Geminiviridae is a family of plant viruses that encode their genetic information on a circular genome of single-stranded (ss) DNA. There are 520 species in this family, assigned to 14 genera.[1][2][3] Diseases associated with this family include: bright yellow mosaic, yellow mosaic, yellow mottle, leaf curling, stunting, streaks, reduced yields.[2][4] They have single-stranded circular DNA genomes encoding genes that diverge in both directions from a virion strand origin of replication (i.e. geminivirus genomes are ambisense). According to the Baltimore classification they are considered class II viruses. It is the largest known family of single stranded DNA viruses.
Geminiviridae | |
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Purified Maize streak virus (MSV) particles stained with uranyl acetate. Size bar indicates 50 nm. | |
Virus classification | |
(unranked): | Virus |
Realm: | Monodnaviria |
Kingdom: | Shotokuvirae |
Phylum: | Cressdnaviricota |
Class: | Repensiviricetes |
Order: | Geplafuvirales |
Family: | Geminiviridae |
Genera | |
Mastrevirus and curtovirus transmission is via various leafhopper species (e.g. maize streak virus and other African streak viruses are transmitted by Cicadulina mbila), the only known topocuvirus species, Tomato pseudo-curly top virus, is transmitted by the treehopper Micrutalis malleifera, and begomoviruses are transmitted by the whitefly species, Bemisia tabaci.
These viruses are responsible for a significant amount of crop damage worldwide. Epidemics of geminivirus diseases have arisen due to a number of factors, including the recombination of different geminiviruses coinfecting a plant, which enables novel, possibly virulent viruses to be developed. Other contributing factors include the transport of infected plant material to new locations, expansion of agriculture into new growing areas, and the expansion and migration of vectors that can spread the virus from one plant to another.[5]
Virology
editThe genome of ssDNA can either be a single component between 2500 and 3100 nucleotides, or, in the case of some begomoviruses, two similar-sized components each between 2600 and 2800 nucleotides. They have elongated, geminate capsids with two incomplete T=1 icosahedra joined at the missing vertex. The capsids range in size from 18 to 20 nm in diameter with a length of about 30 nm. Begomoviruses with two component (i.e. bipartite) genomes have these components separated into two different particles both of which must usually be transmitted together to initiate a new infection within a suitable host cell.
Genus | Type Species | Structure | Symmetry | Capsid | Genomic arrangement | Genomic segmentation |
---|---|---|---|---|---|---|
Becurtovirus | Beet curly top Iran virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Begomovirus | Bean golden yellow mosaic virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Segmented |
Capulavirus[6] | Euphorbia caput-medusae latent virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Curtovirus | Beet curly top virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Eragrovirus | Eragrostis curvula streak virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Grablovirus[7] | Grapevine red blotch virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Mastrevirus | Maize streak virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Topocuvirus | Tomato pseudo-curly top virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Turncurtovirus | Turnip curly top virus | Twinned Icosahedral | Incomplete T = 1 | Non-enveloped | Circular | Monopartite |
Taxonomy
editThe following genera are recognized:[3]
- Becurtovirus
- Begomovirus
- Capulavirus
- Citlodavirus
- Curtovirus
- Eragrovirus
- Grablovirus
- Maldovirus
- Mastrevirus
- Mulcrilevirus
- Opunvirus
- Topilevirus
- Topocuvirus
- Turncurtovirus
Several additional genera have been proposed: Baminivirus, Nimivirus and Niminivirus.[8]
Replication
