Evidence against an important role for infectivity-enhancing antibodies in Ebola virus infections

The neutralizing and enhancing activities of Ebola virus (EBOV)-specific antibodies were tested among four murine antibodies specific to the surface glycoprotein (GP), a recombinant human monoclonal antibody specific to GP, a polyclonal equine IgG, and serum obtained from a convalescent monkey. All but one of these antibodies neutralized EBOV infectivity of primary human monocytes/macrophages or Vero cells. None of the antibodies enhanced EBOV infectivity in these cells. Taken together with in vivo observations that early deaths were not observed in animals immunized with various viral vectors expressing EBOV GP, it is unlikely that any EBOV-enhancing antibodies profoundly affected EBOV pathogenesis.     

The Ebola virus glycoprotein mediates entry via a non-classical dynamin-dependent macropinocytic pathway

Ebola virus (EBOV) has been reported to enter cultured cell lines via a dynamin-2-independent macropinocytic pathway or clathrin-mediated endocytosis. The route(s) of productive EBOV internalization into physiologically relevant cell types remain unexplored, and viral-host requirements for this process are incompletely understood. Here, we use electron microscopy and complementary chemical and genetic approaches to demonstrate that the viral glycoprotein, GP, induces macropinocytic uptake of viral particles into cells. GP's highly-glycosylated mucin domain is dispensable for virus-induced macropinocytosis, arguing that interactions between other sequences in GP and the host cell surface are responsible. Unexpectedly, we also found a requirement for the large GTPase dynamin-2, which is proposed to be dispensable for several types of macropinocytosis. Our results provide evidence that EBOV uses an atypical dynamin-dependent macropinocytosis-like entry pathway to enter Vero cells, adherent human peripheral blood-derived monocytes, and a mouse dendritic cell line.     

Ebola virus-like particles produced in insect cells exhibit dendritic cell stimulating activity and induce neutralizing antibodies

Recombinant baculoviruses (rBV) expressing Ebola virus VP40 (rBV-VP40) or GP (rBV-GP) proteins were generated. Infection of Sf9 insect cells by rBV-VP40 led to assembly and budding of filamentous particles from the cell surface as shown by electron microscopy. Ebola virus-like particles (VLPs) were produced by coinfection of Sf9 cells with rBV-VP40 and rBV-GP, and incorporation of Ebola GP into VLPs was demonstrated by SDS-PAGE and Western blot analysis. Recombinant baculovirus infection of insect cells yielded high levels of VLPs, which were shown to stimulate cytokine secretion from human dendritic cells similar to VLPs produced in mammalian cells. The immunogenicity of Ebola VLPs produced in insect cells was evaluated by immunization of mice. Analysis of antibody responses showed that most of the GP-specific antibodies were of the IgG2a subtype, while no significant level of IgG1 subtype antibodies specific for GP was induced, indicating the induction of a Th1-biased immune response. Furthermore, sera from Ebola VLP immunized mice were able to block infection by Ebola GP pseudotyped HIV virus in a single round infection assay, indicating that a neutralizing antibody against the Ebola GP protein was induced. These results show that production of Ebola VLPs in insect cells using recombinant baculoviruses represents a promising approach for vaccine development against Ebola virus infection.     

The properties of Ebola virus proteins

The paper describes the structure and functions of Ebola virus properties. It also presents information on the role of structural (NP, VP40, VP35, GP, VP30, VP24, and L) and secreted (sGP, delta-peptide, GP1, GP(1,2delta), ssGP) proteins in the viral replication cycle and in the pathogenesis of Ebola hemorrhagic fever.     

Immune mechanisms against canine distemper. I. Identification of K cell against canine distemper virus infected target cells in vitro.

