281 research outputs found
Un nouveau sérotype de Salmonella : S. alfort = 3,10 : f, g : e, n, x
Pantaléon Jean, Gledel J., Billon Jean, Corbion B., Le Minor L., Le Coueffic E. Un nouveau sérotype de Salmonella : S. alfort = 3,10 : f, g : e,n, x. In: Bulletin de l'Académie Vétérinaire de France tome 127 n°8-9, 1974. pp. 373-374
Rabbit haemorrhagic disease: experimental study of a recent highly pathogenic GI.2/RHDV2/b strain and evaluation of vaccine efficacy
[EN] In 2010, a variant of the rabbit haemorrhagic disease virus (RHDV) belonging to a new GI.2 genotype was identified in France and rapidly spread worldwide. Due to antigenic difference, new vaccines including G1.2 strains have been developed to confer adequate protection. An increase in the pathogenicity of the circulating strains was recently reported. The objective of this experimental study was to characterise the infection with a highly pathogenic GI.2/RHDV2/b isolate (2017) and assess the efficacy of Filavac VHD K C+V vaccine (Filavie) against this strain. Four and 10-wk-old specific pathogen-free rabbits were inoculated with a recommended dose of vaccine. After 7 d, controls and vaccinated rabbits were challenged and clinically monitored for 14 d. All animals were necropsied and blood, organs and urine were sampled for quantitative reverse transcription polymerase chain reaction (RT-qPCR) analysis. In adult groups, regular nasal and rectal swabbing were performed, and faeces were collected after death to monitor RNA shedding. In control groups, the challenge strain induced acute RHD between 31 and 72 h post-inoculation, with a mortality rate of 100% for kits and 89% for adult rabbits. Except for a shorter mean time to death in kits, similar clinical signs and lesions were observed between age groups. The vaccination significantly prevented all mortality, clinical signs, detection of viral RNA in serum and gross lesions in kits and adult rabbits. In adult groups, we also demonstrated that vaccine significantly protected from detectable RNA shedding via naso-conjunctival and rectal routes. Two weeks after challenge, RNA copies were not detected by PCR in the liver, spleen, lungs, kidneys, faeces and urine of vaccinated adult rabbits. The findings for kits were similar, except that very low levels of RNA were present in the liver and spleen of a few rabbits. These data show that immunisation prevented any significant viral multiplication and/or allowed a rapid clearance. We concluded that, despite the quick evolution of GI.2/RHDV2/b strains, the protection conferred by the vaccine remains adequate. In the context of coexistence of both GI.1 and GI.2 genotypes in some countries, with the circulation of multiples recombinant viruses, the vaccination should be based on the association of strains from both genotypes.Le Minor, O.; Boucher, S.; Joudou, L.; Mellet, R.; Sourice, M.; Le Moullec, T.; Nicolier, A.... (2019). Rabbit haemorrhagic disease: experimental study of a recent highly pathogenic GI.2/RHDV2/b strain and evaluation of vaccine efficacy. World Rabbit Science. 27(3):143-156. https://doi.org/10.4995/wrs.2019.11082SWORD143156273Abrantes J., van der Loo W., Le Pendu J., Esteves P.J. 2012. Rabbit haemorrhagic disease (RHD) and rabbit haemorrhagic disease virus (RHDV): a review. Vet. Res., 43: 12. https://doi.org/10.1186/1297-9716-43-12Abrantes J., Lopes A.M., Dalton K.P., Melo P., Correia J.J., Ramada M., Alves P.C., Parra F., Esteves P.J. 2013. New variant of rabbit hemorrhagic disease virus, Portugal, 2012-2013. Emerg. Infect. Dis., 19: 1900-1902. https://doi.org/10.3201/eid1911.130908Calvete C., Sarto