Nucleoprotein (P40) Binding to 5HT2C Receptors (5HT2CR) is the Key Point in the Pathogenesis of BoDV-1-Infected Hosts.

Nucleoprotein (P40) is one of the most important proteins of Borna disease virus 1 (BoDV-1), but which proteins it would bind to in the pathogenesis of BoDV-1-infected hosts is unknown. We used lentivirus LV5-P40 overexpressing P40 to infect primary hippocampal neurons and characterized the interactome of P40 with co-immunoprecipitation (Co-IP) followed by mass spectrometry (MS) analysis. These interacting protein partners revealed the pathogenesis of BoDV-1-infected hosts. We also show for the first time that P40 interacts with 5HT2CR in rat neurons, which may be the molecular basis leading to neuropsychiatric diseases such as anxiety disorders and behavioral abnormalities after BoDV-1 infection of hosts.

Borna disease virus replication in organotypic hippocampal slice cultures from rats results in selective damage of dentate granule cells.

In the hippocampus of Borna disease virus (BDV)-infected newborn rats, dentate granule cells undergo progressive cell death. BDV is noncytolytic, and the pathogenesis of this neurodevelopmental damage in the absence of immunopathology remains unclear. A suitable model system to study early events of the pathology is lacking. We show here that organotypic hippocampal slice cultures from newborn rat pups are a suitable ex vivo model to examine BDV neuropathogenesis. After challenging hippocampal slice cultures with BDV, we observed a progressive loss of calbindin-positive granule cells 21 to 28 days postinfection. This loss was accompanied by reduced numbers of mossy fiber boutons when compared to mock-infected cultures. Similarly, the density of dentate granule cell axons, the mossy fiber axons, appeared to be substantially reduced. In contrast, hilar mossy cells and pyramidal neurons survived, although BDV was detectable in these cells. Despite infection of dentate granule cells 2 weeks postinfection, the axonal projections of these cells and the synaptic connectivity patterns were comparable to those in mock-infected cultures, suggesting that BDV-induced damage of granule cells is a post-maturation event that starts after mossy fiber synapses are formed. In summary, we find that BDV infection of rat organotypic hippocampal slice cultures results in selective neuronal damage similar to that observed with infected newborn rats and is therefore a suitable model to study BDV-induced pathology in the hippocampus.

Borna disease virus RNA in immunocompromised patients in southwestern France.

Borna disease virus (BDV) is a neurotropic RNA virus with a wide host range. Human infections, although controversial, have been described in Europe, Asia, and the United States. The present study investigated the existence of BDV infections in immunocompromised human beings, namely, 82 human immunodeficiency virus (HIV)-infected and 80 therapeutically immunosuppressed patients. BDV p40 RNAs were detected in peripheral white blood cells with reverse transcription-nested PCR and hybridization in, respectively, 11 (13.41%) and 1 (1.25%) of the two groups of patients. BDV p24 RNAs were identified in only one of those. BDV RNA was detected in the absence of any neuropsychiatrical illness, suggesting that BDV infections may occur in asymptomatic carriers. The severity and particularity of cellular immunosuppression could explain the significantly increased detection of BDV RNA in HIV-infected patients.

Borna disease in horses.

Borna disease is a sporadically occurring, progressive viral polioencephalomyelitis that primarily affects horses and sheep. The etiological agent, Borna disease virus (BDV), is an enveloped, single-stranded RNA virus that has been classified in the new virus family Bornaviridae within the order Mononegavirales. Serological evidence of BDV infection has been found in an increasing number of countries throughout the world. After an incubation period lasting a few weeks to several months, BDV infection can cause locomotor and sensory dysfunction followed by paralysis and death. Borna disease is the result of a virus-induced immunopathological reaction. BDV-specific antibodies and viral RNA have been found in humans with various psychiatric disorders.

High susceptibility of Mongolian gerbil (Meriones unguiculatus) to Borna disease virus.