Canine peripheral blood lymphocytes, polymorphonuclear leucocytes (PMN) and monocytes (macrophages) were obtained by various cell separation techniques and were tested for their cytotoxic capacity against antibody-sensitized canine distemper virus (CDV) infected Vero cells by an in vitro chromium release assay. Canine lymphocytes were found to destroy CDV infected target cells effectively, while neither PMN nor monocytes (macrophages) could do so. The active lymphocyte was characterized by various rosetting techniques to be a non-T and a non-B lymphocyte. These cells bear no surface immunoglobulin (SIg-) but possessed both Fc receptors (Fc+) and complement receptors (EAC+) suggesting that these cells are neither classical T nor B cells. The possible roles of this K cell in the resistance against canine distemper are discussed.     

Identification and mapping of single nucleotide polymorphisms in the varicella-zoster virus genome

We have analysed the expression and cellular localisation of the matrix protein VP40 from Ebola virus. Full-length VP40 and an N-terminal truncated construct missing the first 31 residues [VP40(31-326)] both locate to the plasma membrane of 293T cells when expressed transiently, while a C-terminal truncation of residues 213 to 326 [VP40(31-212)] shows only expression in the cytoplasm, when analysed by indirect immunofluorescence and plasma membrane preparations. In addition, we find that full-length VP40 [VP40(1-326)] and VP40(31-326) are both released into the cell culture supernatant and float up in sucrose gradients. The efficiency of their release, however, is dependent on the presence of the N-terminal 31 residues. VP40 that is released into the supernatant is resistant to trypsin digestion, a finding that is consistent with the formation of viruslike particles detected by electron microscopy. Together, these results provide strong evidence that Ebola virus VP40 is sufficient for virus assembly and budding from the plasma membrane.     

The creation of stable cell lines expressing Ebola virus glycoproteins and the matrix protein VP40 and generating Ebola virus-like particles utilizing an ecdysone inducible mammalian expression system

Ebola virus is a filovirus that causes hemorrhagic fever in humans and is associated with case fatality rates of up to 90%. The lack of therapeutic interventions in combination with the threat of weaponizing this organism has enhanced research investigations. The expression of key viral proteins and the production of virus-like particles in mammalian systems are often pursued for characterization and functional studies. Common practice is to express these proteins through transient transfection of mammalian cells. Unfortunately the transfection reagents are expensive and the process is time consuming and labour intensive. This work describes utilizing an ecdysone inducible mammalian expression system to create stable cell lines that express the Ebola virus transmembrane glycoprotein (GP), the soluble glycoprotein (sGP) and the matrix protein (VP40) individually as well as GP and VP40 simultaneously (for the production of virus like particles). These products were the same as those expressed by the transient system, by Western blot analysis and electron microscopy. The inducible system proved to be an improvement of the current technology by enhancing the cost effectiveness and simplifying the process.     

Ebola virus infection of human PBMCs causes massive death of macrophages, CD4 and CD8 T cell sub-populations in vitro

Ebola virus causes an often fatal disease characterized by poor immune response and high inflammatory reaction in the patients. One of the causes for poor immunity is virus-mediated apoptosis of lymphocytes in the host. In this study, we infected human PBMCs with Ebola Zaire virus and study apoptosis of different cell types using flow cytometry. We have shown that Ebola virus causes bystander death of CD4 and CD8 T cells. Cells infected with virus had 30-40% active caspase 3(+), annexin-V(+) and Bcl2(low) phenotype by day 8 PI as compared to inactivated virus-treated cells. 60-70% of the macrophages were also dead by day 8 PI and had similar phenotype. Our data also showed that virus may induce death signals in Fas(+)/FasL(+) T lymphocytes and macrophages but did not upregulate Fas/FasL expression in these cells. Lastly, CD4, CD8 and CD14 cells were purified after infection and were studied for death signals by RNAse protection assay. We found an upregulation of TRAIL mRNA in CD4 and CD8 T cells on day 7 PI. A two-fold increase in CD4 T cells and three-fold increase in CD8 T cells were observed in TRAIL mRNA levels as compared to uninfected controls and inactive virus-treated cells. Surprisingly, we did not find any difference in TRAIL mRNA levels between infected macrophages and uninfected controls. These data suggest that Ebola virus evades the immune response by causing massive lymphocyte death. In addition, they may give an explanation on why the host is unable to produce a good antibody response in the absence of CD4 T cells.     

