Michael Hevey

Lipid Raft Microdomains A Gateway for Compartmentalized Trafficking of Ebola and Marburg Viruses

Spatiotemporal aspects of filovirus entry and release are poorly understood. Lipid rafts act as functional platforms for multiple cellular signaling and trafficking processes. Here, we report the compartmentalization of Ebola and Marburg viral proteins within lipid rafts during viral assembly and budding. Filoviruses released from infected cells incorporated raft-associated molecules, suggesting that viral exit occurs at the rafts. Ectopic expression of Ebola matrix protein and glycoprotein supported raft-dependent release of filamentous, virus-like particles (VLPs), strikingly similar to live virus as revealed by electron microscopy. Our findings also revealed that the entry of filoviruses requires functional rafts, identifying rafts as the site of virus attack. The identification of rafts as the gateway for the entry and exit of filoviruses and raft-dependent generation of VLPs have important implications for development of therapeutics and vaccination strategies against infections with Ebola and Marburg viruses.

Comparison of individual and combination DNA vaccines for B. anthracis, Ebola virus, Marburg virus and Venezuelan equine encephalitis virus.

Multiagent DNA vaccines for highly pathogenic organisms offer an attractive approach for preventing naturally occurring or deliberately introduced diseases. Few animal studies have compared the feasibility of combining unrelated gene vaccines. Here, we demonstrate that DNA vaccines to four dissimilar pathogens that are known biowarfare agents, Bacillus anthracis, Ebola (EBOV), Marburg (MARV), and Venezuelan equine encephalitis virus (VEEV), can elicit protective immunity in relevant animal models. In addition, a combination of all four vaccines is shown to be equally as effective as the individual vaccines for eliciting immune responses in a single animal species. These results demonstrate for the first time the potential of combined DNA vaccines for these agents and point to a possible method of rapid development of multiagent vaccines for disparate pathogens such as those that might be encountered in a biological attack.

Generation of Marburg virus-like particles by co-expression of glycoprotein and matrix protein

Marburg virus (MARV), the causative agent of a severe hemorrhagic fever, has a characteristic filamentous morphology. Here we report that co-expression of MARV glycoprotein and matrix protein (VP40) in mammalian cells leads to spontaneous budding of filamentous particles strikingly similar to wild-type MARV. In addition, these particles elicit an immune response in BALB/c mice. The generation of non-replicating Marburg virus-like particles (VLPs) should significantly facilitate the research on molecular mechanisms of MARV assembly and release. Furthermore, VLPs may be an excellent vaccine candidate against Marburg infection.

Marburg virus vaccines: comparing classical and new approaches.

An effort to develop a safe and effective vaccine for Marburg virus (MBGV), one of the filoviruses known to cause high mortality rates in humans, led us to compare directly some of the merits of modern versus classical vaccine approaches for this agent. Prior work had established the MBGV-glycoprotein (GP), the only known virion surface antigen, as a candidate for inclusion in a vaccine. In this study, we vaccinated groups of Hartley guinea pigs with killed MBGV, live attenuated MBGV, soluble MBGV-GP expressed by baculovirus recombinants, MBGV-GP delivered as a DNA vaccine, or MBGV-GP delivered via an alphavirus RNA replicon. Serological responses were evaluated, and animals were challenged with a lethal dose of MBGV given either subcutaneously or via aerosol. Killed MBGV and replicon-delivered MBGV-GP were notably immunogenic and protective against MBGV, but results did not exclude any approach and suggested a role for DNA vaccines in immunological priming.

Characterization of monoclonal antibodies to Marburg virus (strain Musoke) glycoprotein and identification of two protective epitopes.

Monoclonal antibodies (MAbs) reactive with Marburg virus (strain Musoke) were evaluated for both biological activity and specificity. Several of the Marburg virus- (MBGV) specific MAbs reduced the size and/or number of MBGV plaques in vitro. The ability of the MAbs to affect plaque formation in vitro was demonstrated to be specific for the glycoprotein (GP) of the strain of MBGV used for vaccination. Using deletion analysis and peptide mapping, the binding epitopes of several of these neutralizing MAbs were identified. Not unexpectedly, the epitopes were shown to lie in the most hypervariable and highly glycosylated region of MBGV GP. An analysis of the in vivo activity of several MAbs revealed that some antibodies provided substantial but incomplete protection of naive guinea pigs by passive transfer. These data suggest that neutralizing epitopes exist within MBGV GP but that induction of antibodies to these neutralizing epitopes may not be sufficient for protection from lethal infection.

