Epstein–Barr virus

Epstein–Barr
Two Epstein–Barr virions
Virus classification
Group: Group I (dsDNA)
Family: Herpesviridae
Subfamily: Gammaherpesvirinae
Genus: Lymphocryptovirus
Species: Human herpesvirus 4 (HHV-4)

The Epstein–Barr virus (EBV), also called human herpesvirus 4 (HHV-4), is a virus of the herpes family and is one of the most common viruses in humans. It is best known as the cause of infectious mononucleosis. It is also associated with particular forms of cancer, particularly Hodgkin's lymphoma, Burkitt's lymphoma, nasopharyngeal carcinoma, and central nervous system lymphomas associated with HIV.[1] Finally, there is evidence that infection with the virus is associated with a higher risk of certain autoimmune diseases, especially dermatomyositis, systemic lupus erythematosus,[2][3] rheumatoid arthritis,[3] Sjögren's syndrome,[3] and multiple sclerosis.[4]

Most people become infected with EBV and gain adaptive immunity. In the United States, about half of all five-year-olds and 90–95% of adults have evidence of previous infection.[5] Infants become susceptible to EBV as soon as maternal antibody protection disappears. Many children become infected with EBV, and these infections usually cause no symptoms or are indistinguishable from the other mild, brief illnesses of childhood. In the United States and in other developed countries, many people are not infected with EBV in their childhood years. When infection with EBV occurs during adolescence or teenage years, it causes infectious mononucleosis 35% to 50% of the time.[6]

Contents

History

Epstein–Barr virus is named after Michael Anthony Epstein, Professor Emeritus at the University of Bristol and Yvonne Barr, who discovered and documented the virus.[7] In 1961, Michael Anthony Epstein, a pathologist and expert electron microscopist, attended a lecture on "The Commonest Children's Cancer in Tropical Africa—A Hitherto Unrecognised Syndrome." This lecture, by Denis Parsons Burkitt, a surgeon practicing in Uganda, was the description of the "endemic variant" (pediatric form) of the disease that bears his name. In 1963, a specimen was sent from Uganda to Middlesex Hospital to be cultured. Virus particles were identified in the cultured cells, and the results were published in The Lancet in 1964 by Epstein, Bert Achong, and Barr. Cell lines were sent to Werner and Gertrude Henle at the Children's Hospital of Philadelphia who developed serological markers. In 1967, a technician in their laboratory developed mononucleosis and they were able to compare a stored serum sample, showing that antibodies to the virus developed.[8][9][10]

Virology

The virus can execute many distinct programs of gene expression which can be broadly categorized as being lytic cycle or latent cycle.

Programs

From studies of EBV gene expression in cultured Burkitt's lymphoma cell lines, at least three programs exist:

  1. EBER1&2 EBNA1 (Latency I)
  2. EBER1&2 LMP2A LMP2B EBNA1 LMP1 (Latency II)
  3. EBER1&2 LMP2A LMP2B EBNA1 LMP1 EBNA2,3,4,5,6 (Latency III)

It is also postulated that a program exists in which all viral protein expression is shut off(latency 0).

Latent cycle

Epstein–Barr virus and its sister virus KSHV can be maintained and manipulated in the laboratory in continual latency. While many viruses are assumed to have this property during infection of their natural host, they do not have an easily managed system for studying this part of the viral lifecycle. Further, Walter Henle and Gertrude Henle[1], together with Harald zur Hausen, discovered that EBV can directly immortalize B cells after infection, mimicking some forms of EBV-related neoplasia[2].

On infecting the B-lymphocyte by binding to the complement receptor, the linear genome circularizes and the virus subsequently persists within the cell as an episome.

