Ebola virus information

From Wikipedia, the free encyclopedia

For the genus, see Ebolavirus. For the current outbreak, see 2014 West Africa Ebola outbreak.

Species Zaire ebolavirus
Virus classification
Group:	Group V ((-)ssRNA)
Order:	Mononegavirales
Family:	Filoviridae
Genus:	Ebolavirus
Species:	Zaire ebolavirus
Member virus (Abbreviation)
Ebola virus (EBOV)

Ebola
Classification and external resources
ICD-10	A98.4
ICD-9	065.8
DiseasesDB	18043
MedlinePlus	001339
eMedicine	med/626
MeSH	D019142

Ebola virus (formerly officially designated Zaire ebolavirus, or EBOV) is a virological taxon species included in the genus Ebolavirus, family Filoviridae, members are called Filovirus,^[1] the order is Mononegavirales.^[2] The Zaire ebolavirus is the most dangerous of the five species of Ebola viruses of the Ebolavirus genus which are the causative agents of Ebola virus disease.^[2] The virus causes an extremely severe hemorrhagic fever in humans and other primates. EBOV is a select agent, World Health Organization Risk Group 4 Pathogen (requiring Biosafety Level 4-equivalent containment), a U.S. National Institutes of Health/National Institute of Allergy and Infectious Diseases Category A Priority Pathogen, U.S. CDC Centers for Disease Control and Prevention Category A Bioterrorism Agent, and listed as a Biological Agent for Export Control by the Australia Group.
The name Zaire ebolavirus is derived from Zaire (the country in which the Ebola virus was first discovered) and the taxonomic suffix ebolavirus (which denotes an ebolavirus species).^[2]

Virology

The EBOV genome is approximately 19 kb in length. It encodes seven structural proteins: nucleoprotein (NP), polymerase cofactor (VP35), (VP40), GP, transcription activator (VP30), VP24, and RNA polymerase (L).^[3]

Structure

Electron micrographs of EBOV show them to have the characteristic threadlike structure of a filovirus.^[4] EBOV VP30 is around 288 amino acids long.^[5] The virions are tubular in general form but variable in overall shape and may appear as the classic shepherd's crook or eyebolt, as a U or a 6, or coiled, circular, or branched; laboratory techniques, such as centrifugation, may be the origin of some of these formations.^[6] Virions are generally 80 nm in diameter with a lipid bilayer anchoring the glycoprotein which projects 7 to 10 nm long spikes from its surface.^[7] They are of variable length, typically around 800 nm, but may be up to 1000 nm long. In the center of the virion is a structure called nucleocapsid, which is formed by the helically wound viral genomic RNA complexed with the proteins NP, VP35, VP30, and L.^[8] It has a diameter of 80 nm and contains a central channel of 20–30 nm in diameter. Virally encoded glycoprotein (GP) spikes 10 nm long and 10 nm apart are present on the outer viral envelope of the virion, which is derived from the host cell membrane. Between envelope and nucleocapsid, in the so-called matrix space, the viral proteins VP40 and VP24 are located.^[9]

Genome

Each virion contains one molecule of linear, single-stranded, negative-sense RNA, 18,959 to 18,961 nucleotides in length. The 3′ terminus is not polyadenylated and the 5′ end is not capped. It was found that 472 nucleotides from the 3' end and 731 nucleotides from the 5' end are sufficient for replication.^[10] It codes for seven structural proteins and one non-structural protein. The gene order is 3′ – leader – NP – VP35 – VP40 – GP/sGP – VP30 – VP24 – L – trailer – 5′; with the leader and trailer being non-transcribed regions, which carry important signals to control transcription, replication, and packaging of the viral genomes into new virions. The genomic material by itself is not infectious, because viral proteins, among them the RNA-dependent RNA polymerase, are necessary to transcribe the viral genome into mRNAs because it is a negative sense RNA virus, as well as for replication of the viral genome. Sections of the NP and the L genes from filoviruses have been identified as endogenous in the genomes of several groups of small mammals.^[11]

