Structure of Semliki Forest virus in complex with its receptor VLDLR.

Semliki Forest virus (SFV) is an alphavirus that uses the very-low-density lipoprotein receptor (VLDLR) as a receptor during infection of its vertebrate hosts and insect vectors. Herein, we used cryoelectron microscopy to study the structure of SFV in complex with VLDLR. We found that VLDLR binds multiple E1-DIII sites of SFV through its membrane-distal LDLR class A (LA) repeats. Among the LA repeats of the VLDLR, LA3 has the best binding affinity to SFV. The high-resolution structure shows that LA3 binds SFV E1-DIII through a small surface area of 378 Å2, with the main interactions at the interface involving salt bridges. Compared with the binding of single LA3s, consecutive LA repeats around LA3 promote synergistic binding to SFV, during which the LAs undergo a rotation, allowing simultaneous key interactions at multiple E1-DIII sites on the virion and enabling the binding of VLDLRs from divergent host species to SFV.

Correlative light and electron microscopy enables viral replication studies at the ultrastructural level.

Electron microscopy (EM) is a powerful tool to study structural changes within cells caused e.g. by ectopic protein expression, gene silencing or virus infection. Correlative light and electron microscopy (CLEM) has proven to be useful in cases when it is problematic to identify a particular cell among a majority of unaffected cells at the EM level. In this technique the cells of interest are first identified by fluorescence microscopy and then further processed for EM. CLEM has become crucial when studying positive-strand RNA virus replication, as it takes place in nanoscale replication sites on specific cellular membranes. Here we have employed CLEM for Semliki Forest virus (SFV) replication studies both by transfecting viral replication components to cells or by infecting different cell types. For the transfection-based system, we developed an RNA template that can be detected in the cells even in the absence of replication and thus allows exploration of lethal mutations in viral proteins. In infected mammalian and mosquito cells, we were able to find replication-positive cells by using a fluorescently labeled viral protein even in the cases of low infection efficiency. The fluorescent region within these cells was shown to correspond to an area rich in modified membranes. These results show that CLEM is a valuable technique for studying virus replication and membrane modifications at the ultrastructural level.

Conformational change and protein-protein interactions of the fusion protein of Semliki Forest virus.

Fusion of biological membranes is mediated by specific lipid-interacting proteins that induce the formation and expansion of an initial fusion pore. Here we report the crystal structure of the ectodomain of the Semliki Forest virus fusion glycoprotein E1 in its low-pH-induced trimeric form. E1 adopts a folded-back conformation that, in the final post-fusion form of the full-length protein, would bring the fusion peptide loop and the transmembrane anchor to the same end of a stable protein rod. The observed conformation of the fusion peptide loop is compatible with interactions only with the outer leaflet of the lipid bilayer. Crystal contacts between fusion peptide loops of adjacent E1 trimers, together with electron microscopy observations, suggest that in an early step of membrane fusion, an intermediate assembly of five trimers creates two opposing nipple-like deformations in the viral and target membranes, leading to formation of the fusion pore.

Interactions of Semliki Forest virus spike glycoprotein rosettes and vesicles with cultured cells.

Semliki Forest virus (SFV)-derived spike glycoprotein rosettes (soluble octameric complexes), virosomes (lipid vesicles with viral spike glycoproteins), and liposomes (protein-free lipid vesicles) have been used to investigate the interaction of subviral particles with BHK-21 cells. Cell surface binding, internalization, degradation, and low pH-dependent membrane fusion were quantitatively determined. Electron microscopy was used to visualize the interactions. Virosomes and rosettes, but not liposomes, bound to cells. Binding occurred preferentially to microvilli and was inhibited by added SFV; it increased with decreasing pH but was, in all cases, less efficient than intact virus. At 37 degrees C the cell surface-bound rosettes and virosomes were internalized via coated pits and coated vesicles. After a lag period of 45 min the protein components of the internalized ligands were degraded and appeared, as acid-soluble activity, in the medium. The uptake of rosettes and virosomes was found to be similar to the adsorptive endocytosis of SFV except that their average residence times on the cell surface were longer. The rosettes and the liposomes did not show low pH-induced membrane fusion activity. The virosomes, however, irrespective of the lipid compositions used, displayed hemolytic activity at mildly acidic pH and were able to fuse with the plasma membrane of cells with an efficiency of 0.25 that observed with intact viruses. Cell-cell fusion activity was not observed with any of the subviral components. The results indicated that subviral components possess some of the entry properties of the intact virus.