P., Calvo A.J., Monroy F., Calvo J.H. 2014. Letter - Could the new rabbit haemorrhagic disease virus variant (RHDVb) be fully replacing classical RHD strains in the Iberian Peninsula?. World Rabbit Sci., 22: 91-91. https://doi.org/10.4995/wrs.2014.1715Calvete C, Mendoza M, Alcaraz A, Sarto M.P., JimĂ©nez-de-BagĂŒĂ©ss M.P., Calvo A.J., Monroy F., Calvo J.H., 2018. Rabbit haemorrhagic disease: Cross-protection and comparative pathogenicity of GI.2/RHDV2/b and GI.1b/RHDV lagoviruses in a challenge trial. Vet. Microbiol., 219: 87-95. https://doi.org/10.1016/j.vetmic.2018.04.018Capucci L., Cavadini P., Schiavitto M., Lombardi G., Lavazza A. 2017. Increased pathogenicity in rabbit haemorrhagic disease virus type 2 (RHDV2). Vet. Rec., 180: 426. https://doi.org/10.1136/vr.104132Carvalho C.L., Duarte E.L., Monteiro M., Botelho A., Albuquerque T., Fevereiro M., Henriques A.M., Barros SS., Duarte MD. 2017. Challenges in the rabbit haemorrhagic disease 2 (RHDV2) molecular diagnosis of vaccinated rabbits. Vet. Microbiol. 198: 43-50. https://doi.org/10.1016/j.vetmic.2016.12.006Dalton K.P., Balseiro A., Juste R.A., Podadera A., Nicieza I., Del Llano D., GonzĂĄlez R., Martin Alonso J.M., Prieto J.M., Parra F., Casais R. 2018. Clinical course and pathogenicity of variant rabbit haemorrhagic disease virus in experimentally infected adult and kit rabbits: Significance towards control and spread. Vet. Microbiol., 220: 24-32. https://doi.org/10.1016/j.vetmic.2018.04.033Dalton K.P., Nicieza I., Abrantes J., Esteves P.J., Parra F., 2014. Spread of new variant RHDV in domestic rabbits on the Iberian Peninsula. Vet. Microbiol., 169: 67-73. https://doi.org/10.1016/j.vetmic.2013.12.015Dalton K.P., Nicieza I., Balseiro A., Muguerza M.A., Rosell J.M., Casais R., Ălvarez Ă.L., Parra F. 2012. Variant rabbit hemorrhagic disease virus in young rabbits, Spain. Emerg. Infect. Dis., 18: 2009-2012. https://doi.org/10.3201/eid1812.120341Duarte M., Henriques M., Barros S.C., Fagulha T., Ramos F., LuĂs T., Fevereiro M., Benevides S., Flor L., Barros S.V., Bernardo S. 2015. Detection of RHDV variant 2 in the Azores. Vet. Rec.,176: 130. https://doi.org/10.1136/vr.h497Forrester N.L., Boag B., Moss S.R., Turner S.L., Trout R.C., White P.J., Hudson P.J., Gould E.A., 2003. Long-term survival of New Zealand rabbit haemorrhagic disease virus RNA in wild rabbits, revealed by RT-PCR and phylogenetic analysis. J. Gen.Virol., 84: 3079-3086. https://doi.org/10.1099/vir.0.19213-0Gall A., Schirrmeier H. 2006. Persistence of rabbit haemorrhagic disease virus genome in vaccinated rabbits after experimental infection. J. Vet. Med. B. Infect. Dis. Vet. Public Health, 53: 358-362. https://doi.org/10.1111/j.1439-0450.2006.00986.xGall A., Hoffmann B., Teifke J.P., Lange B., Schirrmeier H., 2007. Persistence of viral RNA in rabbits which overcome an experimental RHDV infection detected by a highly sensitive multiplex real-time RT-PCR. Vet. Microbiol.,120: 17-32. https://doi.org/10.1016/j.vetmic.2006.10.006Hall R.N., Mahar J.E., Haboury S., Stevens V., Holmes E.C., Strive T. 2015. Emerging Rabbit Hemorrhagic Disease Virus 2 (RHDVb), Australia. Emerg. Infect. Dis., 21: 2276-2278. https://doi.org/10.3201/eid2112.151210Le Gall G., Boilletot E., Morisse J.P. 1992. Viral haemorrhagic disease of rabbit: purification and characterization of a strain isolated in France. Ann. Rech. Vet., 23: 381-387.Le Gall-ReculĂ© G., Zwingelstein F., Boucher S., Le Normand B., Plassiart G., Portejoie Y., Decors A., Bertagnoli S., GuĂ©rin J.L., Marchandeau S. 2011. Detection of a new variant of rabbit haemorrhagic disease virus in France. Vet. Rec., 168: 