Replication of Sindbis Virus IV. Electron Microscope Study of the Insertion of Viral Glycoproteins into the Surface of Infected Chick Cells

The appearance of Sindbis virus-envelope glycoproteins in the surfaces of chicken embryo fibroblasts was studied by an indirect labeling technique. This technique involved treating infected cells sequentially with rabbit immunoglobulin G (IgG) specific for Sindbis virus followed by hemocyanin-conjugated goat (anti-rabbit IgG) IgG; surface replicas of these cells were then prepared and examined in the electron microscope. As early as 2 h after infection (and at least 1 h before mature virions were released), newly synthesized virus-envelope glycoproteins were detected at the cell surface. By 3 h after infection, cell surface membranes were extensively modified by the insertion of the Sindbis glycoproteins. When infected cells were prefixed with glutaraldehyde before labeling, the glycoproteins were distributed fairly evenly over the cell surface, although a slight clustering was observed on cells labeled early in infection. However, no evidence for large-scale clustering of virus glycoproteins corresponding to patches of budding virus was observed. Similar results were found with unfixed cells labeled at 4 C. However, when unfixed cells were labeled at 37 C, the glycoproteins were shown to be in discrete clusters, demonstrating that these glycoprotein antigens can diffuse laterally through the cell membrane at this temperature.     

Effect of Ionic Strength on the Binding of Sindbis Virus to Chick Cells

Sindbis virus can adsorb to chicken embryo fibroblasts in two different ways. "Loosely" bound virus can be washed off the cell with buffers of ionic strength 0.2 or greater, whereas "tightly" bound virus remains attached under these conditions. When Sindbis virus is adsorbed to chick cells at 4 C from a buffer of ionic strength 0.17, 40 to 50% of the adsorbed virus is loosely bound, the remainder tightly bound. Infection of chick cells by Sindbis virus has only small effects on the total amount of virus that can be bound to the cells. However, the amount of Sindbis virus that can be tightly bound declines rapidly beginning at 2 to 3 h after infection. By 7 h after infection, the amount of virus that can be tightly bound is only 10 to 20% of the amount bound to uninfected cells. The adsorption (and penetration) of virus at 37 C is most efficient at an ionic strength of 0.15 to 0.17; at this ionic strength most of the adsorbed virus is tightly bound. At higher ionic strengths the virus adsorbs poorly. At lower ionic strengths most of the virus is loosely bound. A second enveloped virus, vesicular stomatitis virus, has been studied for the purposes of comparison; its adsorption behavior differs from that of Sindbis virus.     

Failure of defective interfering particles of Sindbis virus produced in BHK or chicken cells to affect viral replication in Aedes albopictus cells.

Whereas defective interfering particles of Sindbis virus are readily produced in BHK-21 cells or chicken embryo fibroblasts by the techniques of serial undiluted passage, similar methods failed to generate such particles in Aedes albopictus cell cultures. In addition, Sindbis virus stocks produced in BHK-21 cells or chicken embryo fibroblasts and which contained defective interfering particles, when tested in A. albopictus cells, failed (i) to interfere with the replication of standard Sindbis virus and (ii) to change the pattern of intracellular viral RNA synthesis from that produced by infection with standard Sindbis virus alone. We conclude that defective interfering particles of Sindbis virus generated in chicken or hamster cells are silent or inert in mosquito cells.     

Production of Sindbis,influenza, and vesicular stomatitis viruses in chicken embryo and rat embryo cell suspensions

Studies were carried out on the production of Sindbis, influenza and vesicular stomatitis viruses in suspensions of chicken embryo and rat embryo cells. The yield of Sindbis virus in chicken embryo cell suspensions was independent of the multiplicity of infection over the range 0.0001 to 0.01 although reduction in multiplicity caused a delay in virus production. With influenza virus the use of higher multiplicities gave increased virus yields possibly due to the very slow production at low multiplicities. In both monolayer and suspension cultures of chicken embryo cells addition of serum or use of media richer than minimum essential medium (Eagle) had little effect on Sindbis virus production, but if the glucose were omitted the virus yield was markedly reduced. In cell suspensions, a marked reduction in virus yield occurred if infection were delayed more than 24 hr after cell preparation whereas in monolayers the delay of infection allowed cell propagation and hence a higher yield of virus. It was also shown that vesicular stomatitis virus can be produced in chicken embryo cell suspensions, and that rat embryo primary cell suspensions can be used to prepare both Sindbis and vesicular stomatitis viruses. Sindbis virus obtained from chicken embryo cell suspensions was purified by polyethylene glycol precipitation and sucrose density gradient centrifugation and shown to contain only those proteins previously identified as viral, without any contamination from chicken cell proteins. The relative ease and economics of virus production by cell suspension and monolayer methods is compared.     