Borna disease virus (BDV) is a neurotropic enveloped virus with a nonsegmented, single-, negative-stranded RNA genome. This virus induced encephalitis in experimentally infected adult rats, but in newborn rats BDV established a persistent, tolerant infection with no apparent clinical signs. Here, we report evidence that newborn Mongolian gerbils (Meriones unguiculatus) are more susceptible to experimental intracranial inoculation of horse-derived BDV in persistently infected MDCK cells, compared with similar inoculation in newborn rats. All inoculated newborn gerbils, but not rats, died 30 days after infection. Reverse transcriptase-polymerase chain reaction amplified BDV-specific sequences in several regions including the brain. Histopathological analysis revealed apparent inflammatory reactions in the brains of inoculated gerbils but not rats, although similar levels of BDV RNA were detected in both gerbil and rat brains. BDV-specific antigen and RNA were identified predominantly in neurons in the brains by immunohistochemistry with antibodies to BDV and in situ hybridization with BDV-specific riboprobes, respectively. BDV in the gerbil brain was easily rescued by co-cultivation of the brain homogenate with human oligodendroglioma cells. Thus, gerbils seem to be a useful animal model for studying BDV-induced pathogenesis in the brain.

Borna disease virus infection in animals and humans.

The geographic distribution and host range of Borna disease (BD), a fatal neurologic disease of horses and sheep, are larger than previously thought. The etiologic agent, Borna disease virus (BDV), has been identified as an enveloped nonsegmented negative-strand RNA virus with unique properties of replication. Data indicate a high degree of genetic stability of BDV in its natural host, the horse. Studies in the Lewis rat have shown that BDV replication does not directly influence vital functions; rather, the disease is caused by a virus-induced T-cell mediated immune reaction. Because antibodies reactive with BDV have been found in the sera of patients with neuropsychiatric disorders, this review examines the possible link between BDV and such disorders. Seroepidemiologic and cerebrospinal fluid investigations of psychiatric patients suggest a causal role of BDV infection in human psychiatric disorders. In diagnostically unselected psychiatric patients, the distribution of psychiatric disorders was found to be similar in BDV seropositive and seronegative patients. In addition, BDV-seropositive neurologic patients became ill with lymphocytic meningoencephalitis. In contrast to others, we found no evidence is reported for BDV RNA, BDV antigens, or infectious B DV in peripheral blood cells of psychiatric patients.

Borna disease--neuropathology and pathogenesis.

Natural BD is a nonpurulent acute/subacute encephalitis of horses and sheep with a propensity to involve the olfactory and limbic systems, and the brain stem. The inflammation is concentrated primarily in the gray matter, but subcortical white matter may also be affected. Experimental BD can be produced in a series of animals from birds to primates. The neuropathology after experimental infection is similar to that in natural disease but the inflammatory changes are more diffuse. In the rat and mouse, a persistent/tolerant infection can also be induced, in which inflammatory changes are conspicuously absent. In the course of persistent infection of the rat, an elective, focal degeneration ensues that involves the dentate gyrus, retina, and, less frequently, the magnocellular part of the hippocampus. The cytopathic destruction of the dentate gyrus is the likely anatomical substrate of learning deficiencies and behavioral changes, prominent features of chronic infection. Later in infection, more diffuse and random degeneration of neurons can be found. In all species infected, viral antigens are produced in excess and fill all neuronal processes. Beside neurons, glial cells are infected as well. The agent spreads in the nervous system axonally and transsynaptically (transneuronally). The type of neurotransmitter receptors in the synapse and their interaction with viral proteins may modulate the spread of infection (Gosztonyi et al. 1994). Virus particles have not been visualized in the brain in any phase of the disease. During persistent infection of the rat, production of viral proteins has a phasic character. Some rats survive acute infection and develop an obesity syndrome. The anatomical basis of this syndrome is not fully clarified; inflammatory destruction of the infundibular region, vacuolar degeneration of the paraventricular nucleus of the hypothalamus and severe, progressive involution of the hippocampal formation most probably play an important role in the production of this neuroendocrine syndrome. In the acute disease, inflammatory reaction can severely aggravate virus-induced cytopathology, but cannot be the sole cause of the neurological disease, since infection with high passage virus can lead to a similarly severe disease in the absence of inflammatory changes.

Rabies and borna disease. A comparative pathogenetic study of two neurovirulent agents.