Entry

Niemann–Pick C1 (NPC1) appears to be essential for Ebola infection. Two independent studies reported in the same issue of Nature showed that Ebola virus cell entry and replication requires the cholesterol transporter protein NPC1.^[12][13] When cells from Niemann Pick Type C patients were exposed to Ebola virus in the laboratory, the cells survived and appeared immune to the virus, further indicating that Ebola relies on NPC1 to enter cells. This might imply that genetic mutations in the NPC1 gene in humans could make some people resistant to one of the deadliest known viruses affecting humans. The same studies described similar results with Ebola's cousin in the filovirus group, Marburg virus, showing that it too needs NPC1 to enter cells.^[12][13] Furthermore, NPC1 was shown to be critical to filovirus entry because it mediates infection by binding directly to the viral envelope glycoprotein.^[13] A later study confirmed the findings that NPC1 is a critical filovirus receptor that mediates infection by binding directly to the viral envelope glycoprotein and that the second lysosomal domain of NPC1 mediates this binding.^[14]
In one of the original studies, a small molecule was shown to inhibit Ebola virus infection by preventing the virus glycoprotein from binding to NPC1.^[13][15] In the other study, mice that were heterozygous for NPC1 were shown to be protected from lethal challenge with mouse adapted Ebola virus.^[12] Together, these studies suggest NPC1 may be potential therapeutic target for an Ebola anti-viral drug.

Replication

Being acellular, viruses do not grow through cell division; instead, they use the machinery and metabolism of a host cell to produce multiple copies of themselves, and they assemble in the cell.^[8]

• The virus attaches to host receptors through the glycoprotein (GP) surface peplomer and is endocytosed into macropinosomes in the host cell ^[16]
• Viral membrane fuses with vesicle membrane, nucleocapsid is released into the cytoplasm
• Encapsidated, negative-sense genomic ssRNA is used as a template for the synthesis (3' – 5') of polyadenylated, monocistronic mRNAs
• Using the host cell's machinery, translation of the mRNA into viral proteins occurs
• Viral proteins are processed, glycoprotein precursor (GP0) is cleaved to GP1 and GP2, which are heavily glycosylated. These two molecules assemble, first into heterodimers, and then into trimers to give the surface peplomers. Secreted glycoprotein (sGP) precursor is cleaved to sGP and delta peptide, both of which are released from the cell.
• As viral protein levels rise, a switch occurs from translation to replication. Using the negative-sense genomic RNA as a template, a complementary +ssRNA is synthesized; this is then used as a template for the synthesis of new genomic (-)ssRNA, which is rapidly encapsidated.
• The newly formed nucleocapsids and envelope proteins associate at the host cell's plasma membrane; budding occurs, destroying the cell.

History

Zaire ebolavirus is pronounced zɑː’ɪər iːˌboʊlə’vɑɪrəs (IPA) or zah-eer ee-boh-luh-vie-ruhs in English phonemic notation. Strictly speaking, the pronunciation of "Ebola virus" (eh-bo-luh vie-ruhs) should be distinct from that of the genus-level taxonomic designation "ebolavirus/Ebolavirus/ebolavirus", as "Ebola" is named for the tributary of the Congo River that is pronounced "Ébola" in French,^[17] whereas "ebola-virus" is an "artificial contraction" of the words "Ebola" and "virus," written without a diacritical mark for ease of use by scientific databases and English speakers. According to the rules for taxon naming established by the International Committee on Taxonomy of Viruses (ICTV), the name Zaire ebolavirus is always to be capitalized, italicized, and to be preceded by the word "species". The names of its members (Zaire ebolaviruses) are to be capitalized, are not italicized, and used without articles.^[2]
Ebola virus (abbreviated EBOV) was first described in 1976.^[18][19][20] Today, the International Committee on Taxonomy of Viruses lists the virus is the single member of the species Zaire ebolavirus, which is included into the genus Ebolavirus, family Filoviridae, order Mononegavirales. The name Ebola virus is derived from the Ebola River - a river that was at first thought to be in close proximity to the area in Democratic Republic of Congo, previously called Zaire, where the first recorded Ebola virus disease outbreak occurred - and the taxonomic suffix virus.^[2]
The species was introduced in 1998 as Zaire Ebola virus.^[21][22] In 2002, the name was changed to Zaire ebolavirus.^[23][24]

