Sibylle Herzog

Replication of Borna disease virus in cell cultures

Borna disease (BD) virus from infected brain tissue of horses or rabbits could be grown in embryonic brain cells from rabbits or rats with high virus yields. The cells became persistently infected and could be subcultivated without loss of infectivity.Cocultivation of infected rabbit brain (ERB) cells with GMK-, Vero-, or MDCK-cells led to persistently infected cell lines. BD virus grown in MDCK cells after cocultivation became adapted to this cell type and could be used directly for further infection of MDCK cells.

Cerebrospinal fluid analysis in affective and schizophrenic spectrum disorders: Identification of subgroups with immune responses and blood–CSF barrier dysfunction

Immune and inflammatory mechanisms are detected in a subgroup of treatment resistant hospitalized affective and schizophrenic spectrum disorder patients. We analysed albumin, IgG, IgA, IgM, oligoclonal IgG and specific antibodies in paired cerebrospinal fluid (CSF) and serum samples. Numerical and graphical interpretation of CSF protein data was performed by Reibergrams with a new CSF statistics tool for nonlinear group analysis with reference to a large control group (n=4100). In 41% of the psychiatric patients (n=63) we observed CSF pathologies: 14% displayed intrathecal humoral immune responses, 10% slightly increased CSF cell counts (5-8/microL) and 29% had moderate blood-CSF barrier dysfunctions, in 24% as the only pathological sign with normal IgG, IgA and IgM concentrations in CSF (p=0.9 testing the null hypothesis for intrathecal synthesis with reference to Qmean of the reference group). In the group of affective (n=24) spectrum disorders 20% displayed a systemic immune reaction as detected by oligoclonal IgG. CSF analysis and interdisciplinary clinical approach revealed 6% of psychiatric patients likely to represent a virusspecific, bacterial or autoimmune associated disorder with CNS involvement. Elevated CSF neopterin concentration in 34% of the patients was interpreted as an increased release from astrocytes or from other glia cells. The low level immune response and barrier dysfunctions are discussed on the base of a mild encephalitis pathomechanism in subgroups of psychiatric patients. CSF analysis is shown to be a useful diagnostic tool for differential diagnosis in psychiatric diseases.

Axonal transport of Borna disease virus along olfactory pathways in spontaneously and experimentally infected rats

In this study it has been shown that infection of mother rats by Borna disease virus (BDV) from infected newborns led to a fatal disease. This differed both in clinical symptoms and in histological alterations from the form of the disease which occurred after intracerebral (i.c.) infection. Both parameters were, however, similar to those seen after experimental intranasal (i.n.) infection of adult rats. Detailed immunohistological studies showed clearly that after experimental i.n. infection, the infecting virus migrates intraaxonally from the neuroreceptors in the olfactory epithelium into the brain. It is therefore suggested that i.n. transmission is an important route of natural BDV infection.

Borna disease, a possible hazard for man?

SummaryEvidence is presented that Borna disease (BD) virus, which is known to cause encephalopathy in horses, sheep, and a broad range of experimental animals, or a related agent, can infect man and may induce mental disorders. BD virus-specific antibodies could be demonstrated in 4–7% of sera (depending on origin) from more than 5000 psychiatric or neurological patients from Germany, U.S.A. and Japan. Antibodies from seropositive patients reacted with a BD virus-specific protein translated by RNAs which were transcribed from a cDNA clone obtained from BD virus-infected tissues. When the cerebrospinal fluid from three seropositive patients was inoculated into rabbits or rabbit embryonic brain cell cultures, evidence was obtained that suggests the presence of BD virus or a related agent.

Replication of Borna disease virus in rats: age-dependent differences in tissue distribution

There are age-dependent differences in the tissue distribution of Borna disease (BD) virus in rats infected intracerebrally. While in adult rats BD virus replication is restricted to neural cells, in neonatally infected rats infectious virus or viral antigens were found in the cells of most organs. The possibility that differences in the immune status between newborn and adult animals are responsible for different tissue susceptibility could be excluded.

