ß8 Integrin Expression and Activation of TGF-ß by Intestinal Dendritic Cells Are Determined by Both Tissue Microenvironment and Cell Lineage.

Activation of TGF-ß by dendritic cells (DCs) expressing αvß8 integrin is essential for the generation of intestinal regulatory T cells (Tregs) that in turn promote tolerance to intestinal Ags. We have recently shown that αvß8 integrin is preferentially expressed by CD103(+) DCs and confers their ability to activate TGF-ß and generate Tregs. However, how these DCs become specialized for this vital function is unknown. In this study, we show that ß8 expression is controlled by a combination of factors that include DC lineage and signals derived from the tissue microenvironment and microbiota. Specifically, our data demonstrate that TGF-ß itself, along with retinoic acid and TLR signaling, drives expression of αvß8 in DCs. However, these signals only result in high levels of ß8 expression in cells of the cDC1 lineage, CD8α(+), or CD103(+)CD11b(-) DCs, and this is associated with epigenetic changes in the Itgb8 locus. Together, these data provide a key illustrative example of how microenvironmental factors and cell lineage drive the generation of regulatory αvß8-expressing DCs specialized for activation of TGF-ß to facilitate Treg generation.

The hsa-miR-125a/hsa-let-7e/hsa-miR-99b cluster is potentially implicated in Cystic Fibrosis pathogenesis.

BACKGROUND: Cystic Fibrosis (CF) is an autosomal recessive disorder implicating the Cystic Fibrosis Transmembrane Regulator (CFTR). Even though CF is mainly considered an inherited monogenic disease, numerous findings over the last few years argue for a more complicated multifactorial disease involving modifier genes. The 19q13.2-19q13.4 region is suspected to contain genetic modifiers that correlate to the severity of CF. METHOD: Here we studied a cohort of p.F508del patients for potential SNPs in the hsa-miR-99b/hsa-let-7e/hsa-miR-125a cluster, which is found within the 19q13.2-19q13.4 region. RESULTS: Three polymorphisms were identified in the hsa-miR-99b/hsa-let-7e/hsa-miR-125a cluster. Using a cell based model, we analysed whether expression of DeltaF508-CFTR influences the expression of mature hsa-miR-99b, hsa-let-7e, and hsa-miR-125a. We found that hsa-miR-99b and hsa-miR-125a were significantly increased in DeltaF508-CFTR expressing cells. The three miRNAs appear to be derived from the same precursor but differ in their expression levels suggesting differential maturation of these miRNAs in CF. In silico analysis revealed that two out of the three polymorphisms we identified in a CF p.F508del patients cohort could modulate miRNA maturation and therefore impact on hsa-miR-99b/hsa-let-7e/hsa-miR-125a expression levels. CONCLUSION: Ingenuity Pathway Analysis indicated that hsa-miR-99b and hsa-miR-125a could be associated with the phenotypes manifested by p.F508del patients. Here we provide novel elements in the mechanism of hsa-miR-99b and hsa-miR-125a biogenesis, and for the role of CFTR and DeltaF508-CFTR on the expression of this miRNA cluster. These findings augment existing data implicating miRNAs as putative CF modifiers.

A 2.5-kilobase deletion containing a cluster of nine microRNAs in the latency-associated-transcript locus of the pseudorabies virus affects the host response of porcine trigeminal ganglia during established latency.

UNLABELLED: The alphaherpesvirus pseudorabies virus (PrV) establishes latency primarily in neurons of trigeminal ganglia when only the transcription of the latency-associated transcript (LAT) locus is detected. Eleven microRNAs (miRNAs) cluster within the LAT, suggesting a role in establishment and/or maintenance of latency. We generated a mutant (M) PrV deleted of nine miRNA genes which displayed properties that were almost identical to those of the parental PrV wild type (WT) during propagation in vitro. Fifteen pigs were experimentally infected with either WT or M virus or were mock infected. Similar levels of virus excretion and host antibody response were observed in all infected animals. At 62 days postinfection, trigeminal ganglia were excised and profiled by deep sequencing and quantitative RT-PCR. Latency was established in all infected animals without evidence of viral reactivation, demonstrating that miRNAs are not essential for this process. Lower levels of the large latency transcript (LLT) were found in ganglia infected by M PrV than in those infected by WT PrV. All PrV miRNAs were expressed, with highest expression observed for prv-miR-LLT1, prv-miR-LLT2 (in WT ganglia), and prv-miR-LLT10 (in both WT and M ganglia). No evidence of differentially expressed porcine miRNAs was found. Fifty-four porcine genes were differentially expressed between WT, M, and control ganglia. Both viruses triggered a strong host immune response, but in M ganglia gene upregulation was prevalent. Pathway analyses indicated that several biofunctions, including those related to cell-mediated immune response and the migration of dendritic cells, were impaired in M ganglia. These findings are consistent with a function of the LAT locus in the modulation of host response for maintaining a latent state. IMPORTANCE: This study provides a thorough reference on the establishment of latency by PrV in its natural host, the pig. Our results corroborate the evidence obtained from the study of several LAT mutants of other alphaherpesviruses encoding miRNAs from their LAT regions. Neither PrV miRNA expression nor high LLT expression levels are essential to achieve latency in trigeminal ganglia. Once latency is established by PrV, the only remarkable differences are found in the pattern of host response. This indicates that, as in herpes simplex virus, LAT functions as an immune evasion locus.

Prediction of altered 3'- UTR miRNA-binding sites from RNA-Seq data: the swine leukocyte antigen complex (SLA) as a model region.

THE SLA (swine leukocyte antigen, MHC: SLA) genes are the most important determinants of immune, infectious disease and vaccine response in pigs; several genetic associations with immunity and swine production traits have been reported. However, most of the current knowledge on SLA is limited to gene coding regions. MicroRNAs (miRNAs) are small molecules that post-transcriptionally regulate the expression of a large number of protein-coding genes in metazoans, and are suggested to play important roles in fine-tuning immune mechanisms and disease responses. Polymorphisms in either miRNAs or their gene targets may have a significant impact on gene expression by abolishing, weakening or creating miRNA target sites, possibly leading to phenotypic variation. We explored the impact of variants in the 3'-UTR miRNA target sites of genes within the whole SLA region. The combined predictions by TargetScan, PACMIT and TargetSpy, based on different biological parameters, empowered the identification of miRNA target sites and the discovery of polymorphic miRNA target sites (poly-miRTSs). Predictions for three SLA genes characterized by a different range of sequence variation provided proof of principle for the analysis of poly-miRTSs from a total of 144 M RNA-Seq reads collected from different porcine tissues. Twenty-four novel SNPs were predicted to affect miRNA-binding sites in 19 genes of the SLA region. Seven of these genes (SLA-1, SLA-6, SLA-DQA, SLA-DQB1, SLA-DOA, SLA-DOB and TAP1) are linked to antigen processing and presentation functions, which is reminiscent of associations with disease traits reported for altered miRNA binding to MHC genes in humans. An inverse correlation in expression levels was demonstrated between miRNAs and co-expressed SLA targets by exploiting a published dataset (RNA-Seq and small RNA-Seq) of three porcine tissues. Our results support the resource value of RNA-Seq collections to identify SNPs that may lead to altered miRNA regulation patterns.