Cholesterol is required in the exit pathway of Semliki Forest virus.

The enveloped alphavirus Semliki Forest virus (SFV) infects cells via a membrane fusion reaction triggered by low pH. For fusion to occur cholesterol is required in the target membrane, as demonstrated both in in vitro fusion assays and in vivo for virus infection of a host cell. In this paper we examine the role of cholesterol in postfusion events in the SFV life cycle. Cholesterol-depleted insect cells were transfected with SFV RNA or infected at very high multiplicities to circumvent the fusion block caused by the absence of cholesterol. Under these conditions, the viral spike proteins were synthesized and transported to the site of p62 cleavage with normal kinetics. Surprisingly, the subsequent exit of virus particles was dramatically slowed compared to cholesterol-containing cells. The inhibition of virus production could be reversed by the addition of cholesterol to depleted cells. In contrast to results with SFV, no cholesterol requirement for virus exit was observed for the production of either the unrelated vesicular stomatitis virus or a cholesterol-independent SFV fusion mutant. Thus, cholesterol was only critical in the exit pathway of viruses that also require cholesterol for fusion. These results demonstrate a specific and unexpected lipid requirement in virus exit, and suggest that in addition to its role in fusion, cholesterol is involved in the assembly or budding of SFV.

Reconstitution of Semliki forest virus membrane.

The spike glycoproteins of the Semliki forest virus membrane have been incorporated into vesicular phospholipid bilayers by a detergent-dialysis method. The detergent used was beta-D-octylglucoside which is nonionic and has an exceptionally high critical micellar concentration which facilitates rapid removal by dialysis. The vesicles obtained were of varying sizes and had spikes on their surface. Two classes of vesicles were preferentially formed, small protein-rich and large lipid-rich (average lipid to protein weight ratios, 0.22 and 3.5, respectively). Both classes of vesicles retained the hemagglutinating activity of the virus. The proteins were attached to the lipid bilayer by hydrophobic peptide segments, as in the viral membrane. Most of the proteins were accessible to proteolytic digestion from the outside, suggesting an asymmetric orientation.

Membrane fusion process of Semliki Forest virus. I: Low pH-induced rearrangement in spike protein quaternary structure precedes virus penetration into cells.

The Semliki Forest virus (SFV) directs the synthesis of a heterodimeric membrane protein complex which is used for virus membrane assembly during budding at the surface of the infected cell, as well as for low pH-induced membrane fusion in the endosomes when particles enter new host cells. Existing evidence suggests that the E1 protein subunit carries the fusion potential of the heterodimer, whereas the E2 subunit, or its intracellular precursor p62, is required for binding to the nucleocapsid. We show here that during virus uptake into acidic endosomes the original E2E1 heterodimer is destabilized and the E1 proteins form new oligomers, presumably homooligomers, with altered E1 structure. This altered structure of E1 is specifically recognized by a monoclonal antibody which can also inhibit penetration of SFV into host cells as well as SFV-mediated cell-cell fusion, thus suggesting that the altered E1 structure is important for the membrane fusion. These results give further support for a membrane protein oligomerization-mediated control mechanism for the membrane fusion potential in alphaviruses.

Electron holography of biological samples.

