Rapid evolutionary dynamics of the Pepino mosaic virus – status and future perspectives
Divisions of PAS
eISSN 1899–007X ; ISSN 1427–4345
Gómez (2012), Phylodynamics of Pepino mosaic virus in Spain, European Journal of Plant Pathology, 134. ; Hasiów (2012), Characterization of the necrosis determinants of the European genotype of Pepino mosaic virus by site specific mutagenesis of an infectious cDNA clone, Archives of Virology, 157. ; Bol (2008), Role of capsid proteins In : Plant Virology Protocols : From Viral Sequence to Protein Function eds Methods in Molecular Press pp, Biology, 21. ; Sung (2001), Plant Hsp molecular chaperones : protein structure , gene family , expression and function, Physiologia Plantarum, 70, 443. ; Callaway (2001), The multifunctional capsid proteins of plant RNA viruses, Annual Review of Phytopathology, 39, 419. ; Hasiów (2013), A new method for detection and discrimination of Pepino mosaic virus isolates using high resolution melting analysis of the triple gene block, Journal of Virological Methods, 3, 193. ; Zong (2014), Rapid detection of Prunus necrotic ringspot virus using magnetic nanoparticle - assisted reverse transcription loop - mediated isothermal amplification mosaic virus isolates from Italy, Journal of Virological Methods Journal of Plant Pathology, 93, 208. ; Hanssen (2009), Pepino mosaic virus isolates and differential symptomatology in tomato, Plant Pathology, 58, 450. ; Blystad (2015), der Host range and symptomatology of Pepino mosaic virus strains occurring in Europe, European Journal of Plant Pathology, 143, 43. ; Schwarz (2010), Spread and interaction of Pepino mosaic virus and Pythium aphanidermatum in a closed nutrient solution recirculation system : effects on tomato growth and yield, Plant Pathology, 59, 443. ; Ling (2008), Pepino mosaic virus on tomato seed : virus location and mechanical transmission, Plant Disease, 92, 1701. ; Zielinska (2012), Cytopathology of Tomato torrado virus infection in tomato and Nicotiana benthamiana, Journal of Phytopathology, 11, 160. ; Duff (2015), A pathogenicity determinant maps to the N - terminal coat protein region of the Pepino mosaic virus genome, Molecular Plant Pathology, 16, 308. ; Whitham (2003), Diverse RNA viruses elicit the expression of common sets of genes in susceptible Arabidopsis thaliana plants, Plant Journal, 33, 271. ; Hasiów (2011), Single mutation converts mild pathotype of the Pepino mosaic virus into necrotic one, Virus Research, 159, 57. ; Pospieszny (2008), Characterization of two distinct Polish isolates of Pepino mosaic virus, European Journal of Plant Pathology, 122, 443. ; Wright (1999), Pepino mosaic Potexvirus : First Records in Tomato in the United Kingdom Central Science Laboratory UK, Plant Disease Notes. ; French (2001), First report of Pepino mosaic virus in Canada and the United States, Plant Disease, 10, 85. ; Chen (2008), Influence of cytoplasmic heat shock protein on viral infection of Nicotiana benthamiana, Molecular Plant Pathology, 70, 809. ; Vozárová (2013), Plum pox virus accumulations in different genome parts during a long - term maintenance in Prunus host plants and passage in Nicotiana benthamiana, Acta Virologica, 57, 369. ; Nagy (2011), Emerging picture of host chaperone and cyclophilin roles in RNA virus replication, Virology, 411. ; Duffy (2008), Rates of evolutionary change in viruses : patterns and determinants, Nature Review Genetics, 9, 267. ; Leisner (1992), Long distance movement of cauliflower mosaic virus in infected turnip plants, Molecular Plant - Microbe Interactions, 5, 41. ; Andino (2015), Viral quasi - species, Virology, 479. ; Pagán (2006), Genetic structure of the population of Pepino mosaic virus infecting tomato crops in Spain, Phytopathology, 96, 274. ; Hasiów (2008), Complete genomic RNA sequence of the Polish Pepino mosaic virus isolate belonging to the US strain, Virus Genes, 36, 1. ; Wang (1987), Effectiveness of cross - protection by mild mutants of papaya ringspot virus for control of ringspot disease of papaya in Taiwan, Plant Disease, 71, 491. ; Morozov (2003), Triple gene block : modular design of a multifunctional machine for plant virus movement, Journal