In primary infection, EBV replicates in oro-pharyngeal epithelial cells and establishes Latency III, II, and I infections in B-lymphocytes. EBV latent infection of B-lymphocytes is necessary for virus persistence, subsequent replication in epithelial cells, and release of infectious virus into saliva. EBV Latency III and II infections of B-lymphocytes, Latency II infection of oral epithelial cells, and Latency II infection of NK- or T-cell can result in malignancies, marked by uniform EBV genome presence and gene expression.[14]

Transformation

When EBV infects B-lymphocytes in vitro, lymphoblastoid cell lines eventually emerge that are capable of indefinite growth. The growth transformation of these cell lines is the consequence of viral protein expression.

EBNA-2, EBNA-3C and LMP-1 are essential for transformation while EBNA-LP and the EBERs are not. The EBNA-1 protein is essential for maintenance of the virus genome.[15]

It is postulated that following natural infection with EBV, the virus executes some or all of its repertoire of gene expression programs to establish a persistent infection. Given the initial absence of host immunity, the lytic cycle produces large amounts of virus to infect other (presumably) B-lymphocytes within the host.

The latent programs reprogram and subvert infected B-lymphocytes to proliferate and bring infected cells to the sites at which the virus presumably persists. Eventually, when host immunity develops, the virus persists by turning off most (or possibly all) of its genes, only occasionally reactivating to produce fresh virions. A balance is eventually struck between occasional viral reactivation and host immune surveillance removing cells that activate viral gene expression.

The site of persistence of EBV may be bone marrow. EBV-positive patients who have had their own bone marrow replaced with bone marrow from an EBV-negative donor are found to be EBV-negative after transplantation.[16]

Latent antigens

All EBV nuclear proteins are produced by alternative splicing of a transcript starting at either the Cp or Wp promoters at the left end of the genome (in the conventional nomenclature). The genes are ordered EBNA-LP/EBNA-2/EBNA-3A/EBNA-3B/EBNA-3C/EBNA-1 within the genome.

The initiation codon of the EBNA-LP coding region is created by an alternate splice of the nuclear protein transcript. In the absence of this initiation codon, EBNA-2/EBNA-3A/EBNA-3B/EBNA-3C/EBNA-1 will be expressed depending on which of these genes is alternatively spliced into the transcript.

Viral entry

EBV can infect a number of different cell types, including B cells and epithelial cells, and under certain cases, it may infect T cells, natural killer cells, and smooth muscle cells. Infecting both the B cells and the epithelial cells is part of the viral normal cycle to persist. However, the entry mechanism and the proteins involved in entry for these two cells are different.

To infect B cells, the gp350 viral protein binds to the cellular receptor complement receptor 2 (CR2, also known as CD21),[17] and triggers endocytosis. In addition, gp42 binds to MHC class II molecule. Through these interactions, the fusion machinery, composed of gHgL and gB, is triggered and the viral membrane fuses with the endosomal membrane to release viral genetic materials.

To infect epithelial cells, gp350 also binds to CR2; however, endocytosis is not triggered. Then, gHgL interacts with a gHgL receptor (possibly integrins αvβ6 or αvβ8) and the fusion machinery gHgL and gB is triggered to allow fusion on cell membrane. Fusion with epithelial cells is actually impeded by gp42.

Tropism

The viral three-part glycoprotein complexes of gHgLgp42 mediate B cell membrane fusion; while the two-part complexes of gHgL mediate epithelial cell membrane fusion. EBV that are made in the B cells have low numbers of the gHgLgp42 complexes as the three-part complexes interact with HLA class II in the endoplasmic reticulum and are degraded. In contrast, EBV from epithelial cells are rich in the three-part complexes because these cells do not have MHC class II. As a result, EBV made from B cells are more infectious to epithelial cells, and EBV made from epithelial cells are more infectious to B cells.