In this paper, we summarise the development of off-axis electron holography on biological samples starting in 1986 with the first results on ferritin from the group of Tonomura. In the middle of the 1990s strong interest was evoked, but then stagnation took place because the results obtained at that stage did not reach the contrast and the resolution achieved by conventional electron microscopy. To date, there exist only a few ( approximately 12) publications on electron holography of biological objects, thus this topic is quite small and concise. The reason for this could be that holography is mostly established in materials science by physicists. Therefore, applications for off-axis holography were powerfully pushed forward in the area of imaging, e.g. electric or magnetic micro- and nanofields. Unstained biological systems investigated by means of off-axis electron holography up to now are ferritin, tobacco mosaic virus, a bacterial flagellum, T5 bacteriophage virus, hexagonal packed intermediate layer of bacteria and the Semliki Forest virus. New results of the authors on collagen fibres and surface layer of bacteria, the so-called S-layer 2D crystal lattice are presented in this review. For the sake of completeness, we will shortly discuss in-line holography of biological samples and off-axis holography of materials related to biological systems, such as biomaterial composites or magnetotactic bacteria.

An Alphavirus E2 Membrane-Proximal Domain Promotes Envelope Protein Lateral Interactions and Virus Budding.

Alphaviruses are members of a group of small enveloped RNA viruses that includes important human pathogens such as Chikungunya virus and the equine encephalitis viruses. The virus membrane is covered by a lattice composed of 80 spikes, each a trimer of heterodimers of the E2 and E1 transmembrane proteins. During virus endocytic entry, the E1 glycoprotein mediates the low-pH-dependent fusion of the virus membrane with the endosome membrane, thus initiating virus infection. While much is known about E1 structural rearrangements during membrane fusion, it is unclear how the E1/E2 dimer dissociates, a step required for the fusion reaction. A recent Alphavirus cryo-electron microscopy reconstruction revealed a previously unidentified D subdomain in the E2 ectodomain, close to the virus membrane. A loop within this region, here referred to as the D-loop, contains two highly conserved histidines, H348 and H352, which were hypothesized to play a role in dimer dissociation. We generated Semliki Forest virus mutants containing the single and double alanine substitutions H348A, H352A, and H348/352A. The three D-loop mutations caused a reduction in virus growth ranging from 1.6 to 2 log but did not significantly affect structural protein biosynthesis or transport, dimer stability, virus fusion, or specific infectivity. Instead, growth reduction was due to inhibition of a late stage of virus assembly at the plasma membrane. The virus particles that are produced show reduced thermostability compared to the wild type. We propose the E2 D-loop as a key region in establishing the E1-E2 contacts that drive glycoprotein lattice formation and promote Alphavirus budding from the plasma membrane.IMPORTANCEAlphavirus infection causes severe and debilitating human diseases for which there are no effective antiviral therapies or vaccines. In order to develop targeted therapeutics, detailed molecular understanding of the viral entry and exit mechanisms is required. In this report, we define the role of the E2 protein juxtamembrane D-loop, which contains highly conserved histidine residues at positions 348 and 352. These histidines do not play an important role in virus fusion and infection. However, mutation of the D-loop histidines causes significant decreases in the assembly and thermostability of Alphavirus particles. Our results suggest that the E2 D-loop interacts with the E1 protein to promote Alphavirus budding.

Viral RNA replication in association with cellular membranes.