Previous designations

Ebola virus was first introduced as a possible new "strain" of Marburg virus in 1977 by two different research teams.^[18][19] At the same time, a third team introduced the name Ebola virus.^[20] In 2000, the virus name was changed to Zaire Ebola virus,^[25][26] and in 2005 to Zaire ebolavirus.^[23][27] However, most scientific articles continued to refer to Ebola virus or used the terms Ebola virus and Zaire ebolavirus in parallel. Consequently, in 2010, the name Ebola virus was reinstated.^[2] Previous abbreviations for the virus were EBOV-Z (for Ebola virus Zaire) and most recently ZEBOV (for Zaire Ebola virus or Zaire ebolavirus). In 2010, EBOV was reinstated as the abbreviation for the virus.^[2]

Species inclusion criteria

This section may be confusing or unclear to readers. (July 2014)

A virus of the genus Ebolavirus is a member of the species Zaire ebolavirus if:^[2]

• it is found in the Democratic Republic of the Congo, Gabon, or the Republic of the Congo
• it has a genome with two or three gene overlaps (VP35/VP40, GP/VP30, VP24/L)
• it has a genomic sequence that differs from the type virus by less than 30%

A virus of the species Zaire ebolavirus is an Ebola virus if it has the properties of Zaire ebolaviruses and if its genome diverges from that of the prototype Zaire ebolavirus, Ebola virus variant Mayinga (EBOV/May), by ≤10% at the nucleotide level.^[2]

Epidemiology

Main article: Ebola virus disease

EBOV is one of four ebolaviruses that causes Ebola virus disease (EVD) in humans (in the literature also often referred to as Ebola hemorrhagic fever, EHF). In the past, EBOV has caused the following EVD outbreaks:

Ebola virus disease (EVD) outbreaks due to Ebola virus (EBOV) infection

Year	Geographic location	Human cases/deaths (case-fatality rate)
1976	Yambuku, Zaire	318/280 (88%)
1976	Sudan, Sudan	284/151 (53%)
1977	Bonduni, Zaire	1/1 (100%)
1988	Porton Down, United Kingdom	1/0 (0%) [laboratory accident]
1994–1995-	Woleu-Ntem and Ogooué-Ivindo Provinces, Gabon	52/32 (62%)
1995	Kikwit, Zaire	317/245 (77%)
1996	Mayibout 2, Gabon	31/21 (68%)
1996	Sergiyev Posad, Russia	1/1 (100%) [laboratory accident]
1996–1997	Ogooué-Ivindo Province, Gabon; Cuvette-Ouest Department, Republic of the Congo	62/46 (74%)
2001–2002	Ogooué-Ivindo Province, Gabon; Cuvette-Ouest Department, Republic of the Congo	124/97 (78%)
2002	Ogooué-Ivindo Province, Gabon; Cuvette-Ouest Department, Republic of the Congo	11/10 (91%)
2002–2003	Cuvette-Ouest Department, Republic of the Congo; Ogooué-Ivindo Province, Gabon	143/128 (90%)
2003–2004	Cuvette-Ouest Department, Republic of the Congo	35/29 (83%)
2004	Koltsovo, Russia	1/1 (100%) [laboratory accident]
2005	Cuvette-Ouest Department, Republic of the Congo	11/9 (82%)
2008–2009	Kasai Occidental Province, Democratic Republic of the Congo	32/15 (47%)
2014	Guinea, Sierra Leone, Liberia (2014 West Africa Ebola outbreak)	1323/729 (56%) (27 July 2014)