Murine leukemia virus
The murine leukemia viruses (MLVs or MuLVs) are retroviruses named for their ability to cause cancer in murine (mouse) hosts. Some MLVs may infect other vertebrates. MLVs include both exogenous and endogenous viruses. Replicating MLVs have a positive sense, single-stranded RNA (ssRNA) genome that replicates through a DNA intermediate via the process of reverse transcription.
Murine leukemia virus | |
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Virus classification | |
(unranked): | Virus |
Realm: | Riboviria |
Kingdom: | Pararnavirae |
Phylum: | Artverviricota |
Class: | Revtraviricetes |
Order: | Ortervirales |
Family: | Retroviridae |
Genus: | Gammaretrovirus |
Species: | Murine leukemia virus |
Classification
The murine leukemia viruses are group/type VI retroviruses belonging to the gammaretroviral genus of the Retroviridae family. The viral particles of replicating MLVs have C-type morphology as determined by electron microscopy.
The MLVs include both exogenous and endogenous viruses. Exogenous forms are transmitted as new infections from one host to another. The Moloney, Rauscher, Abelson and Friend MLVs, named for their discoverers, are used in cancer research.
Endogenous MLVs are integrated into the host's germ line and are passed from one generation to the next. Stoye and Coffin have classified them into four categories by host specificity, determined by the genomic sequence of their envelope region.[1] The ecotropic MLVs (from Gr.eco, "Home") are capable of infecting mouse cells in culture. Non-ecotropic MLVs may be xenotropic (from xenos, "foreign", infecting non-mouse species), polytropic or modified polytropic (infecting a range of hosts including mice). Among the latter MLVs are amphotropic viruses (Gr. amphos, "both") that can infect both mouse cells and cells of other animal species. These terms and descriptions for the MLV biologic classification were initially introduced by Levy.[2] Different strains of mice may have different numbers of endogenous retroviruses, and new viruses may arise as the result of recombination of endogenous sequences.[3][4]
Virion structure
As Type C retroviruses, replicating murine leukemia viruses produce a virion containing a spherical nucleocapsid (the viral genome in complex with viral proteins) surrounded by a lipid bilayer derived from the host cell membrane. The lipid bilayer contains integrated host and viral proteins studded with carbohydrate molecules. The viral particle is approximately 90 nanometres (nm) in diameter. The viral glycoproteins are expressed on the membrane as trimer of a precursor Env, which is cleaved into SU and TM by host furin or furin-like proprotein convertases. This cleavage is essential for the Env incorporation into virus particles.[5]
Genome
The genomes of exogenous and endogenous murine leukemia viruses have been fully sequenced. The viral genome is a single stranded, positive-sense RNA highly folded, molecule of around 8000 nucleotides. From 5' to 3' (typically displayed as "left" to "right"), the genome contains gag, pol, and env regions, coding for structural proteins, enzymes including the RNA-dependent DNA polymerase (reverse transcriptase), and coat proteins, respectively. In addition to these three polyproteins: Gag, Pol and Env, common to all retroviruses, MLV also produces the p50/p60 proteins issued from an alternative splicing of its genomic RNA..[6] The genomic molecule contains a 5' methylated cap structure and a 3' poly-adenosine tail.
The genome includes a conserved RNA structural element called a core encapsidation signal that directs packaging of RNA into the virion;[7] the tertiary structure of this element has been solved using nuclear magnetic resonance spectroscopy.[8][9]
Replication cycle
Infection begins when the surface glycoprotein ( SU) binds to the outer part of the mature, infectious virion to the receptor on the surface of the new host cell. As a result of attachment, changes occur in ENV. These changes lead to the release of the surface glycoprotein (SU)and the conformational regulation of transmembrane (TM). As a result, the fusion of the viral membrane and the plasma membrane occurs. Fusion of the membranes leads to the accumulation of virion content in the cytoplasm of the cell. After entering the cytoplasm, viral RNA is copied into a single dsDNA molecule by RT. This DNA is somehow carried into the nucleus, where the integrase ( IN )protein catalyzes its insertion into chromosomal DNA. Viral DNA is called “provirus” after it is integrated into host DNA. It is copied and translated by normal host cell machines. Encrypted proteins are trafficked to the plasma membrane, where they are combined into progeny virus particles. Immature particles are released from the cell with the help of cellular "ESCRT" machines [23] and then mature as they separate PR viral polyproteins in the virus. The particle cannot start a new infection until ripening occurs.[10]
Viral evolution
As with other retroviruses, the MLVs replicate their genomes with relatively low fidelity. Thus, divergent viral sequences may be found in a single host organism.[11] MLV reverse transcriptases are thought to have a slightly higher fidelity than the HIV-1 RT.[12]
Research
The Friend virus (FV) is a strain of murine leukemia virus. The Friend virus has been used for both immunotherapy and vaccines. Experiments have shown that it is possible to protect against Friend virus infection with several types of vaccines, including attenuated viruses, viral proteins, peptides, and recombinant vaccinia vectors expressing the Friend virus gene. In a study of vaccinated mice, it was possible to identify the immunological epitopes required for protection against the virus, thus determining the types of immunological responses necessary or required for protection against it. The research discovered protective epitopes that were localized to F-MuLV gag and env proteins. This was achieved using recombinant vaccinia viruses expressing the gag and env genes of FV.