of General Virology, 84, 1351. ; Moreno (2014), Ecological and genetic determinants of Pepino mosaic virus emergence, Journal of Virology, 8, 3359. ; Pita (2007), Environment determines fidelity for an RNA virus replicase, Journal of Virology, 81, 9072. ; Alfaro (2010), Ultrastructural aspects of tomato leaves infected by Tomato torrado virus ) and co - infected by other viruses, Plant Pathology, 59, 231. ; Mathioudakis (2012), Pepino mosaic virus capsid protein interacts with a tomato heat shock protein cognate, Virus Research, 70, 28. ; Hasiów (2009), New necrotic isolates of Pepino mosaic virus representing the CH genotype, Journal of Phytopathology, 7, 157. ; Ling (2007), Molecular characterization of two Pepino mosaic virus variants from imported tomato seed reveals high levels of sequence identity between Chilean and US isolates, Virus Genes, 34, 1. ; Ling (2013), Pepino mosaic virus genotype shift in North America and development of a loop - mediated isothermal amplification for rapid genotype identification, Virology Journal, 10, 117. ; Mehle (2014), Survival and transmission of Potato virus Y , Pepino mosaic virus , and Potato spindle tuber viroid in water, Applied and Environmental Microbiology, 80, 1455. ; Pospieszny (2010), Biological and molecular characterization of Polish isolates of Tomato torrado virus, Journal of Phytopathology, 158. ; Domingo (2012), Viral quasispecies evolution and, Microbiology Molecular Biology Review, 76, 159. ; Carrington (1996), Cell - to - cell and long - distance transport of viruses in plants, Plant Cell, 8, 1669. ; Mayer (2005), Hsp chaperones : cellular functions and molecular mechanism Cellular and Molecular, Life Sciences, 62, 70. ; Roggero (2001), First report of Pepino mosaic virus in tomato in Italy, Plant Pathology, 50, 798. ; Gómez (2009), Mixed infections of Pepino mosaic virus strains modulate the evolutionary dynamics of this emergent virus, Journal of Virology, 83, 12378. ; Alfaro (2009), Transmission of Pepino mosaic virus by the fungal vector Olpidium virulentus, Journal of Phytopathology, 158. ; Mumford (2001), The partial sequencing of genomic RNA of a UK isolate of Pepino mosaic virus and the comparison of the coat protein sequence with other isolates from Europe and Peru, Archives of Virology, 146, 2455. ; Rodríguez (1989), Genetic heterogeneity of the RNA genome population of the plant virus U - TMV, Virology, 5, 170. ; Minicka (2015), b Molecular evolution of Pepino mosaic virus during long - term passaging in different hosts and its impact on virus virulence, Annals of Applied Biology, 166. ; Spence (2006), Effect of Pepino mosaic virus on the yield and quality of glasshouse - grown tomatoes in the UK, Plant Pathology, 55. ; Sempere (2016), Pepino mosaic virus RNA - dependent RNA polymerase pol domain is a hypersensitive response - like elicitor shared by necrotic and mild isolates, Phytopathology, 106. ; Aparicio (2005), Virus induction of heat shock protein reflects a general response to protein accumulation in the plant cytosol, Plant Physiology, 70, 138. ; Wan (2015), Turnip mosaic virus moves systemically through both phloem and xylem as membrane - associated complexes, Plant Physiology, 167. ; Noël (2014), Transmission of the Pepino mosaic virus by whitefly, European Journal of Plant Pathology, 138. ; Wang (2009), A key role for heat shock protein in the localization and insertion of tombusvirus replication proteins to intercellular membranes, Journal of Virology, 70, 3276. ; Gutiérrez (2009), Real - time quantitative PCR based sensitive detection and strain discrimination of Pepino mosaic virus, Journal of Virological Methods, 162, 46. ; Tiberini (2011), Complete sequence , genotyping and comparative analysis of Pepino mosaic virus isolates from Italy, Journal of Plant Pathology, 93, 437. ; Verchot (2005), A new cell - to - cell transport model for potexviruses, Molecular Plant - Microbe Interactions, 18, 283. ; Hasiów (2014), Crossprotection between different pathotypes of Pepino mosaic virus representing Chilean genotype, Acta Scientiarum Polonorum , Hortorum Cultus, 13, 177. ; van (2000), del First report of Pepino mosaic virus on tomato, Plant