Respiratory syncytial virus infection induces a subset of types I and III interferons in human dendritic cells.

Whether respiratory syncytial virus (RSV) induces severe infantile pulmonary disease may depend on viral strain and expression of types I and III interferons (IFNs). These IFNs impact disease severity by inducing expression of many anti-viral IFN-stimulated genes (ISGs). To investigate the impact of RSV strain on IFN and ISG expression, we stimulated human monocyte-derived DCs (MDDCs) with either RSV A2 or Line 19 and measured expression of types I and III IFNs and ISGs. At 24h, A2 elicited higher ISG expression than Line 19. Both strains induced MDDCs to express genes for IFN-ß, IFN-α1, IFN-α8, and IFN-λ1-3, but only A2 induced IFN-α2, -α14 and -α21. We then show that IFN-α8 and IFN-α14 most potently induced MDDCs and bronchial epithelial cells (BECs) to express ISGs. Our findings demonstrate that RSV strain may impact patterns of types I and III IFN expression and the magnitude of the ISG response by DCs and BECs.

High-throughput quantitative real-time RT-PCR assay for determining expression profiles of types I and III interferon subtypes.

Described in this report is a qRT-PCR assay for the analysis of seventeen human IFN subtypes in a 384-well plate format that incorporates highly specific locked nucleic acid (LNA) and molecular beacon (MB) probes, transcript standards, automated multichannel pipetting, and plate drying. Determining expression among the type I interferons (IFN), especially the twelve IFN-α subtypes, is limited by their shared sequence identity; likewise, the sequences of the type III IFN, especially IFN-λ2 and -λ3, are highly similar. This assay provides a reliable, reproducible, and relatively inexpensive means to analyze the expression of the seventeen interferon subtype transcripts.

High-throughput quantitative real-time polymerase chain reaction array for absolute and relative quantification of rhesus macaque types I, II, and III interferon and their subtypes.

Rhesus macaques provide a valuable research and preclinical model for cancer and infectious diseases, as nonhuman primates share immune pathways with humans. Interferons (IFNs) are key cytokines in both innate and adaptive immunity, so a detailed analysis of gene expression in peripheral blood and tissues may shed insight into immune responses. Macaques have 18 IFN genes, of which 14 encode for 13 distinct IFN-α subtypes, and one for IFN-ß. Here, we developed a high-throughput array to evaluate each of the IFN-α subtypes, as well as IFN-ß, IFN-γ and 2 subtypes of IFN-λ. With this array, expression of each IFN species may be quantified as relative to a reference (housekeeping) gene (ΔCq) or fitted to its own 4-point standard curve for absolute quantification (copy number per mass unit RNA). After validating the assay with IFN complementary DNA, we determined the IFN expression profile of peripheral blood mononuclear cells from 3 rhesus macaques in response to TLR agonists, and demonstrated that the profiles are consistent among animals. Furthermore, because the IFN expression profiles differ depending on the TLR stimuli, they suggest different biological functions for many of the IFN species measured, including individual subtypes of IFN-α.

Expression profiles of human interferon-alpha and interferon-lambda subtypes are ligand- and cell-dependent.

Recent genome-wide association studies suggest distinct roles for 12 human interferon-alpha (IFN-α) and 3 IFN-λ subtypes that may be elucidated by defining the expression patterns of these sets of genes. To overcome the impediment of high homology among each of the sets, we designed a quantitative real-time PCR assay that incorporates the use of molecular beacon and locked nucleic acid (LNA) probes, and in some instances, LNA oligonucleotide inhibitors. We then measured IFN subtype expression by human peripheral blood mononuclear cells and by purified monocytes, myeloid dendritic cells (mDC), plasmacytoid dendritic cells (pDC), and monocyte-derived macrophages (MDM), and -dendritic cells (MDDC) in response to poly I:C, lipopolysaccharide (LPS), imiquimod and CpG oligonucleotides. We found that in response to poly I:C and LPS, monocytes, MDM and MDDC express a subtype pattern restricted primarily to IFN-ß and IFN-λ1. In addition, while CpG elicited expression of all type I IFN subtypes by pDC, imiquimod did not. Furthermore, MDM and mDC highly express IFN-λ, and the subtypes of IFN-λ are expressed hierarchically in the order IFN-λ1 followed by IFN-λ2, and then IFN-λ3. These data support a model of coordinated cell- and ligand-specific expression of types I and III IFN. Defining IFN subtype expression profiles in a variety of contexts may elucidate specific roles for IFN subtypes as protective, therapeutic or pathogenic mediators.

TLR9 and TLR7 agonists mediate distinct type I IFN responses in humans and nonhuman primates in vitro and in vivo.

Human I-IFNs include IFN-ß and 13 independently regulated subtypes of IFN-α (I-IFNs). TLR7 and -9 induce I-IFNs, but it is unknown whether their subtype repertoire is similar. This study used new PCR arrays that selectively amplify individual I-IFN subtype genes of human and nonhuman primates to characterize the TLR7- and -9-mediated IFN response in vitro and in vivo. We show that in human PBMCs, TLR7 agonists induce a rapid burst of I-IFN transcripts, consisting primarily of IFN-α1/13, -α2, and -α14. In contrast, TLR9 agonists, regardless of the type used (CpG C-, B-, or D-ODN), prompted slower but sustained expression of IFN-α1/13, -α2, -α7, -α8, -α10, -α14, -α16, and -α21. These qualitative differences were translated downstream as differences in the pattern of IFN-inducible genes. In macaque PBMCs, imiquimod produced a short burst of IFN mRNA, dominated by IFN-α8, whereas C- or D-ODN induced a greater than tenfold increase in transcripts for all I-IFN subtypes by 12 h of culture. Differences were more evident in vivo, where TLR7 and -9 agonists induced significantly different levels of I-IFN transcripts in skin. Although the rates of gene transcription differed significantly for individual TLR9 agonists, their IFN-α subtype signature was almost identical, indicating that the type of receptor dictates the quality of the I-IFN response in vitro and in vivo. These results may underlie the differential therapeutic effects of TLR7 and -9 agonists and should inform future clinical studies.