No abstract
Recently, numerous large-scale mumps outbreaks have occurred in vaccinated populations. Clinical isolates sequenced from these outbreaks have invariably been of genotypes distinct from those of vaccine viruses, raising concern that certain mumps virus strains may escape vaccine-induced immunity. To investigate this concern, sera obtained from children 6 weeks after receipt of measles, mumps, and rubella (MMR) vaccine were tested for the ability to neutralize a carefully selected group of genetically diverse mumps virus strains. Although the geometric mean neutralizing antibody titer of the sera was lower against some virus strains than others, all viruses were readily neutralized, arguing against immune escape.
In several vertebrate species, Borna disease virus (BDV), the prototype of a new group of animal viruses, causes central nervous system disease accompanied by diverse behavioral abnormalities. Seroepidemiological data indicate that BDV may contribute to the pathophysiology of certain human mental disorders. This hypothesis is further supported by the detection of both BDV antigens and BDV RNA in peripheral blood mononuclear cells (PBMCs) of patients with psychiatric disorders and the isolation of BDV from such PBMCs.Here we describe serological and molecular epidemiological studies on psychiatric patients and healthy individuals from the area of Homburg, Germany. Using a novel Western blot (immunoblot) assay, we found a BDV seroprevalence of 9.6% among 416 neuropsychiatric patients, which is significantly higher than the 1.4% found among 203 healthy control individuals. Human sera displayed a prominent immunoreactivity against the virus nucleoprotein, the p40 antigen. Reverse transcriptase-mediated PCR analysis of RNA extracted from PBMCs of a subset of 26 of the neuropsychiatric patients revealed that 50% were BDV RNA positive. Three of the 13 BDV RNA-positive patients also had BDV-positive serology, whereas one patient with serum antibodies to BDV p40 antigen did not harbor detectable BDV RNA in PBMCs. BDV p40 and p24 sequences derived from human PBMCs exhibited both a high degree of inter-and intrapatient conservation and a close genetic relationship to animal-derived BDV sequences.
Persistent viral infections can render host cells resistant to superinfection with closely related viruses by largely uncharacterized mechanisms. We present evidence for superinfection exclusion in brains of Borna disease virus (BDV)-infected rats and in persistently infected Vero cells, and we suggest that acquired resistance to BDV is due to unbalanced intracellular levels of viral nucleocapsid components. We observed that expression of BDV protein P, N, or X rendered human cells resistant to subsequent challenge with BDV but not with other RNA viruses, indicating that incorrect stoichiometry of nucleocapsid components selectively blocked the polymerase activity of incoming viruses. Vero cells containing high levels of an untranslatable BDV-N transcript remained virus susceptible, demonstrating that viral protein rather than RNA mediated resistance. Transient overexpression of BDV-P in persistently infected Vero cells was also remarkably effective against BDV, indicating that the intracellular balance of viral nucleocapsid components could serve as a target for future therapeutic antiviral strategies.Borna disease virus (BDV) persistently infects neurons and other cells of the central nervous systems of a broad range of warm-blooded animals and possibly humans (7,21,32,34). Natural and experimental infections with BDV may result in immune system-mediated neurological disease and behavioral abnormalities (17,28). BDV is a newly classified nonsegmented negative-stranded RNA virus that, unlike other Mononegavirales, replicates in the nuclei of infected cells and employs the splicing machinery for the maturation of some of its transcripts. Its genome codes for at least six viral proteins, of which the phosphoprotein P, the nucleoprotein N, and the RNA polymerase complex-associated protein X are abundantly present in infected cells (19,31).It was recently suggested that the remarkable stability of the BDV genome might be a consequence of superinfection exclusion (11). It is well known that certain persistent viral infections can confer resistance to subsequent infection of host cells with the same virus or a closely related virus. This phenomenon, designated superinfection exclusion or homologous interference (1, 20), has been described for retroviruses (5, 9), hepatitis B virus (6), alphaviruses (1, 20), Rift valley fever virus (3), and pestiviruses (23). Superinfection exclusion by retroviruses is primarily due to down-regulation of host cell surface entry receptors (5, 9). A similar mechanism may account for superinfection exclusion in hepatitis B virus-infected duck hepatocytes (6). Poorly defined mechanisms seem to contribute to superinfection exclusion of alphaviruses; one of these is posttranscriptional gene silencing (2). RNA silencing also seems to play a role in the case of Rift valley fever virus, because superinfection exclusion in insect cells could be mimicked by expression of nontranslatable viral RNAs (3).We now present evidence that superinfection exclusion is operative in brain cells of BDV-infect...
Viruses with the ability to establish persistent infection in the central nervous system (CNS) can induce progressive neurologic disorders associated with diverse pathological manifestations. Clinical, epidemiological, and virological evidence supports the hypothesis that viruses contribute to human mental diseases whose etiology remains elusive. Therefore, the investigation of the mechanisms whereby viruses persist in the CNS and disturb normal brain function represents an area of research relevant to clinical and basic neurosciences. Borna disease virus (BDV) causes CNS disease in several vertebrate species characterized by behavioral abnormalities. Based on its unique features, BDV represents the prototype of a new virus family. BDV provides an important model for the investigation of the mechanisms and consequences of viral persistence in the CNS. The BDV paradigm is amenable to study virus-cell interactions in the CNS that can lead to neurodevelopmental abnormalities, immune-mediated damage, as well as alterations in cell differentiated functions that affect brain homeostasis. Moreover, seroepidemiological data and recent molecular studies indicate that BDV is associated with certain neuropsychiatric diseases. The potential role of BDV and of other yet to be uncovered BDV-related viruses in human mental health provides additional impetus for the investigation of this novel neurotropic infectious agent.
Mumps virus is a highly neurotropic virus with evidence of central nervous system invasion (CNS) in approximately half of all cases of infection. In countries where live attenuated mumps virus vaccines were introduced, the number of mumps cases declined dramatically; however, recently, the safety of some vaccine strains has been questioned. For example, one of the most widely used vaccines, the Urabe AM9 strain, was causally associated with meningitis, leading to the withdrawal of this product from the market in several countries. This highlights the need for a better understanding of the attenuation process and the identification of markers of attenuation. To this end, we further attenuated the Urabe AM9 strain by serial passage in cell culture and compared the complete nucleotide sequences of the parental and passaged viruses. Interestingly, despite a dramatic decrease in virus virulence (as assayed in rats), the only genomic changes were in the form of changes in the level of genetic heterogeneity at specific genome sites, i.e., either selection of one nucleotide variant at positions where the starting material exhibited nucleotide heterogeneity or the evolution of an additional nucleotide to create a heterogenic site. This finding suggests that changes in the level of genetic heterogeneity at specific genome sites can have profound neurovirulence phenotypic consequences and, therefore, caution should be exercised when evaluating genetic markers of virulence or attenuation based only on a consensus sequence.
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