Glial cell lineage expression of mutant ataxin-1 and huntingtin induces developmental and late-onset neuronal pathologies in Drosophila models.

BACKGROUND: In several neurodegenerative disorders, toxic effects of glial cells on neurons are implicated. However the generality of the non-cell autonomous pathologies derived from glial cells has not been established, and the specificity among different neurodegenerative disorders remains unknown. METHODOLOGY/PRINCIPAL FINDINGS: We newly generated Drosophila models expressing human mutant huntingtin (hHtt103Q) or ataxin-1 (hAtx1-82Q) in the glial cell lineage at different stages of differentiation, and analyzed their morphological and behavioral phenotypes. To express hHtt103Q and hAtx1-82Q, we used 2 different Gal4 drivers, gcm-Gal4 and repo-Gal4. Gcm-Gal4 is known to be a neuroglioblast/glioblast-specific driver whose effect is limited to development. Repo-Gal4 is known to be a pan-glial driver and the expression starts at glioblasts and continues after terminal differentiation. Gcm-Gal4-induced hHtt103Q was more toxic than repo-Gal4-induced hHtt103Q from the aspects of development, locomotive activity and survival of flies. When hAtx1-82Q was expressed by gcm- or repo-Gal4 driver, no fly became adult. Interestingly, the head and brain sizes were markedly reduced in a part of pupae expressing hAtx1-82Q under the control of gcm-Gal4, and these pupae showed extreme destruction of the brain structure. The other pupae expressing hAtx1-82Q also showed brain shrinkage and abnormal connections of neurons. These results suggested that expression of polyQ proteins in neuroglioblasts provided a remarkable effect on the developmental and adult brains, and that glial cell lineage expression of hAtx1-82Q was more toxic than that of hHtt103Q in our assays. CONCLUSION/SIGNIFICANCE: All these studies suggested that the non-cell autonomous effect of glial cells might be a common pathology shared by multiple neurodegenerative disorders. In addition, the fly models would be available for analyzing molecular pathologies and developing novel therapeutics against the non-cell autonomous polyQ pathology. In conclusion, our novel fly models have extended the non-cell autonomous pathology hypothesis as well as the developmental effect hypothesis to multiple polyQ diseases. The two pathologies might be generally shared in neurodegeneration.

Involvement of IL-1beta and IL-10 in IFN-alpha-mediated antiviral gene induction in human hepatoma cells.

Crosstalk between interferons (IFNs) and several cytokines is likely to play an important role in viral clearance in chronic hepatitides B and C. We investigated the influence of this phenomenon on IFN-inducible antiviral gene expression in HuH-7 human hepatoma cells. HuH-7 cells were treated with IFN-alpha in the absence or presence of interleukin-1beta (IL-1beta) or IL-10 and the expression of antiviral genes such as 2(')5(')-oligoadenylate synthetase (2(')5(')-OAS) and double-stranded RNA-dependent protein kinase (PKR), as well as activation of signal transducer and activator of transcription 1 (STAT1), a key step for relaying the IFN-alpha signals, was analyzed by Northern blotting, Western blotting, and the reporter gene transfection assay. IL-1beta potentiated IFN-alpha-induced 2(')5(')-OAS and PKR gene expression, similar to expression of the transfected reporter genes containing the IFN-stimulated regulatory elements, while IL-10 suppressed IFN-alpha-stimulated gene expression. With regard to IFN-alpha signaling, IL-1beta enhanced both tyrosine and serine phosphorylation of STAT1 through p38 mitogen-activated protein kinase activation. In contrast, IL-10 inhibited IFN-alpha-mediated tyrosine phosphorylation of STAT1 by induction of a Janus kinase inhibitor, JAB. IL-1beta and IL-10 interact with IFN-alpha to up- and down-regulate antiviral gene expression, respectively, by modulating STAT1 activation induced by IFN-alpha.