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Alongside biological, psychological, and social risk factors, psychotic syndromes may berelated to disturbances of neuronal migration. This highly complex process characterizesthe developing brain of the fetus, the early postnatal brain, and the adult brain, as reflectedby changes within the subventricular zone and the dentate gyrus of the hippocampus,where neurogenesis persists throughout life. Psychosis also appears to be linked tohuman cytomegalovirus (HCMV) infection. However, little is known about the connectionbetween psychosis, HCMV infection, and disruption of neuronal migration. The presentstudy addresses the hypothesis that HCMV infection may lead to mental disordersthrough mechanisms of autoimmune cross-reactivity. Searching for common peptidesthat underlie immune cross-reactions, the analyses focus on HCMV and human proteinsinvolved in neuronal migration. Results demonstrate a large overlap of viral peptides withhuman proteins associated with neuronal migration, such as ventral anterior homeobox 1and cell adhesion molecule 1 implicated in GABAergic and glutamatergicneurotransmission. The presentfindings support the possibility of immune cross-reactivity between HCMV and human proteins that—when altered, mutated, orimproperly functioning—may disrupt normal neuronal migration. In addition, thesefindings are consistent with a molecular and mechanistic framework for pathologicalsequences of events, beginning with HCMV infection, followed by immune activation,cross-reactivity, and neuronal protein variations that may ultimately contribute to theemergence of mental disorders, including psychosis
Human cytomegalovirus (HCMV) latency is typically harmless but reactivation can be largely detrimental to immune compromised hosts. We modeled latency and reactivation using a traceable HCMV laboratory strain expressing the Gaussia luciferase reporter gene (HCMV/GLuc) in order to interrogate the viral modulatory effects on the human adaptive immunity. Humanized mice with long-term (more than 17 weeks) steady human T and B cell immune reconstitutions were infected with HCMV/GLuc and 7 weeks later were further treated with granulocyte-colony stimulating factor (G-CSF) to induce viral reactivations. Whole body bio-luminescence imaging analyses clearly differentiated mice with latent viral infections vs. reactivations. Foci of vigorous viral reactivations were detectable in liver, lymph nodes and salivary glands. The number of viral genome copies in various tissues increased upon reactivations and were detectable in sorted human CD14+, CD169+, and CD34+ cells. Compared with non-infected controls, mice after infections and reactivations showed higher thymopoiesis, systemic expansion of Th, CTL, Treg, and Tfh cells and functional antiviral T cell responses. Latent infections promoted vast development of memory CD4+ T cells while reactivations triggered a shift toward effector T cells expressing PD-1. Further, reactivations prompted a marked development of B cells, maturation of IgG+ plasma cells, and HCMV-specific antibody responses. Multivariate statistical methods were employed using T and B cell immune phenotypic profiles obtained with cells from several tissues of individual mice. The data was used to identify combinations of markers that could predict an HCMV infection vs. reactivation status. In spleen, but not in lymph nodes, higher frequencies of effector CD4+ T cells expressing PD-1 were among the factors most suited to distinguish HCMV reactivations from infections. These results suggest a shift from a T cell dominated immune response during latent infections toward an exhausted T cell phenotype and active humoral immune response upon reactivations. In sum, this novel in vivo humanized model combined with advanced analyses highlights a dynamic system clearly specifying the immunological spatial signatures of HCMV latency and reactivations. These signatures can be merged as predictive biomarker clusters that can be applied in the clinical translation of new therapies for the control of HCMV reactivation.