Influence of calcium/calmodulin on budding of Ebola VLPs: implications for the involvement of the Ras/Raf/MEK/ERK pathway

The VP40 matrix protein of Ebola virus is able to bud from mammalian cells as a virus-like particle (VLP). Interactions between L-domain motifs of VP40 and host proteins such as Tsg101 and Nedd4 serve to facilitate budding of VP40 VLPs. Since intracellular levels of calcium are known to influence localization and function of host proteins involved in virus budding, we sought to determine, whether alterations of calcium or calmodulin levels in cells would affect budding of VP40 VLPs. VP40 VLP release was assessed in cells treated with BAPTA/AM, a calcium ion chelator, or with ionomycin, a calcium ionophore. In addition, VLP budding was assessed in cells treated with W7, W13, or TFP; all calmodulin antagonists. Results from these experiments indicated that: (i) budding of VP40 VLPs was reduced in a dose-dependent manner in the presence of BAPTA/AM, and slightly enhanced in the presence of ionomycin, (ii) VP40 VLP budding was reduced in a dose-dependent manner in the presence of W7, whereas VP40 VLP budding was unaffected in the presence of cyclosporine-A, (iii) budding of VSV-WT and a VSV recombinant (M40 virus) possessing the L-domains of Ebola VP40 was inhibited in the presence of W7, W13, or TFP, (iv) inhibition of virus budding by W7, W13, and TFP appears to be L-domain independent, and (v) the mechanism of calcium/calmodulin-mediated inhibition of Ebola VLP budding may involve the Ras/Raf/MEK/ERK signaling pathway.     

Electron microscopic and molecular characterization of turnip vein-clearing virus

Summary Cattle are proposed to be reservoir hosts of bluetongue virus (BTV) because infected animals typically have a prolonged cell-associated viremia. Enriched populations of bovine monocytes, erythrocytes and lymphocytes were inoculated with BTV serotype 10 (BTV 10) and the infected cells then were examined by transmission electron microscopy to characterize the interaction of BTV with bovine blood cells. Replication of BTV 10 in monocytes and stimulated (replicating) lymphocytes was morphologically similar to that which occured in Vero cells, with formation of viral inclusion bodies and virus-specific tubules. In contrast, BTV 10 infection of unstimulated (non-replicating) lymphocytes and erythrocytes did not progress beyond adsorption, after which virus particles persisted in invaginations of the cell membrane. Studies with core particles and neutralizing monoclonal antibodies established that outer capsid protein VP2 is necessary for attachment of BTV 10 to erythrocytes. These in vitro virus-cell interactions provide a cogent explanation for the pathogenesis of BTV infection of cattle, especially the prolonged cell associated viremia that occurs in BTV-infected cattle.     

DC-SIGN and DC-SIGNR bind ebola glycoproteins and enhance infection of macrophages and endothelial cells

Ebola virus exhibits a broad cellular tropism in vitro. In humans and animal models, virus is found in most tissues and organs during the latter stages of infection. In contrast, a more restricted cell and tissue tropism is exhibited early in infection where macrophages, liver, lymph node, and spleen are major initial targets. This indicates that cellular factors other than the broadly expressed virus receptor(s) modulate Ebola virus tropism. Here we demonstrate that the C-type lectins DC-SIGN and DC-SIGNR avidly bind Ebola glycoproteins and greatly enhance transduction of primary cells by Ebola virus pseudotypes and infection by replication-competent Ebola virus. DC-SIGN and DC-SIGNR are expressed in several early targets for Ebola virus infection, including dendritic cells, alveolar macrophages, and sinusoidal endothelial cells in the liver and lymph node. While DC-SIGN and DC-SIGNR do not directly mediate Ebola virus entry, their pattern of expression in vivo and their ability to efficiently capture virus and to enhance infection indicate that these attachment factors can play an important role in Ebola transmission, tissue tropism, and pathogenesis.     