137-138. https://doi.org/10.1136/vr.d697Le Gall-ReculĂ© G., Lavazza A., Marchandeau S., Bertagnoli S., Zwingelstein F., Cavadini, P., Martinelli N., Lombardi G., GuĂ©rin J.L., Lemaitre E., Decors A., Boucher S., Le Normand B., Capucci L. 2013. Emergence of a new lagovirus related to Rabbit Haemorrhagic Disease Virus. Vet. Res., 44: 81. https://doi.org/10.1186/1297-9716-44-81Le Gall-ReculĂ© G., Lemaitre E., Bertagnoli S., Hubert C., Top S., Decors A., Marchandeau S., Guitton J.S., 2017. Large-scale lagovirus disease outbreaks in European brown hares (Lepus europaeus) in France caused by RHDV2 strains spatially shared with rabbits (Oryctolagus cuniculus). Vet. Res., 48: 70. https://doi.org/10.1186/s13567-017-0473-yLe Minor O., Beilvert F., Le Moullec T., Djadour D., Martineau J. 2013. Evaluation de l'efficacitĂ© d'un nouveau vaccin contre le virus variant de la maladie hĂ©morragique virale du lapin (VHD).15Ăšmes JournĂ©es de la Recherche Cunicole, 19-20 novembre, Le Mans, France.Le Minor O., Joudou L., Le Moullec T., Beilvert F. 2017. InnocuitĂ© et efficacitĂ© de la vaccination Ă 2 et 3 semaines d'Ăąge contre le virus RHDV2 de la maladie hĂ©morragique virale du lapin (VHD).17Ăšmes JournĂ©es de la Recherche Cunicole, 22-13 novembre, Le Mans, France.Le Pendu J., Abrantes J., Bertagnoli S., Guitton J.S., Le Gall-ReculĂ© G., Lopes A.M., Marchandeau S., Alda F., Almeida T., CĂ©lio A.P., BĂĄrcena J., Burmakina G., Blanco E., Calvete C., Cavadini P., Cooke B., Dalton K., Delibes Mateos M., Deptula W., Eden J.S., Wang F., Ferreira C.C., Ferreira P., Foronda P., Gonçalves D., Gavier-WidĂ©n D., Hall R., Hukowska-Szematowicz B., Kerr P., Kovaliski J., et al. 2017. Proposal for a unified classification system and nomenclature of lagoviruses. J. Gen. Virol., 98:1658-1666. https://doi.org/10.1099/jgv.0.000840Lopes A.M., Correia J., Abrantes J., Melo P., Ramada M., MagalhĂŁes M.J., Alves P.C., Esteves P.J. 2015. Is the new variant RHDV replacing genogroup 1 in Portuguese wild rabbit populations? Viruses, 7: 27-36. https://doi.org/10.3390/v7010027Mahar J.E., Hall R.N., Peacock D., Kovaliski J., Piper M., Mourant R., Huang N., Campbell S., Gu X., Read A., Urakova N., Cox T., Holmes E.C., Strive T. 2018. Rabbit haemorrhagic disease virus 2 (GI.2) is replacing endemic strains of RHDV in the Australian landscape within 18 months of its arrival. J. Virol., https://doi.org/10.1128/JVI.01374-17Martin-Alonso A., Martin-Carrillo N., Garcia-livia K., Valladares B., Foronda P. 2016. Emerging rabbit haemorrhagic disease virus 2 (RHDV2) at the gates of the African continent. Infect. Genet. Evol., 44: 46-50. https://doi.org/10.1016/j.meegid.2016.06.034Morin H., Le Minor O., Beilvert F., Le Moullec T. 2015. DurĂ©e d'immunitĂ© confĂ©rĂ©e par un vaccin vis-Ă -vis des calicivirus classique et variant de la maladie virale hĂ©morragique. 16Ăšmes JournĂ©es de la Recherche Cunicole, 18-19 novembre, Le mans, France.Neimanis A., Larsson Pettersson U., Huang N., GavierâWidĂ©n D.,Strive T. 2018. Elucidation of the pathology and tissue distribution of Lagovirus europaeus GI.2/RHDV2 (rabbit haemorrhagic disease virus 2) in young and adult rabbits (Oryctolagus cuniculus). Vet. Res., 49: 46. https://doi.org/10.1186/s13567-018-0540-zOIE, 2017. Manual of Diagnostic Tests and Vaccines for Terrestrial Animals 2017. Chapter 2.6.2. Rabbit Haemorrhagic disease. Available at: (Accessed 8 February 2018): http://www.oie.int/fileadmin/Home/fr/Health_standards/tahm/3.06.02_RHD.pdfOIE, 2016. Rabbit Haemorrhagic disease, Canada-immediate notification report. Available at: http://www.oie.int/wahis_2/public/wahid.php/Reviewreport/Review?page_refer=MapFullEventReport&reportid=20799.Puggioni G., Cavadini P., Maestrale C., Scivoli R., Botti G., Ligios C., Le Gall- Recule G., Lavazza A., Capucci L. 2013. The new French 2010 Rabbit Hemorrhagic Disease Virus causes an RHD-like disease in the Sardinian Cape hare (Lepus capensis mediterraneus). Vet. Res., 44: 96.https://doi.org/10.1186/1297-9716-44-96Read A.J., Kirkland P.D. 2017. Efficacy of a commercial vaccine against different strains of rabbit haemorrhagic disease virus. Aust. Vet. J., 95: 223-226. https://doi.org/10.1111/avj.12600SilvĂ©rio D., Lopes A.M., Melo-Ferreira J., MagalhĂŁes M.J., Monterroso P., Serronha A., Maio E., Alves P.C., Esteves P.J., Abrantes J. 2018. Insights into the evolution of the new variant rabbit haemorrhagic disease virus (GI.2) and the identification of novel recombinant strains. Transbound. Emerg. Dis., 65: 983-992. https://doi.org/10.1111/tbed.12830Shien, J.H., Shieh, H.K., Lee, L.H. 2000. Experimental infections of rabbits with rabbit haemorrhagic disease virus monitored by polymerase chain reaction. Res. Vet. Sci., 68, 255-259. https://doi.org/10.1053/rvsc.1999.0372Spikey N., McCabe V.J., Greenwood N.M., Jack S.C., Sutton D., van der Waart L. 2012. Novel bivalent vectored vaccine for control of myxomatosis and rabbit haemorrhagic disease. Vet. Rec., 170: 309. https://doi.org/10.1136/vr.100366Strive T., Wright J., Kovaliski J., Botti G., Capucci L. 2010. The non-pathogenic Australian lagovirus RCV-A1 causes a prolonged infection and elicits partial crossprotection to rabbit haemorrhagic disease virus. Virology, 398, 125-134. https://doi.org/10.1016/j.virol.2009.11.045Westcott D.G., Frossard J.P., Everest D., Dastjerdi A., Duff J.P., Choudhury B. 2014. Incursion of RHDV2- like variant in Great Britain. Vet. Rec., 174: 333-333. https://doi.org/10.1136/vr.g234
Resveratrol Delays Age-Related Deterioration and Mimics Transcriptional Aspects of Dietary Restriction without Extending Life Span
22 pĂĄginas, 4 figuras.A small molecule that safely mimics the ability of dietary restriction (DR) to delay age-related diseases in laboratory animals is greatly sought after. We and others have shown that resveratrol mimics effects of DR in lower organisms. In mice, we find that resveratrol induces gene expression patterns in multiple tissues that parallel those induced by DR and every-other-day feeding. Moreover, resveratrol-fed elderly mice show a marked reduction in signs of aging, including reduced albuminuria, decreased inflammation, and apoptosis in the vascular endothelium, increased aortic elasticity, greater motor coordination, reduced cataract formation, and preserved bone mineral density. However, mice fed a standard diet did not live longer when treated with resveratrol beginning at 12 months of age. Our findings indicate that resveratrol treatment has a range of beneficial effects in mice but does not increase the longevity of ad libitum-fed animals when started midlife.This work was supported by grants from the American Heart Association (0425834T to J.A.B. and 0435140N to A.C.) and from the NIH (RO1GM068072, AG19972, and AG19719 to D.A.S.), (HL077256 to Z.U.), (HD034089 to L.W), (2RO1 EY011733 to N.S.W.), Spanish grant (BFU2005-03017 to P.N.), and by the generous support of Mr. Paul F. Glenn and The Paul F. Glenn Laboratories for the Biological Mechanisms of Aging.Peer reviewe
Search for Nucleon Decay with Final States l+ eta, nubar eta, and nubar pi+,0 Using Soudan 2
We have searched for nucleon decay into five two-body final states using a
4.4 kiloton-year fiducial exposure of the Soudan 2 iron tracking calorimeter.
