Ebola Virus NEU2011: Difference between revisions

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<h3> Ecology </h3>
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[[File:ebola_ecology.jpg‎|300px|thumb|right|d. Distribution of Marbug virus diseas incidents in Africa 1967-1996 [10]]]
<p> EBOV thrives in tropical regions where rivers and lakes are surrounded by dense vegetation. Based on outbreak frequency, the environment and climate in sub-Saharan African appears most ideal – the vast majority of EBOV outbreaks occurred in this region. Also, the lack of effective sanitation and poor living conditions of this region contribute to the spread of the virus [10].</p>
<p> EBOV thrives in tropical regions where rivers and lakes are surrounded by dense vegetation. Based on outbreak frequency, the environment and climate in sub-Saharan African appears most ideal – the vast majority of EBOV outbreaks occurred in this region. Also, the lack of effective sanitation and poor living conditions of this region contribute to the spread of the virus [10].</p>
<p> Possible reservoirs for EBOV include bats, monkeys, and spiders. This conclusion was made based on multiple cases where cultures from bites by these few animals contained EBOV. Bats as a reservoir presents an unusual opportunity for the virus to transfer itself to arthropods as well as a multitude of mammals who could have contact with humans [10].</p>
<p> Possible reservoirs for EBOV include bats, monkeys, and spiders. This conclusion was made based on multiple cases where cultures from bites by these few animals contained EBOV. Bats as a reservoir presents an unusual opportunity for the virus to transfer itself to arthropods as well as a multitude of mammals who could have contact with humans [10].</p>

Revision as of 03:45, 1 April 2011

Ebola Virus

a. Scanning electron micrograph (SEM) depicts a number of Ebola virions (1/3/2008)

Classification


Class: Class V - ssRNA negative-strand viruses
Order: Mononegavirales
Family: Filoviridae
Genus: Ebolavirus
Species: Zaire ebolavirus

[1](based on Baltimore classification system)

Description and Significance

b. Ebolavirus (2/11/2009)

The viral family Filoviridae consists of two distinct genuses, Marburgvirus and Ebolavirus. The family name, from the Latin "filum" meaning "thread" or "filament", describes the threadlike structure of the organisms. Filoviruses are negative-strand RNA viruses, usually between 850 and 920nm in length [2]. In the Ebolavirus genus, four distinct species have been identified, three of which co-circulate in Africa, and are known human pathogens [3].

The Ebola virus (EBOV) strains were first identified in Africa in 1976. Two epidemics occurred almost simultaneously in Zaire and Sudan, killing almost 500 people. In Zaire, an outbreak at a local hospital, possibly due to contaminated hypodermic needles, exhibited an 88% mortality rate for those infected. The predominant symptoms of the virus were hemorrhagic fever and damage to the endothelial cells that form the linings of blood vessels, characterized by severe internal and sometimes external bleeding. The responsible strain was identified and named Ebola, after the Ebola River region where the epidemic occurred. This strain of the virus is referred to as the Zaire virus, and is the type species for the genus [4,5].

Since its discovery over 30 years ago, EBOV research has elucidated much about the mechanism by which an Ebola outbreak occurs. Since the epidemic in Zaire, several more cases have been observed in humans and animals, though no other strain has proved as deadly as that isolated from the Ebola River area [3]. While research has significantly expanded knowledge about how the virus survives between epidemics and how it is passed to human populations, much is still unknown about EBOV. With the modern advent of biological warfare, the contagiousness and lethality of EBOV makes it a potential weapon of bioterrorism [6]. Therefore, further research is important to understand and hopefully identify a vaccine for EBOV, to protect against future epidemics.

Genome Structure

c. Structure of Ebolavirus genome (2/11/2009)

The Ebola genome, as with that of other members of Mononegavirales, is a non-segmented and consists of a single molecule of linear, negative-strand ssRNA. The genome is approximately 19kb long, and constitutes about 1.1% of the viral weight [1, 7, 8].

The Ebola genome has 7 known nucleotide sequences that code for structural and non-structural proteins also known as VPs. The core of the virus is made up of RNA genomic molecules comprised of nucleoprotein (NP) [7].

There are several types of VPs, each with a different function. VP30 proteins play an important role in RNA transcription activation, which is strongly dependent on the concentration of VP30. VP24 the primary matrix protein, and is the most abundant virion component. Its role is unclear. VP35 plays an important role in viral RNA synthesis. It acts as a type of interferon antagonist. VP40 is a matrix protein from the negative strand of RNA. It mainly participates in the assembly of lipid-enveloped viruses by providing a link between the surrounding membrane and the nucleocapsid structure. The protein GP, also known as single surface transmembrane GP, is responsible for attachment and entry into the target cell. The L protein is a non-segmented negative strand RNA, it plays an essential role in catalyzing transcription. The L protein is a RNA-dependent RNA polymerase [1, 7].

All gene expression required for viral replication is carried out within the Ebola virion, with no participation by the host-cell enzymes. Nucleotide sequences at the 3’-terminus are complimentary to similar regions of genetic code in the 5’-end, which does not have a cap. The 3’-end also has no poly(A) trail. Transcription occurs from the 3’-end and results in seven to nine mRNA strands. The Ebola amino acids identity is distinct from that of other Filoviridae viruses, evidenced by its unique method of entry into the host-cell [1, 7].

Structure and Metabolism


The EBOV is an enveloped, non-segmented, negative-strand RNA virus. Glycoprotein is the sole resident of the EBOV surface, and is made up of carbohydrate chains called glycans. In its active form, EBOV glycoprotein (GP) has 2 subunits with separate structural and functional roles: GP1, which effects the attachment to host cells, and GP2, which mediates fusion of viral and host membranes. EBOV is thought to enter host cells by receptor-mediated endocytosis through clathrin-coated pits and caveolae, followed by actin- and microtubule-dependent transport to the endosome.