Studies on the budding process of a temperature-sensitive mutant of murine leukemia virus with a scanning electron microscope.

The scanning electron microscope was used to study the budding process of the wild-type Moloney murine leukemia virus and one of its temperature-sensitive mutants, designated ts 3. A considerably larger number of budding particles was observed on TB cells infected with ts 3 at the nonpermissive temperature (39 C) than at the permissive temperature (34 C). No apparent difference was noted between the number of particles on ts 3-infected cells at (34 C) and wild-type-infected cells at 34 or 39 C. Virions were detected at the cell membrane of ts 3-infected cells at 39 C as early as 8 h postinfection. Virion density increased progressively up to 48 h after which no increase was observed. An average of 1,600 virus particles was observed at the cell surface at the peak of virus production. The distribution of these on the cell membrane appeared to be random. The maximum proportion of the cell surface occupied by the viral particles did not exceed 10%. After temperature shift from 39 to 34 C, approximately 90% of the particles had dissociated from the cell membrane within 1 h.     

Sindbis virus glycoproteins: effect of the host cell on the oligosaccharides.

Sindbis virus was grown in four different host cells and the carbohydrate portions of the glycoproteins were analyzed. Sindbis virus grown in BHK-21 cells has more sialic acid and galactose than Sindbis virus grown in chicken embryo cells. In other respects the carbohydrates from virus grown in these two hosts are very similar. Sindbis virus grown either in chick cells transformed by Rous sarcoma virus or in BHK cells transformed by polyoma virus was also examined. In comparisons of virus from normal and transformed cells, differences in the amount of sialic acid were observed; but otherwise the carbohydrate structures appeared basically similar. The growth conditions used for the host cell also affected the degree of completion of the carbohydrate chains of the viral glycoproteins.     

Binding of Sindbis Virus to Cell Surface Heparan Sulfate

Alphaviruses are arthropod-borne viruses with wide species ranges and diverse tissue tropisms. The cell surface receptors which allow infection of so many different species and cell types are still incompletely characterized. We show here that the widely expressed glycosaminoglycan heparan sulfate can participate in the binding of Sindbis virus to cells. Enzymatic removal of heparan sulfate or the use of heparan sulfate-deficient cells led to a large reduction in virus binding. Sindbis virus bound to immobilized heparin, and this interaction was blocked by neutralizing antibodies against the viral E2 glycoprotein. Further experiments showed that a high degree of sulfation was critical for the ability of heparin to bind Sindbis virus. However, Sindbis virus was still able to infect and replicate on cells which were completely deficient in heparan sulfate, indicating that additional receptors must be involved. Cell surface binding of another alphavirus, Ross River virus, was found to be independent of heparan sulfate.     

Morphogenesis of Sindbis virus in three subclones of Aedes albopictus (mosquito) cells.

The morphogenesis of Sindbis virus in three Aedes albopictus subcloned cell lines was examined. Each line was distinguishable with respect to morphology, cytopathic response to infection, and progeny yield. C7-10 cells, which produced the highest titers of virus and exhibited the most severe cytopathic response, were characterized ultrastructurally by the presence of budding particles at the cell surface and at the membranes of internal vesicles. C6/36 cells, which displayed a moderate cytotoxic response, manifested similar features in response to Sindbis virus infection. Both cell types also produced a structure composed of an electron-dense matrix in which nucleocapsids were embedded. Internally matured virions were released by exocytosis from these cells. In addition to a lack of cytopathic effect, u4.4 cells also failed to exhibit obvious morphogenetic changes upon infection. Virus particles were occasionally seen within vesicles, but budding at the cell surface was not detected. The mechanism of release of internally matured virions was not apparent. These studies provide further evidence that these three subcloned mosquito cell lines represent different tissues in the larval or adult insect.     

