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{{Taxobox_begin | color = violet | name = ''Hepatitis C virus''}}
{{Taxobox_begin_placement_virus}}
{{Taxobox_group_iv_entry}}
{{Taxobox_familia_entry | taxon = ''[[Flaviviridae]]''}}
{{Taxobox_genus_entry | taxon = ''[[Hepacivirus]]''}}
{{Taxobox_species_entry | taxon = '''''Hepatitis C virus'''''}}
{{Taxobox_end_placement}}
{{Taxobox_end}}
:''This page is for the virus. For the disease, see [[Hepatitis C]].''
The '''''Hepatitis C virus''''' ('''HCV''') is a small (50 [[metre#SI prefixes|nm]] in size), enveloped, single-stranded, positive sense [[RNA]] virus in the family ''[[Flaviviridae]]''. HCV mainly replicates within hepatocytes in the liver, although there is controversial evidence for replication in lymphocytes or monocytes. Circulating HCV particles bind to [[receptor (biochemistry)|receptors]] on the surfaces of hepatocytes and subsequently enter the cells. Two putative HCV receptors are CD81 and human scavenger receptor class B1 (SR-BI). However, these receptors are found throughout the body. The identification of hepatocyte-specific cofactors that determine observed HCV liver tropism are currently under investigation.

Once inside the hepatocyte, HCV utilizes the intracellular machinery necessary to accomplish its own replication.<!--
--><ref name="lindenbach">{{cite journal | author = Lindenbach B, Rice C | title = Unravelling hepatitis C virus replication from genome to function. | journal = Nature | volume = 436 | issue = 7053 | pages = 933-8 | year = 2005 | id = PMID 16107832}}</ref>
Specifically, the HCV genome is [[translation (biology)|translated]] to produce a single protein of around 3011 amino acids. This "polyprotein" is then proteolytically processed by viral and cellular [[proteases]] to produce three structural (virion-associated) and seven nonstructural (NS) proteins. Alternatively, a frameshift may occur in the Core region to produce an Alternate Reading Frame Protein (ARFP). HCV encodes two proteases, the NS2 cysteine autoprotease and the NS3-4A serine protease. The NS proteins then recruit the viral genome into an RNA replication complex, which is associated with rearranged cytoplasmic membranes. RNA replication takes places via the viral RNA-dependent [[RNA polymerase]] of NS5B, which produces a negative-strand RNA intermediate. The negative strand RNA then serves as a template for the production of new positive-strand viral genomes. Nascent genomes can then be translated, further replicated, or packaged within new virus particles. New virus particles presumably bud into the secretory pathway and are released at the cell surface.

HCV has a high rate of replication with approximately one trillion particles produced each day in an infected individual. Due to lack of proofreading by the HCV RNA polymerase, HCV also has an exceptionally high mutation rate, a factor that may help it elude the host's immune response.

Early studies of viral loads in eleven asymptomatically infected viral carriers (blood donors in 1989, prior to implementation of blood bank screening for HCV, and from whom the donated blood units were rejected because of elevated [[alanine transaminase]] (ALT) liver enzyme levels) indicated that asymptomatic viral loads in blood plasma varied between 100/mL and 50,000,000/mL.<!--
--><ref name="ulrich">{{cite journal | author = Ulrich P, Romeo J, Lane P, Kelly I, Daniel L, Vyas G | title = Detection, semiquantitation, and genetic variation in hepatitis C virus sequences amplified from the plasma of blood donors with elevated alanine aminotransferase. | journal = J Clin Invest | volume = 86 | issue = 5 | pages = 1609-14 | year = 1990 | id = PMID 2173725 | url=http://www.pubmedcentral.gov/articlerender.fcgi?tool=pubmed&pubmedid=2173725 | format=PDF & scanned pages }}</ref>

Based on genetic differences between HCV isolates, the hepatitis C virus species is classified into six [[genotypes]] (1-6) with several subtypes within each genotype. Subtypes are further broken down into quasispecies based on their genetic diversity. The preponderance and distribution of HCV genotypes varies globally. For example, in [[North America]], genotype 1a predominates followed by 1b, 2a, 2b, and 3a. In [[Europe]], genotype 1b is predominant followed by 2a, 2b, 2c, and 3a. Genotypes 4 and 5 are found almost exclusively in [[Africa]]. Genotype is clinically important in determining potential response to interferon-based therapy and the required duration of such therapy. Genotypes 1 and 4 are less responsive to [[interferon]]-based treatment than are the other genotypes (2, 3, 5 and 6).<!--
--><ref name="simmonds">{{cite journal | author = Simmonds P, Bukh J, Combet C, Deléage G, Enomoto N, Feinstone S, Halfon P, Inchauspé G, Kuiken C, Maertens G, Mizokami M, Murphy D, Okamoto H, Pawlotsky J, Penin F, Sablon E, Shin-I T, Stuyver L, Thiel H, Viazov S, Weiner A, Widell A | title = Consensus proposals for a unified system of nomenclature of hepatitis C virus genotypes. | journal = Hepatology | volume = 42 | issue = 4 | pages = 962-73 | year = 2005 | id = PMID 16149085}}</ref>
Duration of standard [[interferon]]-based therapy for genotypes 1 and 4 is 48 weeks, whereas treatment for genotypes 2 and 3 is completed in 24 weeks.

Although [[hepatitis A]], [[hepatitis B]], and hepatitis C have similar names (because they all cause liver inflammation), these are distinctly different viruses both genetically and clinically. Unlike hepatitis A and B, there is no [[vaccine]] to prevent hepatitis C infection.

