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Volume 77,
Issue 8,
1996
Volume 77, Issue 8, 1996
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Immunological characterization of rice tungro spherical virus coat proteins and differentiation of isolates from the Philippines and India
More LessRice tungro spherical virus (RTSV) has an RNA genome of more than 12 kb with various features which classify it as a plant picornavirus. The capsid comprises three coat protein (CP) species, CP1, CP2 and CP3, with predicted molecular masses of 22.5, 22.0 and 33 kDa, respectively, which are cleaved from a polyprotein. In order to obtain information on the properties of these proteins, each was expressed in E. coli, purified as a fusion to the maltose-binding protein and used for raising a polyclonal antiserum. CP1, CP2 and CP3 with the expected molecular masses were detected specifically in virus preparations. CP3 is probably the major antigenic determinant on the surface of RTSV particles, as was shown by ELISA, Western blotting and immunogold electron microscopy using antisera obtained against whole virus particles and to each CP separately. In some cases, especially in crude extracts, CP3 antiserum detected several other proteins (40–42 kDa), which could be products of CP3 post-translational modification. No serological differences were detected between the three CPs from isolates from the Philippines, Thailand, Malaysia and India. The CP3-related 40–42 kDa proteins of the Indian RTSV isolate have a slightly higher electrophoretic mobility (42–44 kDa) and a different response to cellulolytic enzyme preparations, which allows them to be differentiated from south-east Asian isolates.
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- Other Agents
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Sequential appearance and accumulation of pathognomonic markers in the central nervous system of hamsters orally infected with scrapie
More LessBoth infectivity and TSE-specific amyloid protein (also referred to as protease resistant- or prion protein, PrP) are pathognomonic markers for transmissible spongiform encephalopathies (TSE). This paper presents a new densitometric method for the quantification of TSE-specific amyloid protein and its application to studying the pathogenesis of scrapie in Syrian hamsters after infection with scrapie strain 263K. A first study established a close correlation between infectivity and TSE-specific amyloid protein with a doubling time of 2–2.6 days in the brain and cervical spinal cord for both markers. The ratio of infectivity and TSE-specific unit during the course of infection. A subsequent study addressed the temporal-spatial spread of infection in the central nervous system by tracing the accumulation of the pathological protein. The pathogenetic process was first detected in the spinal cord between vertebrae T4 and T9, and then showed an anterograde and retrograde spread with a rate of 0.8–1⊙0 mm/day. There were also some indications for a possible alternative route of spread of infection from the periphery to the brain, other than via the spinal cord. Involvement of the spleen did not appear essential for the early pathogenesis in hamsters orally infected with the 263K strain of scrapie.
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Replication of scrapie in spleens of SCID mice follows reconstitution with wild-type mouse bone marrow
More LessSCID mice are resistant to intraperitoneal infection with 103 and 104 intracerebral ID50 units of ME7 scrapie agent whereas they develop disease after intracerebral challenge. However, higher doses introduced, by intraperitoneal or subcutaneous routes, produce disease. Immunocompetent mice of the same strain (CB20) developed scrapie following either intracerebral or intraperitoneal infection. Bioassay of spleens from SCID mice infected with 10−1 dilutions of ME7 scrapie by intraperitoneal, intracerebral or abdominal subcutaneous injection showed traces or low levels of infectivity in spleen. However, subcutaneous injection beneath the skin of the neck failed to infect the spleen. CB20 bone marrow reconstitution of SCID mice resulted in the regeneration of a normal lymphoid architecture in the spleen. Spleens from these reconstituted mice, infected intracerebrally with a 10−1 dilution of ME7 contained high levels of infectivity. These results suggest that the ability to replicate scrapie agent in spleen or lymphoid tissue depends on the restoration of normal lymphoid structure and in particular the presence of differentiated follicular dendritic cells. The possibility that SCID mice can select minor strains of scrapie which are normally unrecognized in cloned ME7 is discussed.
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Protease-resistant PrP deposition in brain and non-central nervous system tissues of a murine model of bovine spongiform encephalopathy
More LessInfectivity within the central nervous system has been demonstrated by the transmission of bovine spongiform encephalopathy (BSE) from affected cattle to inbred laboratory mice. Sedimentable, protease-resistant PrP (PrPSc) has also been extracted from BSE-affected cattle brain. Both infectivity and PrPSc have been reported in the lymphoreticular tissues of sheep and mice clinically and preclinically affected with scrapie. Neither infectivity nor PrPSc has yet been detected in non-neural tissues of naturally occurring, clinical cases of BSE in cattle. We have used a murine model of BSE (301V isolate in VM/Dk mice) to investigate when and where PrPSc accumulates. PrPSc was detected both in brain and in extraneural sites prior to the onset of clinical symptoms. This murine BSE model differs, however, in four important aspects from our previously published findings for murine scrapie models: (a) PrPSc was found relatively late into the incubation period; (b) after intracerebral inoculation, PrPSc was found in brain before it was found in other tissues; (c) no PrPSc was found in most of the spleens from clinically affected animals after intracerebral inoculation; and (d) even after intra-peritoneal infection, PrPSc was detected in brain first.
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- Corrigendum
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