The 1918 to 1919 “Spanish” influenza pandemic virus killed up to 50 million people. We report here clinical, pathological, bacteriological, and virological findings in 68 fatal American influenza/pneumonia military patients dying between May and October of 1918, a period that includes ∼4 mo before the 1918 pandemic was recognized, and 2 mo (September–October 1918) during which it appeared and peaked. The lung tissues of 37 of these cases were positive for influenza viral antigens or viral RNA, including four from the prepandemic period (May–August). The prepandemic and pandemic peak cases were indistinguishable clinically and pathologically. All 68 cases had histological evidence of bacterial pneumonia, and 94% showed abundant bacteria on Gram stain. Sequence analysis of the viral hemagglutinin receptor-binding domain performed on RNA from 13 cases suggested a trend from a more “avian-like” viral receptor specificity with G222 in prepandemic cases to a more “human-like” specificity associated with D222 in pandemic peak cases. Viral antigen distribution in the respiratory tree, however, was not apparently different between prepandemic and pandemic peak cases, or between infections with viruses bearing different receptor-binding polymorphisms. The 1918 pandemic virus was circulating for at least 4 mo in the United States before it was recognized epidemiologically in September 1918. The causes of the unusually high mortality in the 1918 pandemic were not explained by the pathological and virological parameters examined. These findings have important implications for understanding the origins and evolution of pandemic influenza viruses.
SUMMARY Recent epidemiological studies have identified interferon regulatory factor 8 (IRF8) as a susceptibility factor for multiple sclerosis (MS). However, how IRF8 influences the neuroinflammatory disease has remained unknown. By studying the role of IRF8 in experimental autoimmune encephalomyelitis (EAE), a mouse model of MS, we found that Irf8−/− mice are resistant to EAE. Furthermore, expression of IRF8 in antigen presenting cells (APCs, such as macrophages, dendritic cells and microglia), but not in T cells, facilitated disease onset and progression through multiple pathways. IRF8 enhanced αvβ8 integrin expression in APCs and activated TGFβ signaling leading to T helper 17 (Th17) cell differentiation. IRF8 induced a cytokine milieu that favored growth and maintenance of Th1 and Th17 cells, by stimulating interleukin-12 (IL12) and IL23 production, but inhibiting IL27 during EAE. Finally, IRF8 activated microglia and exacerbated neuroinflammation. Together, this work provides mechanistic bases by which IRF8 contributes to the pathogenesis of MS.
Neurotropic flaviviruses can efficiently replicate in the developing and mature central nervous systems (CNS) of mice causing lethal encephalitis. Insertion of a single copy of a target for brain-expressed microRNAs (miRNAs) in the 3′ noncoding region (3′NCR) of the flavivirus genome (chimeric tick-borne encephalitis virus/dengue virus) abolished virus neurovirulence in the mature mouse CNS. However, in the developing CNS of highly permissive suckling mice, the miRNA-targeted viruses can revert to a neurovirulent phenotype by accumulating deletions or mutations within the miRNA target sequence. Virus escape from miRNA-mediated suppression in the developing CNS was markedly diminished by increasing the number of miRNA target sites and by extending the distance between these sites in the virus genome. Insertion of multiple miRNA targets into the 3′NCR altered virus neuroinvasiveness, decreased neurovirulence and neuroinflammatory responses, and prevented neurodegeneration without loss of immunogenicity. Although the onset of encephalitis was delayed, a small number of suckling mice still succumbed to lethal intracerebral infection with the miRNA-targeted viruses. Sequence analysis of brain isolates from moribund mice revealed that the viruses escaped from miRNA-mediated suppression exclusively through the deletion of miRNA targets and viral genome sequence located between the two miRNA targets separated by the greatest distance. These findings offer a general strategy to control the reversion of virus to a virulent phenotype: a simultaneous miRNA targeting of the viral genome at many different functionally important regions could prevent virus escape from miRNA-based attenuation, since a deletion of the targeted genomic sequences located between the inserted miRNA binding sites would be lethal for the virus.
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