Gwendoline M. Glasgow scite author profile

Three deletion mutants of the structural protein region of the Semliki Forest virus (SFV) genome, including one which encompassed all the viral structural protein genes, induced apoptosis in BHK cells at 48 h after transfection, as shown by DNA laddering and TUNEL staining, as did the wild-type SFV4 RNA. A similar result was obtained for the SFV1 expression vector, which has a multicloning site inserted in place of the structural protein genes. However, in cells transfected with viral RNA containing a deletion of the nsP2 gene, neither viral RNA synthesis nor the induction of apoptosis occurred. Both SFV1 vector and wild-type SFV4 RNA induced apoptosis in human H358a lung carcinoma cells, which have a homozygous deletion of the p53 gene. It is concluded that the SFV vector encodes a function in the nonstructural coding region which induces p53-independent apoptosis and is dependent on viral RNA synthesis.

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Death mechanisms in cultured cells infected by Semliki Forest virus.

Glasgow

McGee

Sheahan

et al. 1997

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We have investigated the induction of cell death in cultured cells by the virulent SFV4 and avirulent A7 strains of Semliki Forest virus (SFV). In BHK cells, death occurred by a typical apoptotic mechanism, as did the death of oligodendrocytes in glial cell cultures. For cerebellar neuron cultures, virusinduced death was due to necrosis. Although the SFV4 and A7 strains did not differ in the mechanism of induction of cell death, the virulent SFV4 strain did multiply to a higher titre in cultured neurons than the avirulent A7 strain. This is consistent with previous animal studies which indicate that the virulence of SFV strains is controlled by rapidity of multiplication in the CNS, leading to a lethal threshold of damage, rather than differential cell tropism or cell death mechanisms. The immunemediated demyelination induced by avirulent strains may be triggered by apoptosis of oligodendrocytes, the consequences of which are obscured by death for virulent strains.Cell death mechanisms are an important component of pathogenesis in virus infections, although the mechanisms of induction of cell death are not well understood. The fate of infected cells, especially cells of the central nervous system (CNS), is of critical importance to mortality and morbidity in virus disease. A number of animal models of virus neuropathogenesis have been investigated in an attempt to define events which determine virulence (Atkins et al., 1994).One such model is infection of mice and rats by the alphavirus Semliki Forest virus (SFV ; Atkins et al., 1985). SFV causes fatal encephalitis following infection by virulent strains and immune-mediated demyelination following infection by avirulent strains. Virulent strains grow to high titre in the CNS and induce fatal damage to neurons. In contrast, avirulent strains multiply slowly, causing less neuronal damage, and are cleared from the CNS by immune intervention (Atkins &

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Two mutations in the envelope glycoprotein E2 of semliki forest virus affecting the maturation and entry patterns of the virus alter pathogenicity for mice

et al. 1991

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A single amino acid change in the E2 spike protein of a virulent strain of Semliki Forest virus attenuates pathogenicity

Glasgow

Killen

Liljeström

et al. 1994

Journal of General Virology

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The virulent strain SFV4 of Semliki Forest virus (SFV), produced from the infectious clone pSP6-SFV4, is lethal after intranasal (i.n.) infection of adult mice and for pregnant mice after intraperitoneal (i.p.) infection. In contrast, the A7 strain of SFV is avirulent when given i.n. to adult mice, but induces fetal death in pregnant mice after i.p. infection. The nucleotide and deduced amino acid sequences of part of the core and all of the envelope region of A7-SFV were determined and compared to those of SFV4. A7 differed from SFV4 at 80 nucleotides (nt) in the coding sequence, 15 of which were associated with amino acid differences and seven of which (two in the E2 protein and five in El) were nonconservative. The 3' non-coding sequence of A7 was longer (415 nt) than that of SFV4 (263 nt) and a divergent sequence of 181 nt was present adjacent to the end of the E1 coding region. The effects on virulence of two mutations in the E2 gene of SFV4, resulting in the non-conservative amino acid substitutions present in A7, were analysed. One mutation (mut 8729 a/c) resulted in only slight attenuation, whereas the other (mut 8902 a/g) resulted in avirulence for pregnant mice. However, mut 8902 a/g was lethal for the majority of developing fetuses after i.p. infection of the mother.

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Virulent and avirulent strains of Semliki Forest virus show similar cell tropism for the murine central nervous system but differ in the severity and rate of induction of cytolytic damage

Balluz

Glasgow

Killen

et al. 1993

Neuropathology Appl Neurobio

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The pathogenicity of the avirulent, demyelinating A7 strain of Semliki Forest virus (SFV) and the virulent SFV4 strain (derived from an infectious clone) for the central nervous system of adult BALB/c mice following intranasal infection was compared. The techniques used included immunocytochemistry using anti-SFV antibody and antibodies to cell markers, in situ hybridization (ISH) using a biotinylated cDNA probe specific for SFV, and immunocytochemistry/ISH double labelling. Whereas SFV4 was lethal at 4 days post-infection, A7-infected mice appeared normal at all times. Neuronal necrosis in the pyriform cortex was present in both infections, but developed sooner and was more severe following infection with SFV4 than with A7. Intact neurons and putative oligodendrocytes contained viral RNA and virus-specific antigen in SFV4 infected mice; viral RNA but not virus-specific antigen was detected in similar cells in A7-infected mice. These results confirm that SFV4 and A7 share similar cell tropisms for the murine central nervous system, but differ in the severity and rate of development of cytolytic damage. Intranasal infection is an efficient monitoring system for studies of the molecular basis of pathogenicity of SFV infection in mice.

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