Ebola virus (EBOV) causes hemorrhagic fever, resulting in mortality rates as high as 90% among infected humans and non-human primates (NHPs). The 2014 Ebola epidemic in West Africa is the severest in history, leading to WHO taking all control measures to stop any possibility of cross-border outbreaks. Because no licensed vaccines or effective therapeutics against EBOV are available, the current outbreak management has been limited to palliative care and barrier methods to prevent transmission. Several promising experimental EBOV vaccines have demonstrated protection in NHPs against lethal EBOV challenge, and some progresses have been made through clinical trials of EBOV vaccine candidates. It is believed there will be some licensed vaccine available in the near future to control EBOV outbreaks. In this review we provide some insights for further development of EBOV vaccines.
Animals ; Ebola Vaccines ; Ebolavirus ; Hemorrhagic Fever, Ebola ; prevention & control ; Humans

Since the first case of Ebola virus disease (EVD) in Guinea was reported in March 2014 by World Health Organization (WHO), the outbreak has continued through the year and the total number of 19,065 patients was reported as the confirmed or suspected in the EVD-affected countries. Among the cases, 7,388 patients were reported death by 19 December. Currently, available therapeutics to treat the infected patients or vaccines to prevent people from infection is not developed yet while viral diagnostic methods were already developed and firmly established in a lot of countries as a first step for the preparedness of Ebola outbreak. Some potential therapeutic materials including ZMapp were supplied and the treated people got over the EVD. Several candidates of vaccines also were investigated their efficacy in animal models by National Institute of Health (NIH) and Department of Defense, and they are processing of clinical tests in West Africa aiming to finish the development by the 2015. Vaccine and therapeutic development is essential to stop the EVD outbreak in West Africa, also to protect the world from the risk which can be generated by potential spread of Ebola virus.
Africa, Western ; Ebolavirus ; Guinea ; Hemorrhagic Fever, Ebola ; Humans ; Models, Animal ; Vaccines ; World Health Organization

The Ebola virus belongs to the Filovirus family, which causes Ebola hemorrhagic fever (mortality, 25%-90%). An outbreak of infection by the Ebola virus is sweeping across West Africa, leading to high mortality and worldwide panic. The Ebola virus has caused a serious threat to public health, so intensive scientific studies have been carried out. Several vaccines (e.g., rVSV-ZEBOV, ChAd3-ZEBOV) have been put into clinical trials and antiviral drugs (e.g., TKM-Ebola, ZMAPP) have been administered in the emergency setting to patients infected by the Ebola virus. Here, recent advances in vaccines and drugs against the Ebola virus are reviewed.
Animals ; Antiviral Agents ; administration & dosage ; Ebola Vaccines ; administration & dosage ; genetics ; immunology ; Ebolavirus ; drug effects ; genetics ; immunology ; physiology ; Hemorrhagic Fever, Ebola ; drug therapy ; prevention & control ; virology ; Humans

No abstract available.
Antiviral Agents/therapeutic use ; Hemorrhagic Fever, Ebola/drug therapy/*prevention & control/virology ; Humans ; Protective Devices ; Vaccines/immunology

No abstract available.
Antiviral Agents/therapeutic use ; Hemorrhagic Fever, Ebola/drug therapy/*prevention & control/virology ; Humans ; Protective Devices ; Vaccines/immunology

The 2014 outbreak of Ebola virus disease (EVD) in West Africa, caused by Ebola virus (Zaire Ebola virus species), is the largest outbreak of EVD in history. It cause hemorrhagic fever in human and nonhuman primates with high mortality rate up to 90% and can be transmitted by direct contact with blood, body fluids, skin of EVD patients or persons who have died of EVD. As of December 17, 2014, 450 healthcare personnel are known to have been infected with Ebola, of whom 244 died. For development of Ebola vaccine and treatment are highly difficult due to its dangerous and accessibility that requires biosafety level 4 (BSL-4) to conduct experiment. Also there is no specific vaccine and treatment for Ebola virus; however, many candidate vaccines and antiviral-drugs such as ZMapp and TKM-Ebola are being developed for Ebola virus disease. In this review, we focus on the epidemiology of 2014 outbreak of Ebola virus and candidate agent for preventing and curing from Ebola virus.
Africa, Western* ; Body Fluids ; Delivery of Health Care ; Ebolavirus* ; Epidemiology ; Fever ; Hemorrhagic Fever, Ebola ; Humans ; Mortality ; Primates ; Skin ; Vaccines

