Wide Dynamic Range Neutron Flux Monitor Having Fast Time Response for the Large Helical Device

A fast time response, wide dynamic range neutron flux monitor has been developed toward the LHD deuterium operation by using leading-edge signal processing technologies providing maxi- mum counting rate up to ?5 × 109 counts/s. Because a maximum total neutron emission rate over 1 × 1016 n/s is predicted in neutral beam-heated LHD plasmas, fast response and wide dy- namic range capabilities of the system are essential. Preliminary tests have demonstrated success- ful performance as a wide dynamic range monitor along the design

Coupling of transient near infrared photonic with magnetic nanoparticle for potential dissipation-free biomedical application in brain

Combined treatment strategies based on magnetic nanoparticles (MNPs) with near infrared ray (NIR) biophotonic possess tremendous potential for non-invasive therapeutic approach. Nonetheless, investigations in this direction have been limited to peripheral body region and little is known about the potential biomedical application of this approach for brain. Here we report that transient NIR exposure is dissipation-free and has no adverse effect on the viability and plasticity of major brain cells in the presence or absence superparamagnetic nanoparticles. The 808?nm NIR laser module with thermocouple was employed for functional studies upon NIR exposure to brain cells. Magnetic nanoparticles were characterized using transmission electron microscopy (TEM), X-ray diffraction (XRD), dynamic laser scattering (DLS), and vibrating sample magnetometer (VSM). Brain cells viability and plasticity were analyzed using electric cell-substrate impedance sensing system, cytotoxicity evaluation, and confocal microscopy. When efficacious non-invasive photobiomodulation and neuro-therapeutical targeting and monitoring to brain remain a formidable task, the discovery of this dissipation-free, transient NIR photonic approach for brain cells possesses remarkable potential to add new dimension

Turnip mosaic potyvirus probably first spread to Eurasian brassica crops from wild orchids about 1000 years ago

Turnip mosaic potyvirus (TuMV) is probably the most widespread and damaging virus that infects cultivated brassicas worldwide. Previous work has indicated that the virus originated in western Eurasia, with all of its closest relatives being viruses of monocotyledonous plants. Here we report that we have identified a sister lineage of TuMV-like potyviruses (TuMV-OM) from European orchids. The isolates of TuMV-OM form a monophyletic sister lineage to the brassica-infecting TuMVs (TuMV-BIs), and are nested within a clade of monocotyledon-infecting viruses. Extensive host-range tests showed that all of the TuMV-OMs are biologically similar to, but distinct from, TuMV-BIs and do not readily infect brassicas. We conclude that it is more likely that TuMV evolved from a TuMV-OM-like ancestor than the reverse. We did Bayesian coalescent analyses using a combination of novel and published sequence data from four TuMV genes [helper component-proteinase protein (HC-Pro), protein 3(P3), nuclear inclusion b protein (NIb), and coat protein (CP)]. Three genes (HC-Pro, P3, and NIb), but not the CP gene, gave results indicating that the TuMV-BI viruses diverged from TuMV-OMs around 1000 years ago. Only 150 years later, the four lineages of the present global population of TuMV-BIs diverged from one another. These dates are congruent with historical records of the spread of agriculture in Western Europe. From about 1200 years ago, there was a warming of the climate, and agriculture and the human population of the region greatly increased. Farming replaced woodlands, fostering viruses and aphid vectors that could invade the crops, which included several brassica cultivars and weeds. Later, starting 500 years ago, inter-continental maritime trade probably spread the TuMV-BIs to the remainder of the world

Phylogeography and Molecular Evolution of Potato virus Y

Potato virus Y (PVY) is an important plant pathogen, whose host range includes economically important crops such as potato, tobacco, tomato, and pepper. PVY presents three main strains (PVYO, PVYN and PVYC) and several recombinant forms. PVY has a worldwide distribution, yet the mechanisms that promote and maintain its population structure and genetic diversity are still unclear. In this study, we used a pool of 77 complete PVY genomes from isolates collected worldwide. After removing the effect of recombination in our data set, we used Bayesian techniques to study the influence of geography and host species in both PVY population structure and dynamics. We have also performed selection and covariation analyses to identify evolutionarily relevant amino acid residues. Our results show that both geographic and host-driven adaptations explain PVY diversification. Furthermore, purifying selection is the main force driving PVY evolution, although some indications of positive selection accounted for the diversification of the different strains. Interestingly, the analysis of P3N-PIPO, a recently described gene in potyviruses, seems to show a variable length among the isolates analyzed, and this variability is explained, in part, by host-driven adaptation

