Novel function of SART1 in HNF4α transcriptional regulation contributes to its antiviral role during HBV infection.

BACKGROUND & AIMS: Our understanding of the interactions between HBV and its host cells is still quite limited. Spliceosome associated factor 1 (SART1) has recently been found to restrict HCV. Thus, we aimed to dissect its role in HBV infection. METHODS: SART1 was knocked down by RNA interference and over-expressed by lentiviral or adeno-associated virus (AAV) vectors in HBV-infected cell cultures and in vivo in HBV-infected mice. Luciferase reporter assays were used to determine viral or host factor promoter activities, and chromatin immunoprecipitation (ChIP) was used to investigate protein-DNA interactions. RESULTS: In HBV-infected cell cultures, downregulation of SART1 did not affect covalently closed circular HBV DNA but resulted in markedly enhanced HBV RNA, antigen expression and progeny virus production. On the other hand, HBV transcription and replication were significantly inhibited by overexpression of SART1. Similar results were observed in AAV-HBV-infected mice persistently replicating HBV. Inhibition of Janus kinases had no effect on SART1-mediated inhibition of HBV replication. HBV promoter assays revealed that SART1 reduced HBV core promoter activity. By screening known HBV transcription factors, we found that SART1 specifically suppressed the expression of hepatocyte nuclear factor 4α (HNF4α). Luciferase reporter and ChIP assays demonstrated a direct downregulation of HNF4α expression by association of SART1 with the HNF4α proximal P1 promoter element. CONCLUSIONS: We identify SART1 as a novel host factor suppressing HBV cccDNA transcription. Besides its effect on interferon-stimulated genes, SART1 exerts an anti-HBV activity by suppressing HNF4α expression, which is essential for transcription of HBV cccDNA. LAY SUMMARY: Hepatitis B virus (HBV) infects hepatocytes and persists in the form of covalently closed circular DNA (cccDNA), which remains a major obstacle to successful antiviral treatment. In this study, using various HBV models, we demonstrate that the protein SART1 restricts HBV cccDNA transcription by suppressing a key transcription factor, HNF4α.

Macrophages prevent the differentiation of autoreactive B cells by secreting CD40 ligand and interleukin-6.

Activation of the innate immune system promotes polyclonal antibody secretion to eliminate invading pathogens. Inherent in this process is the potential to activate autoreactive B cells and induce autoimmunity. We showed previously that TLR-stimulated dendritic cells and macrophages regulate B cell tolerance to Smith antigen, in part through the secretion of interleukin-6 (IL-6). In this manuscript, we show that neutralization of IL-6 fails to abrogate macrophage-mediated repression and identify soluble CD40 ligand (CD40L) as a second repressive factor secreted by macrophages. CD40L selectively repressed Ig secretion by chronically antigen-experienced (anergic) immunoglobulin transgenic and nontransgenic B cells but not by transiently stimulated B cells. The importance of macrophages in maintaining B cell tolerance was apparent in lupus-prone MRL/lpr mice. Compared with C57BL/6 mice, macrophages from MRL/lpr mice were significantly less efficient at repressing immunoglobulin secretion coincident with diminished IL-6 and CD40 ligand production. These data indicate that macrophages regulate autoreactive B cells by secreting repressive factors that prohibit terminal differentiation of B cells. The regulation of autoreactive B cells by macrophages is diminished in lupus-prone mice suggesting a role in autoimmunity.

Identification and characterization of SmD183-119-reactive T cells that provide T cell help for pathogenic anti-double-stranded DNA antibodies.

OBJECTIVE: The C-terminal peptide of amino acids 83-119 of the SmD1 protein is a target of the autoimmune response in human and murine lupus. This study was undertaken to test the hypothesis that SmD1(83-119)-reactive T cells play a crucial role in the generation of pathogenic anti-double-stranded DNA (anti-dsDNA) antibodies. METHODS: Splenic or lymph node T cells derived from unmanipulated as well as SmD1(83-119)-immunized NZB/NZW mice were analyzed in vitro by enzyme-linked immunospot (ELISpot) assay to determine T cell help for anti-dsDNA generation induced by the SmD1(83-119) peptide. Cytokines expressed by these T cells were measured by ELISpot assay, enzyme-linked immunosorbent assay, and flow cytometry. SmD1(83-119)- and ovalbumin-specific T cell lines were generated and characterized. RESULTS: The SmD1(83-119) peptide, but not the control peptides, significantly increased the in vitro generation of anti-dsDNA antibodies in cultures from unmanipulated NZB/NZW mice. Interferon-gamma (IFNgamma), interleukin-2 (IL-2), IL-4, transforming growth factor beta, and IL-10 production increased in response to the peptide in young mice; only IFNgamma and IL-2 were increased in older, diseased mice. Activation of SmD1(83-119)-reactive T cells by immunization of NZB/NZW mice resulted in elevated anti-dsDNA synthesis and, later, increased antibodies to SmD1(83-119). Most cells in SmD1(83-119)-specific CD4+ T cell lines helping both antibodies had increased intracellular expression of IFNgamma, and most expressed both IFNgamma and IL-4. CONCLUSION: The SmD1(83-119) peptide plays an important role in generating T cell help for autoantibodies, including anti-dsDNA, and activates different subsets of T cells as defined by distinct cytokine expression. This peptide is an interesting target structure for the modulation of autoreactive T cells, and its characterization may contribute to our understanding of the role of autoantigen-reactive T cells in the pathogenesis of SLE.