For proton decay into the fully visible final states mu+ eta and e+ eta, we
observe zero and one event, respectively, that satisfy our search criteria for
nucleon decay. The lifetime lower limits (tau/B) thus implied are 89 x 10^30
years and 81 x 10^30 years at 90% confidence level. For neutron decay into
nubar eta, we obtain the lifetime lower limit 71 x 10^30 years. Limits are also
reported for neutron decay into nubar pi0, and for proton decay into nubar pi+.Comment: 24 pages, 9 figures, 3 table
Plant-made polio type 3 stabilized VLPsâa candidate synthetic polio vaccine
Poliovirus (PV) is the causative agent of poliomyelitis, a crippling human disease known since antiquity. PV occurs in two distinct antigenic forms, D and C, of which only the D form elicits a robust neutralizing response. Developing a synthetically produced stabilized viruslike particle (sVLP)-based vaccine with D antigenicity, without the drawbacks of current vaccines, will be a major step towards the final eradication of poliovirus. Such a sVLP would retain the native antigenic conformation and the repetitive structure of the original virus particle, but lack infectious genomic material. In this study, we report the production of synthetically stabilized PV VLPs in plants. Mice carrying the gene for the human PV receptor are protected from wild-type PV when immunized with the plant-made PV sVLPs. Structural analysis of the stabilized mutant at 3.6 Ă
resolution by cryo-electron microscopy and single particle reconstruction reveals a structure almost indistinguishable from wild-type PV3
First observations of separated atmospheric nu_mu and bar{nu-mu} events in the MINOS detector
The complete 5.4 kton MINOS far detector has been taking data since the beginning of August 2003 at a depth of 2070 meters water-equivalent in the Soudan mine, Minnesota. This paper presents the first MINOS observations of nu” and [overline nu ]” charged-current atmospheric neutrino interactions based on an exposure of 418 days. The ratio of upward- to downward-going events in the data is compared to the Monte Carlo expectation in the absence of neutrino oscillations, giving Rup/downdata/Rup/downMC=0.62-0.14+0.19(stat.)±0.02(sys.). An extended maximum likelihood analysis of the observed L/E distributions excludes the null hypothesis of no neutrino oscillations at the 98% confidence level. Using the curvature of the observed muons in the 1.3 T MINOS magnetic field nu” and [overline nu ]” interactions are separated. The ratio of [overline nu ]” to nu” events in the data is compared to the Monte Carlo expectation assuming neutrinos and antineutrinos oscillate in the same manner, giving R[overline nu ][sub mu]/nu[sub mu]data/R[overline nu ][sub mu]/nu[sub mu]MC=0.96-0.27+0.38(stat.)±0.15(sys.), where the errors are the statistical and systematic uncertainties. Although the statistics are limited, this is the first direct observation of atmospheric neutrino interactions separately for nu” and [overline nu ]”
Salmonella paratyphi C: Genetic Divergence from Salmonella choleraesuis and Pathogenic Convergence with Salmonella typhi
BACKGROUND: Although over 1400 Salmonella serovars cause usually self-limited gastroenteritis in humans, a few, e.g., Salmonella typhi and S. paratyphi C, cause typhoid, a potentially fatal systemic infection. It is not known whether the typhoid agents have evolved from a common ancestor (by divergent processes) or acquired similar pathogenic traits independently (by convergent processes). Comparison of different typhoid agents with non-typhoidal Salmonella lineages will provide excellent models for studies on how similar pathogens might have evolved. METHODOLOGIES/PRINCIPAL FINDINGS: We sequenced a strain of S. paratyphi C, RKS4594, and compared it with previously sequenced Salmonella strains. RKS4594 contains a chromosome of 4,833,080 bp and a plasmid of 55,414 bp. We predicted 4,640 intact coding sequences (4,578 in the chromosome and 62 in the plasmid) and 152 pseudogenes (149 in the chromosome and 3 in the plasmid). RKS4594 shares as many as 4346 of the 4,640 genes with a strain of S. choleraesuis, which is primarily a swine pathogen, but only 4008 genes with another human-adapted typhoid agent, S. typhi. Comparison of 3691 genes shared by all six sequenced Salmonella strains placed S. paratyphi C and S. choleraesuis together at one end, and S. typhi at the opposite end, of the phylogenetic tree, demonstrating separate ancestries of the human-adapted typhoid agents. S. paratyphi C seemed to have suffered enormous selection pressures during its adaptation to man as suggested by the differential nucleotide substitutions and different sets of pseudogenes, between S. paratyphi C and S. choleraesuis. CONCLUSIONS: S. paratyphi C does not share a common ancestor with other human-adapted typhoid agents, supporting the convergent evolution model of the typhoid agents. S. paratyphi C has diverged from a common ancestor with S. choleraesuis by accumulating genomic novelty during adaptation to man
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