Emergence and phylodynamics of Citrus tristeza virus in Sicily, Italy

[EN] Citrus tristeza virus (CTV) outbreaks were detected in Sicily island, Italy for the first time in 2002. To gain insight into the evolutionary forces driving the emergence and phylogeography of these CTV populations, we determined and analyzed the nucleotide sequences of the p20 gene from 108 CTV isolates collected from 2002 to 2009. Bayesian phylogenetic analysis revealed that mild and severe CTV isolates belonging to five different clades (lineages) were introduced in Sicily in 2002. Phylogeographic analysis showed that four lineages co-circulated in the main citrus growing area located in Eastern Sicily. However, only one lineage (composed of mild isolates) spread to distant areas of Sicily and was detected after 2007. No correlation was found between genetic variation and citrus host, indicating that citrus cultivars did not exert differential selective pressures on the virus. The genetic variation of CTV was not structured according to geographical location or sampling time, likely due to the multiple introduction events and a complex migration pattern with intense co- and recirculation of different lineages in the same area. The phylogenetic structure, statistical tests of neutrality and comparison of synonymous and nonsynonymous substitution rates suggest that weak negative selection and genetic drift following a rapid expansion may be the main causes of the CTV variability observed today in Sicily. Nonetheless, three adjacent amino acids at the p20 N-terminal region were found to be under positive selection, likely resulting from adaptation events.A.W. and S.F.E. were supported by grant BFU2012-30805 from the Spanish Secretaria de Estado de Investigacion, Desarrollo e Innovacion and by a grant 22371 from the John Templeton Foundation. The opinions expressed in this publication are those of the authors and do not necessarily reflect the views of the John Templeton Foundation. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.Davino, S.; Willemsen, A.; Panno. Stefano; Davino, M.; Catara, A.; Elena Fito, SF.; Rubio, L. (2013). Emergence and phylodynamics of Citrus tristeza virus in Sicily, Italy. PLoS ONE. 8:66700-66700. doi:10.1371/journal.pone.0066700S66700667008Domingo, E., & Holland, J. J. (1997). RNA VIRUS MUTATIONS AND FITNESS FOR SURVIVAL. Annual Review of Microbiology, 51(1), 151-178. doi:10.1146/annurev.micro.51.1.151Grenfell, B. T. (2004). Unifying the Epidemiological and Evolutionary Dynamics of Pathogens. Science, 303(5656), 327-332. doi:10.1126/science.1090727Moya, A., Holmes, E. C., & González-Candelas, F. (2004). The population genetics and evolutionary epidemiology of RNA viruses. Nature Reviews Microbiology, 2(4), 279-288. doi:10.1038/nrmicro863Gray, R. R., Tatem, A. J., Lamers, S., Hou, W., Laeyendecker, O., Serwadda, D., … Salemi, M. (2009). Spatial phylodynamics of HIV-1 epidemic emergence in east Africa. AIDS, 23(14), F9-F17. doi:10.1097/qad.0b013e32832faf61Holmes, E. C. (2008). Evolutionary History and Phylogeography of Human Viruses. Annual Review of Microbiology, 62(1), 307-328. doi:10.1146/annurev.micro.62.081307.162912Pybus, O. G., Suchard, M. A., Lemey, P., Bernardin, F. J., Rambaut, A., Crawford, F. W., … Delwart, E. L. (2012). Unifying the spatial epidemiology and molecular evolution of emerging epidemics. Proceedings of the National Academy of Sciences, 109(37), 15066-15071. doi:10.1073/pnas.1206598109Talbi, C., Lemey, P., Suchard, M. A., Abdelatif, E., Elharrak, M., Jalal, N., … Bourhy, H. (2010). Phylodynamics and Human-Mediated Dispersal of a Zoonotic Virus. PLoS Pathogens, 6(10), e1001166. doi:10.1371/journal.ppat.1001166Vijaykrishna, D., Bahl, J., Riley, S., Duan, L., Zhang, J. X., Chen, H., … Guan, Y. (2008). Evolutionary