Adsorption of LLCMK2 cell-grown Sendai virus onto human red blood cells and its release from the virus adsorbed cells

An early stage of virus adsorption was studied in a system of Sendai virus metabolically labeled with [3H]leucine in LLCMK2 cells and of human red blood cells (RBCs). The efficiency of viral release from the virus-bound RBCs by incubation at 37 C depended on the number of virus particles which had been used for adsorption onto the RBC at 4 C. When 7.8 x 10(2) virus particles were previously adsorbed onto the RBC at 4 C, most of the viruses were dissociated from the RBC at 37 C. In the case of adsorption of 3 to 12 virus particles per RBC, however, most of the viruses were not dissociated from the RBC by incubation at 37 C. Such RBC-bound viruses were released by incubation with various bacterial neuraminidases (Clostridium perfringens, etc.) or with a large number of LLCMK2 cell-grown Sendai virus (LLCMK2-Sendai) particles, but not released by treatment with hemagglutinin-neuraminidase protein (Sendai-gp) isolated from egg-grown Sendai virus.     

Modification of cell membranes with viral envelopes during fusion of cells with HVJ (Sendai virus) : II. Effects of pretreatment with a small number of HVJ

Ehrlich ascites tumor cell membranes were completely modified after incubation at 37 °C for 30 min with a small dose of HVJ (about 0.7% of the maximum number of the virus particles that could be adsorbed onto the cells). After this treatment, the cells could adsorb further added HVJ onto their surfaces at 0 °C. But the cell agglutination which was induced by viral adsorption at 0 °C was very weak, and the interaction of the adsorbed virus with the lipid layer of the cell membrane at 37 °C preceding fusion or lysis of the cells was not strong. A discrepancy was observed between acquisition of the modification and liberation of sialic acid (destruction of viral receptors) by viral neuraminidase. The modification proceeded well on incubation at 37 °C but not at lower temperatures. The possibility that the modification is induced by fusion of viral envelopes with cell membranes is discussed.     

Herpes simplex viruses lacking glycoprotein D are unable to inhibit virus penetration: quantitative evidence for virus-specific cell surface receptors.

Herpes simplex virus (HSV) glycoprotein D (gD) plays an essential role in the entry of virus into cells. HSV mutants unable to express gD were constructed. The mutants can be propagated on VD60 cells, which supply the viruses with gD; however, virus particles lacking gD were produced in mutant-infected Vero cells. Virus particles with or without gD adsorbed to a large number (greater than 4 x 10(4] of sites on the cell surface; however, virions lacking gD did not enter cells. Cells pretreated with UV-inactivated virions containing gD (approximately 5 x 10(3) particles per cell) were resistant to infection with HSV type 1 (HSV-1) and HSV-2. In contrast, cells pretreated with UV-inactivated virions lacking gD could be infected with HSV-1 and HSV-2. If infectious HSV-1 was added prior to UV-inactivated virus particles containing gD, the infectious virus entered cells and replicated. Therefore, virus particles containing gD appear to block specific cell surface receptors which are very limited in number. Particles lacking gD are presumably unable to interact with these receptors, suggesting that gD is an essential receptor-binding polypeptide.     

Natural resistance-associated macrophage protein is a cellular receptor for sindbis virus in both insect and mammalian hosts

Alphaviruses, including several emerging human pathogens, are a large family of mosquito-borne viruses with Sindbis virus being a prototypical member of the genus. The host factor requirements and receptors for entry of this class of viruses remain obscure. Using a Drosophila system, we identified the divalent metal ion transporter natural resistance-associated macrophage protein (NRAMP) as a host cell surface molecule required for Sindbis virus binding and entry into Drosophila cells. Consequently, flies mutant for dNRAMP were protected from virus infection. NRAMP2, the ubiquitously expressed vertebrate homolog, mediated binding and infection of Sindbis virus into mammalian cells, and murine cells deficient for NRAMP2 were nonpermissive to infection. Alphavirus glycoprotein chimeras demonstrated that the requirement for NRAMP2 is at the level of Sindbis virus entry. Given the conserved structure of alphavirus glycoproteins, and the widespread use of transporters for viral entry, other alphaviruses may use conserved multipass membrane proteins for infection.     