Influence of antigen organization on the development of lupus autoantibodies.

OBJECTIVE: To investigate the reason for grouping of antibodies against small nuclear RNP (snRNP) particles, which are major autoantigens in systemic lupus erythematosus (SLE). METHODS: Mice were immunized with biochemically purified native snRNP particles or recombinant proteins, followed by assessment of antibody and T cell responses. Since mouse (self) snRNPs are not immunogenic in mice, a eukaryotic expression vector was constructed to induce high-level expression of the human U1 snRNP-associated A protein in murine cells. Native chimeric (mouse/human) snRNP particles were used to immunize normal mice of both H-2k and H-2b backgrounds. We also disrupted the native snRNPs by digestion with ribonuclease and used this mixture of proteins to immunize mice. RESULTS: Immunization with native chimeric snRNPs resulted in the development of antibodies against a set of snRNP-associated proteins, a response which was accompanied by breakdown in T cell tolerance to mouse snRNPs in mice immunized with chimeric snRNPs. We also demonstrated that the ordered production of these antibodies was due to the fact that snRNP-associated proteins are grouped together in snRNP particles, since disruption of the particles resulted in development of antibodies in a random order, distinct from antibodies seen with intact particles. CONCLUSION: Our findings directly demonstrate that the pattern of development of antibodies to native snRNPs is similar to that which is commonly observed in SLE, and that disruption of the particles results in disappearance of this ordered pattern. These results suggest that the autoimmune response to snRNPs, and possibly to other autoantigens, in lupus is a specific reaction similar to that seen in a typical immune response to foreign immunogens.

[The immunomodulating and immunoprotective activity of small ribonucleoprotein complexes (alpha RNPs) from the LRec-1sf cell line]. / Immunomoduliruiushchaia i immunoprotektivnaia aktivnost' malykh ribonukleoproteinovykh kompleksov (al'fa RNP) iz kletok linii LRec-1sf.

Effect of nuclear and released into culture medium alpha RNPs (N- and R-alpha-RNPs, resp.) produced by transformed rat embryo fibroblasts of serum-free cell line LRec-1sf on the nonsensibilized mouse splenocyte cytotoxicity (NK-mediated cell lysis) was studied. A preliminary treatment with N-alpha-RNPs resulted in decreasing K562 cell sensitivity to splenocyte cytotoxicity, whereas pretreatment of the splenocytes themselves exerted no cytotoxic effect. The target cell preincubation with R-alpha-RNPs had no influence on K562 cell resistance to NK cell cytotoxicity. The identical splenocyte preincubation was without action on their cytotoxic effect to LRec-1sf cells, however, resulted in an increase of the K562 cell lysis. The addition of R-alpha-RNPs into splenocyte/target cell mixtures had no influence on NK-mediated lysis, when K562 cells were used as a target cell line, but suppressed the NK-mediated lysis of LRec-1sf cells. The results of the present experiments suggest that alpha RNPs produced by LRec-1sf cell line exhibit the capacity for modulating both mouse NK cytotoxicity, and the transformed cell sensitivity to NK-mediated lysis.

[The small Alu-like RNA from the A-431 cell line specifically regulates the activity of the RNA polymerase III from human placental nuclei]. / Malaia Alu-podobnaia RNK iz kletok linii A-431 spetsificheski reguliruet aktivnost' RNK-polimerazy III iz iader platsenty cheloveka.

The influence of small Alu-like RNA, isolated from specific RNP complexes (alpha-RNP), on the activity of RNA polymerase III in cell-free system has been studied. The RNAs transcribed in vitro from Alu-DNA template (BLUR, 8) were isolated and subjected to polyacrylamide gel electrophoresis. A specific stimulation of RNA polymerase III activity by alpha-RNA was demonstrated.

Human snRNP polypeptide D1 promotes pre-mRNA splicing in yeast and defines nonessential yeast Smd1p sequences.

Parallel investigations of yeast and metazoan pre-mRNA splicing have documented enormous complexity in the nucleic acid and protein components of the cellular splicing apparatus, the spliceosome. The degree to which yeast and metazoan spliceosomal proteins differ in composition and structure is currently unknown. In this report we demonstrate that the human small nuclear ribonucleoprotein (snRNP) polypeptide D1 complements the cell lethality, splicing deficiency, and snRNA instability phenotypes associated with a yeast smd1 null allele. Mutational analysis of yeast SMD1, guided by a comparison of the predicted yeast and human proteins, reveals that a large, nonconserved portion of Smd1p is dispensable for biological activity. These observations firmly establish D1 as an essential component of the cellular splicing apparatus and suggest that yeast and metazoa are remarkably similar in the polypeptides guiding early snRNP assembly.