Myoviridae
Myoviridae | |
---|---|
TEM Image of a Synechococcus Phage S-PM2 virion | |
Virus classification | |
(unranked): | Virus |
Realm: | Duplodnaviria |
Kingdom: | Heunggongvirae |
Phylum: | Uroviricota |
Class: | Caudoviricetes |
Order: | Caudovirales |
Family: | Myoviridae |
Subfamilies and genera | |
see text |
Myoviridae was a family of bacteriophages in the order Caudovirales. The family Myoviridae and order Caudovirales have now been abolished, with the term myovirus now used to refer to the morphology of viruses in this former family.[1] Bacteria and archaea serve as natural hosts. There were 625 species in this family, assigned to eight subfamilies and 217 genera.[2][3]
Subdivisions
The subfamily Tevenvirinae (synonym: Tequatrovirinae) is named after its type species Enterobacteria phage T4. Members of this subfamily are morphologically indistinguishable and have moderately elongated heads of about 110 nanometers (nm) in length, 114 nm long tails with a collar, base plates with short spikes and six long kinked tail fibers. The genera within this subfamily are divided on the basis of head morphology with the genus Tequatrovirus (Provisional name: T4virus) having a head length of 137 nm and those in the genus Schizotequatrovirus being 111 nm in length. Within the genera on the basis of protein homology the species have been divided into a number of groups.
The subfamily Peduovirinae have virions with heads of 60 nm in diameter and tails of 135 × 18 nm. These phages are easily identified because contracted sheaths tend to slide off the tail core. The P" phage is the type species.
The subfamily Spounavirinae are all virulent, broad-host range phages that infect members of the Bacillota. They possess isometric heads of 87-94 nm in diameter and conspicuous capsomers, striated 140-219 nm long tails and a double base plate. At the tail tip are globular structures now known to be the base plate spikes and short kinked tail fibers with six-fold symmetry. Members of this group usually possess large (127–142 kb) nonpermuted genomes with 3.1–20 kb terminal redundancies. The name for this subfamily is derived from SPO plus una (Latin for one).
The haloviruses HF1 and HF2 belong to the same genus but since they infect archaea rather than bacteria are likely to be placed in a separate genus once their classification has been settled.[4]
A dwarf group has been proposed on morphological and genomic grounds. This group includes the phages Aeromonas salmonicida phage 56, Vibrio cholerae phages 138 and CP-T1, Bdellovibrio phage φ1422 and Pectobacterium carotovorum phage ZF40.[5] Their shared characteristics include an identical virion morphology, characterized by usually short contractile tails and all have genome sizes of approximately 45 kilobases. The gene order in the structural unit of the genome is in the order: terminase—portal—head—tail—base plate—tail fibers.
Virology
Viruses in the former family Myoviridae are non-enveloped, with head-tail (with a neck) geometries. Genomes are linear, double-stranded DNA, around 33-244kb in length. The genome codes for 40 to 415 proteins.[2] It has terminally redundant sequences. The GC-content is ~35%. The genome encodes 200-300 proteins that are transcribed in operons. 5-Hydroxymethylcytosine may be present in the genome (instead of thymidine).
The tubular tail has helical symmetry and is 16-20 nm in diameter. It consists of a central tube, a contractile sheath, a collar, a base plate, six tail pins and six long fibers. It is similar to Tectiviridae, but differs in the fact that a myovirus' tail is permanent.
Contractions of the tail require ATP. On contraction of the sheath, sheath subunits slide over each other and the tail shortens to 10–15 nm in length.
Life cycle
On attaching to a host cell, the virus uses its contractile sheath like a syringe, piercing the cell wall with its central tube and injecting the genetic material into the host. The injected DNA takes over the host cell's mechanisms for transcription and translation and begins to manufacture new viruses. Replication follows the replicative transposition model. DNA-templated transcription is the method of transcription. Translation takes place by -1 ribosomal frameshifting. The virus exits the host cell by lysis, and holin/endolysin/spanin proteins. Bacteria and archaea serve as the natural host. Transmission route is passive diffusion.[2]
Although Myoviruses are in general lytic, lacking the genes required to become lysogenic, a number of temperate species are known.
