Borna disease virus (BDV) causes a central nervous system disease in several vertebrate species which is characterized by behavioral disturbances. Seroepidemiological data indicate an association of BDV infection with certain human mental disorders. Sclerosis of the hippocampus and astrocytosis constitute histopathological hallmarks of BDV infection in animals. Therefore, we searched for human brain autopsy cases with such histopathological features. Five of 600 cases examined were identified as having hippocampus sclerosis and astrocytosis. Using immunocytochemistry, RT-PCR, and in situ hybridization, we detected both BDV antigen and RNA in autopsy brain samples from 4 of these 5 patients, who presented with a clinical history of mental disorders involving memory loss and depression. This is the first demonstration that BDV can infect human brain tissue, possibly contributing to the pathophysiology of specific human neuropsychiatric disorders.
Mice were subjected to moderate (800 g/cm force) or severe (900 g/cm force) head injury and treated 5 minutes later with various compounds. Treatments consisted of intravenous administration of the following compounds: 1) fructose 1,6-diphosphate (FDP), 2) dimethyl sulfoxide (DMSO), 3) FDP + DMSO, and 4) vehicle nontreated. Sensory-motor evaluations 1 and 2 hours after 800 g/cm-force head injury showed that significant protection of motor function (grip test) was achieved with FDP + DMSO but not with treatment by either drug alone. Evaluation of mice following a severe 900-g/cm force injury demonstrated significant survival after treatment with FDP + DMSO but not with the vehicle or treatment by either of these agents alone. Histopathological morphometry indicated that cortical and hippocampal CA1 neurons were markedly protected from damage when mice were treated with combined FDP + DMSO. More modest protection of CA1 but not of cortical neurons was observed after treatment with DMSO alone but not after treatment with FDP alone or administration of the vehicle. These findings indicate that combining FDP with DMSO results in considerable synergy in protecting animals from sensory-motor loss and neuronal brain damage and in ultimate survival stemming from a moderate or severe closed head injury.
Several arenaviruses cause hemorrhagic fever (HF) diseases that are associated with high morbidity and mortality in humans. Accordingly, HF arenaviruses have been listed as top-priority emerging diseases for which countermeasures are urgently needed. Because arenavirus nucleoprotein (NP) plays critical roles in both virus multiplication and immuneevasion, we used an unbiased proteomic approach to identify NP-interacting proteins in human cells. DDX3, a DEAD-box ATP-dependent-RNA-helicase, interacted with NP in both NP-transfected and virus-infected cells. Importantly, DDX3 deficiency compromised the propagation of both Old and New World arenaviruses, including the HF arenaviruses Lassa and Junin viruses. The DDX3 role in promoting arenavirus multiplication correlated with both a previously un-recognized DDX3 contribution to type I interferon suppression in arenavirus infected cells and a positive effect of DDX3 on viral RNA synthesis. Our results uncover novel mechanisms used by arenavirus to exploit the host machinery and subvert immunity, singling out DDX3 as a potential host target for developing new therapies against highly pathogenic arenaviruses. AUTHOR SUMMARY Arenaviruses include severe clinical pathogens causing hemorrhagic fevers and have been recently incorporated by the World Health Organization in a list of critical emerging diseases for which additional research and identification of clinical targets is urgently required. A better understanding of how viral proteins interact with host cellular factors to favor arenavirus multiplication can illuminate novel pipelines on therapeutic strategies. Here we demonstrated that the ATP-dependent RNA helicase DDX3 interacted with the arenavirus nucleoprotein, which displays fundamental functions in different steps of the viral-cycle. Our work also revealed an unexpected new biology on the role that DDX3 might play during viral infections. In sharp contrast to previous studies showing DDX3 enhancement of IFN-I induction, we demonstrated that DDX3 suppressed IFN-I production at late time points after arenavirus infection, contributing to a DDX3 pro-viral effect. We also showed that early after infection, DDX3 pro-viral role was IFN-I independent and was mediated by DDX3 facilitation of viral RNA synthesis without affecting RNA translation. Altogether, our study established DDX3 as a critical host interacting partner of the arenavirus nucleoprotein and demonstrated two previously unrecognized DDX3-dependent strategies by which these deadly viruses exploit the host cellular machinery and suppress immunity.
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