P.1.016 - Molecular linking of influenza infection to cellular pathology of protein misassembly: the case of Disrupted-in-Schizophrenia 1 (DISC1)

Abstract

Chronic mental illnesses such as schizophrenia or recurrent affective disorders are heterogeneous in their biological causes behind the clinical, syndromatic diagnosis. Viral infection has been linked to chronic mental illnesses both by direct mechanisms and indirect mechanisms through immune stimulation. For example, studies showed that intrauterine influenza infection could be a risk factor for chronic mental illness [1]. It is also established that viral infection can lead to a change in proteostasis impairing regulatory protein networks and leading to disease. The most dramatic consequences of disrupted proteostasis are the so-called protein misfolding diseases that show as a phenotypical hallmark, microscopically visible deposits of one or several proteins, and cell degeneration. More subtle forms of proteostatic imbalance exist where protein deposits are not microscopically visible and the neurons do not die but remain functionally impaired, for example in some forms of chronic mental illness such as schizophrenia [2]. We previously reported insoluble Disrupted-in-schizophrenia 1 (DISC1) protein in a subpopulation of patients with chronic mental illness [3]. This gene/protein is involved in vulnerability to chronic mental disorders, and was discovered mutant and segregating in a large Scottish pedigree with a chromosomal translocation leading to a 3′ truncation of the gene [4]. Subsequent genetic association studies in multiple populations of different ethnicities also support the involvement of this protein in mental illness. For the present study, our hypothesis was that influenza infection could cause significant long-term impairments of specific proteostatic pathways leading to aggregated DISC1 protein in chronic mental illness patients [5]. Neuroblastoma cell lines expressing inducible full-length, non-mutant DISC1 protein were infected with WSN33 influenza (H1N1 strain). The effect of viral infection was investigated by immunocytochemistry, biochemical and functional assays. Furthermore, infected mice with WSN33 influenza where investigated for insoluble DISC1 deposits by immunohistochemistry. Antiviral drugs were tested in order to reverse the influenza-induced DISC1 aggregates. Influenza infection of cell lines induced DISC1 misassembly but not misassembly of the protein TDP43 known to be mislocalized in ALS, but not in mental illness or influenza, and therefore serving as a control for specificity of DISC1 mis-assembly upon influenza infection in cellular models. Appearance of DISC1 deposits was dependent on infectious influenza virus titer, and the infection time. Functional consequences of influenza-induced DISC1 misassembly will be reported, as well as our investigations of influenza-infected mice that are still ongoing. We conclude that influenza infection leads to a very specific proteostatic change, including the misassembly of DISC1, which has functional consequences for dopamine homeostasis. Thus a selective reprogramming of cellular homeostasis, as measured by proteostasis, may be a novel molecular mechanism by which influenza infection can lead to brain disease.