Dynamics and Emergence of Panzootic H5N1 Influenza Viruses. PLoS Pathogens, 4(9), e1000161. doi:10.1371/journal.ppat.1000161Gómez, P., Sempere, R. N., Aranda, M. A., & Elena, S. F. (2012). Phylodynamics of Pepino mosaic virus in Spain. European Journal of Plant Pathology, 134(3), 445-449. doi:10.1007/s10658-012-0019-0Lefeuvre, P., Martin, D. P., Harkins, G., Lemey, P., Gray, A. J. A., Meredith, S., … Heydarnejad, J. (2010). The Spread of Tomato Yellow Leaf Curl Virus from the Middle East to the World. PLoS Pathogens, 6(10), e1001164. doi:10.1371/journal.ppat.1001164TOMITAKA, Y., & OHSHIMA, K. (2006). A phylogeographical study of the Turnip mosaic virus population in East Asia reveals an ‘emergent’ lineage in Japan. Molecular Ecology, 15(14), 4437-4457. doi:10.1111/j.1365-294x.2006.03094.xWu, B., Blanchard-Letort, A., Liu, Y., Zhou, G., Wang, X., & Elena, S. F. (2011). Dynamics of Molecular Evolution and Phylogeography of Barley yellow dwarf virus-PAV. PLoS ONE, 6(2), e16896. doi:10.1371/journal.pone.0016896MORENO, P., AMBRÓS, S., ALBIACH-MARTÍ, M. R., GUERRI, J., & PEÑA, L. (2008). Citrus tristeza virus: a pathogen that changed the course of the citrus industry. Molecular Plant Pathology, 9(2), 251-268. doi:10.1111/j.1364-3703.2007.00455.xTatineni, S., Robertson, C. J., Garnsey, S. M., & Dawson, W. O. (2011). A plant virus evolved by acquiring multiple nonconserved genes to extend its host range. Proceedings of the National Academy of Sciences, 108(42), 17366-17371. doi:10.1073/pnas.1113227108Folimonova, S. Y. (2012). Superinfection Exclusion Is an Active Virus-Controlled Function That Requires a Specific Viral Protein. Journal of Virology, 86(10), 5554-5561. doi:10.1128/jvi.00310-12Bar-Joseph, M., Marcus, R., & Lee, R. F. (1989). The Continuous Challenge of Citrus Tristeza Virus Control. Annual Review of Phytopathology, 27(1), 291-316. doi:10.1146/annurev.py.27.090189.001451Davino, S., Rubio, L., & Davino, M. (2005). Molecular analysis suggests that recent Citrus tristeza virus outbreaks in Italy were originated by at least two independent introductions. European Journal of Plant Pathology, 111(3), 289-293. doi:10.1007/s10658-003-2815-zAlbiach-Marti, M. R., Mawassi, M., Gowda, S., Satyanarayana, T., Hilf, M. E., Shanker, S., … Dawson, W. O. (2000). Sequences of Citrus Tristeza Virus Separated in Time and Space Are Essentially Identical. Journal of Virology, 74(15), 6856-6865. doi:10.1128/jvi.74.15.6856-6865.2000Rubio, L., Ayllon, M. A., Kong, P., Fernandez, A., Polek, M., Guerri, J., … Falk, B. W. (2001). Genetic Variation of Citrus Tristeza Virus Isolates from California and Spain: Evidence for Mixed Infections and Recombination. Journal of Virology, 75(17), 8054-8062. doi:10.1128/jvi.75.17.8054-8062.2001Silva, G., Marques, N., & Nolasco, G. (2011). The evolutionary rate of citrus tristeza virus ranks among the rates of the slowest RNA viruses. Journal of General Virology, 93(2), 419-429. doi:10.1099/vir.0.036574-0Mawassi, M., Mietkiewska, E., Gofman, R., Yang, G., & Bar-Joseph, M. (1996). Unusual Sequence Relationships Between Two Isolates of Citrus Tristeza Virus. Journal of General Virology, 77(9), 2359-2364. doi:10.1099/0022-1317-77-9-2359Vives, M. C., Dawson, W. O., Flores, R., L√≥pez, C., Albiach-Mart√≠, M. R., Rubio, L., … Moreno, P. (1999). The complete genome sequence of the major component of a mild citrus tristeza virus isolate. Journal of General Virology, 80(3), 811-816. doi:10.1099/0022-1317-80-3-811Martín, S., Elena, S. F., Guerri, J., Moreno, P., Sambade, A., Rubio, L., … Vives, M. C. (2009). Contribution of recombination and selection to molecular evolution of Citrus tristeza virus. Journal of General Virology, 90(6), 