Adsorption of Bacteriophages to Adhesions Between Wall and Membrane of Escherichia coli

In plasmolyzed Escherichia coli, wall and membrane adhered to one another at 200 to 400 localized areas. This number of specialized wall areas per cell was of the same order of magnitude as the total number of bacteriophage receptors. When bacteriophages T1 to T7 were adsorbed to the bacteria, they were seen to attach almost exclusively to these areas. Comparisons of the number of adsorbed phage particles observed in ultrathin sections and the expected number of phages per cell were in agreement. These results suggest a sharing of receptive areas by the various phages. Adsorption to the wall-membrane associations would permit the virus to release its nucleic acid at an area closest to the cell's protoplasmic contents.     

Isolation of a line of immortal chicken embryo fibroblasts after transfection with the nuclei of Rous sarcoma virus-transformed Chinese hamster cells

Secondary cultures of chicken embryo fibroblasts were transfected with purified nuclei from lysed cells of a clonal line of temperature-sensitive Rous sarcoma virus (tsRSV)-transformed Chinese hamster fibroblasts. After propagation for 3 months an established cell line designated ChR32 was obtained in one chicken cell culture. The cells of this line have been propagated so far for 18 months, whereas normal chicken embryo fibroblasts died after 2 months. The established cells were heteroploid with a diploid modal number of macrochromosomes and two Z chromosomes. No Chinese hamster chromosomes could be identified. Southern blot analysis of DNA from the uncloned ChR32 cells and the clones provided evidence that these established cells were, in fact, clonal in origin and contained full-length RSV proviruses and no defective proviruses. Furthermore, they contained, at the 3' end proviral-cellular junction, Bg/II, HpaI, KpnI, SacI, and XbaI fragments of the same size as the Chinese hamster donor cells, suggesting that the cellular sequence adjacent to the provirus is of Chinese hamster origin. The cells after establishment were able to grow continuously at 37 degrees or 41 degrees C and produce a large amount of ts sarcoma virus particles. A corollary finding was that these virus particles were non-leaky for the transforming function at the non-permissive temperature.     

Regional distribution of Sindbis virus glycoproteins on the plasma membrane of infected baby hamster kidney cells

Sindbis virus-infected baby hamster kidney (BHK) cells were analysed in surface replicas or conventional thin sections after specific immunolabelling with antiviral glycoprotein antibodies in conjunction with colloidal gold-conjugated protein A. Newly synthesized viral glycoproteins were detected, beginning 1 1/2 h after infection, while the virus maturation started 3 h after infection. The glycoproteins appeared to be inserted on the plasma membrane in large spots located mainly in the central area of the cells: no clustering of the labelling was detected. Later, the glycoproteins appeared to arrange linearly in regions in the medial portion of the cells. No labelling was found in the peripheral area or on the cell edges. A drastic change in the surface labelling was detected following the commencement of virus maturation: gold particles were organized mostly in small clusters, each labelling a budding virus. Very few glycoproteins appeared not to be involved in budding figures. The maturation of the virus was clearly regionalized, but during this time it also involved the peripheral area and the cell edges; preferential budding in narrow cellular processes was often observed. It appeared thus that either isolated glycoproteins soon after infection, or clustered glycoproteins at later times, are strictly regionalized on the plasma membrane: however, the early post-infection distribution is clearly different from that seen later during virus maturation. Our experiments support the concept of discrete plasma membrane domains even in cells that do not display distinct specialization of their surface.     

Conformational changes in Sindbis virus envelope proteins accompanying exposure to low pH.

The attachment of high multiplicities of Sindbis virus to tissue-cultured cells followed by brief treatment at low pH has been shown to produce cell fusion (fusion from without). In this report, experiments to determine the effects of low pH on the physical and biological properties of Sindbis virus are described. Exposure of purified Sindbis virions to mildly acidic conditions resulted in a rapid and irreversible alteration in particle density and sedimentation characteristics, followed by a slower loss of infectivity. Infectivity was not restored by a return to neutral pH; rather, the loss of virus infectivity seemed to be initiated by exposure to low pH but continued at neutral pH. The formation of a virus-cell complex in which virions were attached to the cell surface protected the particles from low-pH inactivation, although low pH could still expose virus functions responsible for cell fusion. Low pH was found to induce a conformational change in the E2 polypeptide of the intact virion. These results are discussed with respect to the process of Sindbis virus infection of tissue-cultured cells.     