Descriptive analysis of Ebola virus proteins

The virion proteins of two strains of Ebola virus were compared by SDS-polyacrylamide gel electrophoresis (PAGE) and radioimmunoprecipitation (RIP). Seven virion proteins were described; an L (180K), GP (125K), NP (104K), VP40 (40K), VP35 (35K), VP30 (30K), and VP24 (24K). The RNP complex of the virus contained the L, the NP, and VP30, with VP35 in loose association with them. The GP was the major spike protein, with VP40 and VP24 making up the remaining protein content of the multilayered envelope.     

Production and titration of African swine fever virus in porcine alveolar macrophages

The broncho-alveolar lavage of a pig (20–40 kg) contains about 1.6 × 10⁹ alveolar cells, half of which were macrophages. The number of cells in the lavage of bacille Calmette Guerin (BCG)-treated pigs increased about 4-fold. Both African swine fever virus-infected porcine alveolar macrophages and blood monocytes produced about 1000 hemadsorption units/cell, a value 10-fold larger than that obtained in virus-infected Vero cells. Porcine alveolar cells could be stored frozen and, after thawing, they could be infected with African swine fever virus, producing the same amount of virus as the unfrozen cells. With the number of alveolar macrophages obtained from a single pig it is possible to titer about 3000 virus samples with the same stock of alveolar macrophages.     

Production and characterization of monoclonal antibodies against different epitopes of Ebola virus antigens

Ebola virus (EBOV) causes hemorrhagic fever in humans and nonhuman primates with up to 90% mortality rate. In this study, Ebola virus like particles (EVLPs) and the aglycosyl subfragment of glycoprotein (GP(1) subfragment D) were used to generate monoclonal antibodies (MAbs) against different epitopes of the viral antigens. Such MAbs could be useful in diagnostics and potential therapeutics of viral infection and its hemorrhagic symptoms. Hybridoma cell fusion technology was used for production of MAbs. The MAbs were characterized using ELISA and Western blot analysis. Furthermore, five recombinant sub-domains of GP(1) subfragment D were produced, which were used as antigen in Western blot analysis for epitope mapping. Seventeen MAbs of different epitope specificities against EBOV antigens [virion protein (VP40), secreted glycoprotein (sGP), and GP(1) subfragment D] were developed. Based on epitope mapping studies, the anti-GP MAbs were categorized into six groups. The binding of the three anti-sGP MAbs with different epitope specificities were mostly between aa 157 and 221. The two anti-VP40 MAbs with the same or overlapping epitopes are potentially good candidates for developing antigen detection assays for early diagnosis of EBOV infection. The anti-GP MAbs with different epitope specificities as an oligoclonal cocktail could be tested for therapy.     

Activation of caprine arthritis-encephalitis virus expression during maturation of monocytes to macrophages.

Lentiviruses, which cause arthritis-encephalitis and maedi-visna in goats and sheep, respectively, cause persistent infections in these animals. The viruses replicate productively at low levels in macrophages in diseased organs such as the "maedi lung" and nonproductively in other cell types such as leukocytes in peripheral blood. Nonproductive infections become productive during in vitro cultivation of the cells. This study showed that monocytes were the only cells in the peripheral blood leukocytes of an infected animal in which virus was detected and that virus activation occurred only when these cells matured into macrophages. Only a minute fraction of cultured monocytes matured into macrophages, and viral infectivity was associated exclusively with this fraction. Antiglobulin-coated glass wool fragments were lethal for monocyte macrophages because of toxic phagocytosis, but had no effect on B or T lymphocytes. The simultaneous addition of the glass fragments and leukocytes to culture dishes resulted in no macrophage maturation and no virus production. The addition of the fragments to virus-producing macrophages caused the death of the cells and a decline in virus production. Virus production in less avidly phagocytic cells was unaffected by the glass. Thus, although macrophages may be permissive for virus replication, one mechanism for restricted virus expression in vivo may be physiological factors controlling the maturation of these cells.     