editGeminivirus genomes encode only a few proteins; thus, they are dependent on host cell factors for replication: these include factors such as DNA polymerase—and probably repair polymerases—in order to amplify their genomes, as well as transcription factors. Geminiviruses replicate via a rolling circle mechanism like bacteriophages such as M13, and many plasmids. Replication occurs within the nucleus of an infected plant cell. First the single-stranded circular DNA is converted to a double-stranded circular intermediate. This step involves the use of cellular DNA repair enzymes to produce a complementary negative-sense strand, using the viral genomic or plus-sense DNA strand as a template. The next step is the rolling circle phase, where the viral strand is cleaved at a specific site situated within the origin of replication by the viral Rep protein in order to initiate replication.[9] This process in a eukaryotic nucleus can give rise to concatemeric double-stranded forms of replicative intermediate genomes, although double-stranded unit circles can be isolated from infected plants and cells. New single-stranded DNA forms of the virus genome (plus-sense) are probably formed by interaction of the coat protein with replicating DNA intermediates, as genomes lacking a CP gene do not form ssDNA. The ssDNA is packaged into germinate particles in the nucleus. It is not clear if these particles can then leave the nucleus and be transmitted to surrounding cells as virions, or whether ssDNA associated with coat protein and a movement protein is the form of the genome that gets trafficked from cell to cell via the plasmodesmata.[10]
These viruses tend to be introduced into and initially infect differentiated plant cells, via the piercing mouthparts of the vector insect: however, these cells generally lack the host enzymes necessary for DNA replication, making it difficult for the virus to replicate. To overcome this block geminiviruses can induce plant cells to reenter the cell cycle from a quiescent state so that viral replication can occur.[11]
Virus Rep protein
editThe only protein encoded in the viral genome that is essential for geminiviral DNA replication is the geminiviral replication protein Rep.[12] Rep initiates rolling circle replication of the viral DNA and interacts with other host proteins that are components of the replication machinery.
Host RAD54 and DNA polymerases
editHost protein RAD54 modulates geminiviral DNA replication.[13] RAD54 protein acts in DNA recombination and repair and appears to be necessary for rolling circle replication of the viral DNA. Also, replication of the geminivirus DNA is mediated by the host plant DNA polymerases alpha and delta.[14]
Genus | Host details | Tissue tropism | Entry details | Release details | Replication site | Assembly site | Transmission |
---|---|---|---|---|---|---|---|
Becurtovirus | Spinach | Phloem; sieve; phloem-limited | Viral movement; mechanical inoculation | Budding | Nucleus | Nucleus | Viral movement; contact |
Begomovirus | Dicotyledonous plants | Phloem; sieve; phloem-limited | Viral movement; mechanical inoculation | Budding | Nucleus | Nucleus | Bemisia tabaci whiteflies |
Capulavirus | Dicotyledonous plants | None | Viral movement; mechanical inoculation | Budding | Nucleus | Nucleus | Aphid |
Curtovirus | Dicotyledonous plants | Phloem-limited | Viral movement; mechanical inoculation | Budding | Nucleus | Nucleus | Beet leefhopper |
Eragrovirus | Plants | None | Viral movement; mechanical inoculation | Budding | Nucleus | Nucleus | Treehopper; leafhopper |
Grablovirus | Vitis vinifera (grapevine) | None | Viral movement; mechanical inoculation | Budding | Nucleus | Nucleus | Treehopper |
Mastrevirus | Monocots[15] | None | Viral movement; mechanical inoculation | Budding | Nucleus | Nucleus | Leafhopper |
Topocuvirus | Dicotyledonous plants | None | Cell receptor endocytosis | Budding | Nucleus | Nucleus | Leafhopper |
Turncurtovirus | Turnip | None | Cell receptor endocytosis | Budding | Nucleus | Nucleus | Leafhopper |
Evolution
editThese viruses may have evolved from a phytoplasma plasmid.[16] Geminiviruses are capable of horizontal gene transfer of genetic information to the plant host.[17]
References
edit- ^ Zerbini, FM; Briddon, RW; Idris, A; Martin, DP; Moriones, E; Navas-Castillo, J; Rivera-Bustamante, R; Roumagnac, P; Varsani, A; ICTV Report Consortium (February 2017). "ICTV Virus Taxonomy Profile: Geminiviridae". The Journal of General Virology. 98 (2): 131–133. doi:10.1099/jgv.0.000738. PMC 5802298. PMID 28284245.
- ^ a b "Geminiviridae". ICTV Online (10th) Report.