Application
- Gene therapy: MLV-derived particles can deliver therapeutic genes to target cells.
- Cancer studies: MLVs are used to study cancer development.
- As a model retrovirus in viral clearance studies
- Reverse transcriptase from MMLV is used in biotechnology
References
- Stoye JP, Coffin JM (September 1987). "The four classes of endogenous murine leukemia virus: structural relationships and potential for recombination". Journal of Virology. 61 (9): 2659–69. doi:10.1128/JVI.61.9.2659-2669.1987. PMC 255766. PMID 3039159.
- Levy JA (1978). "Xenotropic type C viruses". Current Topics in Microbiology and Immunology. Modern Aspects of Electrochemistry. 79: 111–213. doi:10.1007/978-3-642-66853-1_4. ISBN 978-1-4612-9003-2. PMID 77206.
- Coffin JM, Stoye JP, Frankel WN (1989). "Genetics of endogenous murine leukemia viruses". Annals of the New York Academy of Sciences. 567 (1): 39–49. Bibcode:1989NYASA.567...39C. doi:10.1111/j.1749-6632.1989.tb16457.x. PMID 2552892.
- Stoye JP, Moroni C, Coffin JM (March 1991). "Virological events leading to spontaneous AKR thymomas". Journal of Virology. 65 (3): 1273–85. doi:10.1128/JVI.65.3.1273-1285.1991. PMC 239902. PMID 1847454.
- Apte S, Sanders DA (September 2010). "Effects of retroviral envelope-protein cleavage upon trafficking, incorporation, and membrane fusion". Virology. 405 (1): 214–24. doi:10.1016/j.virol.2010.06.004. PMID 20591459.
- Houzet L, Battini JL, Bernard E, Thibert V, Mougel M (September 2003). "A new retroelement constituted by a natural alternatively spliced RNA of murine replication-competent retroviruses". The EMBO Journal. 22 (18): 4866–75. doi:10.1093/emboj/cdg450. PMC 212718. PMID 12970198.
- Mougel M, Barklis E (October 1997). "A role for two hairpin structures as a core RNA encapsidation signal in murine leukemia virus virions". Journal of Virology. 71 (10): 8061–5. doi:10.1128/JVI.71.10.8061-8065.1997. PMC 192172. PMID 9311905.
- D'Souza V, Dey A, Habib D, Summers MF (March 2004). "NMR structure of the 101-nucleotide core encapsidation signal of the Moloney murine leukemia virus". Journal of Molecular Biology. 337 (2): 427–42. doi:10.1016/j.jmb.2004.01.037. PMID 15003457.
- D'Souza V, Summers MF (September 2004). "Structural basis for packaging the dimeric genome of Moloney murine leukaemia virus". Nature. 431 (7008): 586–90. Bibcode:2004Natur.431..586D. doi:10.1038/nature02944. PMID 15457265.
- Rein A (2011). "Murine leukemia viruses: objects and organisms". Advances in Virology. 2011: 403419. doi:10.1155/2011/403419. PMC 3265304. PMID 22312342.
- Voisin V, Rassart E (May 2007). "Complete genome sequences of the two viral variants of the Graffi MuLV: phylogenetic relationship with other murine leukemia retroviruses". Virology. 361 (2): 335–47. doi:10.1016/j.virol.2006.10.045. PMID 17208267.
- Skasko M, Weiss KK, Reynolds HM, Jamburuthugoda V, Lee K, Kim B (April 2005). "Mechanistic differences in RNA-dependent DNA polymerization and fidelity between murine leukemia virus and HIV-1 reverse transcriptases". The Journal of Biological Chemistry. 280 (13): 12190–200. doi:10.1074/jbc.M412859200. PMC 1752212. PMID 15644314.
Further reading
- Wood KJ, Fry J (June 1999). "Gene therapy: potential applications in clinical transplantation". Expert Reviews in Molecular Medicine. 1999 (11): 1–20. doi:10.1017/S1462399499000691. PMID 14585123.
Table 1. A comparison of vectors in use for clinical gene transfer
- Sliva K, Erlwein O, Bittner A, Schnierle BS (December 2004). "Murine leukemia virus (MLV) replication monitored with fluorescent proteins". Virology Journal. 1: 14. doi:10.1186/1743-422X-1-14. PMC 544597. PMID 15610559.