Difference between revisions of "Viroid" - New World Encyclopedia

A viroid is a submicroscopic infectious agent, smaller than a virus, that consists of a short section (a few hundred nucleobases) of highly complementary, circular, single-stranded RNA without the protective protein coat that is typical for viruses. They are known to cause important diseases in plants. The nucleic acid is not known to code for specific proteins, but viroids can replicate themselves by using host enzymes.

Plants such as tomatoes, potatoes, avocados, coconuts, peaches, pears, apples, chrysanthemums, and cucumbers are known to be infected with viroids, which can be transmitted by pollen or seed.

Viroids were discovered and given this name by Theodor O. Diener, a plant pathologist at the Agricultural Research Service in Maryland, in 1971 (ARS 1989; OU 2007). Until this discovery, the scientific dogma was that an entity without a protective protein coat could not replicate itself, even with the support of the host cell, and that one as small as the potato spindle tuber viroid was not supposed to be able to infect anything (OU 2007).

Description

Viroids consist of short strands of the nucleic acid RNA without a protein coat. They lack any DNA. Viroids differ from viruses in that viruses, at their most basic level, consist of genetic material (DNA or RNA) contained within a protective protein shell. Viroids differ from prions, another type of subviral infectious agent, in that prions are made only of protein, lacking nucleic acid.

The smallest viroid identified so far is a 220 nucleobase scRNA (small cytoplasmic RNA) associated with the rice yellow mottle sobemovirus (RYMV) (Collins et al. 1998). In comparison, the genome of the smallest known viruses capable of causing an infection by themselves are around two kilobases in size. Many viroids consist of only 300 to 400 nucleotides.

Viroid RNA does not code for any known protein; some even lack the AUG initiation codon. Nonetheless, they replicate autonomously in host cells. The replication mechanism involves interaction with RNA polymerase II, an enzyme normally associated with synthesis of messenger RNA, and "rolling circle" synthesis of new RNA. Some viroids are ribozymes, having RNA enzyme properties that allow self-cleavage and ligation of unit-size genomes from larger replication intermediates. It has been proposed that viroids are "escaped introns."

Not all viroids are known to be pathogenic, but some are serious pathogens of plants. Viroids are usually transmitted by seed or pollen, but may be transported by farm implements as well. Infected plants can show distorted growth and sometimes are killed by the viroid.

Although viroids by themselves have been identified as an animal pathogen, there is support for the view that hepatitis D is traced to a viroid (Biotecnika 2005). Previously, hepatitis D was tied to a virus called delta agent, but delta agent appears to be a viroid enclosed in a hepatitis B virus capsid (Biotecnika 2005). Hepatitis D thus requires simultaneous infection of a cell with both the viroid and the hepatitis B virus.

The first viroid to be identified was the Potato spindle tuber viroid (PSTVd). Some 33 species of viroids have been identified.

PSTVd is commonly used in research experiments in viroids. A total of 359 nucleotides are included in this viroid (Davis et al. 1999).

Primary and secondary structure of the PSTVd viroid:

1 CGGAACUAAA CUCGUGGUUC CUGUGGUUCA CACCUGACCU CCUGAGCAGA AAAGAAAAAA

61 GAAGGCGGCU CGGAGGAGCG CUUCAGGGAU CCCCGGGGAA ACCUGGAGCG AACUGGCAAA

121 AAAGGACGGU GGGGAGUGCC CAGCGGCCGA CAGGAGUAAU UCCCGCCGAA ACAGGGUUUU

181 CACCCUUCCU UUCUUCGGGU GUCCUUCCUC GCGCCCGCAG GACCACCCCU CGCCCCCUUU

241 GCGCUGUCGC UUCGGCUACU ACCCGGUGGA AACAACUGAA GCUCCCGAGA ACCGCUUUUU

301 CUCUAUCUUA CUUGCUUCGG GGCGAGGGUG UUUAGCCCUU GGAACCGCAG UUGGUUCCU

Putative secondary structure of the PSTVd viroid

Taxonomy

• Family Pospiviroidae
  • Genus Pospiviroid; type species: Potato spindle tuber viroid
  • Genus Hostuviroid; type species: Hop stunt viroid
  • Genus Cocadviroid; type species: Coconut cadang-cadang viroid
  • Genus Apscaviroid; type species: Apple scar skin viroid
  • Genus Coleviroid; type species: Coleus blumei viroid 1
• Family Avsunviroidae
  • Genus Avsunviroid; type species: Avocado sunblotch viroid
  • Genus Pelamoviroid; type species: Peach latent mosaic viroid

Viroids and RNA silencing

There has long been confusion over how viroids are able to induce symptoms on plants without encoding any protein products within their sequences. Evidence now suggests that RNA silencing is involved in the process.

Firstly, changes to the viroid genome can dramatically alter its virulence (Dickson et al. 1979). This reflects that fact that any siRNAs produced would have less complementary base pairing with target messenger RNA. Secondly, siRNAs corresponding to sequences from viroid genomes have been isolated from infected plants (Papaefthimiou et al. 2001). Finally, transgenic expression of the noninfectious hpRNA of potato spindle tuber viroid develop all the corresponding viroid like symptoms (Wang et al. 2004).

This evidence indicates that when viroids replicate via a double stranded intermediate RNA, they are targeted by a dicer enzyme and cleaved into siRNAs that are then loaded onto the RNA-induced silencing complex. The viroid siRNAs actually contain sequences capable of complementary base pairing with the plant's own messenger RNAs and induction of degradation or inhibition of translation is what causes the classic viroid symptoms.

See also

• Virus
• Prion

References

ISBN links support NWE through referral fees

• Agricultural Research Service (ARS). 1989. Tracking the elusive viroid USDA Agricultural Research Service. Retrieved December 4, 2007.
• Biotecnika. 2005. Structure, replication, transmission, and human pathologies induced by viroids Biotecnika. Retrieved December 4, 2007.
• Collins, R. F., D. L. Gellatly, O. P. Sehgal, and M. G. Abouhaidar. 1998. “Self-cleaving circular RNA associated with rice yellow mottle virus is the smallest viroid-like RNA.” Virology, 241(2): 269-275. PMID 9499801
• Davis, R. E., R. Hammond, R. A. Owens, and Y. Zhao. 1999. Viroids! From scourge to boon in the 21st century? USDA Agricultural Research Service. Retrieved December 4, 2007.
• Dickson, E. H. D. Robertson, C. L. Niblett, R. K. Horst, and M. Zaitlin. 1979. “Minor differences between nucleotide sequences of mild and severe strains of potato spindle tuber viroid.” Nature, 277: 60-62.
• Oakland University, Department of Biology (OU). 2007. Discovery of viroids Oakland University, Department of Biology. Retrieved December 4, 2007.
• Papaefthimiou, I., A. Hamilton, M. Denti, D. Baulcombe, M. Tsagris, and M. Tabler. 2001. Replicating potato spindle tuber viroid RNA is accompanied by short RNA fragments that are characteristic of post-transcriptional gene silencing Nucleic Acids Res. 29(11): 2395-2400. PMID 11376158 Retrieved December 4, 2007.
• Wang, M.B., X.Y. Bian, L.M. Wu, L.X. Liu, N. A. Smith, D. Isenegger, R.M. Wu, C. Masuta, V. B. Vance, J. M. Watson, A. Rezaian, E. S. Dennis, and P. M. Waterhouse. 2004. “On the role of RNA silencing in the pathogenicity and evolution of viroids and viral satellites.” Proc. Natl. Acad. Sci. U.S.A., 101(9): 3275-3280. PMID 14978267 Retrieved December 4, 2007.