- ^ a b "Virus Taxonomy: 2020 Release". International Committee on Taxonomy of Viruses (ICTV). March 2021. Retrieved 13 May 2021.
- ^ "Viral Zone". ExPASy. Retrieved 15 June 2015.
- ^ Gray and Banerjee; Banerjee, N (1999). "Mechanisms of Arthropod Transmission of Plant and Animal Viruses". Microbiol Mol Biol Rev. 63 (1): 128–148. doi:10.1128/MMBR.63.1.128-148.1999. PMC 98959. PMID 10066833.
- ^ "Genus: Capulavirus - Geminiviridae - ssDNA Viruses - International Committee on Taxonomy of Viruses (ICTV)". International Committee on Taxonomy of Viruses (ICTV). Retrieved 18 August 2017.[dead link]
- ^ "Genus: Grablovirus - Geminiviridae - ssDNA Viruses - International Committee on Taxonomy of Viruses (ICTV)". International Committee on Taxonomy of Viruses (ICTV). Archived from the original on 22 October 2020. Retrieved 18 August 2017.
- ^ Ng TF, Marine R, Wang C, Simmonds P, Kapusinszky B, Bodhidatta L, Oderinde BS, Wommack KE, Delwart E (November 2012). "High variety of known and new RNA and DNA viruses of diverse origins in untreated sewage". J Virol. 86 (22): 12161–75. doi:10.1128/JVI.00869-12. PMC 3486453. PMID 22933275.
- ^ Chasan R (1995). "Geminiviruses: A Twin Approach to Replication" (PDF). Plant Cell. 7 (6): 659–661. doi:10.1105/tpc.7.6.659. PMC 1464598.
- ^ Gutierrez C (2000). "NEW EMBO MEMBERS' REVIEW: DNA replication and cell cycle in plants: learning from geminiviruses". The EMBO Journal. 19 (5): 792–799. doi:10.1093/emboj/19.5.792. PMC 305619. PMID 10698921.
- ^ Hanley Bowdoin lab Archived 11 February 2007 at the Wayback Machine
- ^ Rizvi I, Choudhury NR, Tuteja N (February 2015). "Insights into the functional characteristics of geminivirus rolling-circle replication initiator protein and its interaction with host factors affecting viral DNA replication". Arch Virol. 160 (2): 375–87. doi:10.1007/s00705-014-2297-7. PMID 25449306.
- ^ Kaliappan K, Choudhury NR, Suyal G, Mukherjee SK (March 2012). "A novel role for RAD54: this host protein modulates geminiviral DNA replication". FASEB J. 26 (3): 1142–60. doi:10.1096/fj.11-188508. PMID 22171001.
- ^ Wu M, Wei H, Tan H, Pan S, Liu Q, Bejarano ER, Lozano-Durán R (May 2021). "Plant DNA polymerases α and δ mediate replication of geminiviruses". Nat Commun. 12 (1): 2780. Bibcode:2021NatCo..12.2780W. doi:10.1038/s41467-021-23013-2. PMC 8119979. PMID 33986276.
- ^ "Mastrevirus ~ ViralZone".
- ^ Krupovic M, Ravantti JJ, Bamford DH (2009). "Geminiviruses: a tale of a plasmid becoming a virus". BMC Evol Biol. 9 (1): 112. Bibcode:2009BMCEE...9..112K. doi:10.1186/1471-2148-9-112. PMC 2702318. PMID 19460138.
- ^ Catoni, Marco; Noris, Emanuela; Vaira, Anna Maria; Jonesman, Thomas; Matić, Slavica; Soleimani, Reihaneh; Behjatnia, Seyed Ali Akbar; Vinals, Nestor; Paszkowski, Jerzy; Accotto, Gian Paolo (13 December 2018). "Virus-mediated export of chromosomal DNA in plants". Nature Communications. 9 (1): 5308. Bibcode:2018NatCo...9.5308C. doi:10.1038/s41467-018-07775-w. ISSN 2041-1723. PMC 6293997. PMID 30546019.