PURPOSE: The goal of this study was to purify and characterize Ebola virus glycoprotein (GP)-specific IgG antibodies from hybridoma clones. MATERIALS AND METHODS: For hybridoma production, mice were injected by intramuscular-electroporation with GP DNA vaccines, and boosted with GP vaccines. The spleen cells were used for producing GP-specific hybridoma. Enzyme-linked immunosorbent assay, Western blot assay, flow cytometry, and virus-neutralizing assay were used to test the ability of monoclonal IgG antibodies to recognize GP and neutralize Ebola virus. RESULTS: Twelve hybridomas, the cell supernatants of which displayed GP-binding activity by enzyme-linked immunosorbent assay and the presence of both IgG heavy and light chains by Western blot assay, were chosen as a possible IgG producer. Among these, five clones (C36-1, D11-3, D12-1, D34-2, and E140-2) were identified to secrete monoclonal IgG antibodies. When the monoclonal IgG antibodies from the 5 clones were tested for their antigen specificity, they recognized GP in an antigen-specific and IgG dose-dependent manner. They remained reactive to GP at the lowest tested concentrations (1.953–7.8 ng/mL). In particular, IgG antibodies from clones D11-3, D12-1, and E140-2 recognized the native forms of GP expressed on the cell surface. These antibodies were identified as IgG1, IgG2a, or IgG2b kappa types and appeared to recognize the native forms of GP, but not the denatured forms of GP, as determined by Western blot assay. Despite their GP-binding activity, none of the IgG antibodies neutralized Ebola virus infection in vitro, suggesting that these antibodies are unable to neutralize Ebola virus infection. CONCLUSION: This study shows that the purified IgG antibodies from 5 clones (C36-1, D11-3, D12-1, D34-2, and E140-2) possess GP-binding activity but not Ebola virus-neutralizing activity.
Animals ; Antibodies* ; Antibody Formation ; Blotting, Western ; Clone Cells ; Ebolavirus* ; Enzyme-Linked Immunosorbent Assay ; Flow Cytometry ; Glycoproteins* ; Hemorrhagic Fever, Ebola ; Hybridomas ; Immunoglobulin G* ; In Vitro Techniques ; Mice ; Sensitivity and Specificity ; Spleen ; Vaccines ; Vaccines, DNA

PURPOSE: The goal of this study was to investigate the utility of DNA vaccines encoding Ebola virus glycoprotein (GP) as a vaccine type for the production of GP-specific hybridomas and antibodies. MATERIALS AND METHODS: DNA vaccines were constructed to express Ebola virus GP. Mice were injected with GP DNA vaccines and their splenocytes were used for hybridoma production. Enzyme-linked immunosorbent assays (ELISAs), limiting dilution subcloning, antibody purification methods, and Western blot assays were used to select GP-specific hybridomas and purify monoclonal antibodies (MAbs) from the hybridoma cells. RESULTS: Twelve hybridomas, the cell supernatants of which displayed GP-binding activity, were selected by ELISA. When purified MAbs from 12 hybridomas were tested for their reactivity to GP, 11 MAbs, except for 1 MAb (from the A6-9 hybridoma) displaying an IgG2a type, were identified as IgM isotypes. Those 11 MAbs failed to recognize GP. However, the MAb from A6-9 recognized the mucin-like region of GP and remained reactive to the antigen at the lowest tested concentration (1.95 ng/mL). This result suggests that IgM-secreting hybridomas are predominantly generated by DNA vaccination. However, boosting with GP resulted in greater production of IgG-secreting hybridomas than GP DNA vaccination alone. CONCLUSION: DNA vaccination may preferentially generate IgM-secreting hybridomas, but boosting with the protein antigen can reverse this propensity. Thus, this protein boosting approach may have implications for the production of IgG-specific hybridomas in the context of the DNA vaccination platform. In addition, the purified monoclonal IgG antibodies may be useful as therapeutic antibodies for controlling Ebola virus infection.
Animals ; Antibodies ; Antibodies, Monoclonal ; Antibody Formation ; Blotting, Western ; Clinical Coding* ; DNA* ; Ebolavirus* ; Enzyme-Linked Immunosorbent Assay ; Glycoproteins* ; Hemorrhagic Fever, Ebola ; Hybridomas* ; Immunization* ; Immunoglobulin G ; Immunoglobulin M ; Mice ; Vaccination ; Vaccines, DNA*