudden injection of hydrogen ions in a solution of anthroyl stearate; (b) when the proton gradient is dissipated by gramicidin or nigericin light-induced anthroyl stearate fllorescence is eliminated; (c) when the proton gradient is dissipated by tetraphenylboron, light-induced anthroyl stearate fluorescence decreases, and (d) light-induced anthroyl stearate fluorescence change as a function of pH is qualitatively similar to that observed with other probes for a proton gradient (e.g. 9-aminoacridine). Furthermore, anthroyl stearate does not monitor H+ uptake per se because (a) the pH dependence of H+ transport is different from that of the anthroyl stearate fluorescence change, and (b) tetraphenylboron, which does not inhibit H+ uptake, reduces anthroyl stearate fluorescence. Thus, anthroyl stearate appears to be a useful probe of a proton gradient supported by phenazine methosulfate of Diquat catalyzed electron flow and is the first "non-amine" fluorescence probe utilized for this purpose in chloroplasts.

13C-NMR studies of the membrane structure of enveloped virions (vesicular stomatitis virus)

The mobility of the lipids in the bilayer of the envelope of vesicular stomatitis virus has been probed over its complete space by the biosynthetic incorporation of [N-13CH3]- choline as a probe for the polar head groups and [3-13C]- and [11-13C] oleic acid and [16-13C]- palmitic acid for the hydrophobic region of the bilayer. These precursors were effectively incorporated as established by the concomitant administration of the same precursors in radioactive form. Spin lattice relaxation time measurements (T1) of the 13C enriched segments in complete virus envelope allowed estimation of their mobility. The mobility of the polar head groups is restricted, probably due to ionic interactions with neighbouring acidic phospholipids (phosphatidylserine) and/or acidic side chains of the glycoprotein (G-protein). The rigidity of the hydrophobic part of the bilayer is due to the high cholesterol content and interaction with the immersing polypeptide chains of the G- and possibly M-protein. The rigidity is limited to a depth of about 15 A ranging from the inner and outer surface, whereas the inner core of the bilayer is fluid. Tryptic cleavage of the hydrophilic part of the G-protein allows the lipophilic immersing polypeptide fragment to enter further the bilayer which then reduces the fluidity of the hydrocarbon chains in the core region by lipid-protein interactions.

Effect of membrane protein on lipid bilayer structure: a spin-label electron spin resonance study of vesicular stomatitis virus

Spin-label electron spin resonance (ESR) methods have been used to study the structure of the envelope of vesicular stomatitis virus (VSV). The data indicate that the lipid is organized in a bilayer structure. Proteolytic digestion of the glycoproteins which are the spike-like projections on the outer surface of the virus particle increases the fluidity of the lipid bilayer. Since the lipid composition of the virion reflects the composition of the host plasma membrane and the protein composition is determined by the viral genome, VSV was grown in both MDBK and BHK21-F cells to determine the effect of a change in lipid composition on the structure of the lipid bilayer of VSV. The lipid bilayer of the virion was found to be more rigid when derived from MDBK cells than from BHK21-F cells. Studies comparing spin-labeled intact cells and cell membrane fractions suggest that upon labeling the whole cell the spin label probes the plasma membrane. Comparison of spin-labeled VSV particles and their host cells indicates that the lipid bilayer of the plasma membrane is considerably more fluid than that of the virion. These results are discussed in terms of the effect of membrane-associated protein on the structure of the lipid bilayer.

Lipid-lipid and lipid-protein interactions as studied with a novel type of fluorescent fatty acid and phospholipid probes

A novel fluorescent-labelled group of fatty acids and phospholipids has been applied to determine phase transitions in liposomes by fluorescence intensity and polarisation measurements. The chromophore of these amphiphilic lipids proved to be very suitable to demonstrate temperature-dependent lipid-lipid interactions. Liposomes from 1,2-dipalmitoyl-3-sn-glycero-phosphoethanolamine and from lipids isolated from membranes of E. coli K 1062 mutant grown on elaidic acid were used in these studies. These probes also made it possible to observe conformational changes in membrane proteins in isolated plasma membranes from this mutant. The changes in protein conformation were dependent on structural changes in the lipid phase.

13-C nuclear magnetic resonance studies on the lipid organization in enveloped virions (vesicular stomatitis virus)

13-C nuclear magnetic resonance (NMR) studies are described regarding the lipid organization in the envelope of the vesicular stomatitis virion. The fatty acid chains (oleic acid) and the choline moiety of the 3-sn-phosphatidylcholine and spingomyelin have been labeled specifically with 13-C by growing the virions in prelabeled host cells (BHK 21 cells). The results suggest that 130C NMR spectroscopy is a very feasible method for the study of natural membranes provided the isotope is highly enriched in specific positions and incorporated biochemically. Spin-lattice relaxation (T1) measurements of particular C atoms have been carried out with whole virions, with virions deprived of their surface projections by trypsinization but unaltered in their shape and size, and with liposomes prepared from the total lipid mixture of the envelope in order to get insight into the molecular structure of this model membrane. The mobility of the central part of 11-13-C-labeled oleic acid incorporated into the ester and amide lipids and the choline group of 3-sn-phosphatidylcholine and sphingomyelin is very restricted as indicated by their short T1 times. It is concluded from the data presented here that the high cholesterol content (cholesterol/P: 0.7) of the envelope lipid phase is responsible for the rather rigidly packed envelope structure. The mode and extent of the interactions between lipids and glycoprotein surface projections are subjects for further study.