Sphingosine-1-phosphate receptor 1 mediates elevated IL-6 signaling to promote chronic inflammation and multitissue damage in sickle cell disease.

Sphingosine-1-phosphate (S1P) is a biolipid involved in chronic inflammation in several inflammatory disorders. Recent studies revealed that elevated S1P contributes to sickling in sickle cell disease (SCD), a devastating hemolytic, genetic disorder associated with severe chronic inflammation and tissue damage. We evaluated the effect of elevated S1P in chronic inflammation and tissue damage in SCD and underlying mechanisms. First, we demonstrated that interfering with S1P receptor signaling by FTY720, a U.S. Food and Drug Administration-approved drug, significantly reduced systemic, local inflammation and tissue damage without antisickling effects. These findings led us to discover that S1P receptor activation leads to substantial elevated local and systemic IL-6 levels in SCD mice. Genetic deletion of IL-6 in SCD mice significantly reduced local and systemic inflammation, tissue damage, and kidney dysfunction. At the cellular level, we determined that elevated IL-6 is a key cytokine functioning downstream of elevated S1P, which contributes to increased S1P receptor 1 ( S1pr1) gene expression in the macrophages of several tissues in SCD mice. Mechanistically, we revealed that S1P-S1PR1 signaling reciprocally up-regulated IL-6 gene expression in primary mouse macrophages in a JAK2-dependent manner. Altogether, we revealed that elevated S1P, coupled with macrophage S1PR1 reciprocally inducing IL-6 expression, is a key signaling network functioning as a malicious, positive, feed-forward loop to sustain inflammation and promote tissue damage in SCD. Our findings immediately highlight novel therapeutic possibilities.-Zhao, S., Adebiyi, M. G., Zhang, Y., Couturier, J. P., Fan, X., Zhang, H., Kellems, R. E., Lewis, D. E., Xia, Y. Sphingosine-1-phosphate receptor 1 mediates elevated IL-6 signaling to promote chronic inflammation and multitissue damage in sickle cell disease.

Allele Specific Expression of MICA Variants in Human Fibroblasts Suggests a Pathogenic Mechanism.

The major histocompatibility complex class I chain-related gene A (MICA) is involved in immune responses of both nature killer (NK) cells and subsets of T cells with its receptor NKG2D. MICA is highly polymorphic in sequence which leads to MICA protein variants with distinct features. Specific polymorphisms of MICA have been associated with inflammatory diseases, including ankylosing spondylitis (AS), ulcerative colitis (UC) and Behçet's disease. Studies herein characterize expression features of three MICA variants including MICA*008, a common variant in general population, and *MICA*007 and *019, which are associated with susceptibility to inflammatory diseases. MICA*019 was highly expressed on the surface of fibroblasts whereas expression of MICA*007 was the lowest in the culture supernatant. MICA*008 had low cell surface expression but was the only MICA allele in which exosomal material was detected. Surface or membrane-bound MICA activates NKG2D-mediated cytotoxicity, whereas soluble and exosomal MICAs down-regulate NKG2D. Therefore, comparisons of these three MICA variants in fibroblasts provides insight into understanding how MICA associated immune responses could be regulated to influence levels of inflammation.

HIV may produce inhibitory microRNAs (miRNAs) that block production of CD28, CD4 and some interleukins.

It is well-known that HIV-1 infection results in a gradual decline of the CD4+ T-lymphocytes, but the underlying mechanism of this decline is not completely understood. Research has shown that HIV-1 infection of CD4+ T cells results in decreased CD28 expression, but the mechanism of this repression is unknown. There is also substantial evidence demonstrating regulatory involvement of microRNA (miRNA) during protein expression in plants and some animals, and reports have recently been published confirming the existence of viral-encoded miRNAs. Based on these findings, we hypothesize that viral-encoded miRNA from HIV-1 may directly alter T cell, macrophage and dendritic cell activity. To investigate a potential correlation between the genomic complementarity of HIV-1 and host cell protein expression, a local alignment search was performed to assess for regions of complementarity between the HIV-1 proviral genome and the mRNA coding sequence of various proteins expressed by CD+ T cells and macrophages. Regions of complementarity with strong correlations to the currently established criteria for miRNA:target mRNA activity were found between HIV-1 and CD28, CTLA-4 and some interleukins, suggesting that HIV-1 may produce translational repression in host cells.