BACKGROUND: Rabies and Borna disease viruses have been regarded as classical neurotropic agents. Many pathogenetic similarities are shared by these two negative strand RNA viruses. In view of recently gained data on the virology and pathology of these two diseases, and up-to-date comparative pathogenetic study seems to be justified. EXPERIMENTAL DESIGN: This study is based on a survey of experimental and natural infections of laboratory animals and natural hosts. The morphologic damage to the nervous system has been evaluated by light and electron microscopy, with special emphasis on immunocytochemical methods. RESULTS: This comparative study disclosed that both viruses are transported inside axons, pass synapses and propagate along neuronal networks. At the sites of synaptic transfer, full virus particles can never be detected in the early phase of rabies virus infection; in Borna disease virus (BDV) infection, virus particles cannot be found in any phase of disease progression. Thus, a major difference exists between the two agents insofar as rabies virus is morphologically well characterized, whereas BDV has never been visualized in tissue sections. Furthermore, rabies virus infects only neurons, whereas BDV also infects glial cells. The host range and the scale of infection of extraneural tissues by both agents is extremely similar. CONCLUSIONS: These observations allow us to postulate that the synaptic transfer of both viruses likely ensures in the form of bare nucleocapsids (ribonucleoprotein-transcriptase complexes). While in the later phases of replication complete rabies virions are regularly assembled, BDV propagates within the central nervous system in an incomplete form, so that it remains morphologically imperceptible. Thus, BDV may appear in a complete, enveloped form only when exiting the host organism. The dissemination patterns of the two agents may be influenced by specific affinities to neurotransmitter receptor sites. It remains unresolved, why BDV readily infects non-neuronal central nervous system cells, while rabies virus remains restricted to neuronal elements.

Pathogenesis of Borna disease.

Borna disease represents a unique model of a virus-induced immunological disease of the brain. Naturally occurring in horses and sheep, the mechanisms of pathogenesis have been studied in experimental animals, namely in the rat. Many investigations have revealed that the infection of the natural hosts principally follows the same pathogenic pathways as observed in rats, leading to a severe encephalomyelitis. This affliction of the central nervous system results in severe neurological disorders that again, are fully comparable in laboratory animals to those in the natural and the different experimental hosts. In addition, alterations have been reported which are also based on the infection of the brain and do not result in the classical encephalitic clinical picture but rather in alterations of behavior. However, to all of our knowledge, the various clinical pictures of Borna disease are not caused by the infecting virus itself but rather by the hosts immune response towards it, i.e. by a virus-induced cell-mediated immunopathological reaction. The importance of virus-specific CD4+ T cells as exemplified by a cultured T cell line and of CD8+ T cells as shown by immunomodulatory substances and specific antibody treatment in vivo for the pathogenesis of acute Borna disease will be elucidated here. In addition, evidence will be provided that virus-specific CD8+ T cells are also responsible for the dramatic brain atrophy in the chronic phase of the disease in rats. Therefore, Borna disease not only lends itself exquisitely well to the study of the pathogenesis of an immunopathological disease of the brain but also represents one of the few models for immune-mediated tissue destruction that eventually leads to brain atrophy and clinically to dementia.

Infection with Borna disease virus: molecular and immunobiological characterization of the agent.

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.

[Immunopathogenesis of Borna disease]. / Immunpathogenese der Borna-Krankheit.

An overview of the pathogenesis of Borna disease (BD) in rats as a model for the naturally occurring infection in horses and sheep is presented. Our findings revealed a virus infection in which a virus-specific T cell-mediated immune response leads to disease. The immune cells capable of mediating this immunopathological reaction were defined as helper/inducer T cells. In all, the described observations indicate that CD4+ T cells and macrophages trigger a delayed-type hypersensitivity reaction and cause BD together with other cells of the immune system.

[Borna disease]. / Die Bornasche Krankheit.

Using Borna disease as a model, the consequences of persistent virus infections of the central nervous system, in particular of "slow virus diseases", are briefly described. Both latent and active forms of the disease have much in common with chronically progressive diseases of the central nervous system in animals and man which have until now remained unexplained. Virologically and serologically there exist simple laboratory procedures to examine the pathogenesis and immunology of the disease, in addition to suitable laboratory animals and a variety of cell cultures.

Immune-mediated pathogenesis of Borna disease.

Borna disease is an endemic progressive encephalomyelitis of horses and sheep prevalent in central Europe. A wide variety of animal species, ranging from chickens to primates can be infected experimentally with the causative virus, which is only poorly characterized. Furthermore, BD virus-specific antibodies have been detected in sera and cerebrospinal fluids of psychiatric patients. Our studies on the pathogenesis of BD have shown that-at least in rats-the disease is not caused by the infecting virus itself, but by a virus-induced immunopathological reaction. Thus, after intracerebral infection immunoincompetent rats do not get the disease despite persistent virus replication in cells of the central nervous system. However, after adoptive transfer of immune cells from diseased rats, immunoincompetent rats exhibit full-blown BD. Recently, we have been successful in establishing a virus-specific T cell line of the helper/inducer phenotype (CD4+). This T cell was shown to play an important role in the pathogenesis of BD, suggesting that the disease is caused by a delayed type hypersensitivity reaction.