All plus-strand RNA viruses replicate in association with cytoplasmic membranes of infected cells. The RNA replication complex of many virus families is associated with the endoplasmic reticulum membranes, for example, picorna-, flavi-, arteri-, and bromoviruses. However, endosomes and lysosomes (togaviruses), peroxisomes and chloroplasts (tombusviruses), and mitochondria (nodaviruses) are also used as sites for RNA replication. Studies of individual nonstructural proteins, the virus-specific components of the RNA replicase, have revealed that the replication complexes are associated with the membranes and targeted to the respective organelle by the ns proteins rather than RNA. Many ns proteins have hydrophobic sequences and may transverse the membrane like polytopic integral membrane proteins, whereas others interact with membranes monotopically. Hepatitis C virus ns proteins offer examples of polytopic transmembrane proteins (NS2, NS4B), a "tip-anchored" protein attached to the membrane by an amphipathic alpha-helix (NS5A) and a "tail-anchored" posttranslationally inserted protein (NS5B). Semliki Forest virus nsP1 is attached to the plasma membrane by a specific binding peptide in the middle of the protein, which forms an amphipathic alpha-helix. Interaction of nsP1 with membrane lipids is essential for its capping enzyme activities. The other soluble replicase proteins are directed to the endo-lysosomal membranes only as part of the initial polyprotein. Poliovirus ns proteins utilize endoplasmic reticulum membranes from which vesicles are released in COPII coats. However, these vesicles are not directed to the normal secretory pathway, but accumulate in the cytoplasm. In many cases the replicase proteins induce membrane invaginations or vesicles, which function as protective environments for RNA replication.

Serum glycoprotein-type sequence of monosaccharides in membrane glycoproteins of Semliki Forest virus.

Semliki Forest virus was grown in BHK-21 cells and labelled in vivo with radioactive monosaccharides. The virus was disrupted with sodium dodecyl sulphate and the polypeptides were hydrolyzed with pronase. A mixture of type A glycopeptides (for nomenclature, see Johnson and Clamp (1971) Biochem. J. 123, 739-745) of the membrane glycoproteins E1 and E3 was isolated by gel filtration and subjected to sequential degradation with exo-glycosidases. The reduction in the apparent molecular weight and the cleavage of radioactive monosaccharides were monitored with gel filtration. The results suggest that the type A oligosaccharides have similar average structures and contain at the non-reducing terminus 3.4 mol of alpha-D-sialic acid and 0.7 mol of alpha-L-focose, folloled by 3.1 mol of beta-D-galactose, 4.2 mol of N-acetyl-beta-D-glucosamine, 0.7-1.5 mol of alpha-D-mannose, 0.5 mol of beta-D-mannose and 0.6-2.2 mol of N-acetyl-beta-D-glucosamine attached to 1.0 mol of N-acetylglucosamine resistant to N-acetyl-beta-D-glucosaminidase. This innermost monosaccharide unit, therefore, appears to be attached to the peptide. The peptides attached to this N-acetyl-glucosamine had an apparent molecular weight of 720+/-100. We propose the following average structure, compatible with most of our data, for the type A glycopeptides of Semliki Forest virus:.

Solubilization of the Semliki Forest virus membrane with sodium deoxycholate.

The effects of increasing concentrations of sodium deoxycholate on Semliki Forest have been studied. Sodium deoxycholate begins to bind to the virus at less than 0.1 mM free equilibrium concentration and causes lysis of the viral membrane at 0.9 +/- 0.1 mM free equilibrium concentration when 2.2 +/- 0.2 - 103 mol of sodium deoxycholate are bound per mol of virus. Liberation of proteins from the membrane begins at 1.5 +/- 0.1 mM sodium deoxycholate and the proteins released are virtually free from phospholipid above 2.0 mM sodium deoxycholate. The overall mechanism of sodium deoxycholate solubilization of the viral membrane resembles that of Triton X-100 and sodium dodecyl sulphate except that with sodium deoxycholate the various stages of membrane disruption occur at about 10-fold higher equilibrium free detergent concentrations. At sodium deoxycholate concentrations higher than 2.3 mM the viral spike glycoproteins can be separated by sucrose gradient centrifugation or gel filtration into constituent polypeptides E1, E2 and E3. E1 carries the haemagglutinating activity of the virus.

Semlike Forest virus membrane proteins. Preparation and characterization of spike complexes soluble in detergent-free medium.

After Triton X-100 delipidation and subsequent Triton X-100 removal in a sucrose gradient the membrane protein spikes of Semliki Forest virus remained soluble in aqueous buffers. It was shown they were present as octameric complexes with a molecular weight of 95-10(4) and that they contain less than 4% lipid and detergent by weight. In electron microscopy after negative staining they appeared as "rosette"-shaped particles. Part of the protein could also be found associated in ordered paracrystalline arrays.