Cerulenin blocks fatty acid acylation of glycoproteins and inhibits vesicular stomatitis and Sindbis virus particle formation

Cerulenin, an antibiotic that inhibits de novo fatty acid and cholesterol biosynthesis, effectively inhibited the formation and release of virus particles from chicken embryo fibroblasts infected with Sindbis or vesicular stomatitis virus (VSV). When added for 1 h at 3 h postinfection, the antibiotic blocked VSV particle production by 80 to 90% and inhibited incorporation of [3H]palmitic acid into the VSV glycoprotein by an equivalent amount. The effect of this antibiotic on virus protein and RNA biosynthesis was significantly less than that on fatty acid acylation. Nonacylated virus glycoproteins accumulated inside and on the surface of cerulenin-treated cells. These data indicate that fatty acid acylation is not essential for intracellular transport of these membrane proteins, but it may have an important role in the interaction of glycoproteins with membranes during virus assembly and budding.     

Adsorption of lymphocytes by cells infected by vaccinia virus]

The interaction of chicken lymphocytes with vaccinia-infected cells was examined HEp-2 cells infected with the virus adsorbed chicken lymphocytes. The phenomenon was inhibited by anti-vaccinia serum. Lymphocytes prepared from a chicken possessing red blood cells insensible to the hemagglutinin of vaccinia virus were also adsorbed. Lymphocytes were adsorbed in similar degree at 37 degrees C and at room temperature.     

Fluorescence photobleaching recovery measurements reveal differences in envelopment of sindbis and vesicular stomatitis viruses

Fluorescence photobleaching recovery (FPR) measurements of virus glycoproteins on the surfaces of cells infected with vesicular stomatitis virus (VSV) and Sindbis virus showed that the VSV glycoprotein (G) remained mobile throughout the infectious cycle, whereas Sindbis virus glycoproteins (E1, E2) were partially mobile early after infection and immobile at later times when greater amounts of these proteins were on the cell surface. A highly mobile fraction of Sindbis virus glycoproteins was detected throughout the replication cycle of a temperature-sensitive mutant unable to form virus particles. Thus immobilization of E1 and E2 was the result of increasing surface glycoprotein concentrations and virus budding. Together with other data, which included the detection of E1 and E2 in particles as soon as these proteins were transported to the cell surface, the FPR results suggest that Sindbis virus assembly initiates on intracellular vesicles, where glycoproteins aggregate and bind nucleocapsids. In contrast, our FPR data on VSV support a model previously suggested by others, in which a small fraction of cell-surface G is immobilized into budding sites formed by interactions with virus matrix and nucleoproteins. FPR measurements also provide direct evidence for strong interactions between E1 and E2, as well as between E1 and PE2, the precursor form of E2.     

Galactose-specific recognition system of mammalian liver: receptor distribution on the hepatocyte cell surface

An isolated perfused liver system was used to study the distribution of asialoglycoprotein (ASGP) binding sites on rat hepatocyte cell surfaces. The number of surface receptors was quantitated by monitoring clearance of 125I-labeled ligands from the perfusate medium under two conditions that blocked their internalization: low temperature (less than 5 degrees C) or brief formaldehyde fixation. The cell surface distribution of binding sites was visualized in the electron microscope with either asialoorosomucoid covalently coupled to horseradish peroxidase (ASOR-HRP) or lactosaminated ferritin (Lac-Fer), both of which were bound with similar kinetics and to similar extents as ASOR itself. At low temperature or after prefixation, ASGP binding sites were present over much of the sinusoidal cell surface, but were concentrated most heavily over coated pits. Quantitation of ligand distribution at 4 degrees C with Lac-Fer gave an approximately 70-fold greater density of ferritin particles over coated membrane than over uncoated regions. We obtained no evidence for gradual movement of ASGP receptors into or out of coated pits within the time-course of our experiments. Finally, the number and distribution of cell surface binding sites was unaffected by previous exposure to ASOR or by inhibition of endocytic vesicle-lysosome fusion and ASOR degradation at 16 degrees C.