Purification and properties of African swine fever virus

Carrascosa, Ángel L.; Val, Margarita Del; Santarén, Juán F.; Viñuela, Eladio

doi:10.1128/jvi.54.2.337-344.1985

Cited by 136 publications

(77 citation statements)

References 35 publications

(26 reference statements)

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“…This is supported in part by an electron microscopic examination of macrophages which reveals that SLA Class I and Class II molecules are associated with internal ASF viral particles detected by mAb and immunogold staining (M. Gonzalez Juarrero et al, unpublished data, 1988 ). As these viral particles bud from the macrophage surface at later times in the infection, they may carry these SLA proteins in the viral envelope, similar to the earlier report of ASFV budding from Vero cells (Carrascosa et al, 1985). A decrease in expression of SLA Class II may lead to a decrease in antigen presentation, a mechanism favorable for survival of the virus.…”

Section: Discussionsupporting

confidence: 79%

Swine leukocyte antigen and macrophage marker expression on both African swine fever virus-infected and non-infected primary porcine macrophage cultures

Gonzalez-Juarrero

Mebus

Pan

et al. 1992

Veterinary Immunology and Immunopathology

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Swine leukocyte antigens (SLA) and a macrophage specific marker were monitored on porcine macrophages cultured with or without macrophage colony stimulatory factor (M-CSF) and on cells infected with African swine fever virus (ASFV). SLA expression was maximal either in the total cell extract or on the cell surface at 3-4 days of culture; after 4 days these values began to decrease. Fluorescence analyses of immunostained macrophages cultured with or without M-CSF indicated a major upward shift in the number of SLA Class I molecules on individual macrophages whereas for SLA Class II both a novel expression of Class II and an upward shift in the number of molecules per cell were evident. Infection of 3-day-old macrophage cultures with three different isolates of ASFV resulted in minor changes in surface expression of SLA Class I, SLA Class II, and macrophage markers. No differences in infection with ASFV was observed whether macrophages were SLA Class II positive or negative, nor was there blocking by anti-SLA Class I or Class II monoclonal antibodies of ASFV infection of cultured macrophages.

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Section: Discussionsupporting

confidence: 79%

Swine leukocyte antigen and macrophage marker expression on both African swine fever virus-infected and non-infected primary porcine macrophage cultures

Gonzalez-Juarrero

Mebus

Pan

et al. 1992

Veterinary Immunology and Immunopathology

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“…This finding raised the possibility that these vesicles could contain virus particles. Previous publications reported that the abundant vesicle fraction released in last ASFV infection stages contains virus (Carrascosa et al, 1985). Then, it is conceivable that the fluorescence detected in the vesicles formed at the end of apoptosis (blebbing), could correspond to GFP labeled virus particles.…”

Section: Discussionmentioning

confidence: 97%

“…In most cases, ASFV stocks from culture supernatants were semipurified from vesicles by ultracentrifugation at 40.000 × g through a 20% (w/v) sucrose cushion in PBS for 1 h at 4°C. When needed, ASFV particles were highly purified from the extracellular medium by Percoll equilibrium centrifugation as previously described (Carrascosa et al, 1985). After centrifugation, Percoll gradients were fractionated and fractions 2 to 8 from Percoll gradients, containing virus particle essentially free of vesicles and contaminant membranes, were collected after sedimentation and gel filtered through Sephacryl S-1000 (Amersham) to remove Percoll.…”

Section: Cells Viruses and Plasmidsmentioning

confidence: 99%

Visualization of the African swine fever virus infection in living cells by incorporation into the virus particle of green fluorescent protein-p54 membrane protein chimera

Hernáez¹,

Escribano²,

Alonso³

2006

Virology

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Many stages of African swine fever virus infection have not yet been studied in detail. To track the behavior of African swine fever virus (ASFV) in the infected cells in real time, we produced an infectious recombinant ASFV (B54GFP-2) that expresses and incorporates into the virus particle a chimera of the p54 envelope protein fused to the enhanced green fluorescent protein (EGFP). The incorporation of the fusion protein into the virus particle was confirmed immunologically and it was determined that p54-EGFP was fully functional by confirmation that the recombinant virus made normal-sized plaques and presented similar growth curves to the wild-type virus. The tagged virus was visualized as individual fluorescent particles during the first stages of infection and allowed to visualize the infection progression in living cells through the viral life cycle by confocal microscopy. In this work, diverse potential applications of B54GFP-2 to study different aspects of ASFV infection are shown. By using this recombinant virus it was possible to determine the trajectory and speed of intracellular virus movement. Additionally, we have been able to visualize for first time the ASFV factory formation dynamics and the cytophatic effect of the virus in live infected cells. Finally, we have analyzed virus progression along the infection cycle and infected cell death as time-lapse animations.

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“…The ASFV strain BA71V, adapted to grow in Vero cells, has been previously described (Enjuanes et al, 1976). Highly purified ASFV was obtained by Percoll equilibrium centrifugation as described by Carrascosa et al (1985).…”

Section: Cells and Virusesmentioning

confidence: 99%

Polyprotein processing in African swine fever virus: a novel gene expression strategy for a DNA virus.

1993

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This report shows that African swine fever virus (ASFV)‐‐a large DNA‐containing virus‐‐synthesizes a polyprotein to produce several of its structural proteins. By immunoprecipitation analysis, we have found that ASFV polyprotein is a 220 kDa myristoylated polypeptide (pp220) which, after proteolytic processing, gives rise to four major structural proteins: p150, p37, p34 and p14. Processing of the ASFV polyprotein takes place at the consensus sequence Gly‐Gly‐X and occurs through an ordered cascade of proteolytic cleavages. So far, polyprotein processing as a mechanism of gene expression had been found only in positive‐strand RNA viruses and retroviruses. According to the results presented here, ASFV is the first example of a DNA virus that synthesizes a polyprotein as a strategy of gene expression.

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Purification and properties of African swine fever virus

Cited by 136 publications

References 35 publications

Swine leukocyte antigen and macrophage marker expression on both African swine fever virus-infected and non-infected primary porcine macrophage cultures

Swine leukocyte antigen and macrophage marker expression on both African swine fever virus-infected and non-infected primary porcine macrophage cultures

Visualization of the African swine fever virus infection in living cells by incorporation into the virus particle of green fluorescent protein-p54 membrane protein chimera

Polyprotein processing in African swine fever virus: a novel gene expression strategy for a DNA virus.

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