1527-1538. doi:10.1099/vir.0.008193-0Vives, M. C., Rubio, L., Sambade, A., Mirkov, T. E., Moreno, P., & Guerri, J. (2005). Evidence of multiple recombination events between two RNA sequence variants within a Citrus tristeza virus isolate. Virology, 331(2), 232-237. doi:10.1016/j.virol.2004.10.037D’Urso, F., Sambade, A., Moya, A., Guerri, J., & Moreno, P. (2003). Variation of haplotype distributions of two genomic regions of Citrus tristeza virus populations from eastern Spain. Molecular Ecology, 12(2), 517-526. doi:10.1046/j.1365-294x.2000.01747.xSambade, A., Rubio, L., Garnsey, S. M., Costa, N., Muller, G. W., Peyrou, M., … Moreno, P. (2002). Comparison of viral RNA populations of pathogenically distinct isolates of Citrus tristeza virus : application to monitoring cross-protection. Plant Pathology, 51(3), 257-265. doi:10.1046/j.1365-3059.2002.00720.xReed, J. C., Kasschau, K. D., Prokhnevsky, A. I., Gopinath, K., Pogue, G. P., Carrington, J. C., & Dolja, V. V. (2003). Suppressor of RNA silencing encoded by Beet yellows virus. Virology, 306(2), 203-209. doi:10.1016/s0042-6822(02)00051-xFolimonova, S. Y., Robertson, C. J., Shilts, T., Folimonov, A. S., Hilf, M. E., Garnsey, S. M., & Dawson, W. O. (2009). Infection with Strains of Citrus Tristeza Virus Does Not Exclude Superinfection by Other Strains of the Virus. Journal of Virology, 84(3), 1314-1325. doi:10.1128/jvi.02075-09Kong, P., Rubio, L., Polek, M., & Falk, B. W. (2000). Virus Genes, 21(3), 139-145. doi:10.1023/a:1008198311398Powell, C. A., Pelosi, R. R., Rundell, P. A., & Cohen, M. (2003). Breakdown of Cross-Protection of Grapefruit from Decline-Inducing Isolates of Citrus tristeza virus Following Introduction of the Brown Citrus Aphid. Plant Disease, 87(9), 1116-1118. doi:10.1094/pdis.2003.87.9.1116Roistacher C, Dodds J. (1993) Failure of 100 mild Citrus tristeza virus isolates from california to cross protect against a challenge by severe sweet orange stem pitting isolates. Proc 12th Conf IOCV: 100–107.Ayllón, M. A., Rubio, L., Sentandreu, V., Moya, A., Guerri, J., & Moreno, P. (2006). Variations in Two Gene Sequences of Citrus Tristeza Virus after Host Passage. Virus Genes, 32(2), 119-128. doi:10.1007/s11262-005-6866-4Ayllón, M. A., Rubio, L., Moya, A., Guerri, J., & Moreno, P. (1999). The Haplotype Distribution of Two Genes of Citrus Tristeza Virus Is Altered after Host Change or Aphid Transmission. Virology, 255(1), 32-39. doi:10.1006/viro.1998.9566Sentandreu, V., Castro, J. A., Ayllón, M. A., Rubio, L., Guerri, J., González-Candelas, F., … Moya, A. (2005). Evolutionary analysis of genetic variation observed in citrus tristeza virus (CTV) after host passage. Archives of Virology, 151(5), 875-894. doi:10.1007/s00705-005-0683-xMatos, L. A., Hilf, M. E., Cayetano, X. A., Feliz, A. O., Harper, S. J., & Folimonova, S. Y. (2013). Dramatic Change in Citrus tristeza virus Populations in the Dominican Republic. Plant Disease, 97(3), 339-345. doi:10.1094/pdis-05-12-0421-reDavino, S., Davino, M., Sambade, A., Guardo, M., & Caruso, A. (2003). The First Citrus tristeza virus Outbreak Found in a Relevant Citrus Producing Area of Sicily, Italy. Plant Disease, 87(3), 314-314. doi:10.1094/pdis.2003.87.3.314aRUBIO, L., AYLLONl, M. A., GUERRI, J., PAPPU, H., NIBLETT, C., & MORENO, P. (1996). Differentiation of citrus tristeza closterovirus (CTV) isolates by single-strand conformation polymorphism analysis of the coat protein gene. Annals of Applied Biology, 129(3), 479-489. doi:10.1111/j.1744-7348.1996.tb05770.xLarkin, M. A., Blackshields, G., Brown, N. P., Chenna, R., McGettigan, P. A., McWilliam, H., … Higgins, D. G. (2007). 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Evaluation of magnetic and thermal properties of ferrite nanoparticles for biomedical applications

10.4283/JMAG.2011.16.2.164Journal of Magnetics162164-16