The organization of the spike complex of Semliki Forest virus.

Semliki Forest virus (SFV) is an enveloped animal virus comprising an icosahedral nucleocapsid surrounded by a membrane containing 80 transmembrane, trimeric spikes. SFV was treated with the non-ionic detergent n-octyl beta-D-glucopyranoside (octylglucoside) and analysed by cryo-electron microscopy and image reconstruction to explore the interaction between the spikes and the capsid. Comparison of the structure of detergent treated SFV (DSFV) with SFV by three-dimensional image reconstruction from cryoelectron micrographs showed that one fourth of the spikes, those on the 3-fold axis, were selectively removed by detergent treatment. Quantitative immunoblotting of gently detergent treated virus showed that polypeptide E1 was selectively removed from the trimeric spike complex (E1, E2, E3)3. Difference imaging between DSFV and SFV in combination with comparison to the previously established structure of Sindbis virus, which lacks the E3 protein, leads to a model for the position of E1, E2 and E3 in the spike. If the trimeric spike is represented as a triangle, E2 extends from the centre to the vertices and E1 fills in between the ridges of E2 to form the edges of the triangle while E3 is at the distal end of the spike, interacting primarily with E2.

The first step: activation of the Semliki Forest virus spike protein precursor causes a localized conformational change in the trimeric spike.

The structure of the particle formed by the SFVmSQL mutant of Semliki Forest virus (SFV) has been defined by cryo-electron microscopy and image reconstruction to a resolution of 21 A. The SQL mutation blocks the cleavage of p62, the precursor of the spike proteins E2 and E3, which normally occurs in the trans-Golgi. The uncleaved spike protein is insensitive to the low pH treatment that triggers membrane fusion during entry of the wild-type virus. The conformation of the spike in the SFVmSQL particle should correspond to that of the inactive precursor found in the early stages of the secretory pathway. Comparison of this "precursor" structure with that of the mature, wild-type, virus allows visualization of the changes that lead to activation, the first step in the pathway toward fusion. We find that the conformational change in the spike is dramatic but localized. The projecting domains of the spikes are completely separated in the precursor and close to generate a cavity in the mature spike. E1, the fusion peptide-bearing protein, interacts only with the p62 in its own third of the trimer before cleavage and then collapses to form a trimer of heterotrimers (E1E2E3)3 surrounding the cavity, poised for the pH-induced conformational change that leads to fusion. The capsid, transmembrane regions and the spike skirts (thin layers of protein that link spikes above the membrane) remain unchanged by cleavage. Similarly, the interactions of the spikes with the nucleocapsid through the transmembrane domains remain constant. Hence, the interactions that lead to virus assembly are unaffected by the SFVmSQL mutation.

Comparison of protein A-gold and ferritin immunoelectron microscopy of Semliki Forest virus in mouse brain using a rapid processing technique.

Processing tissue for transmission electron microscopy by standard laboratory methods can take two to three days. This makes the development of new techniques time consuming and generally restricts the use of the electron microscope in routine diagnostic work. The possibility of viewing tissue with the electron microscope five hours after sampling using rapid processing techniques is presented. The morphology of the tissue appears undamaged with cell and organelle ultrastructures being readily recognized, as is the presence of virus and its replicating stages. When combined with immunoelectron microscopy a rapid labeling protocol is possible. We have used the technique to develop protein A-gold (6 and 16 nm particles) and ferritin immunoelectron microscopic techniques to demonstrate viral antigens in brain cell cultures and brain tissue from mice infected with Semliki Forest virus.

Nucleolar accumulation of Semliki Forest virus nucleocapsid C protein: influence of metabolic status, cytoskeleton and receptors.