Applications
Because most Myoviridae are lytic, rather than temperate, phages, some researchers have investigated their use as a therapy for bacterial diseases in humans and other animals.[7]
Taxonomy
The following eight subfamilies are recognized:[3]
- Emmerichvirinae
- Eucampyvirinae
- Gorgonvirinae
- Ounavirinae
- Peduovirinae
- Tevenvirinae
- Twarogvirinae
- Vequintavirinae
Additionally, the following genera are unassigned to a subfamily:[3]
- Abouovirus
- Acionnavirus
- Agricanvirus
- Ahtivirus
- Alcyoneusvirus
- Alexandravirus
- Anamdongvirus
- Anaposvirus
- Aokuangvirus
- Asteriusvirus
- Atlauavirus
- Aurunvirus
- Ayohtrevirus
- Baikalvirus
- Bakolyvirus
- Barbavirus
- Bcepfunavirus
- Bcepmuvirus
- Becedseptimavirus
- Bellamyvirus
- Bendigovirus
- Biquartavirus
- Bixzunavirus
- Borockvirus
- Brigitvirus
- Brizovirus
- Brunovirus
- Busanvirus
- Carpasinavirus
- Chakrabartyvirus
- Charybdisvirus
- Chiangmaivirus
- Colneyvirus
- Cymopoleiavirus
- Derbicusvirus
- Dibbivirus
- Donellivirus
- Elmenteitavirus
- Elvirus
- Emdodecavirus
- Eneladusvirus
- Eponavirus
- Erskinevirus
- Eurybiavirus
- Ficleduovirus
- Flaumdravirus
- Fukuivirus
- Gofduovirus
- Goslarvirus
- Haloferacalesvirus
- Hapunavirus
- Heilongjiangvirus
- Iapetusvirus
- Iodovirus
- Ionavirus
- Jedunavirus
- Jilinvirus
- Jimmervirus
- Kanagawavirus
- Kanaloavirus
- Klausavirus
- Kleczkowskavirus
- Kungbxnavirus
- Kylevirus
- Lagaffevirus
- Leucotheavirus
- Libanvirus
- Lietduovirus
- Llyrvirus
- Loughboroughvirus
- Lubbockvirus
- Machinavirus
- Marfavirus
- Marthavirus
- Mazuvirus
- Menderavirus
- Metrivirus
- Mieseafarmvirus
- Mimasvirus
- Moabitevirus
- Moturavirus
- Muldoonvirus
- Mushuvirus
- Muvirus
- Myoalterovirus
- Myohalovirus
- Myosmarvirus
- Naesvirus
- Namakavirus
- Nankokuvirus
- Neptunevirus
- Nereusvirus
- Nerrivikvirus
- Nodensvirus
- Noxifervirus
- Nylescharonvirus
- Obolenskvirus
- Otagovirus
- Pakpunavirus
- Palaemonvirus
- Pbunavirus
- Peatvirus
- Pemunavirus
- Petsuvirus
- Phabquatrovirus
- Phapecoctavirus
- Phikzvirus
- Pippivirus
- Plaisancevirus
- Plateaulakevirus
- Polybotosvirus
- Pontusvirus
- Popoffvirus
- Punavirus
- Qingdaovirus
- Rahariannevirus
- Radnorvirus
- Ripduovirus
- Risingsunvirus
- Ronodorvirus
- Rosemountvirus
- Saclayvirus
- Saintgironsvirus
- Salacisavirus
- Salmondvirus
- Sarumanvirus
- Sasquatchvirus
- Schmittlotzvirus
- Seoulvirus
- Shandongvirus
- Sherbrookevirus
- Shirahamavirus
- Shalavirus
- Svunavirus
- Tabernariusvirus
- Takahashivirus
- Tamkungvirus
- Taranisvirus
- Tefnutvirus
- Tegunavirus
- Thaumasvirus
- Thetisvirus
- Thornevirus
- Tijeunavirus
- Toutatisvirus
- Tulanevirus
- Vellamovirus
- Vhmlvirus
- Vibakivirus
- Wellingtonvirus
- Wifcevirus
- Winklervirus
- Yokohamavirus
- Yoloswagvirus
- Yongloolinvirus
References
- ^ Turner D, Shkoporov AN, Lood C, Millard AD, Dutilh BE, Alfenas-Zerbini P, van Zyl LJ, Aziz RK, Oksanen HM, Poranen MM, Kropinski AM, Barylski J, Brister JR, Chanisvili N, Edwards RA, Enault F, Gillis A, Knezevic P, Krupovic M, Kurtböke I, Kushkina A, Lavigne R, Lehman S, Lobocka M, Moraru C, Moreno Switt A, Morozova V, Nakavuma J, Reyes Muñoz A, Rūmnieks J, Sarkar BL, Sullivan MB, Uchiyama J, Wittmann J, Yigang T, Adriaenssens EM (January 2023). "Abolishment of morphology-based taxa and change to binomial species names: 2022 taxonomy update of the ICTV bacterial viruses subcommittee". Archives of Virology. 168 (2): 74. doi:10.1007/s00705-022-05694-2. PMC 9868039. PMID 36683075.
- ^ a b c "Viral Zone". ExPASy. Retrieved 1 July 2015.
- ^ a b c "Virus Taxonomy: 2020 Release". International Committee on Taxonomy of Viruses (ICTV). March 2021. Retrieved 11 May 2021.
- ^ Tang, SL; Nuttall, S; Dyall-Smith, M (2004). "Haloviruses HF1 and HF2: evidence for a recent and large recombination event". J Bacteriol. 186 (9): 2810–7. doi:10.1128/JB.186.9.2810-2817.2004. PMC 387818. PMID 15090523.
- ^ Comeau, AM; Tremblay, D; Moineau, S; Rattei, T; Kushkina, AI; Tovkach, FI; Krisch, HM; Ackermann, HW (2012). "Phage morphology recapitulates phylogeny: the comparative genomics of a new group of myoviruses". PLOS ONE. 7 (7): e40102. Bibcode:2012PLoSO...740102C. doi:10.1371/journal.pone.0040102. PMC 3391216. PMID 22792219.
- ^ J. Bernard Heymann, Bing Wang, William W. Newcomb, Weimin Wu, Dennis C. Winkler, Naiqian Cheng, Erin R. Reilly, Ru-Ching Hsia, Julie A. Thomas, Alasdair C. Steven: The Mottled Capsid of the Salmonella Giant Phage SPN3US, a Likely Maturation Intermediate with a Novel Internal Shell. In: Viruses 2020, 12(9). Special Issue Giant or Jumbo Phages, 910. doi:10.3390/v12090910.
- ^ Capparelli, Rosanna; et al. (August 2007). "Experimental phage therapy against Staphylococcus aureus in mice". Antimicrobial Agents and Chemotherapy. 51 (8): 2765–73. doi:10.1128/AAC.01513-06. PMC 1932491. PMID 17517843.
External links