Crystal structure reveals that most of GP is shielded by a thick coat of carbohydrates and identified very few sites left exposed and available for antibody binding [9].

Ecology


d. Distribution of Marbug virus diseas incidents in Africa 1967-1996 [10]

EBOV thrives in tropical regions where rivers and lakes are surrounded by dense vegetation. Based on outbreak frequency, the environment and climate in sub-Saharan African appears most ideal – the vast majority of EBOV outbreaks occurred in this region. Also, the lack of effective sanitation and poor living conditions of this region contribute to the spread of the virus [10].

Possible reservoirs for EBOV include bats, monkeys, and spiders. This conclusion was made based on multiple cases where cultures from bites by these few animals contained EBOV. Bats as a reservoir presents an unusual opportunity for the virus to transfer itself to arthropods as well as a multitude of mammals who could have contact with humans [10].

Pathology


EBOV is an extremely aggressive pathogen, causing hemorrhagic fever syndrome in humans and non-human primates. Since its recognition in 1976, semi-regular outbreaks in Africa have exhibited 50-90% mortality rates. There is no treatment or vaccine for EBOV, and due to the sampling difficulty and highly hazardous nature of the virus, little is known about its specific mechanism of pathogenicity. However, the symptoms and clinical course of infection are well documented [11].

Research indicates that the viral GP is an important factor in EBOV infection. The two forms of GP synthesized by the virus have different structural and chemical properties, and both appear to contribute to infection in different ways. The full-length transmembrane GP binds preferentially to endothelial cells in the lining of blood vessels, causing sever cell damage and the mass hemorrhagic associated with the disease. Secreted GP (sGP) appears to interact with the host cell neutrophils, which may interfere with the immune system’s ability to recognize the virus in the early days of infection. This evasion, coupled with EBOV’s unusually high replication rate, quickly overwhelms the host’s immune system [11].

The EBOV infection generally lasts 2 to 3 weeks. Early symptoms mimic the flu and include fever and malaise. However, rapid disease progression leads to severe bleeding, reduced blood coagulation, and a diverse array of other hematological symptoms such as lymphopenia. Late in the course of the disease, the virus attacks the liver and vascular endothelium, leading to the diffuse bleeding and hypotensive shock that most often are the direct cause of death [11].

Current Research


Current research on EBOV focuses on the virus’ natural reservoir as well as its methods of transference. Due to the various challenges in studying such a lethal pathogen, little is known about the virus’ natural habitat or how it is spread. Research developing anti-viral medicines and vaccines against EBOV is also underway.

Research on an EBOV vaccine has been underway for quite some time. In a recent break-through, researchers at the Howard Hughes Medical Institute infected guinea pigs with the EBOV and injected them with a DNA vaccine made up of plasmids containing the EBOV protein. The animals resisted infection for two to four months after the immunization with the experimental vaccine [12].

The virus vaccine itself creates an immune response to the proteins of the outer envelope. This is initiated by injecting the vaccine into the muscle tissue of the animal and allowing the plasmid for this protein to be taken up by the animal cell. Once expressed, the immune system’s T cell based response was sufficient enough to stop the virus [12].



References


  1. ICTVdB Management (2006). 01.025.0.02.Ebolavirus. In: ICTVdB - The Universal Virus Database, version 4. Büchen-Osmond, C. (Ed), Columbia University, New York, USA
  2. Regnery, R.L., K.M. Johnson, and M.P. Kiley, Marburg and Ebola viruses: possible members of a new group of negative-strand viruses. The replication of negative-strand viruses, 1981: p. 971-977.
  3. Pourrut, X., et al., The natural history of Ebola virus in Africa. Microbes and Infection, 2005. 7: p. 1005-1014.
  4. McCormick, J.B., et al., Biologic Differences between Strains of Ebola Virus from Zaire and Sudan. The Journal of Infectious Diseases, 1983. 147(2): p. 264-267.
  5. Heymann, D.L., et al., Ebola Hemorrhagic Fever: Tandala, Zaire, 1977-1978. The Journal of Infectious Diseases, 1980. 142(3): p. 372-376.
  6. Groseth, A., et al., Hemorrhagic Fever Viruses as Biological Weapons, in Bioterrorism and Infectious Agents: A New Dilemma for the 21st Century, I.W. Fong and K. Alibek, Editors. 2009, Springer New York. p. 169-191.
  7. Ascenz, P., et al. Ebolavirus and Marburgvirus: Insight the Filoviridae Family. Molecular Aspects of Medicine. 2008. 29(3): p. 151-85.
  8. Paustian. "19-20 Ebola Is a Filamentous Virus with a Single-stranded RNA Genome." The Microbial World :: A Look at All Things Small. 08 Nov. 2008. Web. 21 Feb. 2011. link
  9. Lee, J.E. et al. Structure of the Ebola virus glycoprotein bound to an antibody from a human survivor. Nature, 2008. 454(7201): 177-182
  10. Monath, T.P. Ecology of Marburg and Ebola Viruses: speculations and directions for future research. 1999. 179(1): 127-138.
  11. Sullivan, N., Zhi-Young Y. and G. J. Nabel. Ebola Virus Pathogenesis: Implications for Vaccines and Therapies. Journal of Virology. 2003. 77(18): p.9733-9737.
  12. Henahan, S. [

Images a, b courtesy of Center for Biological Counterterrorism and Emerging Diseases CBC-ED image gallery
Image c courtesy of The Microbial World