The nucleolar accumulation of Semliki Forest Virus (SFV) C protein was examined as a function of intact microtubules, intact microfilaments and accessible intermediate filaments. The cytoskeletal components do not seem to play a role in directing C protein to the nucleolus but nucleolar accumulation is energy-dependent and saturable. This suggests the involvement of some receptor- (or chaperon-) interaction.

An electron microscopical study of the replication of avirulent Semliki Forest virus in the retina of mice.

Electron microscopical (EM) studies were carried out on the retinas of 2-3-(baby), 12-, 14- and 21-28-day-old (adult) mice infected with avirulent (A774) Semliki Forest virus (SFV). Virions (mature virus), spherules and advanced stages of virus replication, cytopathic vacuoles type II (CPV II), were seen in the retinal neurons of baby mice after intracerebral (i.c.) or intraperitoneal (i.p.) infection. Some virions and spherules were also seen in the retinas of 12- and 14-day-old mice. Virions and advanced stages of virus replication were not seen in adult mice despite high virus titres. Some neurons of the inner nuclear layer and some ganglion cells showed reduced basophilia and appeared pale and occasionally some dense clumps of fine granules (DC) were seen in the neurones of the inner nuclear layer in these mice. A few small spherules were seen in the extracellular spaces. Some infiltrating cells were seen in the retinas in all ages of mice. We suggest that SFV causes retinopathy in baby mice and the neurophysiological changes reported in adult mice may be contributed to by virus replication in the retinal neurones and the presence of infiltrating cells in the retina.

An electron-microscopic study of the development of virulent and avirulent strains of Semliki forest virus in mouse brain.

Two strains of Semliki Forest Virus (SFV), the avirulent and virulent, were used to study the development of virus in both baby and adult mouse brain. The development of SFV in the brain was similar in baby and adult brain using the virulent strain and in the baby mouse brain using the avirulent strain. Mature virus could not be found in adult mouse brain using the avirulent strain. This paper shows that extracellular virus particles near the cell membrane stimulate the formation of coated vesicles and thus absorption of virus particles by the cell. It is suggested that these coated vesicles with contained virus particles are stimulated to develop nucleoid cores on their membrane forming cytopathic vacuoles, Type II (CPV-II). Excessive membrane growth takes place and the membrane of the CPV-II with the nucleoid cores invaginates to form intravacuolar tubules. It is suggested that these tubules become responsible fro the formation of mature virus particles. Thus the membrane of the CPV-II appears to be responsible for the development of both the inner core and outer coat of the virus.

An electron-microscopic study of avirulent and virulent Semliki forest virus in the brains of different ages of mice.

Ultrastructural studies of brains infected with avirulent and virulent strains of Semliki forest virus (SFV) were performed in 2-7, 14, 19, and 21-28 day old mice. Mature virus particles, dense clumps of fine granules, spherules and advanced stages of viral development i.e. cytopathic vacuoles, Type II (CPV II) are seen in the brains at all ages with the virulent strain which is pathogenic to all age group of mice. In the avirulent strain infection which is pathogenic to mice below 15 days old, no mature virus particles or advanced stages of viral development are seen in 19 day old and adult mice in spite of high virus titres. However, dense clumps of fine granules and spherules are seen which seem to have the capacity to develop into lethal highly infectious mature virus when reinoculated into 2-7 day old mice. It is suggested that the dense clumps of fine granules and spherules are very early viral forms, which are seen in all age groups of mice. The cut-off mechanism in pathogenicity of the avirulent strain occurs in mice around 14 days old. Though some mature virus particles and advanced viral developmental stages are seen in these mice they were much less frequent compared to baby mice. Lymphoblastic type cells are numerous in this age group. These cells are seen more frequently in all ages of mice infected with the avirulent strain as compared to the virulent strain. These mononuclear cells can have an immunological role and may play a part in limiting the process of viral maturation and hence preventing death. Polymorphs and macrophages are rare with the avirulent infection but are the predominant infiltrating cells in the virulent strain infections. With the avirulent infections the astrocytes show hypertrophy and intranuclear inclusions are seen in them.