- Volume 94, Issue 2, 2013
Volume 94, Issue 2, 2013
- Animal
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- DNA viruses
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Antigenic diversity and seroprevalences of Torque teno viruses in children and adults by ORF2-based immunoassays
More LessTorque teno viruses (TTVs) circulate widely among humans, causing persistent viraemia in healthy individuals. Numerous TTV isolates with high genetic variability have been identified and segregated into 29 species of five major phylogenetic groups. To date, the diversity of TTV sequences, challenges in protein expression and the subsequent lack of serological assays have hampered TTV seroprevalence studies. Moreover, the antigenic relationships of different TTVs and their specific seroprevalences in humans remain unknown. For five TTV strains – belonging to different species of four genogroups – we developed, using recombinant glutathione S-transferase (GST)-fused TTV ORF2 proteins, glutathione–GST capture enzyme immunoassays (EIAs) detecting antibodies towards conformational epitopes. We then analysed serum samples from 178 healthy adults and 108 children; IgG reactivities were observed either towards a single strain or towards multiple strains, which pointed to antigenic distinction of TTV species. The overall seroprevalence for the five TTVs peaked at 43 % (18 of 42) in children 2–4 years of age, subsequently declined, and again reached 42 % (74 of 178) among adults. TTV6 species-specific IgG predominated in children, whereas that for TTV13 predominated in adults. During a 3 year follow-up of the same children, both species-specific seroconversions and seroreversions occurred. This is the first EIA-based study of different TTVs, providing a new approach for seroepidemiology and diagnosis of TTV infections. Our data suggest that different TTVs in humans may differ in antiviral antibody profiles, infection patterns and epidemiology.
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- Plant
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Synonymous site variation due to recombination explains higher genetic variability in begomovirus populations infecting non-cultivated hosts
Begomoviruses are ssDNA plant viruses that cause serious epidemics in economically important crops worldwide. Non-cultivated plants also harbour many begomoviruses, and it is believed that these hosts may act as reservoirs and as mixing vessels where recombination may occur. Begomoviruses are notoriously recombination-prone, and also display nucleotide substitution rates equivalent to those of RNA viruses. In Brazil, several indigenous begomoviruses have been described infecting tomatoes following the introduction of a novel biotype of the whitefly vector in the mid-1990s. More recently, a number of viruses from non-cultivated hosts have also been described. Previous work has suggested that viruses infecting non-cultivated hosts have a higher degree of genetic variability compared with crop-infecting viruses. We intensively sampled cultivated and non-cultivated plants in similarly sized geographical areas known to harbour either the weed-infecting Macroptilium yellow spot virus (MaYSV) or the crop-infecting Tomato severe rugose virus (ToSRV), and compared the molecular evolution and population genetics of these two distantly related begomoviruses. The results reinforce the assertion that infection of non-cultivated plant species leads to higher levels of standing genetic variability, and indicate that recombination, not adaptive selection, explains the higher begomovirus variability in non-cultivated hosts.
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- Other agents
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Mucosal transmission and pathogenesis of chronic wasting disease in ferrets
More LessChronic wasting disease (CWD) of cervids is almost certainly transmitted by mucosal contact with the causative prion, whether by direct (animal-to-animal) or indirect (environmental) means. Yet the sites and mechanisms of prion entry remain to be further understood. This study sought to extend this understanding by demonstrating that ferrets exposed to CWD via several mucosal routes developed infection, CWD prion protein (PrPCWD) amplification in lymphoid tissues, neural invasion and florid transmissible spongiform encephalopathy lesions resembling those in native cervid hosts. The ferrets developed extensive PrPCWD accumulation in the nervous system, retina and olfactory epithelium, with lesser deposition in tongue, muscle, salivary gland and the vomeronasal organ. PrPCWD accumulation in mucosal sites, including upper respiratory tract epithelium, olfactory epithelium and intestinal Peyer’s patches, make the shedding of prions by infected ferrets plausible. It was also observed that regionally targeted exposure of the nasopharyngeal mucosa resulted in an increased attack rate when compared with oral exposure. The latter finding suggests that nasal exposure enhances permissiveness to CWD infection. The ferret model has further potential for investigation of portals for initiation of CWD infection.
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Chimeric elk/mouse prion proteins in transgenic mice
Chronic wasting disease (CWD) of deer and elk is a highly communicable neurodegenerative disorder caused by prions. Investigations of CWD are hampered by slow bioassays in transgenic (Tg) mice. Towards the development of Tg mice that will be more susceptible to CWD prions, we created a series of chimeric elk/mouse transgenes that encode the N terminus of elk PrP (ElkPrP) up to residue Y168 and the C terminus of mouse PrP (MoPrP) beyond residue 169 (mouse numbering), designated Elk3M(SNIVVK). Between codons 169 and 219, six residues distinguish ElkPrP from MoPrP: N169S, T173N, V183I, I202V, I214V and R219K. Using chimeric elk/mouse PrP constructs, we generated 12 Tg mouse lines and determined incubation times after intracerebral inoculation with the mouse-passaged RML scrapie or Elk1P CWD prions. Unexpectedly, one Tg mouse line expressing Elk3M(SNIVVK) exhibited incubation times of <70 days when inoculated with RML prions; a second line had incubation times of <90 days. In contrast, mice expressing full-length ElkPrP had incubation periods of >250 days for RML prions. Tg(Elk3M,SNIVVK) mice were less susceptible to CWD prions than Tg(ElkPrP) mice. Changing three C-terminal mouse residues (202, 214 and 219) to those of elk doubled the incubation time for mouse RML prions and rendered the mice resistant to Elk1P CWD prions. Mutating an additional two residues from mouse to elk at codons 169 and 173 increased the incubation times for mouse prions to >300 days, but made the mice susceptible to CWD prions. Our findings highlight the role of C-terminal residues in PrP that control the susceptibility and replication of prions.