Protein/genes

Protein/gene/antigen Stage Description
EBNA-1 latent+lytic EBNA-1 protein binds to a replication origin (oriP) within the viral genome and mediates replication and partitioning of the episome during division of the host cell. It is the only viral protein expressed during group I latency.
EBNA-2 latent+lytic EBNA-2 is the main viral transactivator.
EBNA-3 latent+lytic These genes also bind the host RBP-Jκ protein.
LMP-1 latent LMP-1 is a six-span transmembrane protein that is also essential for EBV-mediated growth transformation.
LMP-2 latent LMP-2A/LMP-2B are transmembrane proteins that act to block tyrosine kinase signaling.
EBER latent EBER-1/EBER-2 are small nuclear RNAs, which bind to certain nucleoprotein particles, enabling binding to PKR (dsRNA dependent serin/threonin protein kinase) thus inhibiting its function. EBER-particles also induce the production of IL-10 which enhances growth and inhibits cytotoxic T-cells.
miRNAs latent EBV microRNAs are encoded by two transcripts, one set in the BART gene and one set near the BHRF1 cluster. The three BHRF1 miRNAS are expressed during type III latency while the large cluster of BART miRNAs (up to 20 miRNAs) are expressed during type II latency. The functions of these miRNAs are currently unknown.
EBV-EA lytic early antigen
EBV-MA lytic membrane antigen
EBV-VCA lytic viral capsid antigen
EBV-AN lytic alkaline nuclease[18][19]

Surface receptors

The Epstein–Barr virus surface glycoprotein H (gH) is essential for penetration of B cells but also plays a role in attachment of virus to epithelial cells.[20]

In laboratory and animal trials in 2000, it was shown that both antagonism of RA-mediated growth inhibition and promotion of LCL proliferation were efficiently reversed by the glucocorticoid receptor (GR) antagonist RU486.[21]

