The nucleoprotein (N) of Borna disease virus (BDV) is the major target of the disease-inducing antiviral CD8 T-cell response in the central nervous system of mice. We established two transgenic mouse lines which express BDV-N in either neurons (Neuro-N) or astrocytes (Astro-N). Despite strong transgene expression, neurological disease or gross behavioral abnormalities were not observed in these animals. When Neuro-N mice were infected as adults, replication of BDV was severely impaired and was restricted to brain areas with a low density of transgene-expressing cells. Notably, the virus failed to replicate in the transgene-expressing granular and pyramidal neurons of the hippocampus (which are usually the preferred host cells of BDV). When Neuro-N mice were infected within the first 5 days of life, replication of BDV was not suppressed in most neurons, presumably because the onset of transgene expression in the brain occurred after these cells became infected with BDV. Astro-N mice remained susceptible to BDV infection, but they were resistant to BDVinduced neurological disorder. Unlike their nontransgenic littermates, Neuro-N mice with persistent BDV infection did not develop neurological disease after immunization with a vaccinia virus vector expressing BDV-N. In contrast to the situation in wild-type mice, this treatment also failed to induce N-specific CD8 T cells in the spleens of both transgenic mouse lines. Thus, while resistance to BDV infection in N-expressing neurons appeared to result from untimely expression of a viral nucleocapsid component, the resistance to BDV-induced neuropathology probably resulted from immunological tolerance.Borna disease virus (BDV) is a noncytolytic virus that can infect a broad range of warm-blooded animal species and possibly also humans (36, 42). It has a strong tropism for neurons of the central nervous system (CNS) (18). BDV is the causative agent of a severe meningoencephalitis in horses and sheep, resulting in behavioral abnormalities and, often, fatal neurologic disease (36) which is mediated by CNS-infiltrating virusspecific immune cells (44). Mouse-adapted BDV variants cause meningoencephalitis and lead to fatal neurological disease with high frequency in MRL mice (22). In contrast, B10.BR or C57BL/6 mice show low susceptibility to spontaneous neurological disease after experimental infection with BDV, although the virus replicates well in the brain of these animals (22, 23). Disease in susceptible H-2 k mice and Lewis rats is mediated by CD8 T cells recognizing immunodominant epitopes derived from the viral nucleoprotein (N) (BDV-N) (33, 39). Our group recently demonstrated that cell lines persistently infected with BDV are resistant to subsequent superinfection with the same virus (15), a phenomenon termed superinfection exclusion or homologous interference (1, 28). It was further shown that this effect can be mimicked by expression of single BDV nucleocapsid components (17).Transgenic models of infectious diseases represent valuable tools for studying host-path...
Infection of adult rats with Borna disease virus (BDV) causes CD8 T cell-mediated meningoencephalitis. Previously, we described a complex pattern of chemokine gene expression in the central nervous system (CNS) of such rats. We now found that expression of chemokine receptor genes CXCR3, CCR5, CX(3)CR1, and CXCR4 was also upregulated, which is in agreement with the predominance in brains of adult infected rats of T cells and monocytes/macrophages that express these receptors. In contrast to these rats, neonatally infected rats (designated PTI-NB) develop a persistent CNS infection associated with neurodegenerative processes in the absence of inflammation. In brains of PTI-NB rats, sustained expression of chemokines also takes place. We therefore analyzed mRNA expression of selected chemokine receptor genes, as well as of the chemokine fractalkine in brains of PTI-NB rats. We observed a marked increase of CCR5 and CX(3)CR1 transcripts in brains of these rats. CX(3)CR1 expressing cells were predominantly microglia, and upregulation of CX(3)CR1 was mainly due to an increase in the number of CX(3)CR1 expressing microglia. Fractalkine gene expression was found to be reduced to similar extents in brains of adult and newborn infected rats. These findings might be of relevance with respect to the selective neuronal cell loss observed in brains of PTI-NB rats.
Infection of newborn rats with Borna disease virus (BDV) leads to viral persistence in the central nervous system without overt signs of inflammation. Nevertheless, these rats display distinct behavioral and neurodevelopmental abnormalities. The molecular basis of the latter is still unknown. Using a cDNA array representing 1200 genes, we sought to identify cellular genes which are differentially expressed following perinatal BDV-infection. RNA samples prepared from different brain regions were analysed at various time points before or after BDV-induced defects become evident. In infected brains, we found upregulated expression of genes encoding brain fatty acid binding protein (B-FABP), beta2-microglobulin (beta2m) and, as described previously, the chemokine IP-10. Kinetic studies revealed sustained increased expression of B-FABP in infected frontal cortices beginning about three weeks p.i. Moreover, a slight transient increase of B-FABP expression in infected hippocampi was observed 3-5 weeks p.i. In situ hybridization studies combined with immunohistochemistry suggested that expression of beta2m was predominantly upregulated in glial cells and possibly also in some neurons. Employing cultured infected hippocampus slices and infected genetically modified mice, we provide evidence, that the observed upregulation of beta2m expression is not triggered by IFN-gamma, but rather by IFN-alpha/beta.
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