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Protease-sensitive prion species in neoplastic spleens of prion-infected mice with uncoupling of PrPSc and prion infectivity
More LessPrion diseases are fatal neurodegenerative disorders. An important step in disease pathophysiology is the conversion of cellular prion protein (PrPC) to disease-associated misfolded conformers (PrPSc). These misfolded PrP variants are a common component of prion infectivity and are detectable in diseased brain and lymphoreticular organs such as spleen. In the latter, PrPSc is thought to replicate mainly in follicular dendritic cells within spleen follicles. Although the presence of PrPSc is a hallmark for prion disease and serves as a main diagnostic criterion, in certain instances the amount of PrPSc does not correlate well with neurotoxicity or prion infectivity. Therefore, it has been proposed that prions might be a mixture of different conformers and aggregates with differing properties. This study investigated the impact of disruption of spleen architecture by neoplasia on the abundance of different PrP species in spleens of prion-infected mice. Although follicular integrity was completely disturbed, titres of prion infectivity in neoplastic spleens were not significantly altered, yet no protease-resistant PrPSc was detectable. Instead, unique protease-sensitive prion species could be detected in neoplastic spleens. These results indicate the dissociation of PrPSc and prion infectivity and showed the presence of non-PrPSc PrP species in spleen with divergent biochemical properties that become apparent after tissue architecture disruption.
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- Retraction
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Volumes and issues
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Volume 105 (2024)
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Volume 104 (2023)
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Volume 103 (2022)
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Volume 102 (2021)
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Volume 101 (2020)
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Volume 100 (2019)
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Volume 99 (2018)
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Volume 98 (2017)
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Volume 97 (2016)
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Volume 96 (2015)
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Volume 95 (2014)
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Volume 94 (2013)
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Volume 93 (2012)
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Volume 92 (2011)
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Volume 91 (2010)
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Volume 90 (2009)
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Volume 89 (2008)
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Volume 88 (2007)
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Volume 87 (2006)
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Volume 86 (2005)
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Volume 85 (2004)
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Volume 84 (2003)
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Volume 83 (2002)
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Volume 82 (2001)
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Volume 81 (2000)
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Volume 80 (1999)
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Volume 79 (1998)
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Volume 78 (1997)
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Volume 77 (1996)
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Volume 76 (1995)
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Volume 75 (1994)
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Volume 74 (1993)
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Volume 73 (1992)
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Volume 72 (1991)
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Volume 71 (1990)
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Volume 70 (1989)
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Volume 69 (1988)
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Volume 68 (1987)
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Volume 67 (1986)
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Volume 66 (1985)
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Volume 65 (1984)
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Volume 64 (1983)
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Volume 63 (1982)
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Volume 62 (1982)
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Volume 61 (1982)
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Volume 60 (1982)
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Volume 59 (1982)
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Volume 58 (1982)
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Volume 57 (1981)
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Volume 56 (1981)
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Volume 55 (1981)
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Volume 54 (1981)
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Volume 53 (1981)
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Volume 52 (1981)
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Volume 51 (1980)
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Volume 50 (1980)
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Volume 49 (1980)
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Volume 48 (1980)
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Volume 47 (1980)
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Volume 46 (1980)
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Volume 45 (1979)
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Volume 44 (1979)
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Volume 43 (1979)
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Volume 42 (1979)
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Volume 41 (1978)
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Volume 40 (1978)
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Volume 39 (1978)
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Volume 38 (1978)
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Volume 37 (1977)
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Volume 36 (1977)
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Volume 35 (1977)
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Volume 34 (1977)
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Volume 33 (1976)
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Volume 32 (1976)
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Volume 31 (1976)
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Volume 30 (1976)
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Volume 29 (1975)
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Volume 28 (1975)
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Volume 27 (1975)
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Volume 26 (1975)
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Volume 25 (1974)
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Volume 24 (1974)
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Volume 23 (1974)
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Volume 22 (1974)
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Volume 21 (1973)
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Volume 20 (1973)
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Volume 19 (1973)
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Volume 18 (1973)
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Volume 17 (1972)
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Volume 16 (1972)
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Volume 15 (1972)
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Volume 14 (1972)
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Volume 13 (1971)
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Volume 12 (1971)
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Volume 11 (1971)
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Volume 10 (1971)
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Volume 9 (1970)
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Volume 8 (1970)
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Volume 7 (1970)
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Volume 6 (1970)
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Volume 5 (1969)
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Volume 4 (1969)
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Volume 3 (1968)
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Volume 2 (1968)
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Volume 1 (1967)