Determination of immune cells and expression of major histocompatibility complex class II antigen in encephalitic lesions of experimental borna disease

SummaryAfter intracerebral infection with Borna disease virus adult Lewis rats develop a virus-induced immunopathological reaction resulting in severe neurological symptoms and a non-purulent meningoencephalitis. The composition of inflammatory cells and major histocompatibility complex (MHC) class II antigen expression during the course of the infection was investigated using immunocytochemistry with a panel of monoclonal antibodies (mAb). Macrophages and lymphocytes of the T helper phenotype (CD4+) were dominant at all stages of infection, whereas T suppressor/cytotoxic lymphocytes (CD8+) were less frequent. B lymphocytes and plasma cells occurred mainly during later stages of the disease and marked parenchymal deposition of immunoglobulin developed. Beginning 10 days after infection massive expression of MHC class II antigen was noted up to the termination of experiments 70 days after infection. Besides lymphatic cells and macrophages, cells morphologically resembling microglia expressed this antigen. Furthermore, ependymal cells were found positive for MHC class II expression during infection whereas astrocytes remained negative. These findings are consistent with previous results which provide evidence for a delayed-type hypersensitivity reaction being operative in the pathogenesis of Borna disease.

High-avidity human serum antibodies recognizing linear epitopes of borna disease virus proteins

BACKGROUND The recent observation that Borna disease virus (BDV)-reactive antibodies from psychiatric patients exhibit only low avidity for BDV antigen called into question their diagnostic value and raised the possibility that antigenically related microorganisms or self antigens caused the production of these antibodies. We further characterized the specificity of these antibodies. METHODS We established a peptide array-based screening test that allows the identification of antibodies directed against linear epitopes of the two major BDV proteins, the nucleoprotein (N) and the phosphoprotein (P). RESULTS Initial tests employing sera of BDV-infected mice and rats or horses with Borna disease revealed a high specificity and sensitivity of this test. All sera recognized epitopes of N, P, or both. Sera of noninfected rats, mice, and horses showed no signals on either peptide array. Several human sera that recognized BDV antigen by indirect immunofluorescence contained antibodies that recognized various linear epitopes of one or even both BDV proteins. Remarkably, antibodies purified from such human serum by matrix-immobilized peptides showed high-avidity binding to BDV antigens when assayed by IFA or Western blotting. CONCLUSIONS These data suggest that reactive antibodies found in psychiatric patients indeed indicate infection with BDV or a BDV-like agent. However, the poor affinity maturation of BDV-specific human antibodies remains unexplained.

Distribution of Borna disease virus in the brain of rats infected with an obesity-inducing virus strain.

Experimental infection of Lewis rats with Borna disease virus (BDV), a nonsegmented, single‐stranded RNA virus, usually causes an immune‐mediated biphasic neurobehavioral disorder. Such animals develop a persistent infection of the CNS with viral antigen expression in all brain regions and a disseminated nonpurulent meningoencephalitis. Interestingly, intracerebral infection of Lewis rats with a BDV‐variant (BDV‐ob) causes a rapid increase of body weight with the development of an obesity syndrome without obvious neurological signs. The obese phenotype is correlated with a characteristic distribution of inflammatory lesions and BDV‐antigen in the rat brain. Infiltration with mononuclear immune cells and viral antigen expression are restricted to the septum, hippocampus, amygdala and ventromedian tuberal hypothalamus. Therefore, infection with the obesity‐inducing BDV‐ob results most likely in neuroendocrine dysregulations leading to the development of an obesity syndrome. This might be due to the restriction of viral antigen expression and inflammatory lesions to brain areas which are involved in the regulation of body weight and food intake. The BDV‐induced obesity syndrome represents a model for the study of immune‐mediated neuroendocrine disorders caused by viral infections of the CNS.

Demonstration of Borna disease virus-specific RNA in secretions of naturally infected horses by the polymerase chain reaction.

The presence of Borna disease virus (BDV)-specific RNA was traced by the reverse transcriptase-polymerase chain reaction in conjunctival fluid, nasal secretions and saliva of horses which were seropositive but did not have any history of clinical Borna disease. Positive reactions encompassed sequences encoding the p24 BDV-specific protein. Virus specificity of the amplified product was confirmed by hybridization with the respective oligomer probe. Viral infectivity or virus-specific antigen was not found in any of these secretions by conventional assays in cell culture and immunoblotting.

Infection with Borna Disease Virus: Molecular and Immunobiological Characterization of the Agent

Abstract Borna disease virus (BDV), which seems to be distinct from all other known viruses, exhibits a unique mechanism of pathogenesis. This review highlights several aspects of the biology of infection with this virus and summarizes the preliminary characterization of the agent. Studies on BDV may help to illuminate several important areas of neurobiology, including the mechanisms regulating the replication of a new type of RNA virus in the nuclei of neural cells, the neuroinvasiveness and neurotropism of such viruses, their T cell-mediated immunopathology, tolerance in newborn animals to persistent viral infection of the central nervous system, and behavioral diseases and eating disorders induced by such agents.