Disease, 84, 103. ; Hanssen (2010), der a Seed transmission of Pepino mosaic virus in tomato, European Journal of Plant Pathology, 126. ; Pospieszny (2006), New Polish isolate of Pepino mosaic virus highly distinct from European Tomato and US strains, Plant Disease, 2, 1106. ; Bukau (1998), The HSP and HSP chaperone machines, Cell, 70, 92. ; Hanssen (2010), b Cross - protection or enhanced symptom display in greenhouse tomato co - infected with different Pepino mosaic virus isolates, Plant Pathology, 59, 13. ; Hasiów (2013), Detection of Pepino mosaic virus isolates from tomato by one - step reverse transcription loop - mediated isothermal amplification, Archives of Virology, 10, 158. ; Medina (2006), Immunolocalization of Tomato yellow leaf curl sardinia virus in natural host plants and its vector Bemisia tabaci, Journal of Plant Pathology, 88, 299. ; Hanssen (2008), Genetic characterization of Pepino mosaic virus isolates from Belgian greenhouse tomatoes reveals genetic recombination, European Journal Plant Pathology, 121, 131. ; Owor (2004), Field studies of cross protection with cassava mosaic geminiviruses in Uganda, Journal of Phytopathology, 152. ; Jones (1980), Pepino mosaic virus , a new potexvirus from pepino ( Solanum muricatum ), Annals of Applied Biology, 94, 61. ; Lan (2010), A unique glycine - rich motif at the N - terminal region of Bamboo mosaic virus coat protein is required for symptom expression Plant - Microbe Interaction, Molecular, 23, 903. ; Hanssen (2010), Pepino mosaic virus : a successful pathogen that rapidly evolved from emerging to endemic in tomato crops, Molecular Plant Pathology, 11, 179. ; Rast (1972), MII an artificial symptomless mutant of tobacco mosaic virus for seedling inoculation of tomato crops, Netherlands Journal of Plant Pathology, 78. ; Hasiów (2010), a Quasispecies nature of Pepino mosaic virus and its evolutionary dynamics, Virus Genes, 41, 260. ; Hasiów (2013), Ratio of mutated versus wild - type coat protein sequences in Pepino mosaic virus determines the nature and severity of yellowing symptoms on tomato plants, Molecular Plant Pathology, 14, 923. ; Córdoba (2007), Seed transmission of Pepino mosaic virus and efficacy of tomato seed disinfection treatments, Plant Disease, 91, 1250. ; Cotillon (2002), Complete nucleotide sequence of the genomic RNA of a French isolate of Pepino mosaic virus, Archives of Virology, 11, 147. ; Roberts (1997), Phloem unloading in sink leaves of Nicotiana benthamiana : comparison of a fluorescent solute with a fluorescent virus, Plant Cell, 9, 1381. ; Ling (2007), Development of a onestep immunocapture real - time TaqMan RT - PCR assay for the broad spectrum detection of Pepino mosaic virus, Journal of Virological Methods, 144, 65. ; Maroon (2005), Two unique US isolates of Pepino mosaic virus from a limited source of pooled tomato tissue are distinct from a third ( European - like ) US isolate, Archives of Virology, 150. ; Aguilar (2002), Complete sequence of the Pepino mosaic virus RNA genome Archive, of Virology, 10, 147. ; Wallis (2007), Adaptation of Plum pox virus to a herbaceous host ( Pisum sativum ) following serial passages, Journal of General Virology, 88, 2839. ; Minicka (2015), a Ultrastructural insights into tomato infections caused by three different pathotypes of Pepino mosaic virus and immunolocalization of viral coat proteins, Micron, 79. ; Peng (2012), Detection of cucumber mosaic virus isolates from banana by one - step reverse transcription loop - mediated isothermal amplification, Archives of Virology, 11, 157. ; Shipp (2008), Vectoring of Pepino mosaic virus by bumble - bees in tomato greenhouses, Annals of Applied Biology, 153. ; Hasiów (2010), b Evidence for RNA recombination between distinct isolates of Pepino mosaic virus, Acta Biochimica Polonica, 57, 385. ; Ortega (2016), a Single nucleotide polymorphisms in the coat protein of PepMV are responsible for yellowing pathotypes in tomato crops In : Proceedings of the th International pp, Plant Virus Epidemiology Symposium, 13, 122. ; Fletcher (1978), The use of avirulent virus strain to protect plants against the effects of virulent strains, Annals of Applied Biology, 89.