Genomic Differences between Guinea Pig Lethal and Nonlethal Marburg Virus Variants

The complete genome sequences of 2 closely related plaque-derived variants of Marburg virus (MARV) species Lake Victoria marburgvirus, strain Musoke, indicate only a few regions of the RNA genome as underlying the differences between the 2 viruses. One variant is >90% lethal for guinea pigs and the other much less virulent, when guinea pigs are challenged with 1000 pfu of virus. Only 4 mutations that result in amino acid changes were identified, 1 in viral matrix protein VP40 and 3 in L, the RNA-dependent RNA polymerase. In addition, 6 differences were identified in noncoding regions of transcribed mRNA, and 1 silent codon change was identified in the L gene. Interestingly, the amino acid mutation identified in VP40 occurs in a nonconserved loop structure between 2 domains that are homologues only among MARV species. The L gene mutations were equally intriguing, clustering near a highly conserved motif in viral RNA-dependent RNA polymerases.

Quantitative studies of heteropolymer-mediated binding of inactivated Marburg virus to the complement receptor on primate erythrocytes.

Previous in vitro and in vivo experiments in our laboratory have demonstrated that cross-linked bispecific monoclonal antibody (mAb) complexes (Heteropolymers, HP) facilitate binding of prototype pathogens to primate erythrocytes (E) via the E complement receptor, CR1. These E-bound immune complexes are safely and rapidly cleared from the bloodstream. In order to generate a robust bispecific system for HP-mediated clearance of real pathogens such as Filoviruses, we have developed the necessary methodologies and reagents using both inactivated Marburg virus (iMV) and a recombinant form of its surface envelope glycoprotein (rGP). We identified mAbs which bind rGP in solution phase immunoprecipitation experiments. HP were prepared by chemically cross-linking an anti-CR1 mAb with several of these anti-Marburg virus mAbs and used to facilitate binding of iMV and rGP to monkey and human E. These HP mediate specific and quantitative binding (> or = 90%) of both antigens to monkey and human E. Binding was also demonstrable in an indirect RIA. E with bound Marburg virus were probed with 125I labeled mAbs to the Marburg surface glycoprotein and more than 100 mAbs are bound per E. It should be possible to adapt this general approach to other pathogens, and experiments underway should lead to an in vivo test of HP-mediated clearance of Marburg virus.

Medical Countermeasures for Filoviruses and Other Viral Agents

Many viruses were considered historically and have been reconsidered recently as potential agents of great harm, through intentional release as weapons of biological warfare or bioterrorism. Two such lists, of which several circulate, are shown in Table 1. Another variation, a recent prioritization of concerns by the National Institute of Allergy and Infectious Disease (NIAID), is shown in Table 2. The discerning reader may note that regarding certain viral agents, different listings may appear wildly or illogically discordant. Conflicting perspectives will not be resolved herein: a consideration of the particular threat characteristics, diseases, vaccines, and treatments for even these truncated rosters of viral agents is well beyond the scope of this chapter. It suffices to note that priorities and concerns are drawn from imprecise and sometimes disputed information about these viruses in myriad areas, including the medical consequences of infection in terms of morbidity and mortality; the feasibility and ease of agent production; the minimal viral dose required to cause disease; the stability of the virus in storage and in aerosol form; the contagiousness or limited transmissibility of the virus via contacts of infected persons; the current availability of medical countermeasures; the ease by which individuals or groups may acquire the virus; and credible intelligence information indicating past or present weaponization. Variola virus, causative agent of smallpox, is considered separately in this volume. Here, emphasis is on the filoviruses Marburg virus (MARV) and Ebola virus (EBOV); these are among the most frightening of natural viral threat agents, not as contagious as variola virus, but more deadly, and uncontrolled by any currently available vaccine or therapy. Genetically engineered viruses are not considered here, nor are agents that have serious but solely indirect effects on humans through their impacts on agriculture or environment.