Dependoparvovirus

Dependoparvovirus
Virus classification
Group: Group II (ssDNA)
Order: Unassigned
Family: Parvoviridae
Subfamily: Parvovirinae
Genus: Dependoparvovirus
Type species
Adeno-associated dependoparvovirus A
Species

Dependoparvovirus (formerly Dependovirus or Adeno-associated virus group) is a genus in the virus subfamily Parvovirinae, within the family Parvoviridae; they are Group II viruses according to the Baltimore classification. Some dependoparvoviruses are also known as adeno-associated viruses because they cannot replicate productively in their host cell without the cell being coinfected by a helper virus such as an adenovirus, a herpesvirus, or a vaccinia virus.

There are currently seven recognized species in the genus.[1]

Virology

Dependoparvoviruses have an icosahedral shape, measure 22 nm[2] is composed of 60 wedge shaped proteins triangulation number = 1). Three proteins (VP1, VP2 and VP3) are present in each capsomere. Each capsid is made from 5 VP1, 5 VP2, and 50 VP3 proteins. The capsid does not have an envelope.[3]

The genome is a single molecule of single stranded with a length of 4.7 kilobases. It has only two open reading frames. The 3' open reading frame is the structural capsid protein, cap, which can be spliced to form two RNAs, one for virion protein 1 (VP1) and the other goes on to eventually make VP2 and VP3. The second gene, rep, can be spliced into four different, nonstructural, regulatory proteins that all aid in the genome replication. These proteins are named Rep 78, Rep68, Rep 52, and Rep 40 based on their molecular weight.[2]

Due to inverted, complementary long terminal repeats (LTRs) at each end of the genome, a T shaped secondary structure is formed. The complementary areas leave a 3’ hydroxyl group single stranded for the replication to begin. This 3’ hydroxyl group is used as a primer for the leading strand synthesis. Both positive and negative sense strands of DNA are made. Double stranded intermediates are formed throughout the replication; this means the two strands, positive and negative sense, will be matched up.[2][3]

Host range

These viruses are capable of replication within all of the vertebrates. They are only limited by the virus they must infect with, also known as the helper virus. These helper viruses are necessary for the replication of a dependoparvovirus. A common helper virus in humans is the adenovirus (Citation Needed). There is no known disease in humans associated with Dependovirus (Not true as of 2005).[4]

Gene therapy

Dependoparvovirus is not a large enough virus to trigger an immune response; this makes it a good virus to use as a gene therapy tool. Gene therapy is a possible treatment for a variety of disorders and diseases that are genetic in origin. Viral vectors are currently being developed to transport genes into human cells. Since this virus does not stimulate an immune response it can be used multiple times effectively without being neutralized before infection. Another reason these viruses are reliable vectors is the known insertion point for the genome. This virus always inserts its contents into the same place on chromosome 19. This predictability can cut down on the chances of inserting into an important area that might disrupt normal gene function or increase the risk of developing cancer.[5]

At this time, one challenge using this virus as a therapy tool is the fact that the genome is fairly small. With less than 5kb in the genome the amount of genetic material that can fit into the capsid is limited. Work is currently being done to increase the amount of information this vector can deliver. This may be accomplished by the LTRs found at both the 5’ and 3’ end of the genome. Since the LTRs have the same sequence they will leave complementary strands exposed if they are removed. The complementary strands can undergo recombination and join two 5kb inserted fragments together.[6]

References

  1. 1 2 http://talk.ictvonline.org/files/ictv_official_taxonomy_updates_since_the_8th_report/m/vertebrate-official/4844.aspx
  2. 1 2 3 Gonçalves, M (2005). "Adeno-associated virus: from defective virus to effective vector". Virology Journal. 2 (1): 43–60. doi:10.1186/1743-422X-2-43. PMC 1131931Freely accessible. PMID 15877812.
  3. 1 2 ICTVdB Management; Ed. Büchen- Osmond, C. (2006). "ICTVdB - The Universal Virus Database, version 4: Dependovirus". Columbia University, New York, USA. Archived from the original on 2006-04-25. Retrieved May 4, 2009.
  4. Agbandje, M; Parrish, C. R. & Rossmann, M. G (1995). "The recognition of parvovirus capsids by Antibodies" (PDF). Seminars in Virology. 6: 219–231. doi:10.1006/smvy.1995.0027.
  5. Excoffon, K; et al. (2009). "Directed evolution of adeno-associated virus to an infectious respiratory virus" (PDF). Proceedings on the National Academy of Science. 106 (10): 3865–3870. doi:10.1073/pnas.0813365106. PMC 2646629Freely accessible. PMID 19237554.
  6. Ghosh, A., Yue, Y., Lai, Y., and Duan, D. (2008). "A Hybrid Vector System Expands Adeno-associated Viral Vector Packaging Capacity in a Transgene- Independent manner" (PDF). Molecular Therapy. 16 (1): 124–130. doi:10.1038/sj.mt.6300322. PMID 17984978.

External links

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