In a [[2006]] study, 60 patients received four different doses of an experimental hepatitis C vaccine. All the patients produced antibodies that the researchers believe could protect them from the virus.<!--
--><ref name="KGO-TV-HepcVaccine">{{cite news | first=Dean | last=Edell | url=http://abclocal.go.com/kgo/story?section=edell&id=4278043 | title=Hepatitis C Vaccine Looks Promising | publisher=ABC7/KGO-TV | date =2006 | accessdate =2006-07-04}}</ref>

==References==
<references/>
ther is a cure

== External links ==
* [http://www.liverfoundation.org American Liver Foundation: Comprehensive information about Hepatitis C, including links to chapters for finding local resources]

[[Category:Flaviviruses]]

Revision as of 10:24, 11 May 2007

Template:Taxobox begin Template:Taxobox begin placement virus Template:Taxobox group iv entry Template:Taxobox familia entry Template:Taxobox genus entry Template:Taxobox species entry Template:Taxobox end placement Template:Taxobox end

This page is for the virus. For the disease, see Hepatitis C.

The Hepatitis C virus (HCV) is a small (50 nm in size), enveloped, single-stranded, positive sense RNA virus in the family Flaviviridae. HCV mainly replicates within hepatocytes in the liver, although there is controversial evidence for replication in lymphocytes or monocytes. Circulating HCV particles bind to receptors on the surfaces of hepatocytes and subsequently enter the cells. Two putative HCV receptors are CD81 and human scavenger receptor class B1 (SR-BI). However, these receptors are found throughout the body. The identification of hepatocyte-specific cofactors that determine observed HCV liver tropism are currently under investigation.

Once inside the hepatocyte, HCV utilizes the intracellular machinery necessary to accomplish its own replication.[1] Specifically, the HCV genome is translated to produce a single protein of around 3011 amino acids. This "polyprotein" is then proteolytically processed by viral and cellular proteases to produce three structural (virion-associated) and seven nonstructural (NS) proteins. Alternatively, a frameshift may occur in the Core region to produce an Alternate Reading Frame Protein (ARFP). HCV encodes two proteases, the NS2 cysteine autoprotease and the NS3-4A serine protease. The NS proteins then recruit the viral genome into an RNA replication complex, which is associated with rearranged cytoplasmic membranes. RNA replication takes places via the viral RNA-dependent RNA polymerase of NS5B, which produces a negative-strand RNA intermediate. The negative strand RNA then serves as a template for the production of new positive-strand viral genomes. Nascent genomes can then be translated, further replicated, or packaged within new virus particles. New virus particles presumably bud into the secretory pathway and are released at the cell surface.

HCV has a high rate of replication with approximately one trillion particles produced each day in an infected individual. Due to lack of proofreading by the HCV RNA polymerase, HCV also has an exceptionally high mutation rate, a factor that may help it elude the host's immune response.

Early studies of viral loads in eleven asymptomatically infected viral carriers (blood donors in 1989, prior to implementation of blood bank screening for HCV, and from whom the donated blood units were rejected because of elevated alanine transaminase (ALT) liver enzyme levels) indicated that asymptomatic viral loads in blood plasma varied between 100/mL and 50,000,000/mL.[2]

Based on genetic differences between HCV isolates, the hepatitis C virus species is classified into six genotypes (1-6) with several subtypes within each genotype. Subtypes are further broken down into quasispecies based on their genetic diversity. The preponderance and distribution of HCV genotypes varies globally. For example, in North America, genotype 1a predominates followed by 1b, 2a, 2b, and 3a. In Europe, genotype 1b is predominant followed by 2a, 2b, 2c, and 3a. Genotypes 4 and 5 are found almost exclusively in Africa. Genotype is clinically important in determining potential response to interferon-based therapy and the required duration of such therapy. Genotypes 1 and 4 are less responsive to interferon-based treatment than are the other genotypes (2, 3, 5 and 6).[3] Duration of standard interferon-based therapy for genotypes 1 and 4 is 48 weeks, whereas treatment for genotypes 2 and 3 is completed in 24 weeks.

Although hepatitis A, hepatitis B, and hepatitis C have similar names (because they all cause liver inflammation), these are distinctly different viruses both genetically and clinically. Unlike hepatitis A and B, there is no vaccine to prevent hepatitis C infection.

In a 2006 study, 60 patients received four different doses of an experimental hepatitis C vaccine. All the patients produced antibodies that the researchers believe could protect them from the virus.[4]

References

  1. ^ Lindenbach B, Rice C (2005). "Unravelling hepatitis C virus replication from genome to function". Nature. 436 (7053): 933–8. PMID 16107832.
  2. ^ Ulrich P, Romeo J, Lane P, Kelly I, Daniel L, Vyas G (1990). "Detection, semiquantitation, and genetic variation in hepatitis C virus sequences amplified from the plasma of blood donors with elevated alanine aminotransferase" (PDF & scanned pages). J Clin Invest. 86 (5): 1609–14. PMID 2173725.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  3. ^ Simmonds P, Bukh J, Combet C, Deléage G, Enomoto N, Feinstone S, Halfon P, Inchauspé G, Kuiken C, Maertens G, Mizokami M, Murphy D, Okamoto H, Pawlotsky J, Penin F, Sablon E, Shin-I T, Stuyver L, Thiel H, Viazov S, Weiner A, Widell A (2005). "Consensus proposals for a unified system of nomenclature of hepatitis C virus genotypes". Hepatology. 42 (4): 962–73. PMID 16149085.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  4. ^ Edell, Dean (2006). "Hepatitis C Vaccine Looks Promising". ABC7/KGO-TV. Retrieved 2006-07-04.

ther is a cure