See also

References

  1. ^ Maeda E, Akahane M, Kiryu S, et al. (January 2009). "Spectrum of Epstein-Barr virus-related diseases: a pictorial review". Jpn J Radiol 27 (1): 4–19. doi:10.1007/s11604-008-0291-2. PMID 19373526. 
  2. ^ James JA, Kaufman KM, Farris AD, Taylor-Albert E, Lehman TJ, Harley JB (1997). "An increased prevalence of Epstein-Barr virus infection in young patients suggests a possible etiology for systemic lupus erythematosus". Journal of Clinical Investigation 100 (12): 3019–26. doi:10.1172/JCI119856. PMC 508514. PMID 9399948. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=508514. 
  3. ^ a b c Toussirot E, Roudier J (October 2008). "Epstein-Barr virus in autoimmune diseases". Best Pract Res Clin Rheumatol 22 (5): 883–96. doi:10.1016/j.berh.2008.09.007. PMID 19028369. 
  4. ^ Ascherio A, Munch M (March 2000). "Epstein-Barr virus and multiple sclerosis". Epidemiology 11 (2): 220–4. doi:10.1097/00001648-200003000-00023. PMID 11021623. 
  5. ^ In the United States, as many as 95% of adults between 35 and 40 years of age have been infected. National Center for Infectious Diseases
  6. ^ CDC. "Epstein-Barr Virus and Infectious Mononucleosis". CDC. http://www.cdc.gov/ncidod/diseases/ebv.htm. Retrieved 29-12-2011. 
  7. ^ M. A. Epstein, B. G. Achong, and Y. M. Barr: Virus particles in cultured lymphoblasts from Burkitt's lymphoma. The Lancet, March 28, 1964, 1: 702-703
  8. ^ Epstein, M. Anthony (2005). "1. The origins of EBV research: discovery and characterization of the virus". In Robertson, Earl S.. Epstein-Barr Virus. Trowbridge: Cromwell Press. pp. 1–14. ISBN 1904455034. http://books.google.com/books?id=TRO-wXto8hcC. Retrieved September 18, 2010. 
  9. ^ zur Hausen, Harald (2005). "2. The early days of Epstein-Barr Virus research: the Henle years". In Robertson, Earl S.. Epstein-Barr Virus. Trowbridge: Cromwell Press. pp. 15–22. ISBN 1904455034. http://books.google.com/books?id=TRO-wXto8hcC. Retrieved September 18, 2010. 
  10. ^ Miller, George (December 21, 2006). "Book Review: Epstein–Barr Virus". New England Journal of Medicine 355 (25): 2708–2709. doi:10.1056/NEJMbkrev39523. http://www.nejm.org/doi/full/10.1056/NEJMbkrev39523. Retrieved September 18, 2010. 
  11. ^ Lockey TD, Zhan X, Surman S, Sample CE, Hurwitz JL (2008). "Epstein-Barr virus vaccine development: a lytic and latent protein cocktail". Front. Biosci. 13 (13): 5916–27. doi:10.2741/3126. PMID 18508632. http://www.bioscience.org/2008/v13/af/3126/fulltext.htm. 
  12. ^ .The nomenclature used here is that of the Kieff lab. Other laboratories use different nomenclatures.
  13. ^ Hutzinger R, Feederle R, Mrazek J, Schiefermeier N, Balwierz PJ, Zavolan M, Polacek N, Delecluse H, Hüttenhofer A (August 14, 2009). Cullen, Bryan R.. ed. "Expression and Processing of a Small Nucleolar RNA from the Epstein-Barr Virus Genome". PLoS Pathogens 5 (8): e1000547. doi:10.1371/journal.ppat.1000547. PMC 2718842. PMID 19680535. http://www.plospathogens.org/article/info%3Adoi%2F10.1371%2Fjournal.ppat.1000547. 
  14. ^ Robertson, ES (editor) (2010). Epstein-Barr Virus: Latency and Transformation. Caister Academic Press. ISBN 978-1-904455-62-2. 
  15. ^ Yates JL, Warren N, Sugden B (1985). "Stable replication of plasmids derived from Epstein-Barr virus in various mammalian cells". Nature 313 (6005): 812–5. doi:10.1038/313812a0. PMID 2983224. 
  16. ^ Gratama JW, Oosterveer MA, Zwaan FE, Lepoutre J, Klein G, Ernberg I (1988). "Eradication of Epstein-Barr virus by allogeneic bone marrow transplantation: implications for sites of viral latency". Proc. Natl. Acad. Sci. U.S.A. 85 (22): 8693–6. doi:10.1073/pnas.85.22.8693. PMC 282526. PMID 2847171. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=282526. 
  17. ^ "Entrez Gene: CR2 complement component (3d/Epstein Barr virus) receptor 2". http://www.ncbi.nlm.nih.gov/sites/entrez?Db=gene&Cmd=ShowDetailView&TermToSearch=1380. 
  18. ^ Buisson M, Géoui T, Flot D, Tarbouriech N, Ressing ME, Wiertz EJ, Burmeister WP (2009). "A bridge crosses the active-site canyon of the Epstein-Barr virus nuclease with DNase and RNase activities". J Mol. Biol. 319 (4): 717–28. doi:10.1016/j.jmb.2009.06.034. PMID 19538972. 
  19. ^ http://www.pdb.org/pdb/explore/explore.do?structureId=2W45
  20. ^ Molesworth SJ, Lake CM, Borza CM, Turk SM, Hutt-Fletcher LM (July 2000). "Epstein-Barr Virus gH Is Essential for Penetration of B Cells but Also Plays a Role in Attachment of Virus to Epithelial Cells". Journal of virology 74 (14): 6324–32. doi:10.1128/JVI.74.14.6324-6332.2000. PMC 112138. PMID 10864642. http://jvi.asm.org/cgi/pmidlookup?view=long&pmid=10864642. 
  21. ^ Quaia M, Zancai P, Cariati R, Rizzo S, Boiocchi M, Dolcetti R (July 2000). "Glucocorticoids promote the proliferation and antagonize the retinoic acid-mediated growth suppression of Epstein-Barr virus-immortalized B lymphocytes". Blood 96 (2): 711–8. PMID 10887139. http://www.bloodjournal.org/cgi/pmidlookup?view=long&pmid=10887139. 

External links