Association of Ebola-related Reston virus particles and antigen with tissue lesions of monkeys imported to the United States.

During 1989-1990, an epizootic involving a filovirus closely related to Ebola virus occurred in a Reston, Virginia, primate-holding facility. Tissues were collected from cynomolgus monkeys and examined by electron microscopy and immunohistochemistry for Ebola-related viral antigen. Viral replication was extensive in fixed tissue macrophages, interstitial fibroblasts of many organs, circulating macrophages and monocytes, and was observed less frequently in vascular endothelial cells, hepatocytes, adrenal cortical cells and renal tubular epithelium. Viral replication was observed infrequently in epithelial cells lining ducts or mucous membranes, intestinal epithelial cells, eosinophils and plasma cells. Replication of Reston virus in lymphocytes was never observed, in contrast to reports of lymphocytes of monkeys experimentally infected with the Ebola-Zaire virus. Free filoviral particles were seen in pulmonary alveoli and renal tubular lumina, which correlates with epidemiological evidence of droplet and fomite transmission. Viral infection of interstitial fibroblasts and macrophages caused multisystemic disruptive lesions involving connective tissue. Focal necrosis in organs where viral replication was minimal may have been secondary to ischaemia caused by fibrin deposition and occasional platelet-fibrin thrombi. Immunoelectron microscopy on sections of liver, differentiated viral tubular inclusion masses and precursor material from non-viral tubuloreticular inclusions. Immunohistochemistry showed that the distribution of viral antigen in affected tissue correlated well with ultrastructural localization of virions.     

Lassa and Mopeia virus replication in human monocytes/macrophages and in endothelial cells: different effects on IL-8 and TNF-alpha gene expression.

Cells of the mononuclear and endothelial lineages are targets for viruses which cause hemorrhagic fevers (HF) such as the filoviruses Marburg and Ebola, and the arenaviruses Lassa and Junin. A recent model of Marburg HF pathogenesis proposes that virus directly causes endothelial cell damage and macrophage release of TNF-alpha which increases the permeability of endothelial monolayers [Feldmann et al. , 1996]. We show that Lassa virus replicates in human monocytes/macrophages and endothelial cells without damaging them. Human endothelial cells (HUVEC) are highly susceptible to infection by both Lassa and Mopeia (a non-pathogenic Lassa-related arenavirus). Whereas monocytes must differentiate into macrophages before supporting even low level production of these viruses, the virus yields in the culture medium of infected HUVEC cells reach more than 7 log10 PFU/ml without cellular damage. In contrast to filovirus, Lassa virus replication in monocytes/macrophages fails to stimulate TNF-alpha gene expression and even down-regulates LPS-stimulated TNF-alpha mRNA synthesis. The expression of IL-8, a prototypic proinflammatory CXC chemokine, was also suppressed in Lassa virus infected monocytes/macrophages and HUVEC on both the protein and mRNA levels. This contrasts with Mopeia virus infection of HUVEC in which neither IL-8 mRNA nor protein are reduced. The cumulative down-regulation of TNF-alpha and IL-8 expression could explain the absence of inflammatory and effective immune responses in severe cases of Lassa HF.     

Filovirus budding

Family Filoviridae, which includes Ebola virus (EBOV) and Marburg virus (MARV), is a growing threat to human and non-human primate populations in central Africa. Although many facets of the filovirus life cycle remain to be deciphered, a great deal has been learned in recent years. In particular, a clearer understanding of the roles played by viral, as well as cellular, proteins in the assembly and budding processes has been achieved. This review will discuss the current state of filovirus budding research, with especial emphasis placed on the viral matrix protein VP40 and its relationship with the cellular vesicular sorting pathway. Possible budding functions of the viral glycoprotein (GP), as well as the membrane-associated viral protein 24 (VP24), will also be described, and a model for filovirus budding will be proposed.